The Grassland Fragmentation Experiment in the Swiss Jura Mountains: A Synthesis

Bruno Baur; Hans-Peter Rusterholz; Brigitte Braschler

doi:10.3390/d15020130

Baur, Bruno;Rusterholz, Hans-Peter;Braschler, Brigitte

2023-01-18 00:00:00

diversity Review The Grassland Fragmentation Experiment in the Swiss Jura Mountains: A Synthesis Bruno Baur *, Hans-Peter Rusterholz and Brigitte Braschler Department of Environmental Sciences, University of Basel, Bernoullistrasse 30, 4056 Basel, Switzerland * Correspondence: bruno.baur@unibas.ch Abstract: We synthesize ﬁndings from a 7-year fragmentation experiment in species-rich, nutrient- poor, dry calcareous grasslands in the north-western Jura mountains, Switzerland. We used a standardized approach with 48 fragments (0.25–20.25 m ) and corresponding control plots in three sites. The 5-m-wide isolation area around the fragments was maintained by frequent mowing. Frag- ments experienced various ecological changes, e.g., plant biomass increased along fragment edges. We examined fragmentation effects on species richness and composition, abundance, genetic diversity, functional diversity, species traits and species interactions (pollination, herbivory, parasitism, disease) in a wide array of invertebrate (gastropods, spiders, woodlice, various insect groups) and plant taxa. Responses to fragmentation differed between taxonomical groups and species. While species richness and individual density were lower in fragments in some groups, the opposite was true for other groups. Fragmentation effects were most pronounced on species interactions; however, some effects only occurred with a delay. For example, fragmentation inﬂuenced foraging patterns of bumblebees, affecting pollination, which in turn resulted in a decreased outcrossing frequency and reduced genetic diversity in a focal plant species. We highlight key ﬁndings of the experiment and emphasize their implications for grassland conservation. Keywords: biodiversity; calcareous grasslands; environmental change; functional dispersion; habitat fragmentation; invertebrates; population dynamics; time lags Citation: Baur, B.; Rusterholz, H.-P.; 1. Introduction Braschler, B. The Grassland The current biodiversity loss due to environmental change is of great concern glob- Fragmentation Experiment in the ally [1,2]. Habitat fragmentation is generally considered to be one of the major drivers Swiss Jura Mountains: A Synthesis. Diversity 2023, 15, 130. https:// of this loss [1,3–6]. Fragmentation reduces the total area of original habitat, changes the doi.org/10.3390/d15020130 environmental conditions in remnants, creates isolated subpopulations, disrupts individual behavior [7], interrupts the exchange of individuals and genes among populations [8], and Academic Editor: Simona Maccherini alters species interactions [9] and ecological processes [10]. Thus, habitat fragmentation can Received: 25 November 2022 inﬂuence an entire suite of processes, ranging from individual behavior through population Revised: 13 January 2023 dynamics to ecosystem ﬂuxes. Accepted: 14 January 2023 Habitat fragmentation occurs at different spatial scales [11,12]. It ranges from small Published: 18 January 2023 breaks in otherwise homogeneous habitat to widely scattered fragments in a hostile ma- trix [13]. The relevant spatial scale is different for each species [14,15]. The response of a species to fragmentation depends on its dispersal ability, life history, and competitiveness, and on the type and size of the fragments, and the permeability for dispersing individuals Copyright: © 2023 by the authors. of the matrix surrounding the fragment [4,16]. Licensee MDPI, Basel, Switzerland. Large-scale fragmentation on the landscape level entails many challenges unfavorable This article is an open access article to rigorous investigation. Habitat fragments in a landscape differ in size, shape, age (time distributed under the terms and since isolation), distance to large homogeneous habitat, and distance to other fragments: conditions of the Creative Commons all of which make any proper replication of the investigation unit difﬁcult [17]. Further- Attribution (CC BY) license (https:// more, corresponding control areas are frequently lacking [18]. Experimental studies with creativecommons.org/licenses/by/ 4.0/). Diversity 2023, 15, 130. https://doi.org/10.3390/d15020130 https://www.mdpi.com/journal/diversity Diversity 2023, 15, 130 2 of 31 replicates and controls can, therefore, represent a valuable and complementary approach, even if they do not reach the spatial scale of the landscape [10,19]. In a global overview, Debinski and Holt [19] summarized the main features of 20 experimental fragmentation studies: 14 were conducted in grasslands or old ﬁelds and 6 in forests. The experimental studies were grouped into ﬁve broad focal issues: species richness, the interplay of connectivity versus isolation, individual species behavior, de- mography, and genetics [19]. However, Debinski and Holt [19] also reported gaps in their overview. For example, species interactions were relatively poorly studied, an exception being predation. Furthermore, time lags of species’ responses to fragmentation have been rarely studied. One of the twenty experimental studies was the “Grassland fragmentation experiment in the Swiss Jura mountains” conducted by researchers from University of Basel over a period of 7 years [17]. It aimed to examine the effects of grassland fragmentation on various aspects of diversity and population dynamics in plants and various groups of invertebrates, as well as on species interactions. Nutrient-poor, dry calcareous grasslands served as the model ecosystem for this mesocosm experiment. In the north-western Jura mountains in Switzerland, nutrient-poor, dry calcareous grasslands harbor a huge variety of invertebrates and vascular plants [20,21]. This type of grassland is of high conservation importance in Europe (habitat type of the EU Habitats Directive; [22]). The sensitive habitat type has diminished dramatically during recent decades due to changes in agricultural practices, such as increased fertilization [23] or abandonment and reforestation [24,25]. For example, in the Passwang region, 24 km south of Basel, unfertilized grasslands decreased by 78% between 1950 and 1985 [26]. The rapid habitat change and fragmentation of the grasslands have resulted in signiﬁcant losses of specialist plant species [23], and the same may be true for invertebrates as well [21]. In these grasslands, the majority of the plant species are perennial while many of the invertebrates have a life cycle of 1 year or even shorter, suggesting that the latter are suitable model organisms to study short-term responses to experimental habitat fragmentation. With the short generation times of most of the species in these communities, an experimental approach in grasslands potentially offers the opportunity to study patterns in mere years that would otherwise require decades to observe for organisms such as trees or large mammals in forest fragments. Many of the ﬁndings of this 7-year ﬁeld experiment have been published in various independent articles focusing on distinct aspects. However, a general overview of the main results is so far lacking. We present here for the ﬁrst time a synthesis of the research conducted in the grassland fragmentation experiment in the Swiss Jura mountains. We highlight several key ﬁndings and emphasize their implications for grassland conservation. We also discuss the advantages and limits of this kind of mesocosm experiment with randomized fragments and corresponding control plots replicated over three sites. 2. A Replicated, Controlled 7-Year Fragmentation Experiment 2.1. Grasslands Examined For the fragmentation experiment, we rented c. 1.5 ha of semi-natural, nutrient-poor calcareous grassland at each of three sites in the Swiss Jura mountains: Movelier (midpoint of site: 47.413558 N, 7.323867 E, 770 m a.s.l.), Nenzlingen (47.448586 N, 7.567864 E, 510 m a.s.l.), and Vicques (47.363867 N, 7.426114 E, 590 m a.s.l.; Figure 1). We took over the management for 7 years in agreement with the owners. The rental agreement included a provision that no long-term changes in vegetation type and soil characteristics were allowed (e.g., no application of herbicides or fertilizer). We fenced the rented areas to exclude large herbivores and human disturbances and only mowed the grasslands at the end of the growing season in each year to prevent encroachment of shrubs and trees. Diversity Diversity 2023 2023,, 15 15,, x FOR 130 PEER REVIEW 3 of 3 of 31 31 Figure 1. Study sites with the twelve experimental blocks photographed on 11 May 1994. Three Figure 1. Study sites with the twelve experimental blocks photographed on 11 May 1994. Three experimental blocks were near Movelier (left), five near Nenzlingen (middle), and four near Vicques experimental blocks were near Movelier (left), ﬁve near Nenzlingen (middle), and four near Vicques (right) in dry calcareous grasslands in the Jura mountains. Block halves containing fragments sur- (right) in dry calcareous grasslands in the Jura mountains. Block halves containing fragments rounded by a mown isolation area are clearly visible, while block halves with control plots are in- surrounded by a mown isolation area are clearly visible, while block halves with control plots distinguishable from the adjacent undisturbed grasslands. The study sites were fenced to exclude are indistinguishable from the adjacent undisturbed grasslands. The study sites were fenced to grazing by large herbivores. In the study site near Nenzlingen, other experiments were also con- exclude grazing by large herbivores. In the study site near Nenzlingen, other experiments were also ducted, and their infrastructure is visible between the blocks. Photos: M. Wurtz. conducted, and their infrastructure is visible between the blocks. Photos: M. Wurtz. The distances among sites ranged from 9.5 to 18.8 km. The grassland near Movelier The distances among sites ranged from 9.5 to 18.8 km. The grassland near Movelier was situated on a SSE-facing slope with an inclination of 20–22°, the one in Nenzlingen was situated on a SSE-facing slope with an inclination of 20–22 , the one in Nenzlingen on a SW-facing slope (19–22° inclination), and the one in Vicques on a SE-facing slope (15– on a SW-facing slope (19–22 inclination), and the one in Vicques on a SE-facing slope 27°). The three grasslands belong to the Teucrio-Mesobrometum association and were (15–27 ). The three grasslands belong to the Teucrio-Mesobrometum association and were previously used as pasture for centuries [26,27]. Compared to Movelier, soil depth was previously used as pasture for centuries [26,27]. Compared to Movelier, soil depth was shallow in Nenzlingen and Vicques, with the bedrock exposed in several places, resulting shallow in Nenzlingen and Vicques, with the bedrock exposed in several places, resulting in drier conditions. Mixed deciduous forest bordered all three sites. The sites are described in drier conditions. Mixed deciduous forest bordered all three sites. The sites are described in detail in Baur et al. [21]. in detail in Baur et al. [21]. 2.2. Fragmentation Experiment 2.2. Fragmentation Experiment The experimental design chosen considered the following points: (1) a blocked de- The experimental design chosen considered the following points: (1) a blocked design sign with replicated fragments of different size with corresponding control plots nearby; with replicated fragments of different size with corresponding control plots nearby; (2) the (2) the positions of fragments and control plots were randomized within block halves; (3) positions of fragments and control plots were randomized within block halves; (3) three three different grasslands of the same vegetation type with similar aspects were used to different grasslands of the same vegetation type with similar aspects were used to account account for slightly different local species pools and varying environmental conditions. for slightly different local species pools and varying environmental conditions. We created experimental fragments in formerly continuous grassland by mowing the We created experimental fragments in formerly continuous grassland by mowing area surrounding them in May 1993 (Figure 2). We then maintained this kind of fragmen- the area surrounding them in May 1993 (Figure 2). We then maintained this kind of tation over 7 years by frequently mowing the isolation area (hereafter matrix) surrounding fragmentation over 7 years by frequently mowing the isolation area (hereafter matrix) the fragments (7–11 times per year) throughout the growing season. The sward height of surrounding the fragments (7–11 times per year) throughout the growing season. The the matrix was maintained at a few centimeters (Figure 2). Cuttings from the mowing sward height of the matrix was maintained at a few centimeters (Figure 2). Cuttings from were removed. the mowing were removed. We used a block design in which fragments were isolated by 5 m from the nearest We used a block design in which fragments were isolated by 5 m from the nearest unmown grassland and from other fragments, a distance representative of the width of unmown grassland and from other fragments, a distance representative of the width of the typical road in this region. In a mirrored design, we marked corresponding control the typical road in this region. In a mirrored design, we marked corresponding control plots plots 5 5 m m fro from m the s the same ame e edge dge wi within thin the the contin continuous uous undistu undisturb rbed ed habitat habitat ( (Figur Figure e 2) 2).. Each Each block block con contained tained fr fragments agments of th of thr ree d ee idif ffer fer ent sizes, sep ent sizes, separated arated by by 5 m 5 of mown m m of mown atrix matrix: : one one large lar fra ge gm fragm ent m ent easu measuring ring 4.5 m4.5 × 4. m 5 m , one sm 4.5 m, one all fr small agmefragment nt (1.5 m × (1.5 1.5 m m ) , an 1.5 d two m), and tiny two fragm tiny ents fragments (0.5 m × 0.(0.5 5 m)m , and the 0.5 m), ir corr and esp their onding corr co esponding ntrol plots contr (Figure ol plots 2). We (Figur random e 2). - W ize ed randomized the position the s ofpositions the fragm ofen the t–cfragment–con ontrol plot patr irs ol wi plot thin pairs a blwithin ock. Ina to block. tal, we ha In total, d a we had a sample size of 12 large fragments, 12 small fragments, and 24 tiny fragments, sample size of 12 large fragments, 12 small fragments, and 24 tiny fragments, with 48 cor- with 48 corresponding control plots. However, not all experimental plots were used for responding control plots. However, not all experimental plots were used for all studies. all studies. Three blocks were located in Movelier, five in Nenzlingen, and four in Vicques. Within a study site, the distances between the nearest edges of blocks ranged from 25 to 135 m. Further details on the experimental design can be found in Zschokke et al. [28]. Diversity 2023, 15, x FOR PEER REVIEW 4 of 31 Diversity 2023, 15, 130 4 of 31 Figure 2. Experimental design. Starting in 1993, areas of three semi-natural, dry calcareous grass- Figure 2. Experimental design. Starting in 1993, areas of three semi-natural, dry calcareous grasslands lands in the Jura mountains (Switzerland) were experimentally fragmented by regular mowing in the Jura mountains (Switzerland) were experimentally fragmented by regular mowing around the around the fragments. A block (29 m × 32 m) fragments. A block (29 m 32 contai m) contained ned one one large (4.5 m × 4 large (4.5 m 4.5 .5 m), m), one one small (1.5 small (1.5 m m × 1.5 m) and two tiny (0.5 m 0.5 m) fragments, as well as corresponding control plots in unmown vegetation. 1.5 m) and two tiny (0.5 m × 0.5 m) fragments, as well as corresponding control plots in unmown This type of fragmentation was maintained till the end of 1999. Non-invasive methods preventing vegetation. This type of fragmentation was maintained till the end of 1999. Non-invasive methods trampling and harvesting of individuals were applied except in the ﬁnal year. Photos: mowing the preventing trampling and harvesting of individuals were applied except in the final year. Photos: matrix: B. Baur (upper left); fragments with a mobile working platform: B. Braschler (lower left). mowing the matrix: B. Baur (upper left); fragments with a mobile working platform: B. Braschler (lower left). 2.3. Weather Conditions during the 7-Year Study Annual ﬂuctuations in weather conditions (precipitation, temperature) may affect Three blocks were located in Movelier, five in Nenzlingen, and four in Vicques. ﬁndings from a survey in a particular year. The annual amount of precipitation (obtained from the ofﬁcial weather station in Delémont, 6.9 km from Movelier, 19.5 km from Nenzlin- Within a study site, the distances between the nearest edges of blocks ranged from 25 to gen, 5.8 km from Vicques) was 21.7% (1996) and 38.7% (1999) higher, respectively, than the 135 m. Further details on the experimental design can be found in Zschokke et al. [28]. long-term average (norm period 1991–2020; MeteoSwiss [29]; Table 1). In the remaining ﬁve years of the experiment, the annual precipitation was close to the long-term average. 2.3. Weather Conditions during the 7-Year Study Mean annual temperature was 14.7% below long-term average in 1996 (Table 1). This was mainly due to the cold winter (Table 1). In the other years, the mean annual temperature Annual fluctuations in weather conditions (precipitation, temperature) may affect and the mean temperature during the growing season (April to September) were both close findings from a survey in a particular year. The annual amount of precipitation (obtained to the long-term average (Table 1). It should be noted that the experiment was conducted from the official weather station in Delémont, 6.9 km from Movelier, 19.5 km from before the pronounced increase in annual temperature witnessed after 2000 [29]. Nenzlingen, 5.8 km from Vicques) was 21.7% (1996) and 38.7% (1999) higher, respectively, 2.4. Methodology of the Surveys than the long-term average (norm period 1991–2020; MeteoSwiss [29]; Table 1). In the re- Various survey methods were applied in the course of the 7-year study (Table 2). In maining five years of the experiment, the annual precipitation was close to the long-term choosing the adequate method to tackle a question, one needs to consider that we were average. Mean annual temperature was 14.7% below long-term average in 1996 (Table 1). not allowed to alter the habitat permanently and that we had to avoid sampling impacts This was mainly due to the cold winter (Table 1). In the other years, the mean annual on the population sizes of the various organisms in later years of the experiment. Thus, in temperature and the theme ﬁrst an six temper years of ature the experiment, during the g we r exclusively owing season used (Apr non-invasive il to Sep methods tember) such as simple observational counts, mark-release-resight, and life traps (Table 2). Pitfall trapping were both close to the long-term average (Table 1). It should be noted that the experiment was only used in the ﬁnal year of the study. The main survey methods are brieﬂy described was conducted before the pronounced increase in annual temperature witnessed after in the following paragraphs. For further details on survey methodology, sample sizes, and 2000 [29]. statistics, see the respective papers. 2.4. Methodology of the Surveys Various survey methods were applied in the course of the 7-year study (Table 2). In choosing the adequate method to tackle a question, one needs to consider that we were not allowed to alter the habitat permanently and that we had to avoid sampling impacts on the population sizes of the various organisms in later years of the experiment. Thus, in the first six years of the experiment, we exclusively used non-invasive methods such as simple observational counts, mark-release-resight, and life traps (Table 2). Pitfall trapping was only used in the final year of the study. The main survey methods are briefly Diversity 2023, 15, 130 5 of 31 Table 1. Climatic conditions in the years of the study compared with the norm conditions (mean values from 1991–2020). Data on precipitation and temperature from the weather station in Delémont close to the sites in Movelier and Vicques are presented (data obtained from MeteoSwiss [29]). Percent deviation from norm a,b values are shown in brackets . Annual Precipitation Mean Annual Mean Temperature Min Temperature Max Temperature Year [mm; % Deviation] Temperature [ C; % Deviation] in Apr–Sept [ C; % Deviation] in Apr–Sept [ C] in Apr–Sept [ C] 1993 881.0 (4.2) 9.2 (6.5) 14.6 (4.8) 1.6 33.4 1994 936.8 (+1.9) 10.7 (+8.7) 15.5 (+0.5) 2.6 34.6 1995 1118.9 (+21.7) 9.5 (3.5) 14.4 (6.2) 1.1 34.2 1996 832.9 (9.4) 8.4 (14.7) 13.9 (9.3) 3.8 30.9 1997 815.1 (11.3) 9.3 (5.5) 14.6 (5.1) 4.8 30.2 1998 925.0 (+0.6) 9.2 (6.5) 14.8 (3.8) 3.0 35.4 1999 1275.3 (+38.7) 9.8 (0.4) 15.7 (+2.3) 0.4 32.8 a a a a b b Norm 919.4 9.8 15.4 6.4 37.7 Norm values for annual precipitation, annual mean temperature, and mean temperature of the active season Apr–Sept were calculated as means from annual totals (precipitation), annual means (annual temperature), and monthly means from Apr–Sept for the years 1991–2020. Lowest and highest temperature, respectively, measured for the years 1991–2020. Table 2. Overview of publications presenting ﬁndings of the grassland fragmentation experiment in the Swiss Jura mountains. a b Publication Issue(s) Addressed Year(s) of Experiment Organism Group(s) Method(s) Applied Assessing species richness and Classical plant survey, nest counting in species diversity in several Grasses, forbs, ants, butterﬂies, ants, direct census of butterﬂies and Zschokke et al. 2000 [28] taxonomical groups, recording the 4 grasshoppers, and gastropods grasshoppers, wet cardboard sheets as relative abundance of the 65 most traps for gastropods common species Temporal and among-site variation Mapping Bromus erectus inﬂorescences Target species: Bromus erectus; Fungus: Groppe et al. 2001 [30] in fungal infestation of a 1–3 and assessing the fungal infestation of Epichloë bromicola grass species the inﬂorescences Diversity 2023, 15, 130 6 of 31 Table 2. Cont. Publication Issue(s) Addressed Year(s) of Experiment Organism Group(s) Method(s) Applied Mapping the spatial distribution of S. ofﬁcinalis plants in small fragments and Flower visitation rate, taxonomic Target species: Stachys ofﬁcinalis; control plots, recording frequency of Goverde et al. 2002 [31] composition of ﬂower visitors, and 6 Pollinator: mainly Bombus veteranus but different ﬂower visitors, and foraging bumblebee foraging behavior also other ﬂower visitors behavior of B. veteranus in three blocks at two study sites Target species: Trifolium repens, potential Provision of standardized food Quantifying the extent of grazing Ledergerber et al. 2002 [32] 4 grazers: 12 gastropod species, (seedlings of Trifolium repens) in two damage to an herb 15 grasshopper species short periods Inter- and intraspeciﬁc competition; Ants (all species; Lasius paralienus Braschler & Baur 2003 [33] 4, 7 Spatial distribution of ant nests edge effects separately) Infestation rates and abundances of Aphids (all species present); plant Counting aphids and aphid mummies, Braschler et al. 2003 [34] aphids; parasitism rates of aphids; 57 species infested by aphids; ant species only two study sites ant-tending rates tending aphids Counting ants at baits and natural sugar Interspeciﬁc competition Ants (all species; Lasius paralienus Braschler & Baur 2005 [35] 4, 7 resources; pitfall traps; ant nest density, and dominance separately) only small and large fragments Harvesting of plant biomass above a Above-ground biomass of grasses and Quantifying above- and height of 5 cm in 3 years; harvesting of Dolt et al. 2005 [36] 46 herbs, and overall below-ground below-ground plant biomass root-biomass using soil cores in the plant biomass 6th year Assessment of leaf area consumed in Target species: Stachys ofﬁcinalis; spring, summer, and autumn; two small Stoll et al. 2006 [37] Extent of grazing damage on leaves 6 potential grazers: and large fragments each in two gastropods, grasshoppers randomly chosen blocks per site Colonization and extinction rate Joshi et al. 2006 [38] 1, 2, 3, 4, 7 Vascular plants Standardized vegetation survey of plants Effects of fragmentation and Visual survey in large fragments and frequent mowing on orthopteran Orthopterans, also the suborders control plots, and corresponding plots Braschler et al. 2009 [39] 17 species richness, density, and Ensifera and Caelifera separately in the mown matrix; surveys several species composition times per season in each year Diversity 2023, 15, 130 7 of 31 Table 2. Cont. Publication Issue(s) Addressed Year(s) of Experiment Organism Group(s) Method(s) Applied Quantifying the population Six gastropod species (Cochlicopa lubrica, dynamics (population sizes, Vertigo pygmaea, Pupilla muscorum, Stoll et al. 2009 [40] 24 Mark-release-resight approach extinction, and recolonization Punctum pygmaeum, Helicella itala, and frequencies) of six land snail species Trichia plebeia) Counting the number of insects visiting Flower visitation rate, foraging S. ofﬁcinalis inﬂorescences; recording the behavior of pollinators, plant foraging behavior of bumblebees; Target species: Stachys ofﬁcinalis; ﬂower Rusterholz & Baur 2010 [41] reproductive characteristics, 1, 4, 7 assessing seed characteristics; visiting insects, bumblebee species outcrossing frequency, determining of outcrossing frequency genetic diversity and genetic diversity of seedlings using RAPD in the fourth and seventh year. Two pitfall traps per large and small Species richness, density, species fragment and control plot, emptied Gastropods, ants, ground beetles, rove Braschler & Baur 2016 [42] composition, body size, and 7 every 2 weeks for a total of seven beetles, Orthoptera, spiders, woodlice habitat preferences collections from late spring to late summer Temporal and among-site variation in species richness, individual density, species composition, Gastropods (all gastropods or 81 cardboard traps, one night per year Braschler et al. 2022 [43] 47 functional dispersion, snails only) in autumn in large plots morphological and life-history traits, and habitat preferences a b 1: 1993 (initiation of the experiment) to 7: 1999 (ﬁnal year of the experiment). if not otherwise stated all fragments and control plots were surveyed. Diversity 2023, 15, 130 8 of 31 To estimate the above-ground biomass, Dolt et al. [36] harvested plants by clipping them at a 5 cm height above ground level in subsamples of fragments and control plots of all sizes at the end of the growing season in the fourth to sixth year of the experiment. In the sixth year, they assessed below-ground biomass (root biomass) using soil cores in all plots in six out of the twelve blocks. The sampling design was adjusted to detect potential edge effects on plant biomass [36]. Two methods were used to survey ants [33,35]. Nest counts were considered as a proxy for the number of colonies. This survey was conducted in all fragments and control plots in the fourth year of the experiment as well as in large fragments and control plots in the ﬁnal year of the study. Nests were identiﬁed by carefully searching for their entrances and by following workers returning from baits consisting of a mix of turkey meat and sugar solution. To assess forager density, ants were also counted at baits in large fragments and control plots in the ﬁnal year of the experiment. In this case, baits consisted of small plastic dishes ﬁlled with sugar solution and were placed in the center of each 50 cm 50 cm subplot of fragments and control plots. Ants were counted for 2 min, 1 h after setting a bait. Wet sheets of cardboard attract gastropods. Therefore, to assess gastropod diversity and density, we placed cardboard sheets in the center of each 50 cm 50 cm subplot of each fragment and control plot for one rainy autumn night from the fourth to ﬁnal year of the experiment [43]. Sheets were checked for gastropods attached to them at dawn, and individuals were identiﬁed in situ. Where examination with a dissecting microscope was required, individuals were subsequently released in the plot from which they originated. Orthopterans were surveyed twice per year in all 7 years of the experiment in each large fragment, large control plot, and an equivalent plot in the mown isolation area surrounding the fragment. The plots were carefully searched for orthopterans with the help of a bamboo rod to ﬂush out individuals so that individuals could be counted without capturing them [39]. In the ﬁnal year of the study, two pitfall traps were set in each large and small fragment, and their respective control plots [42]. Traps were 6.7 cm in diameter and partly ﬁlled with 10% glycerol solution, which is non-attractive to arthropods. Traps were emptied every 2 weeks throughout the period of highest invertebrate activity from 6 May to 12 August 1999 for a total of seven collections. For analysis, the data from both traps in each plot were averaged. To examine fragmentation-related changes in genetic diversity in the self-compatible plant Stachys ofﬁcinalis, inﬂorescences were harvested in small and large fragments and control plots in two study sites in the third and seventh year of fragmentation [41]. Seeds were allowed to germinate. Genetic diversity was then determined by using RAPD-PCR with DNA extracted from young leaves. 2.5. Procedure of this Synthesis In the course of the 7-year ﬁeld experiment, various MSc and PhD students used this setting to conduct a part or all of their thesis projects. They considered a wide range of ecological questions and taxonomical groups. The ﬁndings were published over a period of more than 20 years (Table 2). As a consequence, in some groups, taxonomic nomenclature changed for a signiﬁcant proportion of the examined species. In this synthesis, we adjusted species names to the currently accepted names. For example, the plant Stachys ofﬁcinalis, which was the focus of several papers, was previously named Betonica ofﬁcinalis. Statistical methods have been further developed in the past decades. For this synthesis, we thus used the original data to analyze species composition and functional dispersion for some taxonomical groups. Data used for these analyses are presented in the supplementary material (Tables S1–S5). In contrast to these new analyses, test statistics presented in original articles were not repeated in the synthesis. The variety of students in this project resulted in a slightly different use of the termi- nology concerning plot size across the published articles (particularly in small and tiny plots). This was standardized for this synthesis (Figure 2). Diversity 2023, 15, 130 9 of 31 3. Findings 3.1. High Species Richness in the Studied Grasslands The various surveys of the different taxonomical groups conducted in the course of the 7-year study conﬁrm the extraordinarily high species richness of these nutrient-poor, dry calcareous grasslands (Table 3). In this context, it is important to note that any survey just represented a snapshot, which did not capture the full species pool. 3.2. Increased Primary Productivity in the Edge Zone of Fragments Productivity has frequently been considered as one of the most important factors determining plant diversity and ecosystem function in grasslands, with the highest diversity often at the medium level of productivity at smaller spatial scales [44–46]. In respect to habitat fragmentation, changes in plant productivity are assumed to inﬂuence the diversity of plants as well as that of higher trophic levels. For example, changes in plant productivity may alter the density and species composition of herbivores [34]. In our experiment, above-ground biomass was higher in fragments than in the control plots in all 3 years. However, the difference between fragments and control plots in above- ground biomass varied between years (38% higher in fragments in the fourth, 14% in the ﬁfth, and 17% in the sixth year) and among sites [36]. Plot size inﬂuenced the above- ground biomass only in the fourth year of fragmentation. The fragmentation impact was more pronounced in tiny plots than in small and large plots indicating the importance of edge effects [36]. Thus, in contrast to many other fragmentation effects recorded in our experiment, the effect on plant biomass decreased from the fourth to the sixth year of the experiment [36], showing that some early responses may become weaker over time. Root biomass used as a surrogate for below-ground biomass was 52% higher in fragments than in corresponding control plots [36]. In addition, the fragmentation effect on root biomass was less pronounced in small plots (15%) than in large and tiny plots (62% and 86%, respectively; [36]). Furthermore, no edge effect on below-ground biomass could be detected. Interestingly, below-ground biomass was not correlated with above-ground biomass of the same plots. These results conﬁrm that small-scale fragmentation can affect both the above- and below-ground plant biomass of calcareous grasslands. The biomass increase was mainly a result of a higher grass density, which might change competitive interactions among plants as well as plant species composition [36]. Diversity 2023, 15, 130 10 of 31 Table 3. Number of species recorded in various taxonomical groups in the three study sites (and overall). Some taxonomical groups were surveyed at different times during the experiment using different methods and are thus listed more than once. In a few groups, the number of species recorded was not reported in publications. In these cases, the ﬁgures are based on the raw data from those surveys. Taxonomic Group Movelier Nenzlingen Vicques Overall Year and Sampling Effort Vascular plants 116 111 96 143 1993 and 1994; all fragments and control plots [21] Gastropods 16 21 15 22 1994; all fragments and control plots [21] Gastropods 15 14 10 19 1996–1999; cardboard traps in all large fragments and control plots [43] 1999; 2 pitfall traps each in all small and large fragments and control plots Gastropods 18 18 10 22 exposed for 14 weeks [42] Spiders 63 60 66 108 1994; 9 pitfall traps per site in the surroundings of blocks [21] 1999; 2 pitfall traps each in all small and large fragments and control plots Spiders 52 76 58 99 exposed for 14 weeks [42] 1999; 2 pitfall traps each in all small and large fragments and control plots Woodlice 3 4 3 5 exposed for 14 weeks [42] Orthopterans 16 13 10 17 1994; all fragments and control plots [21] 1993–1999; 2 surveys per year in large fragments and control plots and a Orthopterans 21 17 12 19 comparable plot of mown matrix in each block [39] 1998; vouchers were collected from all aphid colonies in tiny fragments and Aphids NA 13 17 24 control plots and subsamples in small and large fragments and control plots in Nenzlingen and Vicques [34] Ants 12 11 7 14 1996; nest counts assisted by following foragers attracted to sugar baits [28] 1999; 2 pitfall traps each in all small and large fragments and control plots Ants 16 20 15 24 exposed for 14 weeks [42] Butterﬂies 46 32 40 46 1993 and 1994; three 10 m x 10 m plots per site adjacent to the blocks [21] Butterﬂies 26 19 20 29 1996; 13 30 min observation per block [28] Ground beetles 19 19 21 38 1994; 9 pitfall traps per site in the surroundings of blocks [21] 1999; 2 pitfall traps each in all small and large fragments and control plots Ground beetles 19 20 18 33 exposed for 14 weeks [42] 1999; 2 pitfall traps each in all small and large fragments and control plots Rove beetles 14 25 16 35 exposed for 14 weeks [42] NA, not assessed Diversity 2023, 15, 130 11 of 31 3.3. Differing Responses by Taxonomic Groups to Altered Conditions in Mown Isolation Area The type of the surrounding area (matrix) and the extent of the difference between the matrix habitat and the fragment habitat (remnant of original habitat) affect population dynamics of many species, including their dispersal and foraging behavior [47–49]. From the perspective of taxa (species or groups of related species), a particular matrix is perceived in a different way, resulting in taxa-speciﬁc responses [49]. Furthermore, a large difference between the matrix and the original habitat type hinders the movement of particular species across the fragmented landscape. Thus, the matrix and its permeability are often key factors determining which species are present in fragments [48,50]. In our habitat fragmentation experiment, the matrix can be characterized by vegetation height, total cover of vegetation, and ﬂower density. In the course of the growing season (April–September), we recorded the three vegetation characteristics on 5 days in the matrix and in the undisturbed control area of each block in the ﬁrst, third, and seventh year of the study. The vegetation of the matrix changed over the course of the experiment. By the ﬁnal year, vegetation height in the matrix was reduced by 50%, total vegetation cover by 34%, and ﬂower density by 64% compared to the measures of the ﬁrst year [41]. In relation to the vegetation in the undisturbed control area in the ﬁnal year, vegetation height in the matrix was reduced by 95%, total vegetation cover by 40%, and ﬂower density by 85% [51]. The mown matrix differed from the experimental fragments in air temperature close to the ground [28]. Mean ground air temperature was slightly but signiﬁcantly higher in the short turf of the matrix (pooled data: 15.6 C) than in the vegetation of the fragments (14.9 C) in late summer (31 August to 12 September 1995). The mean daily maximum ground air temperature showed a sharp change at the edge of fragments (Figure 3). Overall, the mean daily maximum ground air temperature was higher in the matrix area (pooled data: 36.5 C) than inside the fragments (26.2 C; [28]). Similarly, the mean daily minimum ground air temperature changed abruptly at the fragment edge (Figure 3). The daily minimum ground air temperature was lower in the matrix (pooled data: 8.5 C) than in the fragments (10.5 C). The minimum temperatures measured on the ground surface in both the matrix and the fragments were lower than the minimum air temperatures recorded under standard conditions (shaded place, 2 m above ground, situated 30 m from the fragments), whereas the maximum temperatures on the ground surface were higher than those measured under standard conditions (Figure 3), indicating the large daily temperature ﬂuctuation at the ground surface [28]. The matrix also served as temporal habitat for some invertebrate species during part of the day or season. For example, 12 out of 19 species of Orthoptera, which were recorded in the experimental blocks during repeated visual surveys in every year of the study, were also observed in the mown matrix [39]. However, both species richness and individual density were reduced in the mown matrix when compared to either fragments or control plots [39]. Considering orthopteran suborders separately, of half of the Ensifera species, no individuals were ever observed in the matrix, whereas individuals of most Caelifera species did use the matrix, even if some of those species were not abundant there [39]. This indicates that the isolation effect of the matrix differed within all taxonomic ranks from species to higher taxa. Diversity 2023, 15, x FOR PEER REVIEW 11 of 31 Diversity 2023, 15, 130 12 of 31 Figure 3. Temperature difference between fragments (green) and the mown isolation area (light Figure 3. Temperature difference between fragments (green) and the mown isolation area (light green). Air temperature close to the ground was measured at different distances to the fragment edge green). Air temperature close to the ground was measured at different distances to the fragment both inside and outside large fragments in Vicques. Temperature was recorded every 10 min along six edge both inside and outside large fragments in Vicques. Temperature was recorded every 10 min logger transect lines from 31 August to 12 September 1995, a period with no rain. For comparison, air along six logger transect lines from 31 August to 12 September 1995, a period with no rain. For temperature at 2 m above ground was measured nearby inside a shaded box. Red dots display mean comparison, air temperature at 2 m above ground was measured nearby inside a shaded box. Red daily maximum temperature (with SD), while blue dots refer to mean daily minimum temperature. dots display mean daily maximum temperature (with SD), while blue dots refer to mean daily min- Redrawn from Zschokke et al. [28]. imum temperature. Redrawn from Zschokke et al. [28]. 3.4. Contrasting Effects on Species Richness and Diversity 3.4. Contrasting Effects on Species Richness and Diversity 3.4.1. Effects on Species Richness 3.4.1. Effects on Species Richness Zschokke et al. [28] assessed the effect of grassland fragmentation on the species rich- ness of vascular plants (grasses and forbs), ants, butterﬂies, grasshoppers, and gastropods Zschokke et al. [28] assessed the effect of grassland fragmentation on the species rich- in all fragments and control plots in the fourth year of the experiment. More grass species ness of vascular plants (grasses and forbs), ants, butterflies, grasshoppers, and gastropods and fewer butterﬂy species were recorded in fragments than in the corresponding control in all fragments and control plots in the fourth year of the experiment. More grass species plots. However, fragments and control plots did not differ in species richness of forbs, ants, and fewer butterfly species were recorded in fragments than in the corresponding control grasshoppers, and gastropods [28]. plots. However, fragments and control plots did not differ in species richness of forbs, Braschler and Baur [42] used data from pitfall traps to examine the species density ants, grasshoppers, and gastropods [28]. (number of species per sampling unit) of several groups of invertebrates in the ﬁnal year of theBrasch experiment. ler and The Ba experimental ur [42] used d fragmentation ata from af piftf ected all tr the apspecies s to exam density ine th ofe sp spiders ecies and density woodlice (Figure 4). Spider species density was lower in fragments than in control plots, (number of species per sampling unit) of several groups of invertebrates in the final year while woodlouse species density was higher in fragments. Species density of gastropods, of the experiment. The experimental fragmentation affected the species density of spiders ants, ground beetles, and that of rove beetles did not differ between fragments and control and woodlice (Figure 4). Spider species density was lower in fragments than in control plots (Figure 4). The lack of a fragmentation effect on gastropod species richness matched plots, while woodlouse species density was higher in fragments. Species density of gas- the ﬁndings from a survey using a different trapping method (wet cardboard sheets) tropods, ants, ground beetles, and that of rove beetles did not differ between fragments in four years (fourth to ﬁnal year; Braschler et al. [43]). Similarly, the non-response to and control plots (Figure 4). The lack of a fragmentation effect on gastropod species rich- fragmentation by ant species was upheld by two surveys made by Braschler and Baur [35] ness matched the findings from a survey using a different trapping method (wet card- using a different method to measure species richness (nest counts) in small and large plots board sheets) in four years (fourth to final year; Braschler et al. [43]). Similarly, the non- in the fourth and the ﬁnal year of the study. Furthermore, we found no fragmentation effect on the species richness of orthopterans in any year of the experiment [39]. response to fragmentation by ant species was upheld by two surveys made by Braschler and Baur [35] using a different method to measure species richness (nest counts) in small and large plots in the fourth and the final year of the study. Furthermore, we found no fragmentation effect on the species richness of orthopterans in any year of the experiment [39]. Diversity 2023, 15, x FOR PEER REVIEW 12 of 31 Diversity 2023, 15, 130 13 of 31 Figure 4. Species density of invertebrate groups in fragments and control plots in the ﬁnal year of Figure 4. Species density of invertebrate groups in fragments and control plots in the final year of the experimental fragmentation. Species density was calculated as the mean of two pitfall traps per the experimental fragmentation. Species density was calculated as the mean of two pitfall traps per fragment or control plot averaged over seven 2-week collections. Only large and small plots were fragment or control plot averaged over seven 2-week collections. Only large and small plots were used. Means SD are shown; n = 24; + p < 0.10, * p < 0.05, ** p < 0.01. Data from [42]. used. Means ± SD are shown; n = 24; + p < 0.10, * p < 0.05, ** p < 0.01. Data from [42]. Assessments of environmental change effects on biodiversity focus often on one taxo- Assessments of environmental change effects on biodiversity focus often on one tax- nomic group whose response is assumed to reﬂect overall changes [52]. In our controlled onomic group whose response is assumed to reflect overall changes [52]. In our controlled experiment, however, responses to fragmentation varied widely among taxonomical groups experiment, however, responses to fragmentation varied widely among taxonomical and even among species within groups [28,42]. groups and even among species within groups [28,42]. 3.4.2. Few Effects on Shannon Diversity and Species Turnover 3.4.2. Few Effects on Shannon Diversity and Species Turnover Both observed species richness and species density do not capture all aspects of Both observed species richness and species density do not capture all aspects of bio- biodiversity [53]. Another frequently used index is the Shannon diversity index [54]. In our diversity [53]. Another frequently used index is the Shannon diversity index [54]. In our experiment, no signiﬁcant differences in the Shannon diversity index of the taxonomical experiment, no significant differences in the Shannon diversity index of the taxonomical groups examined (grasses, forbs, ants, butterﬂies, grasshoppers, and gastropods) were groups examined (grasses, forbs, ants, butterflies, grasshoppers, and gastropods) were found between fragments and control plots in the fourth year [28]. found between fragments and control plots in the fourth year [28]. The turnover in species composition between different communities (i.e., -diversity) The turnover in species composition between different communities (i.e., β-diversity) may also be affected by the experimental fragmentation. Communities in fragments may may also be affected by the experimental fragmentation. Communities in fragments may be more similar to each other than those in control plots provided the species composition be more similar to each other than those in control plots provided the species composition in fragments is a direct consequence of the fragmentation. This is the case when always in fragments is a direct consequence of the fragmentation. This is the case when always the same species suffer (become extinct) or beneﬁt (colonize or become more abundant). the same species suffer (become extinct) or benefit (colonize or become more abundant). Conversely, communities in fragments may be more different from each other than those Conversely, communities in fragments may be more different from each other than those in control plots. In that case, extinction and recolonization rates of species are generally in control plots. In that case, extinction and recolonization rates of species are generally higher in fragments than in control plots, but which species are affected is random [55,56]. higher in fragments than in control plots, but which species are affected is random [55,56]. Braschler and Baur [42] calculated [57] followed by PERMANOVA for invertebrate Braschler and Baur [42] calculated βz [57] followed by PERMANOVA for invertebrate groups sampled with pitfall traps in large and small fragments and control plots in the groups sampled with pitfall traps in large and small fragments and control plots in the ﬁnal year of the study. -diversity was increased in fragments for gastropods and ground final year of the study. β-diversity was increased in fragments for gastropods and ground beetles, while no signiﬁcant fragmentation effect on -diversity was found for ants, rove beetles, while no significant fragmentation effect on β-diversity was found for ants, rove beetles, spiders, and woodlice [42]. This indicates that species assemblages in fragments beetles, spiders, and woodlice [42]. This indicates that species assemblages in fragments did not represent a speciﬁc subset of those present in the grasslands but rather that different did not represent a specific subset of those present in the grasslands but rather that differ- species changed in abundance or went extinct in different fragments. ent species changed in abundance or went extinct in different fragments. Diversity 2023, 15, 130 14 of 31 3.5. Little Inﬂuence of Fragmentation on Species Composition but Huge Variation among Sites Nutrient-poor, dry calcareous grasslands are generally very species rich [58,59]. How- ever, despite belonging to the same vegetation type and being located relatively close to each other, many species occurred only in one or two of the three sites included in our experiment. For example, 98 of the 230 species of seven invertebrate groups collected with pitfall traps in the ﬁnal year of the experiment (43%) only occurred in one out of the three study sites [42]. Similarly, only 6 out of 24 aphid species occurred in both sites surveyed for this group [34]. Among-site variation in species richness was not necessarily related to differences in relative densities. Vicques had lower observed and rareﬁed gastropod species richness than the other two sites despite similar numbers of individuals recorded [43]. Considering seven groups of invertebrates captured by pitfall traps in large and small plots in the ﬁnal year of the experiment, species composition between fragments and control plots differed for all taxonomical groups analyzed combined and for spiders, ground beetles, and woodlice considered separately [42]. In contrast, no fragmentation effect was found for the species composition of gastropods, ants, and rove beetles. Similarly, using data from cardboard traps, Braschler et al. [43] found no difference in species composition between large fragments and control plots for gastropods in the fourth to the ﬁnal year of the study. For this synthesis, we reanalyzed fragmentation effects on the species composition of aphids, plants, and butterﬂies using NMDS and PERMANOVA (not yet done in [28,34]). Aphid species composition was not affected by grassland fragmentation in Nenzlingen and Vicques in the sixth year of the experiment. Similarly, plant and butterﬂy species composition were not inﬂuenced by fragmentation in the fourth year of the experiment. Braschler et al. [39] showed that over the full duration of the experiment (7 years) species composition in orthopterans varied among sites (26.7% of explained variation in RDA model), treatment (3 levels: fragment, control plot, mown matrix, 15.4%), and to a lesser extent with the duration of the experiment (6.8%). While much of the treatment effect was due to a different species composition in the matrix, some species also differed strongly in abundance between fragments and control plots [39]. 3.6. Several Species Had Higher Abundance in Fragments We expected that the abundance of certain species responds faster to the experi- mental fragmentation than the species richness of the taxonomic group they belong to. Zschokke et al. [28] investigated fragmentation effects on the abundance of vascular plants (grasses and forbs), ants, butterﬂies, grasshoppers, and gastropods in the fourth year of the experiment. The abundances of 19 (29%) of the 65 common species examined separately were affected by fragmentation [28]. Butterﬂies, the most mobile animals among the in- vertebrates studied, responded most sensitively: foraging abundances of various butterﬂy species were lower in fragments than in control plots [28]. Of the few other taxonomic groups or single species that were affected by the experimental fragmentation, most had a higher abundance in fragments than in control plots. A possible explanation for this ﬁnding is that the type of fragmentation used is beneﬁcial to some plants via decreased competition intensity along the fragment edges. Furthermore, some animals may use fragments as retreats between foraging bouts into the mown matrix. Aphid density responded strongly to the experimental grassland fragmentation, (ex- amined in two sites [34]). Overall aphid density was higher in fragments than in control plots in each of the three years examined (ﬁfth to seventh year) with the fragmentation effect increasing over time [34]. One of the two most abundant aphid species had higher densities in fragments than control plots, while the density of the other common species did not differ between fragments and control plots. Several of the less common species contributed to the overall higher aphid density in fragments [34]. The increased density in fragments was a combined result of a larger number of aphid-infested plants in fragments and on average larger aphid colonies in fragments than in control plots [34]. Considering data from surveys in all 7 years of the experiment, orthopteran individual density differed among fragments, control plots, and corresponding plots in the matrix [39]. Diversity 2023, 15, 130 15 of 31 Individual density was higher in large fragments than in large control plots for the suborder Ensifera. In contrast, individual density of the suborder Caelifera did not differ between large fragments and corresponding control plots. Densities of both suborders were signiﬁ- cantly lower in the mown matrix than in either large fragments or large control plots [39]. In addition, the overall density of orthopterans (all species combined) in our experimental blocks increased linearly over time [39]. This increase was mainly due to an increased individual number in species belonging to the suborder Caelifera, while no such directional change in density was recorded for species belonging to the suborder Ensifera [39]. All species of the suborder Ensifera together showed a strong among-year density variation, which could explain the absence of a directional change [39]. In the ﬁnal year, pitfall traps were used to assess the individual density of surface- active invertebrates (expressed as individuals per 14 trap days) in large and small fragments and control plots [42]. Spider individual density was lower in fragments than in control plots, while woodlouse individual density was higher in fragments [42]. Similarly, the individual density of the only orthopteran examined, Gryllus campestris, was higher in fragments than in control plots [42]. Individual density of the other whole groups (gas- tropods, ants, ground beetles, and rove beetles) did not differ between fragments and control plots. However, some species within these groups differed in individual density between fragments and control plots [42]. The findings in gastropods and ants are contrasted when life traps (wet cardboard sheets for gastropods) and observational methods or baits (for ants) were used. Braschler et al. [43] found no difference in individual density of gastropods between large fragments and control plots in the fourth to ﬁnal year of the study. Ant nest density, however, was higher in large fragments than in large control plots in the ﬁnal year of the study [33]. This ﬁnding was supported by a higher forager density at sugar baits in large fragments than in large control plots in the same year [33], even though the individual density of ant workers in pitfall traps did not differ [42]. Nest counts in the fourth year revealed that ant nest density did not differ between fragments and control plots of all sizes [33]. There are different explanations for these contrasting ﬁndings. Firstly, a chosen method may not be very suitable for a particular organism group (e.g., pitfall trapping for gastropods). Secondly, depending on the focus of the study, different methods may be more or less adequate. For example, an assessment of ant nest density is a proxy for the number of ant colonies and thus the reproductive unit of ants, while baits and pitfall traps both measure worker activity [60]. Thirdly, depending on the prevailing conditions, a snapshot approach may capture an uncommon situation, and this may result in overlooking a potential fragmentation effect. Weather conditions inﬂuencing invertebrate abundance also vary among years. As a consequence, most short-lived invertebrate species show huge yearly ﬂuctuations in abundance [61,62]. This is important because the density of a species may inﬂuence whether a fragmentation effect can be demonstrated in a given year. Therefore, multi-year surveys are required to disentangle fragmentation effects from background variation. In our experiment, the relative density and rareﬁed species richness of gastropods increased from the fourth to seventh year of the experiment in all three study sites [43]. The increase was recorded in both snails and slugs, but was especially pronounced in slugs. The high gastropod density in the ﬁnal years of the study (especially in 1999) may have been a consequence of above-average precipitation (Table 1) [43]. Abundance may vary between core and edge zones within the same fragment. For example, individuals that forage in the matrix may use the fragment as a refuge to avoid the most extreme microclimatic conditions, resulting in higher abundance in the edge zone. Furthermore, the enhanced plant productivity in the edge zone of fragments [36] and the consequently altered vegetation structure and microclimate in the edge zone [28] may be suitable for some species. Both these factors may have contributed to a higher ant nest density in the edge zone of fragments [33]. Diversity 2023, 15, 130 16 of 31 3.7. Fragmentation Affected Colonization and Extinction Rates in Some Species Habitat fragmentation, among other effects, decreases the size of remnant animal and plant populations, which in turn leads to an increased risk of local extinctions [4]. The fate of remnant plant populations in fragments depends on fragment size, degree of isolation, the type and quality of the matrix, and on species characteristics including mating system, seed dispersal ability, and longevity [4,48]. MacArthur and Wilson [63] proposed that the colonization rate of new species will be lower and the extinction rate higher in isolated islands than in areas of continuous habitats of the same size and that both colonization and extinction rate are related to the size of the isolated islands. Similar patterns can also be expected for habitat fragments embedded in a matrix of less suitable habitat. Changes in extinction and colonization rates in fragments can also lead to shifts in community composition and decreases in species richness [63]. Joshi et al. [38] reported that the colonization rate of plant species (grasses and forbs) was 29% lower in fragments than in the corresponding control plots over the whole duration of the experiment. The extinction rate over the same period, however, was not inﬂuenced by habitat fragmentation. Therefore, the overall species turnover was 22% lower in fragments than in the corresponding control plots [38]. The same pattern of reduced colonization rate in fragments but similar extinction rate in fragments and control plots was already recorded in the period from the ﬁrst to third year of the experiment and was repeated in the period from the fourth to the seventh year [38]. However, because in the latter period the extinction rate in fragments tended to be higher than in control plots in two of the three sites, the turnover rate in this latter period, if considered separately, did not differ signiﬁcantly between fragments and control plots. Colonization rate and species turnover rate were inﬂuenced by plot size. Both were higher in tiny and small fragments than in the corresponding control plots. In general, habitat specialist plant species were less likely to colonize fragments than habitat generalist species; a pattern already observed in the ﬁrst three years of the experiment and holding true over the whole duration of the experiment [38]. Despite reduced colonization rate and a tendency of increased extinction rate in fragments in two sites in the later period of the experiment, fragments had only marginally fewer plant species than control plots in the ﬁnal year of our study. Stoll et al. [40] used a mark-release-resight approach to assess the population sizes and extinction and recolonization frequencies of six land snail species, which ranged in adult shell size from 1.4 mm to 17.0 mm in all fragments and control plots from the second to fourth year of the experiment. Experimental grassland fragmentation inﬂuenced the population size in all snail species except Helicella itala, which is the species with the biggest shell (17.0 mm). This species is also active under mild conditions in winter, thus increasing the chances to cross the matrix [64]. Extinction frequency (disappearance from a plot) increased with time, decreasing population size, and decreasing plot size in all species [40]. The experimental fragmentation increased the probability of extinction, which also differed among snail species. The effect of plot size on extinction probability was still signiﬁcant even after the effect of population size had been taken into account. Fragments and control plots did not differ in recolonization frequencies when all six species were considered. However, fragmentation inﬂuenced recolonization frequency when the two species with large shells (H. itala and Trichia plebeia [8.5 mm]) were excluded from the analysis. 3.8. Delayed Reduction in Functional Dispersion in Fragments The response of a species to habitat fragmentation may depend on its morphological and life-history traits. It is therefore expected that species assemblages in fragments would harbor species that, on average, differ in their traits from those in control plots. Thus, functional diversity might be affected by fragmentation. Functional dispersion (FDis) is a measure of functional richness, which considers the species’ relative abundances by estimating their dispersion in a multi-dimensional trait space [65]). We expected that FDis of assemblages in fragments is smaller than that of assemblages in control plots. However, FDis of gastropods (snails and slugs) was not affected by the experimental fragmentation Diversity 2023, 15, 130 17 of 31 in large fragments and control plots in the fourth to ﬁnal year of the experiment [43]. Conversely, if only snails (shelled gastropods) were considered, FDis was lower in large fragments than control plots in the ﬁnal year of the experiment. We reanalyzed data on orthopterans recorded in large fragments and control plots from Braschler et al. [39] using the dispersal mode as presented in that paper and mean body size, feeding guild, and stratum use as reported in Gossner et al. [66] and the website Orthoptera.ch [67]. FDis of orthopterans did not differ between large fragments and control plots in any year after applying Bonferroni correction to the statistical tests. 3.9. Species Interactions Responded Strongly to Fragmentation 3.9.1. Changes in Herbivore Abundance Altered Extent of Plant Damage Habitat fragmentation inﬂuences herbivores through changes in the relative abun- dance of different plant species, edge effects on plant growth, and altered microclimatic conditions caused by changes in vegetation structure [19,48]: all of which was also the case in our grassland fragments [28,36]. The isolation of fragments may also lead to reduced predator and parasitoid pressures on herbivores provided that predators and parasitoids search over larger areas than that of a single fragment for their prey/host or arrive only with a delay [68]. As a consequence, herbivore populations may initially have higher growth rates in fragments than in unfragmented habitats [69]. In individually tagged leaves of Stachys ofﬁcinalis, the extent of damage (% leaf area removed) increased over the vegetation period in the sixth year of the experiment [37]. Fragmentation signiﬁcantly affected the extent of leaf damage in autumn but not in spring and summer [37]. Plot size also affected the extent of leaf damage in spring and autumn. Rosettes in large fragments and control plots were more severely damaged than those in small plots [37]. Gastropod density (recorded in the same year) and the extent of leaf damage in fragments were positively correlated in two of the three sites [37]. The fact that the fragmentation effect on leaf damage of S. ofﬁcinalis rosettes was only signiﬁcant in autumn indicates the importance of cumulative effects over the growing season. In an approach avoiding cumulative effects, Ledergerber et al. [32] used standardized food offers (petri dishes with Trifolium repens seedlings exposed in all fragments and control plots for 2–3 days both in summer and autumn in the fourth year of the experiment) to as- sess grazing damage. In summer, grazing intensity (expressed as leaf biomass loss per petri dish and day) was 43% lower in fragments than in control plots [32]. Grazing intensity in summer was positively correlated with relative gastropod density (number of individuals from 12 species found per plot) but not with the relative density of grasshoppers (number of individuals from 15 species recorded per plot). In autumn, no fragmentation effect on grazing intensity was found, and grazing intensity was correlated neither with gastropod nor grasshopper density [32]. A combination of factors can explain the seasonal difference in fragmentation effect on grazing intensity using standardized food offerings. Different herbivore species are active at different seasons and/or under different environmental conditions. Furthermore, different herbivore species react differently to the type of grass- land fragmentation chosen in our experiment [32]. This example shows that fragmentation effects may also vary with season. Our experimental fragmentation also affected the abundance of sap-sucking insects. Aphids (all species combined) had more colonies in fragments than in control plots, and the mean colony size was larger in fragments, resulting in higher aphid densities in all three years examined (ﬁfth to seventh year of the experiment; [34]). Braschler et al. [34] analyzed the infestation rates of twelve abundant host plant species in Vicques and Nenzlingen separately. In 5 out of 23 fragment–control plot comparisons (one host plant species only occurred in one site), potential hosts showed a higher infestation rate in fragments than in control plots [34]. In contrast, none of the host plant species were more frequently infested in control plots [34]. These ﬁndings were not inﬂuenced by differences in the abundance of host plant species between fragments and control plots. Some other studies have investigated the effect of habitat fragmentation on invertebrate herbivores with Diversity 2023, 15, 130 18 of 31 contrasting results. For example, different aphid species responded in different ways to fragmentation of alfalfa cropland [70]. Kareiva [68] reported more frequent aphid outbreaks in experimental fragments of goldenrod ﬁelds. Little or no effects of fragmentation on species richness and abundance were found in stem-boring insects of fragmented habitats dominated by the grass Calamagrostis epigeios [71]. 3.9.2. Fragmentation Affected the Prevalence of a Fungal Disease Habitat fragmentation may inﬂuence parasitism rates, for example, if it takes longer for a host to be discovered in a fragmented landscape [69]. In our fragmentation experiment, however, parasitoid pressure on aphids (assessed through the proportion of mummies) was not affected [34]. This ﬁnding contrasts with those of other experiments in which hosts in habitat fragments experienced reduced parasitism pressure [69,72] or predator release [68]. Many effective parasitoid species may be themselves rare as they maintain their hosts at low density. Disruptions caused by habitat loss and fragmentation may thus have disproportional effects on these interactions [73]. Fragmentation-induced changes in biotic and abiotic factors can disturb host–pathogen interactions. Bromus erectus is the most characteristic grass species of nutrient-poor, dry calcareous grasslands in the Swiss Jura mountains [27]. This grass species is the host for the fungal pathogen Epichloë bromicola (Figure 5). The fungus infects the ﬂowering tillers of B. erectus and causes the abortion of developing inﬂorescences, which can result in a total failure of sexual reproduction. In our experiment, Groppe et al. [30] found a signiﬁcant increase in the number of Bromus erectus ﬂowering tillers infected by E. bromicola in fragments in the ﬁrst 3 years. The number of infected ﬂowering tillers in fragments increased with the duration of the experiment (Figure 6). The largest increase in the number of ﬂowering tillers with infected inﬂorescences was recorded in tiny fragments, followed by small and large fragments [30]. This was probably due to both a switch of genets from the asymptomatic to the symptomatic state and to increased horizontal transmission of the disease in fragments. Interestingly, however, the increase in the number of ﬂowering tillers with infected inﬂorescences was outweighed by that in the number of tillers with healthy inﬂorescences [30]. Disease incidence was therefore decreased by fragmentation if assessed at the level of the host ﬂowering tiller population. The effect on healthy plants was probably due to beneﬁcial abiotic edge effects following fragmentation [30]. Signiﬁcant site-to-site and year-to-year variation in the number of diseased plants and in the number Diversity 2023, 15, x FOR PEER REVIEW 18 of 31 of tillers with diseased inﬂorescences were recorded. Figure 5. Tillers of the grass Bromus erectus infested with the fungal endophyte Epichloë bromicola. Figure 5. Tillers of the grass Bromus erectus infested with the fungal endophyte Epichloë bromicola. The The fungal infection prevents the development of inflorescences in the grass species. Figure adapted from a photo published by AfroBrazilian on Wikimedia commons under a CC-BY-SA-3.0 license. fungal infection prevents the development of inﬂorescences in the grass species. Figure adapted from a photo published by AfroBrazilian on Wikimedia commons under a CC-BY-SA-3.0 license. Figure 6. Number of Bromus erectus tillers (per m ) infested with Epichloë bromicola in tiny, small, and large fragments (black bars) and in the corresponding control plots (open bars) in the first year (a), second year (b), and third year (c) of the experiment. Means ± SE are shown. Redrawn from Groppe et al. [30]. 3.9.3. Altered Mutualistic and Competitive Interactions in Fragments Habitat fragmentation can affect mutualistic interactions if the abundance of one or the other of the partners involved or even of alternative partners is affected [74]. Changes Diversity 2023, 15, x FOR PEER REVIEW 18 of 31 Figure 5. Tillers of the grass Bromus erectus infested with the fungal endophyte Epichloë bromicola. Diversity 2023, 15, 130 19 of 31 The fungal infection prevents the development of inflorescences in the grass species. Figure adapted from a photo published by AfroBrazilian on Wikimedia commons under a CC-BY-SA-3.0 license. Figure 6. Number of Bromus erectus tillers (per m ) infested with Epichloë bromicola in tiny, small, and large fragments (black bars) and in the corresponding control plots (open bars) in the ﬁrst year (a), Figure 6. Number of Bromus erectus tillers (per m ) infested with Epichloë bromicola in tiny, small, and second large frag year ments (bla (b), and ckthir bars) a d year nd in the (c) of the correspondi experiment. ng contr Means ol plots (open SE are bars) in the first year ( shown. Redrawn from a), second year (b), and third year (c) of the experiment. Means ± SE are shown. Redrawn from Groppe Groppe et al. [30]. et al. [30]. 3.9.3. Altered Mutualistic and Competitive Interactions in Fragments 3.9.3. Altered Mutualistic and Competitive Interactions in Fragments Habitat fragmentation can affect mutualistic interactions if the abundance of one or the other of the partners involved or even of alternative partners is affected [74]. Changes in Habitat fragmentation can affect mutualistic interactions if the abundance of one or mutualistic relationships may in turn inﬂuence the abundance of the partners involved [75]. the other of the partners involved or even of alternative partners is affected [74]. Changes Many, though not all, aphid species recorded in our experiment are ant-attended. Both aphids and ants were more abundant in large fragments than in corresponding control plots in some of the years examined (aphids in all three years examined; ants in the seventh year but not in fourth year; [34]). This may have affected the proportion of ant-attended aphid colonies, which was larger in fragments than in control plots [34]. This effect may have been further modiﬁed by the relative abundance of plant species offering alternative sugar resources, as several of the ant species visiting aphid colonies were also observed at extraﬂoral nectaries in the experimental plots [35]. Intra- and interspeciﬁc competitive interactions can be altered when habitat fragmenta- tion affects species composition or the availability of resources [76,77]. Ant assemblages are frequently structured by competition [60]. In nutrient-poor, dry calcareous grasslands, most ant species are food generalists and have simple soil nests or soil nests with mounds [78]. In our experimental plots, the spatial distribution of nests was either random or overdis- persed [33], the latter indicating competition among colonies [76,77,79]. However, nearest neighbor distances among nests of all species, or of nests of the numerically dominant species considered separately, were not affected by the experimental fragmentation in the fourth and the ﬁnal year [33]. The species richness of other ant species decreased with the increasing density of the numerically dominant ant species Lasius paralienus in fragments but not in control plots [35]. The relationship between the nest density of L. paralienus and that of other species was U-shaped in fragments, while no relationship was observed in control plots [35]. The relationship between the total number of nests of each ant species in a plot and its habitat niche overlap with L. paralienus was hump-shaped in control plots, while no relationship was found in fragments [35]. In contrast, the overall forager density of the other species was positively related to their habitat niche overlap with L. paralienus both in fragments and control plots, and the density of foragers of the other species at sugar resources (aphids, extraﬂoral nectaries, and artiﬁcial sugar baits) was not signiﬁcantly affected by L. paralienus forager density [35]. The experimental fragmentation resulted in Diversity 2023, 15, 130 20 of 31 an increase in natural sugar resources in fragments, which may have reduced interspeciﬁc competition for this resource [33,35]. 3.9.4. Fragmentation-Related Changes in Pollinator Behavior Pollinators are of crucial importance for ecosystem functioning [80,81]. Habitat frag- mentation can affect both the abundance and species composition of pollinators and thus reduce the pollination of various plant species, which may negatively inﬂuence the re- productive success and ﬁtness of plants [82]. Animal foraging behavior may change immediately in response to habitat fragmentation, which in the case of pollination will then further affect the genetic diversity of plants. In our experiment, Goverde et al. [31] and Rusterholz and Baur [41] examined fragmen- tation effects on the ﬂower-visiting patterns of pollinators of Stachys ofﬁcinalis inﬂorescences and the resulting ﬁtness consequences for the plant. Goverde et al. [31] found that the bumblebee Bombus veteranus was the most frequent visitor of S. ofﬁcinalis inﬂorescences (69%), followed in decreasing order by Zygaena spp. (13%), other Hymenoptera (11%), other Lepidoptera (4%), and Diptera (3%) in small fragments and control plots in the sixth year of the experiment. However, individuals of B. veteranus visited fragments less frequently than control plots (a reduction of 54%). Fragmentation also altered the foraging behavior of B. veteranus [51]. Bumblebees visited more S. ofﬁcinalis inﬂorescences (frequently neighbor plants) in fragments than in control plots (Figure 7). This resulted in a slightly higher Diversity 2023, 15, x FOR PEER REVIEW visiting time of S. ofﬁcinalis inﬂorescences in fragments than in control plots [31,4120 of ]. This 31 ﬁnding was not inﬂuenced by the densities of S. ofﬁcinalis rosettes and inﬂorescences, which did not differ between fragments and control plots. Figure 7. Foraging behavior of bumblebees in a small fragment and control plot. Red dots represent Figure 7. Foraging behavior of bumblebees in a small fragment and control plot. Red dots represent the positions of single Stachys ofﬁcinalis inﬂorescences. In fragments, bumblebees visited repeatedly the positions of single Stachys officinalis inflorescences. In fragments, bumblebees visited repeatedly the same inﬂorescences during a trip, considering almost all inﬂorescences. In contrast, in control the same inflorescences during a trip, considering almost all inflorescences. In contrast, in control plots, inﬂorescences were only visited once [51]. plots, inflorescences were only visited once [51]. The foraging behavior of bumblebees is plastic and can easily be adjusted to changes in The foraging behavior of bumblebees is plastic and can easily be adjusted to changes the environment and food resources [83,84]. The nectar reward of S. ofﬁcinalis inﬂorescences, in the environment and food resources [83,84]. The nectar reward of S. officinalis inflores- an important energy resource for bumblebees, was reduced in fragments [51]. Thus, the cences, an important energy resource for bumblebees, was reduced in fragments [51]. altered foraging behavior might be a result of bumblebees optimizing their net energy gain Thus, the altered foraging behavior might be a result of bumblebees optimizing their net by considering all available S. ofﬁcinalis inﬂorescences in fragments [83,85]. energy gain by considering all available S. officinalis inflorescences in fragments [83,85]. Rusterholz and Baur [41] reported that the inﬂorescence visitation rate of S. ofﬁcinalis Rusterholz and Baur [41] reported that the inflorescence visitation rate of S. officinalis plants was not yet affected after 3 years of experimental fragmentation but signiﬁcantly plants was not yet affected after 3 years of experimental fragmentation but significantly reduced in fragments in the final year of the study (by 25% in large fragments and by 40% in small fragments). Fragmentation-induced changes in the patchiness, size, and density of floral resources can be responsible for an alteration in flower visitation behavior [86,87]. This is not the case in our studies because the rosette and inflorescence density, as well as inflorescence length, of S. officinalis were similar in fragments and control plots [41]. Frag- mentation also caused a significant shift in the composition of inflorescence visitors in the third and final year of the experiment [41]. The lower visitation rate of S. officinalis inflorescences in fragments and the altered foraging behavior of bumblebees point to a decrease in gene flow, which in turn may af- fect the breeding system of the plant [82]. The reproductive characteristics (seed set, seed weight, and germination rate) of S. officinalis, examined in the first, third and seventh year of the experiment, were not influenced by fragmentation [41]. Similar responses have fre- quently been reported for self-compatible plants such as S. officinalis with various pollina- tors [88,89]. However, the outcrossing frequency in S. officinalis was reduced in fragments (Figure 8). The extent of reduction increased with the duration of the experiment, from 15% in the third year to 33% in the seventh year. Diversity 2023, 15, 130 21 of 31 reduced in fragments in the ﬁnal year of the study (by 25% in large fragments and by 40% in small fragments). Fragmentation-induced changes in the patchiness, size, and density of ﬂoral resources can be responsible for an alteration in ﬂower visitation behavior [86,87]. This is not the case in our studies because the rosette and inﬂorescence density, as well as inﬂorescence length, of S. ofﬁcinalis were similar in fragments and control plots [41]. Fragmentation also caused a signiﬁcant shift in the composition of inﬂorescence visitors in the third and ﬁnal year of the experiment [41]. The lower visitation rate of S. ofﬁcinalis inﬂorescences in fragments and the altered foraging behavior of bumblebees point to a decrease in gene ﬂow, which in turn may affect the breeding system of the plant [82]. The reproductive characteristics (seed set, seed weight, and germination rate) of S. ofﬁcinalis, examined in the ﬁrst, third and seventh year of the experiment, were not inﬂuenced by fragmentation [41]. Similar responses have frequently been reported for self-compatible plants such as S. ofﬁcinalis with various pollinators [88,89]. However, the outcrossing frequency in S. ofﬁcinalis was reduced in Diversity 2023, 15, x FOR PEER REVIEW 21 of 31 fragments (Figure 8). The extent of reduction increased with the duration of the experiment, from 15% in the third year to 33% in the seventh year. Figure 8. Frequency of outcrossing in S. ofﬁcinalis in small and large fragments (black bars) and the corresponding Figure 8. Frequenc controly of plots outc (open rossing in bars) S in . off the icin thir alisd in year small and large (a), and seventh fragme year nts (bla (b) of ck bars) experimental and the corresponding control plots (open bars) in the third year (a), and seventh year (b) of experimental fragmentation. Means SE are shown; n = 7; ** p < 0.01, *** p < 0.001. Data from Rusterholz and fragmentation. Means ± SE are shown; n = 7; ** p < 0.01, *** p < 0.001. Data from Rusterholz and Baur Baur [41]. [41]. 3.10. Fragmentation-Related Changes in Pollinator Behavior Led to Reduced Genetic Diversity in a 3.10. Fragmentation-Related Changes in Pollinator Behavior Led to Reduced Genetic Diversity Plant Species in a Plant Species Habitat fragmentation leads to small and isolated populations [4]. The combination of Habitat fragmentation leads to small and isolated populations [4]. The combination increased random genetic drift, inbreeding and reduced gene ﬂow may substantially reduce of increased random genetic drift, inbreeding and reduced gene flow may substantially genetic variation in remnant populations [90,91]. The loss of genetic variation in turn may reduce genetic variation in remnant populations [90,91]. The loss of genetic variation in negatively inﬂuence population viability and ﬁtness in the short- and long-term [92]. In the turn may negatively influence population viability and fitness in the short- and long-term short-term, an increase in degree of homozygosity leads to the expression of deleterious [92]. In the short-term, an increase in degree of homozygosity leads to the expression of alleles, which reduce individual ﬁtness through inbreeding depression [90,93]. In the deleterious alleles, which reduce individual fitness through inbreeding depression [90,93]. long-term, a reduced genetic diversity decreases the potential of a species or population to In the long-term, a reduced genetic diversity decreases the potential of a species or popu- adapt to changing environmental conditions [94,95]. lation to adapt to changing environmental conditions [94,95]. In plants, self-incompatible species are more likely to lose genetic diversity through In plants, self-incompatible species are more likely to lose genetic diversity through genetic drift than self-compatible species [96]. Besides the breeding system other life-history genetic drift than self-compatible species [96]. Besides the breeding system other life-his- traits including longevity inﬂuence the genetic response to habitat fragmentation [97,98]. tory traits including longevity influence the genetic response to habitat fragmentation In our experiment, fragmentation-related changes in pollinator foraging reduced the out- [97,98]. In our experiment, fragmentation-related changes in pollinator foraging reduced crossing frequency in Stachys ofﬁcinalis, which in turn led to a time-delayed decrease in the outcrossing frequency in Stachys officinalis, which in turn led to a time-delayed de- genetic diversity in the self-compatible plant [41]. In the third year of the experiment, the crease in genetic diversity in the self-compatible plant [41]. In the third year of the exper- genetic diversity of S. ofﬁcinalis seedlings reared from collected seeds did not yet differ iment, the genetic diversity of S. officinalis seedlings reared from collected seeds did not yet differ between fragments and control plots [41]. However, in the seventh year of the experiment, genetic diversity of the seedlings was significantly lower in fragments than in the control plots (Figure 9; [41]). Diversity 2023, 15, 130 22 of 31 between fragments and control plots [41]. However, in the seventh year of the experiment, Diversity 2023, 15, x FOR PEER REVIEW 22 of 31 genetic diversity of the seedlings was signiﬁcantly lower in fragments than in the control plots (Figure 9; [41]). Figure 9. Genetic diversity [99] of S. ofﬁcinalis-seedlings in small and large fragments (black bars) and the corresponding control plots (open bars) in the (a) third year and (b) seventh year of experimental Figure 9. Genetic diversity [99] of S. officinalis-seedlings in small and large fragments (black bars) and the corresponding control plots (open bars) in the (a) third year and (b) seventh year of experi- fragmentation. Means SE are shown; n = 7; ** p < 0.01; N.S. not signiﬁcant. Data from Rusterholz mental fragmentation. Means ± SE are shown; n = 7; ** p < 0.01; N.S. not significant. Data from and Baur [41]. Rusterholz and Baur [41]. 3.11. Differing Responses to Fragmentation Can Be Explained by Species Traits 3.11. Differing Responses to Fragmentation Can Be Explained by Species Traits Species- or group-speciﬁc responses to habitat fragmentation can also be explained by Species- or group-specific responses to habitat fragmentation can also be explained differences in morphological and life-history traits and/or in behavior. For example, for by differences in morphological and life-history traits and/or in behavior. For example, invertebrate species partly active during winter, the barrier effect of the mown matrix is for invertebrate species partly active during winter, the barrier effect of the mown matrix almost absent [40]. is almost absent [40]. 3.11.1. Smaller Species Were More Frequently Adversely Affected by Fragmentation 3.11.1. Smaller Species Were More Frequently Adversely Affected by Fragmentation Body size can inﬂuence a species’ response to fragmentation through its relationship Body size can influence a species’ response to fragmentation through its relationship with dispersal ability, as well as through resource and habitat size requirements [100,101]. with dispersal ability, as well as through resource and habitat size requirements [100,101]. Generally, larger species require larger home ranges, which may lead to their absence in Generally, larger species require larger home ranges, which may lead to their absence in small fragments. On the other hand, large body size is frequently related to increased small fragments. On the other hand, large body size is frequently related to increased dis- dispersal ability [100,102]. Therefore, large species may be more likely to reach isolated persal ability [100,102]. Therefore, large species may be more likely to reach isolated frag- fragments. Body size has thus been frequently considered as a factor in studies on the ments. Body size has thus been frequently considered as a factor in studies on the effects effects of habitat fragmentation on biodiversity but with varying ﬁndings [100]. of habitat fragmentation on biodiversity but with varying findings [100]. In our experiment, Braschler and Baur [42] studied the effect of standardized adult In our experiment, Braschler and Baur [42] studied the effect of standardized adult body size on species’ responses (individual density) to fragmentation in gastropods, ants, body size on species’ responses (individual density) to fragmentation in gastropods, ants, ground beetles, rove beetles, the orthopteran Gryllus campestris, spiders, and woodlice ground beetles, rove beetles, the orthopteran Gryllus campestris, spiders, and woodlice col- collected with pitfall traps in the ﬁnal year of the experiment. Overall, there was a signiﬁcant lected with pitfall traps in the final year of the experiment. Overall, there was a significant relationship with larger species responding more positively to fragmentation (having relationship with larger species responding more positively to fragmentation (having higher densities in fragments than in control plots), while smaller species responded more higher densities in fragments than in control plots), while smaller species responded more negatively (lower densities in fragments than in control plots). However, considering the negatively (lower densities in fragments than in control plots). However, considering the groups separately, the relationship was only signiﬁcant for gastropods [42]. In contrast, groups separately, the relationship was only significant for gastropods [42]. In contrast, using data from non-invasive cardboard traps, Braschler et al. [43] found no signiﬁcant using data from non-invasive cardboard traps, Braschler et al. [43] found no significant fragmentation effect on the mean body size of snail assemblages (shelled gastropods) in fragmentation effect on the mean body size of snail assemblages (shelled gastropods) in the fourth to ﬁnal years of the experiment. the fourth to final years of the experiment. 3.11.2. Species with Certain Life-History Traits Were More Abundant in Fragments 3.11.2. Species with Certain Life-History Traits Were More Abundant in Fragments Many of the invertebrate species occurring in calcareous grasslands have relatively Many of the invertebrate species occurring in calcareous grasslands have relatively short generations. Thus, in our 7-year experiment, such species went through several short generations. Thus, in our 7-year experiment, such species went through several gen- generations, and we therefore expected strong responses in these species, which in turn erations, and we therefore expected strong responses in these species, which in turn may may contribute to changes in trait distributions in species assemblages in fragments. contribute to changes in trait distributions in species assemblages in fragments. Diversity 2023, 15, 130 23 of 31 Large fragments harbored a higher proportion of gastropod individuals (slugs and snails combined) belonging to species with an age at sexual maturity <1 year than large control plots only in the ﬁnal year of the experiment but not in the three preceding years [43]. However, fragments also had a higher proportion of gastropod species with long lifespans (>2 years) than the corresponding control plots in the ﬁnal year [43]. Thus, on average, gastropods in fragments belonged to species maturing earlier but living longer than those in control plots. 3.12. Species-Speciﬁc Humidity Preferences Could Hardly Explain Fragmentation Responses Habitat suitability for a species may be altered through fragmentation-induced changes in microclimatic conditions and vegetation structure (edge effects; see Sections 3.2 and 3.3). These changes may be reﬂected in the average preference for higher or lower humidity and temperature of the species forming the assemblage in the fragment. Experimental habitat fragmentation affected the proportion of gastropod individuals with different humidity preferences [43]. Fragments contained a higher proportion of individuals showing a preference for moist conditions (as opposed to dry or wet conditions) than control plots in the fourth and seventh year of the experiment [43]. Using pitfall trap data from the ﬁnal year to examine the role of habitat preferences, no correlation between a species’ response to fragmentation (t-value for the factor fragmentation from an overall model) and its humidity preference (indicator values or ordinal scale depending on the group) was found for each of the three groups examined (gastropods, ants, and rove beetles [42]). The same approach revealed that ant species that prefer colder temperatures were relatively more abundant in fragments than in control plots [42]. Data on species- speciﬁc temperature preferences were not available for the other groups. 3.13. Habitat Specialists Were Generally More Adversely Affected by Fragmentation Fragments may be too small for some habitat specialist species. In contrast, habitat generalist species, which are also able to use the matrix, may increase their relative abun- dance in fragments. We therefore expected fragments to have a relatively higher share of individuals belonging to habitat generalist species than control plots. Braschler et al. [43] found that the proportion of gastropod individuals, which belong to habitat generalist species (determined based on literature data), was higher in large fragments than in large control plots in the ﬁnal 2 years of the experiment, with the difference being marginally signiﬁcant in 1998 but strongly signiﬁcant in 1999. In the two preceding years, there was no signiﬁcant difference between fragments and control plots regarding the share of habitat generalist gastropods [43]. This indicates that the effect of the fragmentation increased over time. Species with high occupancy in control plots can be assumed to be well adjusted to the environmental conditions of these grasslands. Conversely, these species may be more likely to respond negatively to the changed conditions in fragments than species that are less specialized for the original conditions. Indeed, in spiders, there was a negative relationship between a species’ occupancy in control plots and its response in individual density to the experimental fragmentation (expressed as t-value for the factor fragmentation from an overall model) in the ﬁnal year of the experiment [42]. No such relationship was found for gastropods, ants, ground beetles, rove beetles, and woodlice [42]. 3.14. Long-Term Research Allowed Serendipitous Findings 3.14.1. Extending Biological Knowledge and Testing Methods Associated research conducted in fragments, control plots, or adjacent grassland contributed to the understanding of the ecosystem and the interpretation of the ﬁndings in the fragmentation experiment. Oggier [64] investigated the circadian and year-round activity of the land snails Candidula unifasciata and Helicella itala and found that individuals of both species are also active during warm and rainy periods in the winter months. Diversity 2023, 15, 130 24 of 31 These results were important to interpret the patterns observed in Stoll et al. [40] and Braschler et al. [43]. Not all survey methods are equally suitable to assess different groups of organisms in different habitat types [54]. Therefore, research was also conducted to develop or adjust survey methods to the grassland ecosystem. Oggier et al. [103] compared three different methods (mark-release-resight, cardboard trapping, and soil sampling) to assess the community structure of terrestrial gastropods in the grasslands. Cardboard trapping appeared to be best suited to examine population biological questions in selected species distributed over relatively large grassland areas, while stratiﬁed soil sampling might be the most reliable method to obtain complete species lists (species richness) in small grassland areas [103]. Ecological processes and interactions between species are often scale dependent [104]. Using the control plots of the experiment, we examined the grain dependence of the relationships between productivity (above-ground plant biomass), species richness of plants and herbivores (gastropods and grasshoppers), and the biomass of these consumers [45]. Signiﬁcant relationships at the smallest grain size (0.5 m ) were hump-shaped, while all signiﬁcant relationships at larger grain sizes were linearly decreasing [45]. This background information also helps to interpret ﬁndings from habitat fragmentation experiments at different spatial scales. Niemelä and Baur [105] examined the among-site variation of threatened species in the three grasslands. As many as 58 (22%) of the 266 species of vascular plants, gastropods, butterﬂies, grasshoppers, and ground beetles collected were considered as threatened in northern Switzerland, conﬁrming the high conservation values of these nutrient-poor, dry calcareous grasslands. The number of threatened species ranged from 27 to 49 per site, and 26 species occurred only in one of the three grasslands. The richness of threatened butterﬂy species correlated with that of threatened vascular plants, while those of the other groups did not covary. 3.14.2. Expanding Faunistic Knowledge Conducting repeated surveys on different groups has the potential to add knowledge on the population dynamics, habitat associations, and distributions of lesser-known species. In our experiment, Borcard et al. [106] reported the ﬁrst presence of a female of the ant tribe Dacetini in Switzerland. The dealate female (found in Vicques in 1993, the ﬁrst year of our experiment) was subsequently identiﬁed by Baroni-Urbani [107] as Strumigenys baudueri, a species not formerly known from Switzerland. In the ﬁnal year of the experiment, two workers of S. baudueri were captured in pitfall traps in Nenzlingen [108], proving for the ﬁrst time the existence of a colony of the cryptic group in Switzerland. The mostly sub-terranean workers would have been unlikely to be found without such thorough examination of the sites. Other records of rare or new species were forwarded to the relevant authorities and organizations but not published out of conservation concerns. 4. Advantages and Limitations of Grassland Fragmentation Experiments Our synthesis demonstrated that experimental grassland fragmentation has negative effects on various types of species interactions and the genetic diversity of plant populations. Effects on species richness and species composition were less frequently recorded. Most effects were subtle and varied over time: ﬁndings that would not have been detected in remnants of grassland, which vary in size, shape (and thus in the amount of edge), age, and degree of isolation [17,26]. This variation complicates any analysis and makes it difﬁcult to distinguish between different factors that may inﬂuence the population dynamics of plants and animals, their interactions, and the species’ assemblages. The various sources of uncontrolled variation can be circumvented by applying an experimental approach with standardized fragments and appropriate control plots at different ﬁeld sites [17]. Diversity 2023, 15, 130 25 of 31 Debinski and Holt [19] reviewed 20 habitat fragmentation experiments worldwide. Most of these experiments focused on the effects of fragmentation on species richness or on the abundance(s) of particular species, with a remarkable lack of consistency in results across studies [19]. Studies of arthropods reported the most pronounced fragmentation effects, while highly mobile taxa such as birds and mammals, long-lived species, and gen- eralist predators did not respond to the fragmentation [19]. These ﬁndings were paralleled by those of our ﬁeld experiment with less mobile taxa, short-lived, and specialized species showing the strongest responses to fragmentation. Among the 20 fragmentation experiments reviewed, ours belonged to the ones with rel- atively small fragments [19]. The spatial scale chosen for our study allowed an experimental design with standardized fragment sizes, equal isolation distance, and corresponding con- trol plots situated in equal distances in continuous habitat, arranged in a randomized block design. Furthermore, the distribution of the twelve blocks over three sites accounted for natural variation in soil properties, local climate, and species pools of nutrient-poor, dry calcareous grasslands. Few other fragmentation experiments did consider all of these aspects in their design [19]. Compared with the existing grassland remnants in the Swiss Jura mountains, the fragment sizes chosen in our experiment were small [23]. However, habitat fragmentation in the landscape occurs at different spatial scales. For each species, the relevant spatial scale is different depending on their resource needs and mobility [109,110]. Thus, choosing the appropriate taxonomical group(s) for a given landscape scale is a key issue in frag- mentation studies. In our experiment, we focused on taxonomical groups and species characteristic for dry grasslands, with most of the species having limited dispersal and short generation times. In our experiment, the isolation distance of the fragments (5 m) was chosen to repre- sent the width of local roads as they frequently occur in the Swiss Jura mountains. This allows a comparison with ﬁndings of other studies conducted on either side of roads in real landscapes. Five-meter-wide roads crossing grasslands function as partial or even com- plete barriers for dispersing individuals of various invertebrate groups, as shown in land snails [111,112]. Moreover, the movements of more mobile organisms, such as wild bees, are inﬂuenced by roads. Bhattacharya et al. [113] reported alterations in foraging behavior of bumblebees in road verges, with a strongly reduced number of individuals crossing the road. Similarly, we recorded an altered foraging behavior in bumblebees in small fragments compared to control plots [31,41]. The design of our experiment allowed an examination of the consequences of this behavioral change (namely, a decrease in the genetic diversity of pollinated plants [41]). Such a stringent disentangling of cause and effect would not be possible in grassland remnants with no standardization of isolation distance and fragment size, etc. However, it is important to note that fragmentation experiments cannot replace ﬁeld studies on real fragments in the landscape; rather, both complement each other. In our experiment, some responses to habitat fragmentation became only apparent after a few years [4]. It has been reported that some species show a delayed response to altered environmental conditions [114,115]. Thus, species-speciﬁc responses can partly be explained by the time since fragmentation [114,115]. Long generations are therefore expected to cause time lags in the response of species richness to fragmentation. This may explain why ant species richness was not changed in our 7-year experiment [33,35,42] because colonies of these social insects can persist for 10 or more years. Some impacts of fragmentation on biodiversity may thus be underestimated in short-term studies. It is therefore essential to conduct fragmentation experiments or surveys over several years to assess time lags in responses [19]. 5. Lessons for Conservation 5.1. Even Mild Fragmentation Results in Noticeable Effects Our experiment used a very mild fragmentation, with the matrix being an intensively managed grassland (frequent mowing) with altered environmental characteristics. The Diversity 2023, 15, 130 26 of 31 isolation distance of 5 m matches that of a country road. While at ﬁrst glance rather artiﬁcial, our experiment represents frequently occurring conditions where adjacent parcels of grass- lands are managed differently by farmers. Indeed, semi-natural grasslands are frequently surrounded by intensively managed grasslands or crop ﬁelds [23,59]. Nonetheless, in our experiment the effects of the fragmentation were wide ranging, though sometimes subtle. This indicates a need to consider the consequences of relative minor breaks in initially continuous habitats that will be fragmented by infrastructure projects (e.g., new country roads). Furthermore, conservation actions should aim to increase the permeability of the matrix around grasslands of high conservation value. New corridors would be another way to mitigate the isolation of grassland remnants [116,117]. 5.2. Even a Small-Scale Fragmentation Matters We conducted a mesocosm experiment whose spatial scale was small in relation to real landscapes. Nonetheless, because of adequate control plots, we could demonstrate frag- mentation effects, which are rarely investigated in real grassland remnants (e.g., changed pollinator behavior resulted in a decreased genetic diversity of plant species). These and other ﬁndings of our experiment indicate the presence of small-scale fragmentation effects, which have hitherto rarely been noticed. 5.3. Assessment Shortly after Environmental Change Underestimates Long-Term Effects We showed that fragmentation-related behavioral alteration in a species has the poten- tial to profoundly affect other species they interact with, even changing their population dynamics and genetic diversity. Such effects may accumulate over time as behavioral changes are likely to occur immediately after fragmentation, but their effects on other species may only become apparent in coming generations. Similarly, other fragmentation effects, such as reduced dispersal, may affect populations over time. Thus, any assessments made shortly after a disturbance-like fragmentation may be misleading as many effects become only apparent over time. Considering that many species had short generations, the experimental duration of 7 years allowed us to partly assess long-term effects. This suggests that any assessments of the success of conservation management decisions are ideally based on long-term data. 5.4. Conservation Decisions Should Not Be Based on a Single Taxonomical Group Our experiment showed that different taxonomical groups responded differently to grassland fragmentation. The taxonomical groups studied were poor indicators of each other ’s diversity. Consequently, we support the ‘shopping basket’ approach to conservation evaluation, i.e., measuring species richness, species composition, and the complementarity of several groups instead of just one [105]. It is therefore necessary to place management decisions on a broad base. 5.5. Biodiversity of a Grassland Does Not Substitute Those of Other Grasslands We studied three grasslands belonging to the same vegetation type, managed in the same way for a long period, and situated in the same mountain range. Nonetheless, we recorded considerable variation in species composition of plants and invertebrates. Thus, none of the three sites can substitute for the others if the overall biodiversity of these grasslands is to be maintained. Supplementary Materials: The following are available online at https://www.mdpi.com/article/ 10.3390/d15020130/s1, Table S1: Butterﬂy abundance, Table S2: Plant abundance, Table S3: Or- thoptera abundance, Table S4: Orthoptera traits following [66,67,118], Table S5: Aphid abundance. Diversity 2023, 15, 130 27 of 31 Author Contributions: Conceptualization, B.B. (Bruno Baur); methodology, B.B. (Bruno Baur), H.-P.R., and B.B. (Brigitte Braschler); validation, B.B. (Bruno Baur), H.-P.R., and B.B. (Brigitte Braschler); formal analysis, H.-P.R. and B.B. (Brigitte Braschler); investigation, B.B. (Bruno Baur), H.-P.R., and B.B. (Brigitte Braschler); resources, B.B. (Bruno Baur); data curation, H.-P.R. and B.B. (Brigitte Braschler); writing—original draft preparation, B.B. (Bruno Baur), H.-P.R., and B.B. (Brigitte Braschler); writing —review and editing, B.B. (Bruno Baur), H.-P.R., and B. Braschler; visualization, H.-P.R. and B.B. (Brigitte Braschler); supervision, B.B. (Bruno Baur) and H.-P.R.; project administration, B.B. (Bruno Baur); funding acquisition, B.B. (Bruno Baur). All authors have read and agreed to the published version of the manuscript. Funding: The study was funded by the Swiss National Science Foundation (www.snf.ch (accessed on 5 October 2022); grants 5001-035241, 5001-044620, and 5001-058265 awarded to B. Baur). Institutional Review Board Statement: Not applicable. Data Availability Statement: The data presented in this study are available within the paper and its Supporting Information Files (Tables S1–S5). Acknowledgments: We thank M. Wurtz, S. Schüpbach, and many students for their assistance and T. Boller, E. Turner, S. Zschokke, and an anonymous reviewer for their comments on the manuscript. Conﬂicts of Interest: The authors declare no conﬂict of interest. 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The Grassland Fragmentation Experiment in the Swiss Jura Mountains: A Synthesis

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ISSN: 1424-2818
DOI: 10.3390/d15020130
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Abstract

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Diversity – Multidisciplinary Digital Publishing Institute

Published: Jan 18, 2023

Keywords: biodiversity; calcareous grasslands; environmental change; functional dispersion; habitat fragmentation; invertebrates; population dynamics; time lags

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The Grassland Fragmentation Experiment in the Swiss Jura Mountains: A Synthesis

The Grassland Fragmentation Experiment in the Swiss Jura Mountains: A Synthesis

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The Grassland Fragmentation Experiment in the Swiss Jura Mountains: A Synthesis

The Grassland Fragmentation Experiment in the Swiss Jura Mountains: A Synthesis

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