Niche partitioning and coexistence of two spiders of the genus Peucetia (Araneae, Oxyopidae) inhabiting Trichogoniopsis adenantha plants (Asterales, Asteraceae)
Authors:
German Antonio Villanueva-Bonilla aff001; Suyen Safuan-Naide aff002; Mathias Mistretta Pires aff003; João Vasconcellos-Neto aff003
Authors place of work:
Programa de Pós-graduação em Biologia Animal, Instituto de Biologia, Universidade Estadual de Campinas, Campinas, SP, Brazil
aff001; Instituto de Biociências, Universidade Estadual Paulista Júlio de Mesquita Filho, Campus Botucatu, Botucatu, SP, Brazil
aff002; Departamento de Biologia Animal, Instituto de Biologia, Universidade Estadual de Campinas, Campinas, SP, Brazil
aff003
Published in the journal:
PLoS ONE 14(10)
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pone.0213887
Summary
Niche theory suggests that the coexistence of ecologically similar species in the same site requires some form of resource partitioning that reduces or avoids interspecific competition. Here, from July 2013 to December 2015, we investigated spatial niche differentiation at three different scales of two sympatric congeneric spiders, Peucetia rubrolineata and P. flava, along an altitudinal gradient in shaded and open areas in an Atlantic forest in Serra do Japi, SP, Brazil. These spiders are peculiar in that they present an exclusive association with the plant Trichogoniopsis adenantha (Asteraceae). In theory, the coexistence of two Peucetia species could be explained by: (1) microhabitat segregation with individuals from different species occupying different parts of the same plants; (2) mesohabitat segregation with different species using plant in different environments; (3) macrohabitat segregation, where different species would not co-occur along the altitudinal gradient. With respect to micro-habitat use, in both species, different instars used different plant parts, while the same instars of both species used the same type of substrate. However, the two Peucetia species segregated by meso-habitat type, with P. rubrolineata preferring T. adenantha plants in shaded areas and P. flava preferring those in open areas. Our results support the hypothesis of niche partitioning begetting diversity, and highlight the importance of analyzing habitat use at multiple scales to understand mechanisms related to coexistence.
Keywords:
Spiders – Leaves – Species interactions – Predation – Ecological niches – Flowering plants – Flowers – Chi square tests
Introduction
The mechanisms involved in species coexistence are a central theme in ecology, as they are responsible for maintaining high species diversity in ecosystems worldwide [1–5]). Competitive interactions are stronger between morphologically similar and phylogenetically close sympatric species [6]. The first mathematical models of resource competition proposed that when two species compete for the same resource, one species invariably eliminated the other [7–9]. However, considerable species diversity can be observed coexisting and persisting in the same trophic level of a given web of species interactions [10–12]. Coexistence theory proposes that the coexistence of ecologically similar species at the same site requires a form of resource partitioning [13].
Resource use partitioning has been reported for several taxa, including, mammals [6,14], birds [15–16]), reptiles and amphibians [17–18] fishes [19], and invertebrates [20]. These studies showed that several mechanisms, such as differences in phenology or specific habitat selection, led to a decrease in competition, allowing the species to coexist.
One particular group whose coexistence mechanisms have been given considerable attention are spiders [21–24]. Spiders are one of the most diverse group of terrestrial predators [21,25], with up to 4 species and 131 individuals co-occurring per m2 in tropical forests [26–30]. Partitioning of resources among spiders is generally explained by: (1) variation in prey types or sizes as a consequence of different hunting strategies or body size[31–34] reducing interspecific competition and allowing coexistence among species; (2) activity time, with different species varying in phenologies or circadian cycles [34–36] resulting in different population densities of the species throughout the year which reduces interspecific competition; (3) use of space, with different species using different microhabitats as the result of cryptic colorations [37], different foraging behaviors or different sites chosen for the placement of webs (e.g., different heights) [38–42], physiological tolerance [11,43] or based on thermal preference in a gradient of environmental characteristics in cave-dwelling spiders [44–45]. (4) Indirect influence of a species-specific fungus parasite, where the intensity of competition for space is reduced when the dominant host species is highly affected by the parasite and allows the colonization of other less dominant species [46]. (5) Predation, when agonistic interactions (e.g. predation by birds or intraguild predation) determine habitat occupation and niche assembly in tree-dwelling spiders [47]. In the literature, there is controversy over temporal segregation being one of the key mechanisms of coexistence in spider communities. On the one hand, [48] and [49] suggested that temporal segregation is an important factor that reduces niche overlap. [50] also argued that temporal segregation may facilitate the coexistence of species because the peak of abundance of each population will occur at different times, which reduces interspecific competition. For example, the spiders Meta menardi and Metellina merianae (Tetragnathidae), in addition to presenting distinct abundances throughout the year, also present distinct hunting strategies; M. merianae combines foraging outside and inside the web whereas M. menardi feeds exclusively on prey that fall into the web [34]. Temporal segregation may also occur when species differ in periods of activity during the day [51].
Despite the variety of mechanisms mediating coexistence in spiders, only a few studies have assessed different niche dimensions simultaneously in sympatric and ecologically similar species (e.g. [50,52–53]). Understanding how different partitioning mechanisms acting through multiple niche dimensions contribute to the coexistence of ecologically similar organisms can help us advance in the understanding of the processes shaping diversity patterns in local scales. Here we study different aspects of habitat use of two co-occurring spiders in the genus Peucetia (Oxyopidae): Peucetia rubrolineata Keyserling, 1877 and P. flava Keyserling 1877. Peucetia is a cosmopolitan group, comprising 47 known species, with most species occurring in tropical regions [54–55]. Spiders of this genus do not build webs, weaving silk threads leading to the branches, flowers, or leaves of plants where they live. Some Peucetia species were observed showing strong associations with more than 50 species of plants belonging to 17 families, all with glandular trichomes, showing their strong associations with this plant characteristic [56]. Both species P. rubrolineata and P. flava occur from Venezuela to Argentina [55,57] and in the Serra do Japi—Brazil, P. rubrolineata and P. flava are found exclusively associated with the same plant: Trichogoniopsis adenantha (DC) (Asteraceae) [56,58]. The two spiders seem to use the same micro-habitat and food resources [57] and have similar phenologies and population fluctuation through the year [58]. Considering all ecological similarities, this pair of species living in the same plant comprises a promising study system to understand niche partitioning. In this sense the question we address here is: Is there niche partitioning at any level that helps explaining the coexistence of these two species? There are some possibilities that could explain the coexistence of these two Peucetia species: (1) microhabitat segregation—whereby P. rubrolineata and P. flava would occupy different parts of the plant (e.g., leaves, stems, and flower heads) avoiding competition and allowing coexistence even while inhabiting the same plant. 2) mesohabitat segregation—in which Peucetia species exhibit differential distribution based on luminosity and humidity where the host plant is found. 3) macrohabitat segregation—P. rubrolineata and P. flava may be distributed differently along an altitudinal gradient. On the one hand, in the field these two species apparently occur in the same specific parts in the host plant (microhabitat), occur in similar proportions along the altitudinal gradient (macrohabitat) and their dynamics and phenologies are similar [58]. On the other hand, these two species of spiders are observed in places with different light levels even if they occupy the same plant, P rubrolineata occurring more in shaded places and P. flava occurring more in open places. Our hypothesis is that there is segregation at a different spatial level (mesohabitat), where one species occurs more often in shaded places and the other species occurs more often in open places due to its physiological tolerances. However, the other possibilities of habitat segregation (micro and macrohabitat) will also be tested in the present study.
Materials and methods
Study area
This study was carried out at Serra do Japi, located between 23° 11ʹ S and 46° 52ʹ W of the Atlantic Plateau between the municipalities of Jundiaí, Itupeva, Cabreúva, Pirapora do Bom Jesus, and Cajamar in the state of São Paulo, Brazil. Located between 700 and 1,300m above the sea level, this area (354 km2) comprises seasonal mesophyllous forests. The climate is seasonally well defined, with average monthly temperatures varying from 13.5°C in July to 20.3°C in January and with a rainy season in summer (December–March) and dry season in winter (June–August) [59]. Surveys were conducted in different regions of the Serra: (1) at the Department of Water and Sewage (DAE) dam; (2) near the field base at the area locally known as “Biquinha”; (3) along a regional pathway at a locality named “TV cultura” at two altitudes (900–1000 m and 1170–1290 m). To determine the role of (1) microhabitat—stratification on plants, and (2) mesohabitat—patches with different environmental conditions in resource partitioning, studies were conducted from 2013–2015. To determine the role of macrohabitat—altitudinal distribution, research was carried out in March 2014 and March 2017. At the end of the Materials and Methods, there is a table summarizing all methods used, dates, and specific record locations (Table 1).
Occurrence of Peucetia rubrolineata and P. flava in Trichogoniopsis adenantha
During the period between July 2013 to December 2015, we inspected 300 T. adenantha in open and shaded areas (S1 Table). For each plant with spiders, we registered the species of spider, the instar of development and the specific part in the plant where the spider was found. In each monthly survey the 300 plants were randomly selected so that these 300 plants could be different each month. The two species of Peucetia can be easily recognized in the field by the different pattern of staining on the cephalothorax and abdomen. In P. rubrolineata a continuous double line can be observed in the cephalothorax and in P. flava that same line is cracked (Fig 1). We identified the instars in accordance with the guidelines published by [60]. This classification was based on the size of the cephalothorax and the first pair of legs (For details see [58,61]. We collected some individuals from both species of Peucetia for later corroboration of identification with the specialist (Brescovit A.D.),
Microhabitat—Stratification on plant
Phenology and availability of types of branches of the plant Trichogoniopsis adenantha
To uncover the phenology of T. adenantha, of the 300 plants previously recorded we selected 20 plants randomly in each month and registered the number of vegetative branches and the state of development of flower heads. Once the phenology of the plant was recorded, we could evaluate if the phenology affected the occurrence of instars of P. rubrolineata and P. flava on different branches of the host plant.
We classified flower heads in situ into five phenophases as described by [62] and [63]: (F1) closed bud, very small, bracts covering the whole bud; (F2) open bud, with all flowers visible but all closed (pre-anthesis); (F3) open flowers with long and bluish-pink stigmas (anthesis and fertilization); (F4) complete formation of yellow flowers on flower head; stigmas beginning to drop (fruit development phase); and (F5) dry flower head; mature seeds, beginning of the dispersion phase (S2 Table).
Subsequently, based on the predominance of the phenophases of each flower head, we classified the branches into the following categories: (1) vegetative branches; (2) branches with flower buds, with the mean number of flowers in the F1 or F2 phase greater than 50% of the total number of flower heads (owing to inter-individual variation in the number of flower heads from 6 to 18 flower heads per branch); (3) branches with open flowers, with the mean number of flowers in the F3 greater than 50% of the total number of flower heads; (4) type 4 branches, with the mean number of flowers in the F4 greater than 50% of the total number of flower heads; (5) type 5 branches, with the mean number of flowers in the F5 greater than 50% of the total number of flower heads.
Distribution of Peucetia rubrolineata and Peucetia flava instars on Trichogoniopsis adenantha branches
To verify whether the distribution of the P. rubrolineata instars was similar in the different types of branches, we compared the frequency of the types of branches available with the branches actually occupied by the instars of the spiders. For this analysis, we used only the information from the months where P. rubrolineata was most abundant within the two-and-a-half-year period previously recorded. The same procedure was performed for P. flava.
Micro-site on the branch of the Trichogoniopsis adenantha plant
To verify whether instars of P. rubrolineata have the same pattern of distribution in different specific parts of the plant (leaf, stem, and flower head and dry flower head), we used the Chi-square Test. Here again, we used the data from the same two-and-a-half-year period previously recorded. As the null hypothesis, we predicted the spiders of each instar would occur on similar parts of the branch with similar probability. We also adopted the same protocol for P. flava.
Similarity in the distribution of instars of the two Peucetia species on Trichogoniopsis adenantha
We also investigated whether the same instars of both species occupy the same part of the plant and used the Chi-squared Test to examine the significance of observed differences in the frequency of occupation. To do this, we related the total available parts of the inspected plants to the parts that were actually occupied by the same instar of both Peucetia species.
Mesohabitat—Patches with different environmental conditions
Plant habitat
In a separate survey, we recorded T. adenantha plants that had at least one individual of some of the two species of Peucetia until reaching a total of 100 records of individuals of each species. In those plants in which an individual of Peucetia was registered we set a camera with a fisheye lens to photograph the cover vegetation above each plant. Subsequently, we divided photographs into sectors and classified each site according to canopy cover percentage classes: 0–20%; 21–40%; 41–60%; 61–80%, and 81–100%. We then tested if the distribution pattern of the two species of Peucetia differed among classes of vegetal cover, using a Chi-squared Test.
Co-occurrence of both spider species
To determine the degree of niche overlap of the two species of Peucetia in each instar, we used the Jaccard overlap index [64]:
Where "A" is the number of plants where both species of spiders were present simultaneously, "B" is the number of plants where only P. rubrolineata was present and "C" the number of plants where only P. flava was present. To calculate the index, we pooled together all the surveyed plants where at least one individual of some of the spider species was present during the two-and-a-half-year period. The index was calculated for the same instar of the two species of Peucetia separately because the two species presented in similar proportions of abundance throughout the year and the same instars of the two species occupy the same type of branch on the plant.
Macrohabitat—Altitudinal separation
Altitudinal distribution
We verified whether the species of Peucetia had a differential altitudinal distribution pattern. Here, T. adenantha plants were inspected in March 2014 at four different sites with different altitudes: (1) first site called dam of the DAE with an altitude of 800–900 m; (2) this second location at an elevation of 900–1,100 m was subdivided into two locations which have the same altitude, (2a) region near the research base that has a shaded area and (2b) pathway of “TV culture” that has an open region; (3) third location regional "TV culture" at an altitude of 1,170–1,290 m. In each altitudinal range, we inspected the T. adenantha plants in open and shaded areas as follows: (1) in the first location we registered 199 plants (149 and 50 plants in shaded and open areas, respectively); (2a) in this location was registered 189 plants (29 and 160 plants in shaded and open areas, respectively);(2b) in this location was registered 113 (98 and 15 plants in shaded and open areas, respectively); (3) finally, in this location was registered 115 plants (20 and 95 plants in shaded and open areas, respectively). The numbers of plants available for inspection varied at different altitudes. In relation to the site (2a) that presents an altitude range of 900–1,100 m, in the year in which the sampling was re-sampled, in 2014, it was an open area due to the mixed vegetation of native trees and Eucalyptus had been cut and, consequently, T. adenantha plants were more abundant in these open areas. Three years later (2017), the tree vegetation grew and shaded most of the T. adenantha. Thus, we sampled this area (2a) again in 2017 to verify the effect of shading on the relative abundance of the two Peucetia species. In each T. adenantha observed, we recorded the environment in which the plant was (open or shaded according to the photographs of canopy cover) and the Peucetia species found on each plant. We used an altimeter to measure altitude. Subsequently, we applied the Chi-squared test (with Williams' correction) to compare the frequencies of the two spider species with the frequencies of T. adenantha in open or shaded environments at different altitudes. We conducted these analyses to separate the effect of altitude with respect to the occurrence of these spiders in different microenvironments, in the case of open areas and more shaded areas.
For all comparisons regarding the frequencies of use of habitat—temporal segregation, ontogenetic variation, microhabitat segregation and macrohabitat partitioning—we used a Chi-square test with Monte Carlo permutations with 10000 simulations [65] to test for significance considering an alpha value of 0.05. In cases of multiple pairwise comparisons we used the Williams´ correction. For all statistical analyzes, we used the free software R [66]. The package “rmngb” was used for all Chi-squared analyses.
Results
Phenology of Trichogoniopsis adenantha
In general, T. adenantha had both vegetative and reproductive branches throughout the year; however, the proportions varied with the season (Fig 2). In winter and spring, vegetative branches occurred in larger proportions. At the end of the dry season, usually in spring (months), there was growth of vegetative branches, followed by an increase in the number of reproductive branches, with a large number of buds in spring and summer. During March and April, there was a period with greater abundance of branches with open flowers. In May, a large number of flowering branches occurred in phase 4 (seed formation), and in June and July, there were several flowering branches in phases 4 and 5 dry (flower heads). In general, vegetative branches were more abundant than reproductive branches. Production of flower heads occurred throughout the year; however, the proportion of each phenophase varied from year to year (Fig 2).
Microhabitat—Stratification on the plant
Distribution of the Peucetia species on T. adenantha branches types
Young spiders of both species were more frequent on the vegetative branches than in reproductive ones (Chi-squared test = P. rubrolineata: χ2 = 9.37, P = 0.034; P. flava: χ2 = 10.777, P = 0.005; in 10000 simulations). Juvenile spiders were more frequent on vegetative branches and on type five branch (Chi-squared test = P. rubrolineata: X2 = 8.31, P = 0.043; P. flava: X2 = 11.111, P = 0.009), as well as subadults, (Chi-squared test = P. rubrolineata: X2 = 11.327, p = 0.005; P. flava: X2 = 8.512, p = 0.006) although the other types of branches are more frequent. Adult individuals were more frequent on type 5 branches, especially in the inflorescences where shelters made with leaves and dry flower heads are often observed (Chi-squared test = P. rubrolineata: X2 = 10.096, P = 0.0038; P. flava: X2 = 12.791, P = < 0.001). Finally, spiderlings of the two Peucetia species were the only ones that presented similar observed and expected frequencies in all types of branches (Chi-squared test = P. rubrolineata: X2 = 4.22, P = 0.215; P. flava: X2 = 1.22, P = 1) (Fig 3). Regardless of the proportion of the different branches, the pattern of distribution of the instars of the two species of Peucetia in these branches remained the same throughout the year.
Micro-sites on the branches of Trichogoniopsis adenantha plants
The distribution of different instars of both P. rubrolineata and P. flava on different parts of the branches was inhomogeneous (Table 2). Second and third instars of P. rubrolineata were more frequently recorded on leaves, whereas fourth-instar spiders were observed on the leaves, stem, and flower heads, the fifth, sixth, and seventh instars occurred more frequently in the dry flower heads. Adults (eighth-instar) occurred more frequently in dry flower heads and in shelters made from remnants of the dry flower heads (Table 2; Fig 4).
Despite the difference in the occupation of the types of branches and parts of the plant among instars of the same species, when the same instars of the two species are compared, the pattern of occupation on the plant is similar (Table 3; Fig 5). Only spiderlings presented a different occupation pattern between species; P. rubrolineata spiderlings used preferentially the leaves, whereas P. flava spiderlings were mostly found in the stem and flower heads (Table 3; Fig 5).
Mesohabitat—Patches with different environmental conditions
Co-occurrence of both Peucetia species
The frequencies of the two species of Peucetia were different in the two types of vegetation cover (X2 = 75.444, P = < 0.001; in 10000 simulations) (Fig 6). Peucetia rubrolineata was recorded at a higher frequency in T. adenantha plants located in environments with denser canopy (X2 = 41.622, P = < 0.001) (Fig 6B). Conversely, P. flava was recorded more frequently in T. adenantha plants in more open environments (X2 = 13.085; P = 0.01) (Fig 6A). In the intermediary levels of vegetation cover, the frequencies of both Peucetia species were similar (Fig 6).
In environments with intermediate canopy cover, a larger number of plants were observed with the two Peucetia species. Of the 729 plants that had spiders during the study period, 43.5% contained only P. flava and 53.3% contained only P. rubrolineata, whereas only 3.4% of the plants contained both species. The values of niche overlap varied from 0.024 to 0.059, with a mean of 0.034, indicating low overlap between the same instar of the two species of Peucetia (Table 4).
Macrohabitat—Altitudinal separation
Altitudinal distribution
Both Peucetia species were found at all altitudes at the study site, but in different frequencies (63 individuals of P. rubrolineata and 37 individuals of P. flava in total). However, these frequencies varied depending on availability of T. adenantha plants in more open areas (low canopy cover) or in more closed places (high canopy cover) and not with respect to the altitude. Sites with low canopy cover had mostly individuals of P. flava, whereas sites with high canopy cover had individuals of P. rubrolineata (Table 5). In the observation made in 2014 at site (2b), called the TV Cultura Pathway Region, T. adenantha plants were found with little canopy cover and a higher abundance of P. flava was recorded. Three years later, in 2017, a higher abundance of P. rubrolineata was observed (Table 5) in the same region and at the same altitude (2b*), when vegetation grew and canopy cover increased on T. adenantha plants.
Discussion
Niche theory suggests that the coexistence of ecologically similar species requires some form of resource partitioning that reduces or prevents interspecific competition [13]. In the studied system, the two Peucetia species inhabiting plants of T. adenantha present similar phenology and population dynamics [58]. In addition, the same instars of the two spider species had similar distributions across the different parts of the plant, indicating that the microhabitat use overlaps between the two species. However, our hypothesis that the two Peucetia species inhabiting T. adenantha plants are segregated has been confirmed, because they were distributed differently at the mesohabitat level. Peucetia rubrolineata occurred more frequently in places where canopy cover was high, whereas P. flava occurred more frequently in sites with open canopy. Although several studies have shown that interspecific competition is one of the main factors frequently observed in phylogenetically close spiders (e.g. [41]), in our study there is low overlap at the mesohabitat scale. Thus, we can infer from our results that competition may not be an important factor currently shaping these populations, although competition in the past might have favored habitat segregation patterns. Further research on sites where these species do not occur in sympatry could shed light on whether this segregation is a product of interspecific interactions or simply reflect different responses to abiotic conditions.
Results also indicated that these species have different altitudinal distributions because P. rubrolineata was more abundant at lower altitudes in the Serra do Japi, whereas P. flava occurred more frequently at higher altitudes. However, this difference seems to be more related to the availability of plants in different environments (shaded and exposed) than related to the altitude. At higher altitudes, the frequency of plants in the sunny areas was higher, as was the frequency of P. flava. In contrast, at lower altitudes, shaded areas were more frequent and the frequency of P. rubrolineata was higher. At intermediate altitudes, the abundance of spiders depended on the abundance of plants in the sun and shade. At the same site, the abundance of P. flava and P. rubrolineata varied in different years depending on the degree of shading. Although the two Peucetia species occurred in environments with intermediate canopy cover, the co-occurrence of these spiders in the same host plant was infrequent. Although we observed a clear distribution pattern of the two species of Peucetia more related to the type of environment (open or shaded) than to altitude, this statement should be taken with caution, because the recorded abundances of the two species for each altitude were low. Future studies would be necessary where the number of spiders collected by altitude was higher, and the low influence of altitude on the coexistence of the two species of Peucetia was corroborated.
Although P. rubrolineata and P. flava are sympatric and their population dynamics are similar throughout the year, the general pattern of spatial segregation registered occurred in the two years of study. This type of segregation as a central mechanism in the coexistence of sympatric spiders has been recorded in other cursorial spiders of the genus Syspira (Miturgidae), where two species of Miturgidae also exhibited different spatial distribution related to differences in temperature and humidity at the site [67]. In a central Amazon forest, [50] recorded significant differences in the soil type preference (sandy and clay soils) of four species of Ctenus (Ctenidae). In Lycosidae, horizontal stratification appears to be a common mechanism of niche differentiation [68]. In the temperate region the relative abundance of Pardosa alacris gradually increased with the canopy opening (mesohabitat level), whereas the opposite trend was observed for P. lugubris. Thus, niche differentiation along the canopy opening gradient seems to mediate the coexistence of these two species in meta-communities [52]. The Lycosids Geolycosa xera archboldi and G. hubbelli also exhibited preferences for different types of vegetation (mesohabitat level) and for different percentage of litter cover (micro habitat level) [69]. These examples show that habitat segregation at the mesohabitat level, as we found here, may be an important mechanism maintaining the high diversity of arthropods, especially spiders, in forested habitats.
Spiderlings of the two Peucetia species were more frequent on the vegetative branches of T. adenantha. A number of predatory arthropods (e.g., others Peucetia spider species, the spider Misumenops argenteus, Thomisidae) are specifically associated with glandular trichome-bearing plants like T. adenantha, where they capture prey attached to the sticky thricomes [57,70]. Spiderlings are probably more frequent in plant parts with more trichomes, which would increase the number of prey trapped [71]. Moreover, trichomes provide some protection to the spiderlings from their enemies, such as other spiders [72]. Fourth-instar young spiders were observed preying on endophytic herbivores of the flower head of T. adenantha, especially the fruit flies Trupanea sp. (Tephritidae), whereas juveniles (fifth and sixth instars) consumed inchworms of Geometridae that feed on flower heads and other insects that inhabit the plant (see [60]). In the case of subadults and adult spiders, they occurred more frequently in the flower head of the plant, especially those branches that also have dry structures where they rest. This higher frequency likely occurred because, besides having a place for camouflaging, it is also easier for them to capture larger prey, such as floral visitors, which visit flower heads with open flowers at phase 3 and phase 4. In fact, [71] recorded adult spiders feeding on Pseudoscada erruca, Aeria olena, and Episcada carcinia (Ithomiinae), and all floral visitors on the flowers of T. adenantha. Additionally, adult females build the nest to place the egg sac using the plant's dried structures (personal observation). Thus, preferences for types of branches could be partially explained by the types of prey available and used as food by different instars as well as reproductive behavior. This ontogenetic habitat segregation found in both of the studied species may also decrease intraspecific competition among different instars of the same species, which would be reflected in the success of individuals in different stages of development.
Finally, because these two species of Peucetia are associated exclusively with T. adenantha, we expect that in the other parts of the Serra where we did not register these species, the same pattern of distribution and the same degree of spatial overlap occur in the different scales that we study. However, these species of Peucetia may be associated with other plants that have glandular trichomes, so if there are other plants in other places with glandular trichomes there would probably be other distribution patterns. However, further studies would be needed to compare the degree of effect of the availability of other plants on the distribution of Peucetia. Examining the niche partition between two morphologically similar, sympatric spiders, with overlapping temporal distributions we show inter- and intraspecific segregation in habitat use at different spatial scales. Although P. flava and P. rubrolineata are occurring in sympatry with similar phenologies, at similar altitudes and using the same parts of the same plants species, the distribution of the T. adenantha plant in shaded and open environments affects the distribution of the two species corroborating our hypothesis. Our results support the hypothesis of niche partitioning begetting diversity, and highlight the importance of analysing habitat use at multiple scales to understand mechanisms related to coexistence.
Supporting information
S1 Table [txt]
Phenology and abundance species.
S2 Table [txt]
Phenology plants.
Zdroje
1. Stevens GC. The latitudinal gradient in geographical range: how so many species coexist in the tropics. Am Nat. 1989;133(2): 240–256.
2. Hubbell SP. The unified neutral theory of biodiversity and biogeography (MPB-32) (Vol. 32). Princeton University Press; 2001
3. Tilman D. Niche tradeoffs, neutrality, and community structure: a stochastic theory of resource competition, invasion, and community assembly. Proc Natl Acad Sci USA. 2004;101 (30): 10854–10861. doi: 10.1073/pnas.0403458101 15243158
4. Siepielski AM, McPeek MA. On the evidence for species coexistence: a critique of the coexistence program. Ecology. 2010;91(11): 3153–3164. doi: 10.1890/10-0154.1 21141177
5. Brown JH. Why are there so many species in the tropics? J Biogeogr. 2014;41: 8–22. doi: 10.1111/jbi.12228 25684838
6. Chillo V, Rodríguez D, Ojeda RA. Niche partitioning and coexistence between two mammalian herbivores in the Dry Chaco of Argentina. Acta Oecol. 2010;36: 611–616.
7. Gause GF. Experimental analysis of Vito Volterra’s mathematical theory of the struggle for existence. Science. 1934;79(2036): 16–17.
8. Hardin G. The competitive exclusion principle. Science. 1960;131(3409): 1292–1297. doi: 10.1126/science.131.3409.1292 14399717
9. Vance RR. Interference competition and the coexistence of two competitors on a single limiting resource. Ecology. 1984;65(5): 1349–1357.
10. Hendrickx F, De Cock K, De Bakker D, Maelfait JP. Differences in geographic distribution and habitat of some cryptic species in the Pardosa lugubris group (Lycosidae, Araneae) in Belgium. Belgian journal of zoology. 2001;131(2): 79–84.
11. DeVito J, Meik JM, Gerson MM, Formanowicz JrDR. Physiological tolerances of three sympatric riparian wolf spiders (Araneae: Lycosidae) correspond with microhabitat distributions. Canadian journal of zoology. 2004;82(7): 1119–1125.
12. Kelly CK, Bowler MG. Temporal niche dynamics, relative abundance and phylogenetic signal of coexisting species. Theor Ecol. 2009;2: 161–169.
13. Chesson P. Mechanisms of maintenance of species diversity. Annu Rev Ecol Syst. 2000;31(1), 343–366.
14. Di Bitetti MS, De Angelo CD, Di Blanco YE, Paviolo A. Niche partitioning and species coexistence in a Neotropical felid assemblage. Acta Oecol. 2010;36: 403–412.
15. Young HS, Shaffer SA, McCauley DJ, Foley DJ, Dirzo R, Block BA. Resource partitioning by species but not sex in sympatric boobies in the Central Pacific Ocean. Mar. Ecol. Prog. Ser. 2010;403: 291–301.
16. Novcic I. Niche dynamics of shorebirds in Delaware Bay: Foraging behavior, habitat choice and migration timing. Acta Oecol. 2016;75: 68–76.
17. Toft CA. Resource partitioning in amphibians and reptiles. Copeia, 1985;1: 1–21.
18. Segurado P, Figueiredoa D. Niche partitioning and species coexistence in a Neotropical felid assemblage. Acta Oecol. 2007;32: 134–144.
19. Ross S. T. Resource partitioning in fish assemblages: a review of field studies. Copeia. 1986;352–388.
20. Boyer S, Rivault C. Habitat selection and coexistence of invasive cockroach species (Dictyoptera) in sugar-cane fields on Réunion island. Acta Oecol. 2005;29: 16–26.
21. Wise DH. Spiders in ecological webs. Cambridge: Cambridge University Press; 1995.
22. Wise DH. Cannibalism, food limitation, intraspecific competition, and the regulation of spider populations. Annu. Rev. Entomol. 2006;51: 441–465. doi: 10.1146/annurev.ento.51.110104.150947 16332219
23. Marshall SD, Rypstra AL. Spider competition in structurally simple ecosystems. Journal of Arachnology 1999;27: 343–350.
24. Michalko R, Pekar S. Niche partitioning and niche filtering jointly mediate the coexistence of three closely related spider species (Araneae, Philodromidae). Ecol Entomol. 2015;40(1): 22–33.
25. Turnbull AL. Ecology of the true spiders. Annu Rev Entomol, 1973;18: 305–348.
26. Castanheira P, Pérez-González A, Baptista R. Spider diversity (Arachnida: Araneae) in Atlantic Forest areas at Pedra Branca State Park, Rio de Janeiro, Brazil. Biodiversity Data Journal. 2016;4: e7055. doi: 10.3897/BDJ.4.e7055
27. Huber BA. Spider diversity and endemism in a South American hotspot: 20 new species of Carapoia (Araneae: Pholcidae) from Brazil's Atlantic Forest. Zootaxa. 2016;4177(1): 1–69. doi: 10.11646/zootaxa.4177.1.1 27811735
28. Rodrigues EN, Rodrigues PE, Mendonça MDS Jr. Spider species composition in the tree-shrub strata of riparian forests and its microhabitats in southern Brazil. Zoologia (Curitiba). 2016;33(3):1–17.
29. Nyffeler M, Birkhofer K. An estimated 400–800 million tons of prey are annually killed by the global spider community. Sci. Nat. 2017;104(3–4): 30.
30. Raub F, Höfer H, Scheuermann L. Spider (Arachnida, Araneae) diversity in secondary and old‐growth southern Atlantic forests of Paraná state, Brazil. Ecology. 2017;98(7): 1975–1975. doi: 10.1002/ecy.1854 28403544
31. Olive CW. Foraging Specialization in Orb‐Weaving Spiders. Ecology. 1980;61(5): 1133–1144.
32. Nyffeler M. Prey selection of spiders in the field. J Arachnol. 1999;27: 317–324.
33. Yamanoi T, Miyashita T. Foraging strategy of nocturnal orb-web spiders (Araneidae: Neoscona) with special reference to the possibility of beetle specialization by N. punctigera. Acta Arachnol. 2005;54(1), 13–19.
34. Novak T, Tkavc T, Kuntner M, Arnet AE, Delakorda SL, Perc M, et al. Niche partitioning in orbweaving spiders Meta menardi and Metellina merianae (Tetragnathidae). Acta Oecol 2010;36: 522–529.
35. Herberstein ME, Elgar MA. Foraging strategies of Eriophora transmarina and Nephila plumipes (Araneae: Araneoidea): Nocturnal and diurnal orb‐weaving spiders. Aust J Ecol. 1994;19(4), 451–457.
36. Herberstein M. E. Niche partitioning in three sympatric web-building spiders (Araneae: Linyphiidae). Bull. Br. Arachnol. Soc. 1997;10 (7): 233–238.
37. Oxford GS, Gillespie RG. Evolution and ecology of spider coloration. Annu Rev Entomol. 1998;43(1): 619–643.
38. Hénaut Y, García-Ballinas JA, Alauzet C. Variations in web construction in Leucauge venusta (Araneae, Tetragnathidae). J Arachnol. 2006;34(1): 234–240.
39. Harwood JD, Obrycki JJ. Web-construction behavior of linyphiid spiders (Araneae, Linyphiidae): competition and co-existence within a generalist predator guild. J Insect Behav. 2005;18(5): 593–607.
40. Cumming MS, Wesołowska W. Habitat separation in a species‐rich assemblage of jumping spiders (Araneae: Salticidae) in a suburban study site in Zimbabwe. J Zoo. 2004;262(1): 1–10.
41. Portela E, Willemart RH, Gasnier TR. Soil type preference and the coexistence of two species of wandering spiders (Ctenus amphora and C. crulsi: Ctenidae) in a rainforest in Central Amazonia. J Arachnol. 2013;41(1), 85–87.
42. Souza HS, Messas YF, de Oliveira Gonzaga M, Vasconcellos-Neto J. Substrate selection and spatial segregation by two congeneric species of Eustala (Araneae: Araneidae) in southeastern Brazil. J Arachnol. 2015;43(1), 59–66.
43. Frick H, Kropf C, Nentwig W. Laboratory temperature preferences of the wolf spider Pardosa riparia (Araneae: Lycosidae). Arachnology. 2007;14(1), 45–49.
44. Mammola S, Isaia M. Niche differentiation in Meta bourneti and M. menardi (Araneae, Tetragnathidae) with notes on the life history. Int J Speleol. 2014;43(3): 343–353.
45. Mammola S, Piano E, Isaia M. Step back! Niche dynamics in cave-dwelling predators. Acta Oecol. 2016;75: 35–42.
46. Cardoso JCF, Michalko R, Gonzaga MO. Specific parasites indirectly influence niche occupation of non-hosts community members. Oecologia. 2018;188(2): 343–353. doi: 10.1007/s00442-018-4163-x 29785698
47. Černecká Ľ, Michalko R, Krištín A. Abiotic factors and biotic interactions jointly drive spider assemblages in nest-boxes in mixed forests. J Arachnol. 2017;45(2): 213–223.
48. Turner M, Polis GA. 1979. Patterns of co-existence in a guild of raptorial spiders. J Animal Ecol. 1985;48(2): 509–520.
49. Uetz GW. 1977. Coexistence in a guild of wandering spiders. J. Animal Ecol. 1973;46(2): 531–541.
50. Gasnier TR, Höfer H. Patterns of abundance of four species of wandering spiders (Ctenidae, Ctenus) in a forest in central Amazonia. J Arachnol. 2001;29(1): 95–104.
51. Krumpálová Z, Tuf IH. Circadian rhythms of ground living spiders: mechanisms of coexistence strategy based on the body size. Pol J Ecol. 2013;61(3): 575–586.
52. Michalko R, Košulič O, Hula V, Surovcová K. Niche differentiation of two sibling wolf spider species, Pardosa lugubris and Pardosa alacris, along a canopy openness gradient. J. Arachnol. 2016;44(1), 46–51.
53. Pétillon J, Leroy B, Djoudi EA, Vedel V. Small and large spatial scale coexistence of ctenid spiders in a neotropical forest (French Guiana). Tropical zoology. 2018;31(2): 85–98.
54. Santos AJ, Brescovit AD. A revision of the Neotropical species of the lynx spider genus Peucetia Thorell 1869 (Araneae: Oxyopidae). Insect Syst Evol. 2003;34(1): 95–116.
55. World Spider Catalog. World Spider Catalog. Natural History Museum Bern. Version 20.0; 2019. [cited 2019 May 20]. Available from: http://wsc.nmbe.ch
56. Vasconcellos‐Neto J, Romero GQ, Santos AJ, Dippenaar‐Schoeman AS. Associations of spiders of the genus Peucetia (Oxyopidae) with plants bearing glandular hairs. Biotropica. 2007;39(2): 221–226.
57. Vasconcellos-Neto J, Messas YF, da Silva Souza H, Villanueva-Bonila GA, Romero GQ. Spider–plant interactions: an ecological approach. In: Viera C, Gonzaga MO, editors. Behaviour and Ecology of Spiders. Springer, Cham; 2017. pp. 165–214.
58. Villanueva-Bonilla GA, Safuan-Naide S, Vasconcellos-Neto João. Population dynamics and phenology of two congeneric and sympatric lynx spiders Peucetia rubrolineata Keyserling, 1877 and Peucetia flava Keyserling, 1877 (Oxyopidae). J. Nat. Hist. 2018; https://doi.org/10.1080/00222933.2018.1433339
59. Pinto HS. Clima na Serra do Japi. In: Morellato LPC, editors. História Natural da Serra do Japi: Ecologia e Preservação de uma Área Florestal no Sudeste do Brasil. Campinas: Editora da Unicamp/Fapesp; 1992. pp. 30–38.
60. Romero GQ, Vasconcellos-Neto J. Flowering phenology, seed set and arthropod guilds in Trichogoniopsis adenantha (Asteraceae) in south-east Brazil. Rev Brasil. Bot. 2005;28:171–178.
61. Villanueva-Bonilla GA, Vasconcellos-Neto J. Population dynamics and phenology of the wall crab spider Selenops cocheleti Simon, 1880 (Araneae: Selenopidae) in Southeastern Brazil. Stud Neotrop Fauna Environ. 2016;51(3):215–230
62. Almeida AM. Padrões de ocorrência em insetos endófagos associados com capítulos de Trichogoniopsis adenantha (DC) (Asteraceae). M.Sc. Thesis, Universidade Estadual de Campinas (UNICAMP). 1997
63. Romero GQ. Estudo experimental da associação de Runcinioides argenteus (Araneae, Thomisidae) em Trichogoniopsis adenantha (DC) (Asteraceae). M.Sc. Thesis, Universidade Estadual de Campinas. 2001.
64. Chao A, Chazdon RL, Colwell RK, Shen TJ. A new statistical approach for assessing similarity of species composition with incidence and abundance data. Ecology letters. 2005;8(2), 148–159.
65. Hope A. C. A. A simplified Monte Carlo significance test procedure. J. Roy, Statist. Soc. B 1968;30, 582–598.
66. R Core Team. R: A language and environment for statistical computing. Vienna: R Foundation for Statistical Computing. 2019. Available from: http://www.R-project.org/
67. Nieto-Castañeda IG, Jiménez-Jiménez ML. Possible niche differentiation of two desert wandering spiders of the genus Syspira (Araneae: Miturgidae). J. Arachnol. 2009;37(3): 299–305.
68. Suwa M. Space partitioning among the wolf spider Pardosa amentata species group in Hokkaido, Japan. Res Popul Ecol (Kyoto). 1986;28(2): 231–252.
69. Carrel J. Ecology of Two Burrowing Wolf Spiders (Araneae: Lycosidae) Syntopic in Florida Scrub: Burrow/Body Size Relationships and Habitat Preferences. J. Kans. Entomol. Soc. 2003;76(1): 16–30.
70. Romero GQ, Vasconcellos-Neto J. Natural history of Misumenops argenteus (Thomisidae): seasonality and diet on Trichogoniopsis adenantha (Asteraceae). J Arachnol. 2003;31: 297–304.
71. Romero GQ, Souza JC, Vasconcellos-Neto J. Anti-herbivore protection by mutualistic spiders and the role of plant glandular trichomes. Ecology 2008;89: 3105–3115.
72. Langellotto GA, Denno RF. Responses of invertebrate natural enemies to complex-structured habitats: a meta-analytical synthesis. Oecologia. 2004;139(1): 1–10. doi: 10.1007/s00442-004-1497-3 14872336
Článek vyšel v časopise
PLOS One
2019 Číslo 10
- S diagnostikou Parkinsonovy nemoci může nově pomoci AI nástroj pro hodnocení mrkacího reflexu
- Je libo čepici místo mozkového implantátu?
- Metamizol jako analgetikum první volby: kdy, pro koho, jak a proč?
- Pomůže v budoucnu s triáží na pohotovostech umělá inteligence?
- AI může chirurgům poskytnout cenná data i zpětnou vazbu v reálném čase
Nejčtenější v tomto čísle
- Correction: Low dose naltrexone: Effects on medication in rheumatoid and seropositive arthritis. A nationwide register-based controlled quasi-experimental before-after study
- Combining CDK4/6 inhibitors ribociclib and palbociclib with cytotoxic agents does not enhance cytotoxicity
- Experimentally validated simulation of coronary stents considering different dogboning ratios and asymmetric stent positioning
- Risk factors associated with IgA vasculitis with nephritis (Henoch–Schönlein purpura nephritis) progressing to unfavorable outcomes: A meta-analysis