Local and regional richness and rarity of leaf-litter ants: An overview from spacial scale in neotropical region ()
1. INTRODUCTION
Why this distribution of species abundances is so regularly observed among different taxonomic sets in geographically diverse systems is a question that has received considerable theoretical and empirical investigation [1-5].
There is an abiding interest in the number of species in local communities, because species are fundamental biodiversity units [1,6]. A major research agenda in ecology is to explain geographic patterns of species richness [7]. Many studies address the latitudinal change in species richness and why there are so many species in the tropics [8]. Others examine species distribution changes related with elevation [9-11], asking whether and why there is a mid-elevation peak in diversity. Conservation biologists examine whether species richness changes with land use or landscape fragmentation, and whether richness changes over time [12]. What challenges our ability to interpret natural phenomena when we investigate what apparently is not correlated to any of the physical, climatic and taxocenotic characteristics whose involving the patterns of species distribution? In which situations and how often this lack of standards can occur on a local and regional scale?
Ants and other invertebrate organisms should be included in biodiversity studies because of their high diversity and rapid response to environmental changes [13, 14]. When choosing invertebrate taxa to survey, the relative merits of different taxa are often discussed [15], but are several reasons for choosing ants to investigate biodiversity patterns [16]. In most terrestrial ecosystems ants are a conspicuous presence and they are among the most commonly studied terrestrial invertebrates. They are mostly scavengers and predators, and they have large impacts on soil formation, seed predation/dispersal, and in the invertebrate community structure [17,18]. Therefore, ants are particularly good candidates for monitoring community changes that may occur due to climate change or habitat fragmentation [19].
Rarity patterns of leaf-litter ants is an important research topic in myrmecology, because has relevance to biogeographical and ecological research. The assessment to leaf-litter ants community reveals a high structural complexity on micro-scales and represents the next step on biodiversity studies. A challenging task is to understand patterns of species richness, abundance and rarity at larger spatial scales, extending to the entire geographic range of species [20,21].
The high number of species that co-occur presupposes the availability of nests and a spatiotemporal constancy of resources [22]. In the Leaf-litter strata, the ant species richness are high, with up to 30 species co-occurring in one square meter [13,23-25]. The assessment of this situation could promote a better comprehension about the ant species incidence in local and regional scale, and could answer some questions about permanence of rare species on forests sites, and establishing indicative of what possible environmental filters and/or exclusion competitive processes can prevail in model observed.
The species rarity of hyperdiverse taxon such as Formicidae could be an excellent tool for investigate forests primaries environments which corroborates for understanding ecological patterns like rare species and environmental heterogeneity [21]. Regional patterns of species richness in nature which occur over a variety of spatiotemporal scales are sometimes referred to as general laws of ecology [26,27]. Numerous ecological patterns exist, although many generalizations have been accepted without substantial evidence [28]. These general ecology laws are changing with the chaotic vision, and many traditional metrics of diversity need revision. A simple characterization of ant diversity in an uninsulated unit area can be more complicated than we think. The general assumption that habitat complexity is positively associated with the diversity and rarity of its constituent fauna may not be strongly supported across scale, taxa and systems being investigated to historical and contemporaneous process [29].
In this paper, we purpose a unusual discussion about richness and rarity of ant species on the leaf-litter strata in a dry forests reminiscent in mid-western of Brazil, in the Pantanal province, inserted on the Chacoan sub-region [30], and how can we infer which the boundaries demarcating local and regional scales, testing by Bayesian methods if the species richness is autocorrelated with latitude and longitude profile to local from regional scale.
2. MATERIAL AND METHODS
We’d been surveying on the Serra da Bodoquena National Park, localized on mid-western region of Brazil. The Bodoquena’s mountain range National Park, with 77.232 ha, frames on Cerrado-Pantanal biodiversity corridor; it is inserted on core area of Atlantic Forest biosphere reserve. The area is an environmental planning unit being a watershed which supplies the hydrological basin of western Brazil [31].
We surveyed on 10 localities occurred from September 2005 to February 2008, totalizing 262 leaf-litter samples along the one continuum block of Decidual Forest. The geographical coordinates of the sites was as following: Site 01—21˚27'55''S, 56˚48'34.3''W; 02—21˚30'58.7''S, 56˚57'59.1''W; 03—21˚07'14.7''S, 56˚43'08.2''W; 04— 20˚46'56.2''S, 56˚44'31.2''W; 05—21˚17'09.8''S, 56˚41'45.5''W; 06—20˚42'07.0''S, 56˚52'47.7''W; 07— 20˚32'41.48''S, 56˚54’44.66''W; 08—20˚50’26.16''S, 56˚47'31.85''W; 09—20˚45'53,6''S, 56˚44'53.11''W; 10— 21˚25'39.24''S, 56˚45'48.90''W (Figure 1).
Figure 1. Investigated area in mid-western Brazil, showing land cover and Bodoquena’s mountain range National Park.
The leaf-litter sampling was realized following Ants of the Leaf Litter protocol [32]. For each sample unit was extracted one square meter of leaf-litter in Winkler’s apparatuses covering one transect with 10.000 m2. The sampling site was choosing by selective form inside of each point, seeking the best micro-habitats for the leaflitter extraction on forest, in general, near to biggest trees. In each sampling point was extracted material until the superficial soil layer. The sifted volume with up 2 kg was transfer to a collector bag. In the field laboratory this material was extracted with mini-Winkler apparatuses for 24 hours, and after this period, the specimens were put in Eppendorfs pots. In the Hymenoptera Ecology Laboratory (HECOLAB-UFGD) individuals were kept in entomological pins on triangles of plastic. The voucher specimens were deposited on Biodiversity Museum of Universidade Federal da Grande Dourados (UFGD), Mato Grosso do Sul State, Brazil.
Data Analyses
We perform our analyses for calculate ICE, Singletons (uniques) and Doubletons (duplicates) utilizing EstimateS statistic package, 8.0 version [33]. ICE belongs to a class of non parametric estimators of species richness that are based on the number of rare species found in samples and assumes that the number of rare species decreases with increased sampling [34,35].
The data was available utilizing the species record’s frequency at the each sampling plot because is the better parameter for social insects [36]. We utilized a scale of classes of frequency (F) of records to 1% - 100%.
The correlation analysis was realized utilizing the datasets (ICE, Sobs, Singletons and Doubletons) and computed on Systat 12 software [37]. We utilized the Pearson Correlation index. For test if the local geographical coordinates has relationship with species richness we utilized the WinBUGS software for Bayesian models, version 3.1.2 [38]. The model is on the Appendix 01.
3. RESULTS
We recorded 170 species of leaf-litter ants on dry forests inside the Bodoquena’s mountain range National Park. For the complete species list see [21]. A total of 37 species were recorded just once (singletons) and 17 species recorded twice (doubletons). The total number of singletons and doubletons was representative reflecting about 32% of all ants species collected in all field campaigns. We observed an inverse relation between the number of most frequent species and the number of rare species, or else, species group recorded in 100% of samples was lesser than others groups recorded once and twice times (Figure 2).
The Pearson’s correlation analysis (Table 1, Figure 3) indicated a strong positive correlation between the number of species observed (Sobs) with singletons (R = 0.999) and doubletons (R = 0.881) and a moderate nega-
Figure 2. Frequency distribution of numbers of species per octave (p: 0.27) in 262 Winkler’s samples collected in Bodoquena Mountain Range National Park. Mato Grosso do Sul State/Brazil.
(a)(a)(c)
Figure 3. Pearson’s correlation with datasets adjusted (p = 0.5 and CI = 95%). (a) Strong positive correlation between Sobs and Singletons; (b) Strong positive correlation between Sobs and Doubletons; (c) Moderate negative correlation between Sobs and ICE estimator.
tive correlation between ICE estimator values with singletons (R = −0.691) and doubletons (R = −0.889) for all study sites.
The averages of species richness for each sampled site (Table 2, Figure 4) kept a constant profile for leaf-litter
Figure 4. Minimum and maximum averages of ants species richness in 10 localities along Bodoquena range mountain, Brazil. The number of Winkler’s sample for each localitie was as follow: Site 1: 25 samples, Site 2: 32, Site 3: 25, Site 4:25, Site 5: 25, Site 6: 25 Site 7:25, Site 8: 25, Site 9: 30, Site 10: 25.
Table 1. Pearson’s correlation values for 262 Winkler’s samples on 10 localities at the Bodoquena range mountain National Park, Brazil.
Table 2. Averages, Standard Deviation (sd) and Percentiles (P2,5% and P97%) of a Posteriori distribution with values of Species richness of 10 sampling sites through Bodoquena range mountain National Park, Brazil.
ants. Bayesian inference analysis showed no autocorrelation between species richness and latitudinal and longitudinal gradients for ten sites sampled in dry forest from Bodoquena range mountain (Figure 5).
4. DISCUSSION
The relationship between sample size and estimated species richness resulted in part because the number of rare species (low frequency of occurrence) did not necessarily decreases with increases the sample size in this spectrum of samples. Richness estimates are highly influenced by species with low frequencies of records. This fact reflects a complex pattern of distribution on the leaf-litter ant fauna for the sites observed. In the most preserved forests sites, this faunistic segment harbors a high number of specific ants species assemblages that nest and explore the litter by diversify forms. In general, this rarity syndrome could be explained by the following ways: 1) microhabitat specificity, 2) many localized populations with geographic restriction, 3) species with small population range size, 4) a high number of species in specific guilds, and 5) by the forest land cover fragmentation (Figure 1) that causes a strong selective
(a)(b)(c)
Figure 5. Bayesian inference for autocorrelation parameters with species richness (a); latitude (b) and longitude (c). The model is on the appendix 01.
pressure and induces a chaotic effect of vicariance. One of this driving force is explained by niche differentiation, where micro-habitats modeling the action of cryptic ants species, and many unpredictable filters can be act.
We consider richness among samples the most appropriate parameter for understand local species richness and the boundaries from local to regional scale. We infer that these dynamics is given by autocorrelation between species richness and geographical gradients, or else, the transition from local to regional diversity presuppose that richness is not autocorrelated with latitudinal and longitudinal patterns, considering the phytophisionomic matrix.
The abundance and distribution of each species is determined by combinations of many historical, physical and biotic factors, and that spatial variation in population density reflects the probability density distribution of the required combinations of these variables. We argue that on the litter strata, some sets of environmental variables are distributed independently of each other, and environmental variation isn’t spatially autocorrelated.
Characteristics of leaf-litter environment present a highly diverse ecological community with a small number of “common” species [39]; and other ant assemblages such as subterraneous species activity could propitiate the increase of singletons and doubletons. Studies realized by Silvestre et al. [40] and Silva & Silvestre [41] showing that the subterraneous ant species overlap activities between subterraneous layer and the upper layer, exploring the complex litter resources. The heterogenic factors such as light incidence, diversity of resources and nesting sites, amounted with an environment preserved propitiates an installation capacity of several species inside of specific guilds [42]. The regional geographic gradient showed that there was no autocorrelation with species richness for the sites sampled along Bodoquena range mountain. We verified in previous study [21] that in 100 leaf-litter samples the similarities between the samples has low values, going to 46% for unities with biggest similarities and some cases with 0% of similarities among the total of samples analyzed. The most of similarities was driven by species inside of generalists guilds. We conclude that in a continuous forest cover is impossible to define a scale of alpha diversity for Formicidae, this being possible only on islands; that the usual metrics of alpha e beta diversity do not apply to this model in Neotropical region [43].
We must investigate if the frequency of species substitution on each guild follows this profile and if these patterns of rarity could be compared with others localities through Neotropical region for a macro scale, considering different biomes.
5. ACKNOWLEDGEMENTS
We special thank ICMBio for collection authorization, Dr. Bruno Spacek for help and suggestions in Bayesian model, and Fabrício Baccaro for critical review of the manuscript.