Figures
Abstract
The effects of Late Quaternary climate change have been examined for many temperate New World taxa, but the impact of Pleistocene glacial cycles on Neotropical taxa is less well understood, specifically with respect to changes in population demography. Here, we examine historical demographic trends for six species of milksnake with representatives in both the temperate and tropical Americas to determine if species share responses to climate change as a taxon or by area (i.e., temperate versus tropical environments). Using a multilocus dataset, we test for the demographic signature of population expansion and decline using non-genealogical summary statistics, as well as coalescent-based methods. In addition, we determine whether range sizes are correlated with effective population sizes for milksnakes. Results indicate that there are no identifiable trends with respect to demographic response based on location, and that species responded to changing climates independently, with tropical taxa showing greater instability. There is also no correlation between range size and effective population size, with the largest population size belonging to the species with the smallest geographic distribution. Our study highlights the importance of not generalizing the demographic histories of taxa by region and further illustrates that the New World tropics may not have been a stable refuge during the Pleistocene.
Citation: Ruane S, Torres-Carvajal O, Burbrink FT (2015) Independent Demographic Responses to Climate Change among Temperate and Tropical Milksnakes (Colubridae: Genus Lampropeltis). PLoS ONE 10(6): e0128543. https://doi.org/10.1371/journal.pone.0128543
Academic Editor: Ulrich Joger, State Natural History Museum, GERMANY
Received: July 2, 2014; Accepted: April 28, 2015; Published: June 17, 2015
Copyright: © 2015 Ruane et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data can be found within the manuscript and its supporting information. GenBank accession numbers are in the manuscript.
Funding: This work was supported, in part, by the American Museum of Natural History (Theodore Roosevelt Memorial Fund); Graduate Women in Science (Vanessa Notchev Fund); The Explorer’s Club; and CUNY-PSC. This research was also supported, in part, under National Science Foundation Grants (CNS-0958379, CNS-0855217); Secretaría de Educación Superior, Ciencia y Tecnología (SENESCYT); The City University of New York High Performance Computing Center; and for tissue samples loaned from the University of Texas at Arlington, support was granted by National Science Foundation Grant (DEB-0613802) to J.A. Campbell.
Competing interests: The authors have declared there are no competing interests.
Introduction
Populations of all extant species that originated prior to the Holocene have experienced cyclical climatic change. For those found in temperate regions of North America and Europe, populations likely responded directly to climate changes induced by the glacial and interglacial cycles of the Quaternary [1]. Populations of different species occurring in areas of changing environments may each respond uniquely and experience either size decreases or increases, or simply remain stable. Some taxa, such as mammoths and other large mammals, declined in abundance, and ultimately became extinct [2]. Others persisted by adapting to the new environments [3] or, for instance during the Last Glacial Maximum (LGM), by migrating to more suitable areas [3,4]. Although some species persisted through periods of climatic change, population sizes may have been drastically reduced (e.g., [5]). In contrast, when conditions become favorable, population sizes for some species increased rapidly (e.g., [6–9]; reviewed in Hewitt [4,10–12]).
The signature of these demographic changes can be detected from genetic data analyzed with coalescent-based models (reviewed in Ho and Shapiro [13]). Trends with respect to changes in effective population size (Ne) through time can be associated with climatic or geological phenomena which may have altered population sizes or structure [14–21]. Demographic studies have until recently relied heavily on a single locus. Unfortunately, single loci may not represent the demographic history of the species or population under examination, especially if there has been selection on that particular gene region [22]. For example, balancing selection results in an excess of intermediate-frequency alleles for a locus, giving a genetic signature that is indistinguishable from population contraction [23,24]. Conversely, it may not be possible to separate the effects of purifying selection from population expansion, as both yield an excess of rare alleles [23,24]. These confounding effects of selection are therefore avoided by using multiple, unlinked markers (e.g., [25]).
For Nearctic species, Pleistocene glacial cycles may have directly altered distributions and populations sizes, where cycles of decline and growth are expected to occur with the contraction and expansion of favorable habitat, respectively [20,26–29]. The most recent glacial event in North America, the Wisconsin, began ~120–80 kya and reached its maximum at ~20 kya [30], with retreat at ~10 kya marking the end of the Pleistocene and beginning of the Holocene. During the LGM, much of eastern North America (NA) was covered by ice sheets as far south as the 38° latitude in some areas (Illinois, Indiana, and Ohio [31]). Cooler temperatures and boreal forests dominated much of the eastern U.S., pushing hardwood forests much farther south [32]. Open pine-forest habitat was predominant across western NA and the deserts of the southwest were cooler and wetter compared to current climates [33]. Several studies have found that after the LGM, temperate North American species expanded as more suitable habitat became available (e.g., pitvipers [9], woodpeckers [34], and rodents [35]). These climate changes may have also contributed to the diversification of species by isolating once contiguous populations into separate southern refugia [4,11,12,36,37].
The same glacial cycles may also be important for speciation and population size changes in the Neotropics [38–40], yet studies examining historical demography in the species-rich tropical biota of the New World (NW) are lacking (reviewed in [37]). In contrast to the impacts that glacial cycles had on Nearctic species, the effects on Neotropical taxa may not have been as severe [7] given the lack of extensive ice sheet formation in the tropics. Earlier studies suggested that the Neotropics were a region of climatic stability during the Pleistocene [41–43], but some studies now demonstrate that significantly lower temperatures by ~4–9°C were common across the NW tropics during the LGM [44–52]. Additionally, glaciers existed in high altitude regions of Mexico, Guatemala, Costa Rica, and in the Andes Mountains of South America during this time [53–56], with evidence of Pleistocene cooling in both Central and South America and increased aridity persisting until the start of the Holocene [11,12,51,57]. Climate alterations subsequently affected plant distributions [51], causing high altitude vegetation to shift to lower elevations and reducing tropical rain forest while increasing grasslands in Central and South America (reviewed in [11,12,51]). These habitat changes may have altered population dynamics of species inhabiting tropical rainforests, but the demographic impacts of these changes have not been extensively explored. Time-calibrated phylogenetic studies that include tropical species indicate that diversification took place during the Pleistocene for some taxa [58–63], but geological events throughout the Miocene and Pliocene also contributed to speciation in both Meso and South America [61,63–67]. Additionally, Quaternary climatic events may have affected population demographics of taxa, as they did with temperate species.
Although there are numerous examples of vertebrate clades that have representatives in both the NW temperate and tropical regions, no studies have directly compared the historical demography between such taxa. The snake genus Lampropeltis, commonly known as the kingsnakes and milksnakes, is composed of several closely related species in both temperate North America and tropical Central and South America. A recent study demonstrated that diversity within Lampropeltis, specifically within milksnakes, was underestimated, indicating that the former single species of milksnake, L. triangulum, is composed of seven taxa distributed in North, Central, and South America [62]. Therefore, we propose to examine the effects of Quaternary climate change on six closely related taxa that are found in both Nearctic (N = 3 species) and Neotropical (N = 3 species) regions. The three temperate species (L. triangulum, L. gentilis, and L. elapsoides) are found primarily within the United States, with one extending into southeastern Canada, and are found across a variety of habitats, which include deciduous forest, pine forest, plains, and desert conditions [68,69]. The three tropical species (L. abnorma, L. micropholis, and L. polyzona) are distributed throughout Central America and northern South America, with their very southern limit in Ecuador. These three species are found in thornscrub and in wet and dry tropical forest, as well as in both lowland and highland habitats [69–71]. Using a multilocus dataset, we test whether temperate North American species of milksnake had similar demographic responses compared to tropical Central/South American species. Specifically, we examine changes in population size through time for each taxon to determine if temperate and tropical species show similar demographic trends throughout the Pleistocene. We hypothesize that temperate species will show evidence of declines leading up to/and or during the LGM due to habitat contraction into southern refugia. This model suggests that temperate species, two of which have a current range that extends beyond the former southern extent of the glacier (L. triangulum, L. gentilis), would have then experienced range expansion after the retreat of the Laurentide Ice Sheet and increase in available habitat, as has been reported for other North American taxa [7].. Conversely, the tropical species may have maintained stable population sizes throughout the recent Pleistocene as has been shown for Amazonian mammals [7]. However we also expect to see increases in tropical milksnake population sizes around the beginning of the Holocene, which would be associated with the favorable environmental conditions present today.
By examining milksnakes across their extensive range in a historical demographic context, we address how population structure has been altered by Pleistocene climate change in closely related Nearctic and Neotropical taxa. We ask if there are general unified responses to climate change for closely related species. If so, these responses suggest that closely related taxa experience similar population increases or decreases regardless of location given changing climates. In contrast, it is possible that specific historical demographic trends are reflective of climate change associated with a specific region. In this case, we would expect that the population histories of species would be similar based on geographic ranges, with temperate species sharing similar demographic responses and tropical species sharing similar demographic responses).
Methods
Sampling and Genes
We selected six milksnake species for our analyses of demographic change; L. triangulum, L. gentilis, L. elapsoides, L. polyzona, L. abnorma, and L. micropholis, following the revised taxonomy of Ruane et al. [62] and using GenBank sequences from accession series KF214996–KF216452. These six taxa, with an abundance of populations previously sampled, have extensive distributions throughout the Nearctic and portions of Neotropics (Figs 1 and 2). The three temperate species included L. triangulum (n = 34), L. gentilis (n = 30), and L. elapsoides (n = 32), occurring in the USA and Canada. The tropical species included L. polyzona (n = 31), L. abnorma (n = 11), and L. micropholis (n = 16), rangeing from Western/Central Mexico to Ecuador (see S1 Table in supporting information for details of samples). All six species originated between 1.1 and 3.6 Ma [62] and so would have experienced Late Pleistocene climate change. For L. triangulum, L. elapsoides, and L. gentilis, three genes were used, the mitochondrial gene cytochrome b (Cytb) and two anonymous nuclear loci, 2CL8 and CL4. For L. polyzona, L. abnorma, and L. micropholis, the same three genes were used; additional nuclear loci were available for the tropical taxa as well and so we also included the protein coding genes NT3 and PRLR, the introns SPTBN intron 1, Vimenton intron 5, NAV intron 5, and Z-chromosome GAD intron 15, and the anonymous loci 2CL3, 2CL4, and LATCL (S2 Table). Nuclear loci heterozygosities were previously resolved with PHASE v2.1.1 [72] in Ruane et al. [62], and so we used the most probable pair of resulting alleles for analyses.
The extent of the Laurentide Ice Sheet during the last glacial maximum is shown by the grey dotted line (adapted from Pielou [85]). Ranges of all species are based on Ruane et al. [62]
Ranges of all species are based on Ruane et al. [62].
Historical Demographic Analyses
To determine if temperate and tropical milksnakes show similar or distinctly different trends with respect to demographic histories, we examined population size changes through time using Extended Bayesian Skyline Plots (EBSP; [73]) implemented in BEAST v.1.7.2 [74]. Using a multi-gene coalescent approach, this method estimates population size through time and does not require a pre-specified demographic model. We ran the EBSPs using all available loci, as well as using only the nuclear loci to determine if mtDNA had a large influence on the results. For the dataset including all loci, we used the mean substitution rate of Cytb estimated for Lampropeltis of 1x10-8 to scale the time axis, following Pyron and Burbrink [75]. For the nuclear only EBSPs, we used the mean rate estimated for the locus 2CL8, based on the full loci analyses (3.7x10-10). The EBSP for each species was run between 2x10 8 to 5x108 generations to achieve high effective sample size (ESS) values. Stationarity was assessed using Tracer v.1.5 [76]. We examined the demographic populationSizeChange parameter in Tracer, which indicates the most probable number of population size changes for each species. To determine if higher Ne (based on using the full loci datasets) was correlated with range size, we calculated the approximate range size in square kilometers in Google Earth Pro using the polygon function (www.googleearth.com) for each species, with the ranges based on Ruane et al. [62] (complete species range) as well as using the minimum polygon spanning only the samples used here (sample species range). We then used a Spearman rank correlation test to determine the relationship between range size and mean Ne. We also used this test to determine if the net population size change (the difference between the Ne at start of the EBSP and the Ne at time zero) and range were correlated. Spearman rank correlations were performed in the statistical program R [77].
We also tested for population size changes using non-genealogical coalescent methods (i.e., these methods do not reconstruct the genealogy of sequences) to compare estimates for each locus independently. These tests help address the confounding effects of changes on Ne versus selection upon a particular locus. We used the program DNAsp 5.0 [78] to examine population size changes using several summary statistics. The R2 statistic [79] was used to test for population expansion and is based on the difference in the number of singleton mutations and the average number of pairwise differences between samples. Coalescent simulations implemented in DNAsp were then used to assess significance and confidence intervals. We also generated mismatch distributions; resulting distributions indicate changes in population size or selection [80]. Harpending’s raggedness index (rg, [81]) was then used to assess the statistical significance of these distributions. Additionally, Tajima’s D [82] and Fu and Li’s D* and F* statistics [83] were used to test for population growth or decline versus constant population size. For these three statistics, an overabundance of rare polymorphisms (resulting in negative values) indicates there has been population expansion or positive selection, while positive values, resulting from an overabundance of intermediate-frequency polymorphism, indicate population decline or balancing selection.
Results
Sampling and Genes
For the EBSP analyses including all loci, all sequences were included, with 3–11 polymorphic loci for each species and 11–34 individuals per locus (S2 Table). For the nuclear only EBSP analyses, the same loci, excluding Cytb were included with 2–10 polymorphic loci for each species and 11–34 individuals per locus (S2 Table). For DNAsp analyses, sequences missing a significant amount of data for a gene were removed from analyses, as DNAsp excludes all sites with missing data (S2 Table).
Demographic Analyses
We recovered high ESS values (>200) for all parameters in BEAST and for every taxon, with the exception of L. micropholis. Despite increasing the chain length for L. micropholis, the ESS values for some parameters (e.g., the prior) did not greatly improve and so multiple runs were used to ensure consistency among results. The EBSPs using all loci generally showed stable populations through time for L. triangulum and L. gentilis, but for L. elapsoides, there was an increase in population size at ~50 kya (Fig 3). In contrast, the two most southerly distributed species, L. abnorma and L. micropholis, showed a slight population increase at ~70 kya and then a decline starting ~45 kya continuing to the present (Fig 3). The third tropical species, L. polyzona, showed a long period of population decline starting at least 1 Ma, followed by a slight increase and population stability beginning ~80 kya (Fig 3). Mean Ne ranged from ~1,100,000 (L. micropholis) to ~10,000,000 (L. polyzona; Table 1). The temperate species had fewer detectable population size changes (mean/median number of changes = 0.5−1.6/0.0−2.0; 95% HPD = 0.0−3.0 changes across species) compared to the tropical species (mean/median number of changes = 2.0−2.6/2.0; 95% HPD = 2.0−4.0 changes across species; Table 1). Overall, the temperate species also had larger population sizes and larger ranges than did the tropical species, with the exception of L. polyzona, which had the largest population size and the smallest complete species range (Table 1). However, the Spearman rank correlations for both complete range size versus mean Ne (rs = -0.029) and complete range size vs. net Ne (rs = 0.086) were not significant (d. f. = 4; P > 0.05), nor were the sample range sizes versus mean Ne (rs = 0.37) and sample range size vs. net Ne (rs = 0.20); (d. f. = 4; P > 0.05). When the EBSP analyses were run using only the nuclear loci, results were similar to the full loci EBSPs for some species for the populationsizechange parameter (L. polyzona, L. micropholis), but only L. micropholis resulted in a non-zero HPD (mean/median = 2.0/2.0; 95% HPD = 2.0−2.0 changes). Being that the EBSP estimates for the nuclear only datasets had larger posterior distributions for both population sizes and the population size change parameter and that these results were likely less accurate than those including all available data (S3 Table), we do not discuss them further here and instead rely upon the EBSPs that include all the loci. The results from tests performed in DNAsp (the R2 statistic, mismatch distributions, Tajima’s D, and Fu and Li’s D* and F* statistics) did not reject the scenarios of neutrality/population stability for L. triangulum, which indicate no detectable selective or demographic forces operating on this species. For the other five species, no clear trend was detected across any of the loci for any species using these summary statistics (S3 Table). Although several loci resulted in positively and negatively significant test results, these results were not consistent across loci for a given species and in several cases, different loci for the same species indicated different patterns (S4 Table).
Discussion
Whether glacial cycles have had similar effects on population sizes in both temperate and tropical regions is of interest for two reasons. First, it provides insight into the factors that have shaped the current demographic patterns and distributions of organisms in disparate environments and helps determine whether closely related taxa respond similarly regardless of location. Second, from a conservation perspective, understanding how past climate change affected populations or taxa may be applicable to determining what threats species face when confronted with anthropogenic climatic alteration. Here, we find that for milksnakes in the genus Lampropeltis, there is no shared demographic pattern with respect to temperate versus tropical species, although tropical species show less population stability when compared to the temperate species. Based on the EBSPs, populations of temperate species have either remained generally stable or increased in size during the recent Pleistocene/Holocene (Fig 3). This stability is surprising, considering that the LGM would have had a direct impact on snakes living in temperate North America, with the Laurentide Ice Sheet covering a proportion of the ranges of both L. triangulum and L. gentilis (Fig 1; [31,84,85]). The three tropical taxa showed population expansion as well as declines (Fig 3), which in part supportsthe hypothesis that tropical environments did were not stable throughout the last glacial period.
Previous work has demonstrated that tropical species tend to have smaller geographic ranges compared to temperate species and that with smaller ranges come smaller population sizes (reviewed in [86–88]). Some studies have also shown that for snake lineages, those with larger ranges generally have a higher Ne (e.g., [8]), although this trend is not consistent among taxa (e.g., [89]). Despite a general lack of correlation between range size and population size in milksnakes, we do find the temperate species did have greater ranges and larger mean effective population sizes. The exception to this pattern was the tropical L. polyzona, which had the largest mean population size despite having the smallest complete species range (Table 1; Figs 1 and 2). There is the possibility that individuals with the greatest amounts of genetic variation were inadvertently sampled, which would result in signal that indicates large population sizes [90]. This potential bias could be corrected by increasing sample sizes, which would better reflect the actual allelic variation within L. polyzona and result in a more accurate estimate of population size. However, if L. polyzona represents a single, panmictic species, as is indicated by the results of a prior study [62], the large Ne is likely an accurate estimate, as the sample size for this species (n = 31) should be sufficient for detecting population size changes [73]. Although most studies on historical demography only consider the effects of climate change on Ne, it is important to note that there are other plausible biotic reasons for changes in historical population size that should not be dismissed, such as competition between species or predation (reviewed in [91]). Unfortunately, there is no clear way to separate the effects of biotic interactions from climate change on Ne through time in these snakes and so we limit our discussion to climatic or geological events within the time frame considered here.
EBSP Results and Summary Statistics
We find a lack of concordance between the EBSPs and the non-genealogical summary statistic results. The summary statistics for many loci did not indicate the same demographic signal as the EBSP trends did, resulting in conflicting signals or a lack of significance (S4 Table). The exception to this is L. triangulum, which showed no significant Ne changes for any non-genealogical test across loci and demonstrated stable population sizes via EBSP (Fig 3, Table 1). For the remaining species, the degree to which the summary statistics disagreed with the EBSP trends was variable. For example, one locus for L. abnorma was significantly negative and indicated expansion (PRLR, R2; S4 Table), another was significantly positive for population decline (SPTBN1, Fu and Li’s D*; S4 Table) and the remaining nine loci were neutral for all tests (S4 Table). In contrast, the EBSP showed a population decline beginning ~45 ka. These results may indicate there is either balancing or purifying selection acting on some of the loci as the signal cannot be detected across all or most of the loci and would explain the conflicting results. However, for the majority of loci that are not significantly different from neutral, it is possible the summary statistics cannot adequately detect subtle population size changes. Summary statistics may not provide as realistic an estimate of historical population size changes compared to methods that are based on a coalescent genealogy [90]. Previous studies have recognized that Ne estimates that rely on the calculation of pairwise differences and segregating sites are inefficient at estimating population demographics when compared to methods that account for population trees [92]. EBSPs in contrast generate both demographic signal and coalescent history across all loci simultaneously and provide an estimate of the phylogenetic error associated with the data [13]. Ideally, all loci should retain demographic signature, but events such as extreme bottlenecks can erase signal at a given locus; when using multiple loci given varying substitution rates, there is a chance that some loci are preserving signal lost by other genes [13]. With respect to loci and lost signal, we note our demographic reconstructions are likely influenced most by the highly variable mtDNA locus included, as the results for each species when using only the nuclear loci have larger 95% HPDs for both Ne and the population size change parameter, and generally predict much smaller population sizes for all species (Appendix 3). However, discounting the additional information provided through the inclusion of multiple independent loci in these analyses would be imprudent as any given locus, even those with slower substitution rates, may provide demographic signature that may not be recovered by other loci. Furthermore, in cases where population growth rates are slow and/or size changes are small, genealogical methods should outperform pairwise methods [93,94]; this is likely important here since the EBSPs for several milksnakes reveal only moderate changes in population size (Table 1; Fig 3). Although simulation-based studies have found that changes in population sizes using Bayesian skyline plots, particularly with respect to declines, may be occasionally incorrect, we note that the sampling strategy used here is most similar to that which was shown to perform best with respect to detecting actual demographic changes (“pooled sampling” [95]). Considering the overall robustness associated with genealogical methods using coalescent models and specifically those using multiple loci [90,94], we base our discussion on the EBSP results rather than the summary statistics.
Temperate Milksnakes
For two of the temperate species we found no discernible changes in the population size change parameter (both species mean/median size changes < 1.0/0.0; 0.0−2.0 = 95% HPD; Table 1) although the EBSP does show some increase in population size for L. triangulum ~18 kya (Fig 3). Lampropeltis triangulum inhabits deciduous forests of eastern North America, as far north as southern Ontario, and the transition from eastern deciduous hardwood forest to the western prairies coincides with the limit of its distribution (Fig 1; [68]). The equally wide-ranging L. gentilis is frequently found in grassland or prairie habitat [68,69] west of the Mississippi River, from Arizona to Montana (Fig 1). These two species may have moved into suitable habitat that was pushed further south by the Laurentide Ice Sheet and population sizes therefore remained overall constant, with some possibility of expansion for L. triangulum after the LGM. In addition, while L. gentilis is often associated with prairies and grasslands, it can be found in desert lowlands, pine and hardwood forests, and stream valleys [68,69]; the ability of L. gentilis to inhabit multiple habitat types may indicate it was able to readily adapt to climatic changes of the Pleistocene and thus population sizes remained stable [96]. Other studies of temperate North American snakes have found similar patterns of stability throughout the Pleistocene (e.g., [8,9,97]).
Unlike the two most northern temperate milksnakes, the southeastern U.S. milksnake L. elapsoides underwent at least one population expansion (mean/median size changes = 1.6/2.0; 0.0–3.0 = 95% HPD) that can be visualized on the resulting EBSP ~50 kya (Fig 3). Lampropeltis elapsoides is found in the pine forests of the southeastern coastal plain, throughout the Florida peninsula, and west to eastern Louisiana (Fig 1). The onset of the population increase occurred during the middle of the Wisconsin glacial interval (Fig 3; [98]), and continued to the present. A “thermal enclave” from warm ocean winds throughout the southeastern U.S. during the Pleistocene may have facilitated this population growth [99]. It is also possible that L. elapsoides shifted its distribution and populations subsequently expanded, as species inhabiting the eastern U.S. may have moved south into both peninsular Florida and Mexico during periods of glacial cooling and returned north once climates became more favorable, as has been proposed for multiple species [100].
Tropical Milksnakes
Our results indicate that one of the tropical milksnake species increased its population size during the last 100 kya, while the two remaining taxa experienced population declines, suggesting that environmental conditions may not have been stable throughout the Neotropics. At ~80 ka, the EBSP for the Mexican milksnake L. polyzona shows increasing population sizes(Fig 3). While the mean number of size changes for this species indicates that it has likely undergone several population size changes (mean/median number of size changes = 2.6/2.0; 2.0−4.0 = 95% HPD), we focus on this most recent size change here pertinent to understanding how recent climatic change impacts population demography. This species has a range that abuts several major geological features of Mexico, including the Sierra Madre Occidental, the Sierra Madre del Sur, the eastern versant of the Sierra Madre Oriental, and throughout the Trans-Mexican Volcanic Belt region (Fig 2), and the presence of glaciers in these montane regions during the Wisconsin glacial may have influenced population demography [54]. However, the L. polyzona populations showed no decline during the late Quaternary as might be expected. It has been proposed that despite glacial presence in northern and central Mexico, climate did not change significantly [101] and has been consistent during the last 30 kya [102], although arguments against stability have been made [54]. The range of L. polyzona also appears tightly correlated with that of Mexican tropical dry forest, which appeared prior to the origin of this species of milksnake [62,103]. If this habitat remained stable during the Pleistocene, the L. polyzona population may have persisted and expanded. Interestingly, although there are few studies that examine historical demography for organisms specifically in this region, one of the few species studied that has a similar range in Mexico, the jaguar, shows genetic signal indicating recent population expansion [104], as does a recent study on Boa constrictor in that region [105]. Additional demographic studies that focus on this region would help determine whether Mexican dry tropical forest was a stable habitat during the late Quaternary.
In contrast to L. polyzona, both L. abnorma and L. micropholis have experienced population declines beginning ~45 kya (Fig 3), although similar to L. polyzona, these species likely underwent more than a single population size change (both species mean/median number of size changes = 2.0/2.0; 2.0−2.0 = 95% HPD). The areas occupied by both species are thought to have experienced significant cooling and increased aridity during the Pleistocene. Lampropeltis abnorma inhabits much of Mesoamerica, from south of the Sierra Madre del Sur in Mexico, and throughout Central America as far south as Costa Rica, while L. micropholis occurs in eastern Costa Rica, Panama, and Colombia, Ecuador, and Venezuela north/west of the Andes (Fig 2). Glaciation of the Talamanca cordillera of Costa Rica and the highlands of Guatemala and Mexico during the Wisconsin contributed to the cooling of Central America [53,56], which may have started as early as 45 kya [106,107] potentially resulting in the decline of L. abnorma populations. While it is suggested that deglaciation occurred ~11 ka, aridity throughout Central America was at its maximum at this point in time [107]. Snakes are sensitive not only to changes in temperature but also precipitation, with drier conditions potentially limiting the distribution of a species [108]. Like L. abnorma, L. micropholis populations may have been influenced by the glaciers in Costa Rica as well as the changing climate of lower Central America, which was cooler and drier throughout much of the last 100 kya [109]. The extent of its range also means L. micropholis may have been impacted by Andean glaciations during the Pleistocene. As glaciers expanded across the Andes [55] vegetation moved with respect to elevation [106,110], and similar to Central America, South American climates became drier and tropical forests decreased [45]. This may have restricted the size of the habitat available for L. micropholis and caused the population to decline during the last 45 kya. Although the NW tropics were initially thought to be a stable region during recent glacials [7,41–43], the response patterns for the three tropical milksnakes examined here are more similar to studies that show disparate demographic histories for closely related Neotropical taxa (e.g., birds [111], frogs [112]) and the numerous population size changes detected for all three species (Table 1) further underscore that the tropics are not necessarily demographically stable enclaves during climatic oscillations..
Conclusions
Our study illustrates that glacial cycles have impacted both Nearctic and Neotropical milksnakes but that species did not share similar demographic responses by area. Most surprising, we found little evidence for expansions in the two most northerly distributed species, which were closest to the southern extent of the glacier during the LGM. In addition, results showed population declines for two of the tropical taxa. While it is likely that climatic events have contributed to the historical demographic patterns of these snakes, we cannot discount the possibility that unknown abiotic or biotic factors have altered populations. However, our examination of milksnake demography demonstrates that we cannot assume all temperate NW taxa have had similar responses to the last Ice Age. Furthermore, our study adds to the evidence that the tropics were not necessarily an area of stability during the Pleistocene and that populations underwent both expansions and declines. Based on these results we recommend using caution in generalizing demographic responses of taxa by region. Future studies that include greater numbers of loci, such as next-generation datasets comprised of hundreds of markers, combined with a comparative phylogeographic framework examining multiple taxonomic groups would be especially useful in achieving greater demographic resolution and determining whether species respond individually or if there are discernible patterns with respect to both phylogeny and biotic community.
Supporting Information
S1 Table. Individuals sequenced for demographics.
Identification numbers correspond to those of Ruane et al. [62].
https://doi.org/10.1371/journal.pone.0128543.s001
(DOCX)
S2 Table. Total number of individuals sequenced (and used in EBSP analyses) for each locus and the number of individuals used only in DNAsp analyses.
https://doi.org/10.1371/journal.pone.0128543.s002
(DOCX)
S3 Table. Approximate complete range size, sample range size, mean and median effective population size and number of size changes for six species of Lampropeltis based on the nuclear loci only.
The 95% highest posterior density (HPD) is shown for each in parentheses; for number of size changes, species that had non-zero HPDs are indicated (*).
https://doi.org/10.1371/journal.pone.0128543.s003
(DOCX)
S4 Table. DNAsp results for each species and locus, including the number of haplotypes (h), haplotype diversity (Hd), number of segregating sites (S), nucleotide diversity (Pi), average number of nucleotide differences (k), Tajima's D, Fu and Li's D*, Fu and Li's F*, Ramos-Onsins and Rozas'S R2, and Harpending's raggedness index (rg).
For all tests, the P-value (P) is included and for the R2 and rg results, the coalescent simulation results are shown, including the average R2 and rg, and the upper and lower confidence intervals for each (CI). Significant results are highlighted and in bold.
https://doi.org/10.1371/journal.pone.0128543.s004
(DOCX)
Acknowledgments
We would like to thank E. A. Myers and three anonymous reviewers for comments that considerably improved this manuscript
Author Contributions
Conceived and designed the experiments: SR FTB. Performed the experiments: SR. Analyzed the data: SR. Contributed reagents/materials/analysis tools: FTB OTC. Wrote the paper: SR FTB. Contributed to the collection and sequencing of the Ecuadorian samples included: OTC.
References
- 1. Zachos JC, Shackleton NJ, Revenaugh JS, Pälike H, Flower BP. Climate response to orbital forcing across the Oligocene-Miocene boundary. Science. 2001; 292: 274–278. pmid:11303100
- 2. Nogués-Bravo D, Ohlemüller R, Batra P, Araújo MB. Climate predictors of late Quaternary extinctions. Evolution. 2010;64: 2442–2449. pmid:20707809
- 3. Davis MB, Shaw RG. Range shifts and adaptive responses to Quaternary climate change. Science. 2001;292: 673–9. pmid:11326089
- 4. Hewitt G. The genetic legacy of the Quaternary ice ages. Nature. 2000; 405: 907–913. pmid:10879524
- 5. Mapelli FJ, Mora MS, Mirol PM, Kittlein MJ. Effects of Quaternary climatic changes on the phylogeography and historical demography of the subterranean rodent Ctenomys porteousi. J Zool. 2012;286: 48–57.
- 6. Mila B, Girman DJ, Kimura M, Smith TB. Genetic evidence for the effect of a postglacial population expansion on the phylogeography of a North American songbird. Proc R Soc London Ser B Biol Sci. 2000;267: 1033–1040.
- 7. Lessa EP, Cook JA, Patton JL. Genetic footprints of demographic expansion in North America, but not Amazonia, during the Late Quaternary. Proc Natl Acad Sci USA. 2003;100: 10331–4. pmid:12913123
- 8. Fontanella FM, Feldman CR, Siddall ME, Burbrink FT. Phylogeography of Diadophis punctatus: extensive lineage diversity and repeated patterns of historical demography in a trans-continental snake. Mol Phylogenet Evol. 2008;46: 1049–70. pmid:18055224
- 9. Guiher TJ, Burbrink FT. Demographic and phylogeographic histories of two venomous North American snakes of the genus Agkistrodon. Mol Phylogenet Evol. 2008; 48: 543–53. pmid:18539486
- 10. Hewitt GM. Some genetic consequences of ice ages, and their role in divergence and speciation. Biol J Linn Soc. 1996;58: 247–276.
- 11. Hewitt GM. Genetic consequences of climatic oscillations in the Quaternary. Philos Trans R Soc Lond B Biol Sci. 2004;359: 183–95. pmid:15101575
- 12. Hewitt GM. The structure of biodiversity–insights from molecular phylogeography. Front Zool. 2004;1: 1–16. pmid:15679902
- 13. Ho SYW, Shapiro B. Skyline-plot methods for estimating demographic history from nucleotide sequences. Mol Ecol Resour. 2011;11: 423–34. pmid:21481200
- 14. Kingman JFC. The coalescent. Stoch Process their Appl. 1982;13: 235–248.
- 15. Kingman JFC. On the genealogy of large populations. J Appl Probab. 1982; 27–43.
- 16. Avise JC, Arnold J, Ball RM, Bermingham E, Lamb T, Neigel JE, et al. Intraspecific phylogeography: the mitochondrial DNA bridge between population genetics and systematics. Annu Rev Ecol Syst. 1987;18: 489–522.
- 17. Hudson RR. Gene genealogies and the coalescent process. Oxford Surv Evol Biol. 1990. 7: 44.
- 18.
Harding RM. New phylogenies: an introductory look at the coalescent. In: Harvey PH, Brown AJL, Smith JM, Nee S, editors. New uses for new phylogenies. Oxford: Oxford University Press; 1998. pp. 15–22.
- 19.
Neigel JE. Estimation of effective population size and migration parameters from genetic data. Molecular genetic approaches in conservation. Oxford University, Oxford; 1996. pp. 329–346.
- 20. Avise JC, Walker D, Johns GC. Speciation durations and Pleistocene effects on vertebrate phylogeography. Proc Biol Sci. 1998; 265: 1707–12. pmid:9787467
- 21. Edwards S, Beerli P. Perspective: gene divergence, population divergence, and the variance in coalescence time in phylogeographic studies. Evolution. 2000;54: 1839–1854. pmid:11209764
- 22. Brito PH, Edwards S V. Multilocus phylogeography and phylogenetics using sequence-based markers. Genetica. 2009;135: 439–55. pmid:18651229
- 23. Maruyama T, Fuerst PA. Population bottlenecks and nonequilibrium models in population genetics. I. Allele numbers when populations evolve from zero variability. Genetics. Genetics Soc America; 1984;108: 745–763.
- 24.
Schmidt D, Pool J. The effect of population history on the distribution of the Tajima’s D statistic. New York: Cornell University Press; 2002. https://doi.org/10.1002/hed.21649 pmid:21259377
- 25. Galtier N, Depaulis F, Barton NH. Detecting Bottlenecks and Selective Sweeps From DNA Sequence Polymorphism. Genetics. 2000;155: 981–987. pmid:10835415
- 26. Rand AL. Glaciation, an isolating factor in speciation. Evolution. 1948; 2: 314–321. pmid:18104589
- 27. Beecher WJ. Late-Pleistocene isolation in Salt-Marsh Sparrows. Ecology. Ecological Society of America; 1955;36: 23–28.
- 28. Mengel RM. The probable history of species formation in some northern wood warblers (Parulidae). Living Bird. 1964;3: 9–43.
- 29. Avise JC, Walker D. Pleistocene phylogeographic effects on avian populations and the speciation process. Proc Biol Sci. 1998; 265: 457–63. pmid:9569664
- 30. Andrews JT, Barry RG. Glacial Inception and Disintegration During the Last Glaciation. Annu Rev Earth Planet Sci. 1978;6: 205–228.
- 31. Dyke AS, Prest VK. Late Wisconsinan and Holocene history of the Laurentide ice sheet. Géographie Phys Quat. Les Presses de l’Université de Montréal; 1987;41: 237–263.
- 32. Jackson ST, Webb RS, Anderson KH, Overpeck JT, Webb T III, Williams JW, et al. Vegetation and environment in Eastern North America during the Last Glacial Maximum. Quat Sci Rev. 2000;19: 489–508.
- 33. Thompson RS, Anderson KH. Biomes of western North America at 18,000, 6000 and 0 14C yr BP reconstructed from pollen and packrat midden data. J Biogeogr. 2000; 27: 555–584.
- 34. Pulgarín-R PC, Burg TM. Genetic signals of demographic expansion in downy woodpecker (Picoides pubescens) after the last North American glacial maximum. PLoS One. Public Library of Science; 2012;7: e40412. pmid:22792306
- 35. Light JE, Hafner JC, Upham NS, Reddington E. Conservation Genetics of Kangaroo Mice, Genus Microdipodops. J Mamm Evol. 2012; 20: 129–146.
- 36. Johnson NK, Cicero C. New mitochondrial DNA data affirm the importance of Pleistocene speciation in North American birds. Evolution; 2004;58: 1122–1130. pmid:15212392
- 37. Beheregaray LB. Twenty years of phylogeography: the state of the field and the challenges for the Southern Hemisphere. Mol Ecol. 2008;17: 3754–74. pmid:18627447
- 38. Haffer J. Speciation in Amazonian forest birds. Science. 1969;165: 131–137. pmid:17834730
- 39. Vuilleumier BS. Pleistocene changes in the fauna and flora of South America. Science. 1971;173: 771–780. pmid:17812182
- 40. Simpson BB, Haffer J. Speciation patterns in the Amazonian forest biota. Annu Rev Ecol Syst. 1978;9: 497–518.
- 41. CLIMAP C. Long-Range Investigation, Mapping, and and Prediction Project Members (1981) CLIMAP, Climate: Long-Range Investigation, Mapping, and Prediction Project Members. Seas Reconstr Earth’s Surf Last Glacial Maximum, Geol Soc Am Map Chart Ser MC. 1981;36: 1–18.
- 42. Broecker WS. Oxygen isotope constraints on surface ocean temperatures. Quat Res. 1986; 26: 121–134.
- 43. Lyle MW, Prahl FG, Sparrow MA. Upwelling and productivity changes inferred from a temperature record in the central equatorial Pacific. Nature. 1992;355: 812–815.
- 44. Rind D, Peteet D. Terrestrial conditions at the last glacial maximum and CLIMAP sea-surface temperature estimates: Are they consistent? Quat Res. Elsevier; 1985; 24: 1–22.
- 45. Clapperton CM. Nature of environmental changes in South America at the Last Glacial Maximum. Palaeogeogr Palaeoclimatol Palaeoecol. 1993;101: 189–208.
- 46. Stute M, Forster M, Frischkorn H, Serejo A, Clark JF, Schlosser P, et al. Cooling of Tropical Brazil (5-Degrees-C) During the Last Glacial Maximum. Science. 1995; 269: 379–383. pmid:17841260
- 47. Thompson LG, Mosley-Thompson E, Davis ME, Lin P-N, Henderson KA, Cole-Dai J, et al. Late glacial stage and Holocene tropical ice core records from Huascaran, Peru. Science. 1995; 269: 46–50. pmid:17787701
- 48. Colinvaux PA, de Oliveira PE, Moreno JE, Miller MC, Bush MB. A Long Pollen Record from Lowland Amazonia: Forest and Cooling in Glacial Times. Science.1996; 274: 85–88.
- 49. Webb RS, Rind DH, Lehman SJ, Healy RJ, Sigman D. Influence of ocean heat transport on the climate of the Last Glacial Maximum. Nature. 1997;385: 695–699.
- 50. Van der Hammen T, Hooghiemstra H. Neogene and Quaternary history of vegetation, climate, and plant diversity in Amazonia. Quat Sci Rev. 2000;19: 725–742.
- 51. Piperno DR, Jones JG. Paleoecological and archaeological implications of a Late Pleistocene/Early Holocene record of vegetation and climate from the Pacific coastal plain of Panama. Quat Res. 2003;59: 79–87.
- 52. Bush MB, Silman MR, Urrego DH. 48,000 years of climate and forest change in a biodiversity hot spot. Science. 2004; 303: 827–9. pmid:14764876
- 53. Horn SP. Timing of deglaciation in the Cordillera de Talamanca, Costa Rica. Edad de la deglaciación en la Cordillera de Talamanca, Costa Rica. Clim Res. 1990;1: 81–83. pmid:11656107
- 54. Metcalfe SE, O’Hara SL, Caballero M, Davies SJ. Records of Late Pleistocene–Holocene climatic change in Mexico—a review. Quat Sci Rev. 2000;19: 699–721.
- 55. Thompson LG, Mosley-Thompson E, Henderson KA. Ice-core palaeoclimate records in tropical South America since the Last Glacial Maximum. J Quat Sci. 2000;15: 377–394.
- 56. Lachniet MS, Seltzer GO. Late Quaternary glaciation of Costa Rica. Geol Soc Am Bull. 2002;114: 547–558.
- 57. Leyden BW. Guatemalan forest synthesis after Pleistocene aridity. Proc Natl Acad Sci. 1984;81: 4856–4859. pmid:16593498
- 58. Rull V. Quaternary speciation in the Neotropics. Mol Ecol. 2006;15: 4257–4259. pmid:17054517
- 59. Peterson AT, Nyári AS. Ecological niche conservatism and Pleistocene refugia in the Thrush-like Mourner, Schiffornis sp., in the neotropics. Evolution. 2008;62: 173–183. pmid:18005155
- 60. Koscinski D, Handford P, Tubaro PL, Sharp S, Lougheed SC. Pleistocene climatic cycling and diversification of the Andean treefrog, Hypsiboas andinus. Mol Ecol. 2008;17: 2012–25. pmid:18373535
- 61. Daza JM, Smith EN, Páez VP, Parkinson CL. Complex evolution in the Neotropics: the origin and diversification of the widespread genus Leptodeira (Serpentes: Colubridae). Mol Phylogenet Evol. 2009;53: 653–67. pmid:19643196
- 62. Ruane S, Bryson RW, Pyron RA, Burbrink FT. Coalescent species delimitation in milksnakes (genus Lampropeltis) and impacts on phylogenetic comparative analyses. Syst Biol. 2014;63: 231–250. pmid:24335429
- 63. Zarza E, Reynoso VH, Emerson BC. Diversification in the northern neotropics: mitochondrial and nuclear DNA phylogeography of the iguana Ctenosaura pectinata and related species. Mol Ecol. 2008;17: 3259–3275. pmid:18564087
- 64. Klicka J, Zink RM. The importance of recent ice ages in speciation: a failed paradigm. Science. 1997; 277: 1666–1669. pmid:9169882
- 65. Moritz C, Patton JL, Schneider CJ, Smith TB. Diversification of rainforest faunas: an integrated molecular approach. Annu Rev Ecol Syst. 2000;31: 533–563.
- 66. Kronauer DJC, Bergmann PJ, Mercer JM, Russell AP. A phylogeographically distinct and deep divergence in the widespread Neotropical turnip-tailed gecko, Thecadactylus rapicauda. Mol Phylogenet Evol. 2005;34: 431–437. pmid:15619453
- 67. Devitt TJ. Phylogeography of the Western Lyresnake (Trimorphodon biscutatus): testing aridland biogeographical hypotheses across the Nearctic-Neotropical transition. Mol Ecol. 2006;15: 4387–407. pmid:17107472
- 68.
Ernst CH, Ernst EM. Snakes of the United States and Canada. Washington, DC: Smithsonian Books; 2003.
- 69.
Werler JE, Dixon JR. Texas snakes: identification, distribution, and natural history. Austin, TX: University of Texas Press; 2000.
- 70.
Williams KL. Systematics and natural history of the American Milk Snake, Lampropeltis triangulum. Milwaukee Public Museum; 1988.
- 71.
Campbell JA. Amphibians and Reptiles of Northern Guatemala, the Yucatan, and Belize. University of Oklahoma Press; 1999. p. 400.
- 72. Stephens M, Donnelly P. A comparison of bayesian methods for haplotype reconstruction from population genotype data. Am J Hum Genet. 2003;73:1162–1169. pmid:14574645
- 73. Heled J, Drummond AJ. Bayesian inference of population size history from multiple loci. BMC Evol Biol. 2008;8: 289. pmid:18947398
- 74. Drummond AJ, Rambaut A. BEAST: Bayesian evolutionary analysis by sampling trees. BMC Evol Biol. 2007;7: 214. pmid:17996036
- 75. Pyron RA, Burbrink FT. Neogene diversification and taxonomic stability in the snake tribe Lampropeltini (Serpentes: Colubridae). Mol Phylogenet Evol. 2009;52: 524–529. pmid:19236930
- 76.
Rambaut A, Drummond AJ. Tracer v1. 4. 2007.
- 77.
R Core Team. R: A Language and Environment for Statistical Computing. Vienna, Austria; 2014. https://doi.org/10.1016/j.jneumeth.2014.06.019 pmid:24970579
- 78. Librado P, Rozas J. DnaSP v5: a software for comprehensive analysis of DNA polymorphism data. Bioinformatics. 2009; 25: 1451–1452. pmid:19346325
- 79. Ramos-Onsins SE, Rozas J. Statistical properties of new neutrality tests against population growth. Mol Biol Evol. 2002;19: 2092–2100. pmid:12446801
- 80. Rogers AR, Fraley AE, Bamshad MJ, Watkins WS, Jorde LB. Mitochondrial mismatch analysis is insensitive to the mutational process. Mol Biol Evol.1996;13: 895–902. pmid:8751998
- 81. Harpending HC. Signature of ancient population growth in a low-resolution mitochondrial DNA mismatch distribution. Hum Biol. 1994; 66: 591–600. pmid:8088750
- 82. Tajima F. Statistical method for testing the neutral mutation hypothesis by DNA polymorphism. Genetics. Genetics Soc America; 1989;123: 585–595.
- 83. Fu YX, Li WH. Statistical Tests of Neutrality of Mutations. Genetics. 1993;133: 693–709. pmid:8454210
- 84. Delcourt PA, Delcourt HR. Late-quaternary vegetational dynamics and community stability reconsidered. Quat Res. 1983;19: 265–271.
- 85.
Pielou EC. After the ice age: the return of life to glaciated North America. Chicago: University of Chicago Press; 1991.
- 86. Lawton JH. Range, population abundance and conservation. Trends Ecol Evol. 1993;8: 409–413. pmid:21236213
- 87. Gaston KJ. The multiple forms of the interspecific abundance-distribution relationship. Oikos. 1996; 76: 211–220.
- 88. Gaston KJ, Blackburn TM, Spicer JI. Rapoport’s rule: time for an epitaph? Trends Ecol Evol. 1998;13: 70–74. pmid:21238203
- 89. Burbrink FT, Fontanella F, Alexander Pyron R, Guiher TJ, Jimenez C. Phylogeography across a continent: the evolutionary and demographic history of the North American racer (Serpentes: Colubridae: Coluber constrictor). Mol Phylogenet Evol. 2008;47: 274–88. pmid:18093846
- 90. Kuhner MK. Coalescent genealogy samplers: windows into population history. Trends Ecol Evol. 2009; 24: 86–93. pmid:19101058
- 91. Lavergne S, Mouquet N, Thuiller W, Ronce O. Biodiversity and Climate Change: Integrating Evolutionary and Ecological Responses of Species and Communities. Annu Rev Ecol Evol Syst. Annual Reviews; 41: 321–350.
- 92.
Felsenstein J. Estimating effective population size from samples of sequences: inefficiency of pairwise and segregating sites as compared to phylogenetic estimates. Genet Res. Cambridge University Press; 1992;59: 139–147. https://doi.org/10.1017/S0016672300030354 pmid:1628818
- 93. Slatkin M, Hudson RR. Pairwise comparisons of mitochondrial DNA sequences in stable and exponentially growing populations. Genetics. Genetics Soc America; 1991;129: 555–562.
- 94. Kuhner MK, Yamato J, Felsenstein J. Maximum Likelihood Estimation of Population Growth Rates Based on the Coalescent. Genetics. 1998;149: 429–434. pmid:9584114
- 95. Heller R, Chikhi L, Siegismund HR. The confounding effect of population structure on Bayesian skyline plot inferences of demographic history. PLoS One. 2013;8: e62992. pmid:23667558
- 96. King MG, Horning ME, Roalson EH. Range persistence during the last glacial maximum: Carex macrocephala was not restricted to glacial refugia. Mol Ecol. 2009;18: 4256–69. pmid:19754517
- 97. Myers EA, Weaver RE, Alamillo H. Population stability of the northern desert nightsnake (Hypsiglena chlorophaea deserticola) during the Pleistocene. J Herpetol. BioOne; 2013;47: 432–439.
- 98. Duplessy JC, Roche DM, Kageyama M. The deep ocean during the last interglacial period. Science. 2007;316: 89–91. pmid:17412954
- 99. Russell DA, Rich FJ, Schneider V, Lynch‐Stieglitz J. A warm thermal enclave in the Late Pleistocene of the South‐eastern United States. Biol Rev. 2009;84: 173–202. pmid:19391200
- 100. Martin PS, Harrell BE. The Pleistocene history of temperate biotas in Mexico and eastern United States. Ecology. 1957;38: 468–480.
- 101. Deevey ES. Pollen analysis and Mexican archaeology: an attempt to apply the method. Am Antiq. 1944;10: 135–149.
- 102. Bradbury JP. Late Quaternary lacustrine paleoenvironments in the Cuenca de México. Quat Sci Rev. 1989;8: 75–100.
- 103. Becerra JX. Timing the origin and expansion of the Mexican tropical dry forest. Proc Natl Acad Sci USA. 2005;102: 10919–23. pmid:16033871
- 104. Eizirik E, Kim J-H, Menotti-Raymond M, Crawshaw PG JR., O’Brien SJ, Johnson WE. Phylogeography, population history and conservation genetics of jaguars (Panthera onca, Mammalia, Felidae). Mol Ecol. 2001;10: 65–79. pmid:11251788
- 105. Suárez-Atilano M, Burbrink F, Vázquez-Domínguez E. Phylogeographical structure within Boa constrictor imperator across the lowlands and mountains of Central America and Mexico. J Biogeogr. 2014;41: 2371–2384. pmid:24469714
- 106. Bush MB. On the interpretation of fossil Poaceae pollen in the lowland humid neotropics. Palaeogeogr Palaeoclimatol Palaeoecol. 2002;177: 5–17.
- 107.
Bush M, Correa-metrio A, Hodell D, Brenner M, Anselmetti F, Ariztegui D, et al. Re-evaluation of Climate Change in Lowland Central America During the Last Glacial Maximum Using New Sediment Cores from Lake Petén Itzá, Guatemala. In: Vimeux F, Sylvestre F, Khodri M, editors. Past Climate Variability in South America and Surrounding Regions. Springer Netherlands; 2009. pp. 113–128. https://doi.org/10.1007/978-90-481-2672-9_5
- 108. Araújo MB, Thuiller W, Pearson RG. Climate warming and the decline of amphibians and reptiles in Europe. J Biogeogr. 2006;33: 1712–1728.
- 109. Bush MB, Colinvaux PA. A pollen record of a complete glacial cycle from lowland Panama. J Veg Sci. 1990;1: 105–118.
- 110.
Pielou EC. Biogeography. New York: John Wiley & Sons Inc; 1979.
- 111. Cheviron ZA, Hackett SJ, Capparella AP. Complex evolutionary history of a Neotropical lowland forest bird (Lepidothrix coronata) and its implications for historical hypotheses of the origin of Neotropical avian diversity. Mol Phylogenet Evol. 2005;36: 338–57. pmid:15955514
- 112. Wang IJ, Crawford AJ, Bermingham E. Phylogeography of the Pygmy Rain Frog (Pristimantis ridens) across the lowland wet forests of isthmian Central America. Mol Phylogenet Evol. 2008;47: 992–1004. pmid:18424088