Evolutionary Drivers of Diversification and Distribution of a Southern Temperate Stream Fish Assemblage: Testing the Role of Historical Isolation and Spatial Range Expansion

Albert Chakona; Ernst R. Swartz; Gavin Gouws

doi:10.1371/journal.pone.0070953

Abstract

This study used phylogenetic analyses of mitochondrial cytochrome b sequences to investigate genetic diversity within three broadly co-distributed freshwater fish genera (Galaxias, Pseudobarbus and Sandelia) to shed some light on the processes that promoted lineage diversification and shaped geographical distribution patterns. A total of 205 sequences of Galaxias, 177 sequences of Pseudobarbus and 98 sequences of Sandelia from 146 localities across nine river systems in the south-western Cape Floristic Region (South Africa) were used. The data were analysed using phylogenetic and haplotype network methods and divergence times for the clades retrieved were estimated using *BEAST. Nine extremely divergent (3.5–25.3%) lineages were found within Galaxias. Similarly, deep phylogeographic divergence was evident within Pseudobarbus, with four markedly distinct (3.8–10.0%) phylogroups identified. Sandelia had two deeply divergent (5.5–5.9%) lineages, but seven minor lineages with strong geographical congruence were also identified. The Miocene-Pliocene major sea-level transgression and the resultant isolation of populations in upland refugia appear to have driven widespread allopatric divergence within the three genera. Subsequent coalescence of rivers during the Pleistocene major sea-level regression as well as intermittent drainage connections during wet periods are proposed to have facilitated range expansion of lineages that currently occur across isolated river systems. The high degree of genetic differentiation recovered from the present and previous studies suggest that freshwater fish diversity within the south-western CFR may be vastly underestimated, and taxonomic revisions are required.

Citation: Chakona A, Swartz ER, Gouws G (2013) Evolutionary Drivers of Diversification and Distribution of a Southern Temperate Stream Fish Assemblage: Testing the Role of Historical Isolation and Spatial Range Expansion. PLoS ONE 8(8): e70953. https://doi.org/10.1371/journal.pone.0070953

Editor: Axel Janke, BiK-F Biodiversity and Climate Research Center, Germany

Received: April 10, 2013; Accepted: June 28, 2013; Published: August 9, 2013

Copyright: © 2013 Chakona 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.

Funding: Funding was provided by the International Foundation for Science (grant no. A/4174-2; www.ifs.se), The Rufford Small Grants for Nature Conservation (RSG reference 59.04.08; www.rufford.org), WWF Prince Bernhard Scholarship (wwf.panda.org), National Research Foundation (South Africa; www.nrf.ac.za) and the Claude Leon Foundation (www.leonfoundation.co.za). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Understanding the processes that promoted diversification and shaped the distributions of extant taxa is a central question of evolutionary studies [1]–[8]. Studies have cited a plethora of processes, such as global sea-level changes, climatic oscillations, orogenic events, river capture and ecological gradients as the major drivers of diversification and geographical distribution of many freshwater assemblages [5]–[16]. One challenge, particularly in understudied regions, is identifying which of these processes played a major role in shaping patterns of regional diversity. Integrating data from multiple co-distributed taxa provides a more powerful approach for investigating the evolutionary and biogeographical effects of both historical events and the environmental characteristics of a region [15], [16]. The present study uses comparative phylogeographic and biogeographic approaches to examine the evolutionary drivers of diversification and the processes that gave rise to extant geographical distributions of co-distributed stream fishes from the south-western Cape Floristic Region (CFR) of South Africa.

The CFR located at the southern tip of Africa (Fig. 1) is renowned for its high plant diversity and endemism that is unrivalled by other Mediterranean-type ecosystems in the world [17]–[19]. Although the CFR’s ichthyofaunal diversity is much lower, the region is a hotspot of high endemism for freshwater fishes [20]–[22]. Genetic studies are increasingly detecting considerable levels of population structuring in almost all fish species from the CFR investigated thus far [13], [14], [23]–[26]. Many of the newly identified lineages are likely to be described as distinct species, indicating that the region’s taxonomic diversity and endemism has been vastly underestimated [22]. However, knowledge of the mechanisms underpinning diversification and distribution of freshwater taxa in the region is still rudimentary. River capture events and isolation by major mountain barriers have been traditionally proposed as the dominant processes that had major impacts on diversification and distribution patterns of stream fishes in the CFR [27]–[28]. While lineage diversification of freshwater taxa consistent with mountain barriers and river captures can be detected [13], [29], there is an emerging picture that the situation in the CFR has been more complex. For example, a recently identified galaxiid displays phylogeographic patterns indicative of recent range expansion across major mountain ranges and drainage divides [8], while other taxa exhibit a pattern consistent with a model of river confluences during periods of low sea-levels [14].

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Figure 1. The Cape Floristic Region (CFR) of South Africa showing the Cape Fold Mountains.

Location of the south-western CFR and the river systems (1–11) considered in the present study are indicated.

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Southern Africa experienced a complex geological and climatic history marked by tectonism, sea-level fluctuations and extreme wet and dry periods [30]–[37]. The Cape Fold Mountains started to form in the Jurassic (c. 140 Ma), but all major present day landform features were probably established by the early Cenozoic (c. 65 Ma) [31]. The CFR landscape has been stable since the Post-African uplift events in the Miocene (c. 22 Ma) and Pliocene (c. 5.3–2.6 Ma) [32], [33]. Southern Africa also experienced repeated climatic oscillations marked by extreme wet and dry conditions since the Oligocene through to the Holocene epoch [34]–[37]. The present dry conditions of the region were probably established by the end of the Pliocene (c. 2.6 Ma) [38], [39], but some areas, such as the coastal regions of the southern CFR, are thought to have experienced wetter climatic conditions as recent as the Holocene Altithermal (c. 8 000–6 000 years ago) [34].

Apart from tectonic activity and extreme climatic variability, southern Africa also experienced repeated fluctuations in sea-level throughout the Tertiary as a result of global cycles of glaciation [30], [31], [40]. However, there are uncertainties regarding estimates of the timing and amplitudes of global sea-level changes [40]. This is further compounded by the possibility of differential continental uplift [41], which makes it difficult to assess the true height reached by historical sea-levels. Despite these uncertainties, the documented estimates provide important insights into the relative amplitudes of historical sea-levels [30], [40]. In southern Africa, the last major sea-level transgression occurred from the middle Miocene (c. 15 Ma) to the late Pliocene (c. 2.6 Ma), with levels being estimated to have reached about 330 m above the current coastline ([30]; Fig 2). The last major regression in southern Africa occurred during the LGM, about 18 ka, when the coastline is estimated to have been about 130 m below the current level ([30], [31]; Fig 2). These processes could have potentially left an imprint in the genetic structure and geographical distribution of stream-dwelling taxa, particularly obligate freshwater fishes.

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Figure 2. Sea-level changes.

Potential fragmentation of river systems during the Miocene-Pliocene sea-level transgression and the proposed palaeoriver systems (1–8) of the Last Glacial Maximum (LGM) in the south-western Cape Floristic Region (CFR). The potential range of the maximum transgression level is indicated by the area in yellow. The white area would therefore have been vulnerable to marine incursion, whereas the area in orange was possibly never affected by the Miocene-Pliocene transgression. The approximate LGM sea-level is represented by the −130 m contour line. The palaeorivers are 1) Palmiet, 2) Bot-Onrus, 3) Klein, 4) Uilkraals, 5) Haelkraal, 6) Ratel, 7) Breede-Heuningnes-Duiwenhoks and 8) Gouritz-Goukou.

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The south-western portion of the CFR (Fig. 1) is well-suited for evolutionary studies to unravel the impact of palaeogeographic events on the diversification and geographical distribution of stream fishes. This region is clearly demarcated from surrounding areas by the Hottentot’s Holland, Franschhoek, Drakenstein and Du Toitskloof Mountain ranges to the west, the Hex River, Langeberg and Riversdale Mountain ranges to the north, and the Gouritz basin to the east (Fig 1). A unique feature of the south-western CFR is the Agulhas Bank, a shallow continental shelf that would have been periodically exposed and submerged due to repeated fluctuations in sea-level ([30]; Fig 2). Rivers of the south-western CFR have only four currently recognised native primary freshwater fishes: three smaller species [Galaxias zebratus Castelnau, 1861, Pseudobarbus burchelli Smith, 1841 and Sandelia capensis (Cuvier, 1831)] and a large cyprinid barb, Barbus andrewi Barnard 1937 [42]. The three smaller species are broadly co-distributed across several river systems, while B. andrewi is now largely confined to two man-made impoundments in the Breede River catchment. Molecular studies have revealed existence of historically-isolated lineages within Galaxias, Pseudobarbus and Sandelia in the south-western CFR [14], [43], [44].

The present study extends this previous research by undertaking finer-scale geographic sampling of co-distributed stream fishes belonging to three genera, Galaxias, Pseudobarbus and Sandelia, across 11 river systems in the south-western CFR (Fig 1; Appendix S1), with the aim of assessing the roles of vicariance and population expansion in driving diversification and shaping the present-day distributions of these groups. From a vicariance biogeographic perspective, we hypothesise that the marine incursions during the Miocene-Pliocene (Fig. 2) truncated river systems, fragmenting once widely distributed populations of freshwater fishes (Fig 3a), and isolating them in upland river reaches, potentially driving genetic divergence (Refugia hypothesis: Fig 3b). Under this hypothesis, lineage splitting in Galaxias, Pseudobarbus and Sandelia would be expected to be chronologically associated with the period of the highest sea-level transgression (late Miocene to late Pliocene epochs), and the distribution of unique lineages is expected to show affinities with rivers that were not completely inundated.

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Figure 3. Hypotheses of factors that could have shaped genetic and distribution patterns of fishes in the south-western CFR.

Panel (a) assumes that populations could have been historically connected probably during a period of a major sea-level regression. Panel (b) describes the hypothesis that truncation of rivers during the Miocene-Pliocene major sea-level transgression fragmented populations and isolated them into upland areas that were not inundated (Refugia hypothesis), leading to allopatric divergence and the formation of unique lineages (indicated by the different colours). Panel (c) shows the river systems that would have coalesced forming the palaeoriver systems of the Last Glacial Maximum (LGM) (Palaeoriver hypothesis), allowing the exchange of unique lineages between systems sharing a common confluence. Panel (d) illustrates the hypothesis that alternative dispersal routes such as freshwater connections through low drainage divides could have facilitated range expansion of unique lineages (Interdrainage Dispersal hypothesis), leading to unique lineages being distributed across river systems that did not coalesce during the LGM.

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From the post-speciation population expansion perspective, we hypothesise that confluence of adjacent rivers during periods of lower sea-levels could have facilitated dispersal of genetically-differentiated lineages (Palaeoriver hypothesis: Fig 3c). Under this hypothesis, genetically-distinct lineages of the same genus would be expected to occur in sympatry across river systems that coalesced during the LGM (Fig 3c). Assuming that genetically-differentiated lineages could have also used alternative dispersal routes such as low drainage divides during periods of heavy flooding [Inter-basin Dispersal hypothesis; 8], we would expect to find a pattern where distinct lineages have broad distributions across rivers that did not coalesce during the LGM low sea-levels (Fig 3d).

Finally, it was predicted that if Galaxias, Pseudobarbus and Sandelia were similarly affected by shared historical events and environmental factors, they would be expected to exhibit congruent geographical patterns and similar dates of lineage splitting. According to Birmingham & Martin [45], evidence of shared history across multiple co-distributed taxa would probably reflect the role of extrinsic climatic or landscape history in shaping contemporary biogeographic patterns, while different patterns would probably reflect the influence of intrinsic biological or ecological differences.

Materials and Methods

Ethics Statement

The research was conducted under permit from CapeNature (permit number: AAA-004-000205-0035) issued only after the approval of methods by a review panel.

Field Sampling

Specimens of Galaxias, Pseudobarbus and Sandelia were collected from 146 localities across the south-western CFR (Appendix S1) between November 2008 and December 2009 using a combination of electric fishing, seine netting, fyke nets and snorkelling with a handnet. Fish were euthanised with clove oil (0.2 ‰). A small piece of muscle tissue or whole specimen was preserved in 95% ethanol. All samples collected for the present study have been deposited at the South African Institute for Aquatic Biodiversity (SAIAB).

DNA Extraction, Amplification and Sequencing

DNA was extracted from preserved tissue using the Wizard® Genomic DNA purification kit (Promega, USA) following the manufacturer’s protocol. A partial fragment of the mitochondrial cytochrome b gene was amplified. For Galaxias (n = 205), the amplification was done as outlined in Chakona et al [8]. The primers GluF and ThrR [46] were used for Pseudobarbus (n = 177) and the PCR protocol was 94°C for 2 minutes, and 35 cycles of 94°C for 30 seconds, 54°C for 30 seconds and 72°C for 45 seconds, followed by 72°C for 5 minutes. The primers used for Sandelia (n = 98) were H16091 and L14841 [47] and the PCR protocol was similar to that of Pseudobarbus, except that the denaturing and annealing temperatures were 93°C and 55°C, respectively. Sequencing, alignment and editing of sequences were done as outlined by Chakona et al [8]. Sequences were submitted to GenBank (accession numbers: Galaxias KC821878–KC821890, KC821898–KC821917, KC821922–KC821925, KC821934–KC821938, KC821941–KC821952, KC821954, KC821955, KF222589–KF222667; Pseudobarbus KF222577–KF222588, KF222668–KF222791; Sandelia KF222792–KF222890).

Data Analyses

Shared and unique haplotypes for each genus were identified using the program DnaSp 5.10 [48]. Phylogenetic relationships among unique haplotypes within each taxon were inferred using Maximum Likelihood and Bayesian Inference based on the selected model of sequence evolution. The most appropriate model of sequence evolution for each taxon was selected using the AIC in Modeltest 3.7 [49]. The model of sequence evolution selected for Galaxias was GTR+I+Γ [50]. For Pseudobarbus, the GTR+I model was selected. For Sandelia the TIM+I+Γ [51] was the best model selected. Pseudobarbus tenuis, P. asper and P. burgi were used as outgroups for the Pseudobarbus phylogeny. Galaxias sp. ‘mollis’ (Swartz, unpublished) and Sandelia sp ‘Berg’ both from the Leeu River (Berg River system) were used to root the Galaxias and Sandelia phylogenies respectively.

The ML analyses were done in PAUP4.0b10, using heuristic tree searches and applying the tree-bisection-reconnection (TBR) branch-swapping algorithm with 10 random addition replicates. Bayesian analyses were performed using the Bayesian Markov Chain Monte Carlo (BMCMC) algorithm implemented in MrBayes 3.1.2 [52]. Each analysis was run across four chains for five million generations and sampled every 100^th generation to obtain 50 000 sampled trees. The burn-in value was determined by plotting the average standard deviation of split frequencies, tree length and log-likelihood scores against generation time using the program Tracer 1.5 [53]. The first 5000 trees were discarded as burn-in and the remaining trees were used to calculate Bayesian posterior probabilities. For each data set, two separate BI runs were done to assess whether the chains converged to the same point. Model-corrected genetic distances between unique lineages identified for each taxon were calculated using Paup* [54].

Phylogeographic Patterns

For each genus, genealogical relationships among all samples were also inferred using the statistical parsimony method implemented in the program tcs 1.21 [55]. To test for evidence of recent population expansion, as predicted by the Palaeoriver and Interdrainage Dispersal hypotheses, Fu’s [56] F_s statistic was calculated for each unique lineage with 15 or more individuals using Arlequin [57]. Statistical significance of Fu’s F_s statistic was tested using 1000 random permutations.

Divergence Time Estimation

Dates of divergence among lineages within Galaxias, Pseudobarbus and Sandelia were estimated using *Beast 1.7.4 [58] based on the respective best models of molecular evolution estimated using Modeltest 3.7. A UPGMA topology was used as the starting tree. A yule tree prior, piecewise linear and constant root population size model and uncorrelated lognormal molecular clock were assumed. As there are no fossil calibration points for southern African freshwater fishes, divergence times for lineages of the three genera were estimated under a uniform prior (using the ucld.mean) with a lower bound of 0.76 and an upper bound of 2.2% per million years. These values were chosen because they encompass the published range of cyt b substitution rates in teleost fishes [46], [59]–[62]. All other priors were set to default values. Analyses were run for 6 × 10⁷ generations and sampled every 1000 generations. The first 10 percent of the sampled trees was discarded as burn-in. Beast results were visualised using the program Tracer 1.5 [53] to assess the adequacy of the effective sample sizes (ESS) for each estimated parameter and to obtain the mean divergence estimates in millions of years and their 95 percent highest posterior density (HPD) for all nodes.

Results

Galaxias Lineage Diversity and Distribution

For the individuals of Galaxias analysed, the edited alignment of mtDNA cyt b sequences was 648 base pairs in length of which 183 sites were variable. These variable sites resulted in 74 unique haplotypes, and their geographic distribution is presented in Appendix S2.

Tree topologies obtained by the BI and ML methods were identical, with only minor differences at some terminal nodes. The ML tree is presented with posterior probability support values from the BI analysis (Fig. 4a). Nine main clades (lineages) were found from the south-western CFR (Fig. 4a), with deep phylogenetic divergences among lineages (3.49–25.27%) (Table 1). Haplotypes were grouped within these lineages with high Bayesian posterior probability values (0.98–1.00) for those lineages that had multiple haplotypes. Deeper relationships among lineages were not well resolved, but G. sp. ‘rectognathus’ was resolved as sister to G. sp. ‘nebula’ (posterior probability = 1.00) and G. sp. ‘Heuningnes’ was resolved as sister to G. sp. ‘klein’ (posterior probability = 1.00). The clade containing G. sp. ‘Heuningnes’ and G. sp. ‘Klein’ was resolved as sister to the clade containing G. sp. ‘rectognathus’ and G. sp. ‘nebula’ (posterior probability = 0.98) (Fig. 4a). The TCS haplotype network (Fig. 4b) consisted of six distinct clades and three disconnected haplotypes, reflecting the same nine lineages as the BI and ML phylogenies.

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Figure 4. Galaxias lineage diversity.

(a) Maximum Likelihood phylogenetic estimate of relationships among mitochondrial cytochrome b haplotypes of Galaxias from the south-western CFR. Bayesian posterior probabilities are given on the branches. The numbers (1–74) represent unique haplotypes and the colours indicate lineages, corresponding to distribution maps in Figure S1 in Appendix S2. River systems in which the lineages occur are listed below the lineage names and their ranges are presented in Figure S1 in Appendix S2. (b) TCS network of cyt b haplotypes (1–74) from individuals of Galaxias from the south-western CFR. The sizes of circles are proportional to haplotype frequency, and the colours indicate the river system(s) where the haplotype occurred. Black dots represent missing haplotypes in the network. Each branch represents one mutation step.

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Table 1. Means and ranges (in parentheses) of model-corrected genetic divergences (%) between Galaxias lineages from the south-western CFR.

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All the rivers mentioned in the text are presented in Fig. 1. Geographic distributions of the lineages are presented in Figure S1 in Appendix S2. Galaxias sp. ‘nebula’ is the most widespread of the nine lineages as it was collected in all river systems of the south-western CFR, except the Onrus and Palmiet Rivers. This lineage occurs in sympatry with six other lineages that have highly restricted geographic ranges (Fig. 4b; Figure S1 in Appendix S2). Galaxias sp. ‘Heuningnes’ was found in two currently isolated river systems, while Galaxias sp. ‘Klein’ was found in three river systems (Figure S1 in Appendix S2). Galaxias sp. ‘slender’ is restricted to the Uilkraals River system. Galaxias sp. ‘mollis’ occurs in the Onrus River system in the south-western CFR as well as in the Leeu River, a tributary of the Berg River system on the west coast. Galaxias sp. ‘Goukou’ was only found in the Goukou River system, while Galaxias sp. ‘rectognathus’ was collected in two tributaries of the Riviersonderend River, a major subcatchment of the Breede River system (Figure S1 in Appendix S2). Galaxias sp. ‘Riviersonderend’ was found in the upper Riviersonderend and six of its tributaries as well as in the Keurbooms River just below the confluence of the Breede and the Riviersonderend (Figure S1 in Appendix S2). This lineage was also collected in the Palmiet River system despite this system being separated from the Riviersonderend sub-catchment by the Hottentots Holland Mountain Range (Figure S1 in Appendix S2). Galaxias sp. ‘Breede’ was collected at three localities in the Breede River (Figure S1 in Appendix S2).

Galaxias sp. ‘nebula’ and G. sp. ‘Riviersonderend’ show significant signals of recent population expansion (Table 1). Galaxias sp. ‘Heuningnes’ had a negative Fs value, but it was not statistically significant. Galaxias sp. ‘Klein’ showed no evidence of recent population expansion, while the other lineages had too few individuals for meaningful computation.

Pseudobarbus Burchelli Lineage Diversity and Distribution

The edited alignment of mtDNA cyt b sequences from 177 individuals was 676 base-pairs long and 95 of these characters were variable. This resulted in 47 unique haplotypes. Both BI and ML analyses revealed identical relationships among historically-isolated lineages. The ML tree is presented with Bayesian posterior probabilities indicating branch support (Fig. 5a). The analyses revealed substantial genetic structuring within P. burchelli. Four distinct lineages: Pseudobarbus sp. ‘Breede’, Pseudobarbus sp. ‘Heuningnes’, Pseudobarbus sp. ‘Tradou’ and Pseudobarbus sp. ‘giant’ were identified (Fig. 5a). TCS analysis produced four distinct clades (Fig. 5b) reflecting the same lineages as the BI and ML phylogenies. Deep phylogenetic divergences were found among lineages (2.58–9.99%), while minor genetic divergences were found within lineages (0.30–0.71%) (Table 2).

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Figure 5. Pseudobarbus lineage diversity.

(a) Maximum Likelihood analysis of phylogenetic relationships among mitochondrial cyt b haplotypes identified in Pseudobarbus from the south-western CFR. Bayesian posterior probabilities are given on the branches. The numbers (1–47) represent unique haplotypes and the colours represent unique lineages, corresponding to distribution maps in Figure S2 in Appendix S2. Distribution ranges of these lineages are presented in Figure S2 in Appendix S2. River systems in which the lineages occur are given in parentheses. (b) TCS network of cyt b haplotypes (1–47) from individuals of Pseudobarbus from the south-western CFR. The sizes of circles are proportional to haplotype frequency, and the colours indicate the river system (s) where the haplotype occurred. Black dots represent missing haplotypes in the network. Each branch represents one mutation step.

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Table 2. Mean and range of model-corrected genetic divergence (%) between Pseudobarbus lineages from the south-western CFR.

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Pseudobarbus sp. ‘Breede’, P. sp. ‘giant’ and P. sp. ‘Tradou’ are restricted to inland rivers, while P. sp. ‘Heuningnes’ was found exclusively at coastal sites. Pseudobarbus sp. ‘Breede’ is the most widespread of the four lineages, being distributed across the isolated Breede, Duiwenhoks and Goukou River systems (Figure S2 in Appendix S2). This lineage occurs in sympatry with P. sp. ‘giant’ in the upper Riviersonderend. Pseudobarbus sp. ‘Tradou’ is restricted to the Tradou River, a tributary of the Breede River system (Figure S2 in Appendix S2). Pseudobarbus sp. ‘Heuningnes’ is restricted to the Heuningnes River system (Figure S2 in Appendix S2). Results of Fu’s F_s tests suggest recent population expansion for Pseudobarbus sp. ‘Breede’, while P. sp ‘Tradou’ and P. sp. ‘Heuningnes’ show no evidence of recent population expansion (Table 2).

Sandelia capensis Lineage Diversity and Distribution

DNA sequencing resulted in 98 sequences of the mtDNA cyt b gene and the edited alignment was 621 bp long. The sequences contained 66 variable sites which resulted in 30 haplotypes. BI and ML phylogenetic reconstructions (Fig. 6a) recovered eight lineages with strong geographical affinities (described below).

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Figure 6. Sandelia lineage diversity.

(a) Eight lineages with strong geographic affinities recovered with Maximum Likelihood phylogenetic analysis of mitochondrial cyt b haplotypes (1–30) identified in Sandelia from the south-western CFR. Bayesian posterior probabilities are given on the branches. The colours denote lineages and their distribution ranges are presented in Figure S3 in Appendix S2. (b) TCS network of cyt b haplotypes (1–30) from individuals of Sandelia from the south-western CFR. The sizes of circles are proportional to haplotype frequency, and the colours indicate the river system (s) where the haplotype occurred. Black dots represent missing haplotypes in the network. Each branch represents one mutation step.

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The TCS output consisted of one large network and a disconnected haplotype from the Klein River system (haplotype 30) (Fig. 6b). Within the large haplotype network, seven with strong geographical affinities can be identified. Similar to both Galaxias and Pseudobarbus, some Sandelia lineages are associated with coastal rivers while others are restricted to inland rivers. The first lineage, Sandelia sp. ‘Duiwenhoks’, comprised haplotypes that are restricted to the Duiwenhoks River system, and the second lineage, Sandelia sp. ‘Goukou’, occurred in the Goukou River system. The third lineage, Sandelia sp. ‘Breede’, comprised of haplotypes collected from multiple sites in the Breede, Duiwenhoks and Goukou River systems (Figure S3 in Appendix S2). The haplotypes which comprised the phylogenetically well-supported Sandelia sp. ‘Riviersonderend’ were restricted to the Riviersonderend and Palmiet Rivers (Figure S3 in Appendix S2). Sandelia sp. ‘Koekedou’, also well-supported in the tree, was restricted to localities in the upper Breede (Figure S3 in Appendix S2). Sandelia sp. ‘Agulhas’ (supported with a Bayesian posterior probability of 1.00) comprised of haplotypes from the Heuningnes, Haelkraal and Klein River systems, while Sandelia sp. ‘Uilkraals’ was restricted to the Uilkraals River system. Seven of the eight lineages had shallow divergences among them (1.03–2.86%), with Sandelia sp. ‘Klein’ being the only deeply divergent lineage within Sandelia (5.31–6.09%; Table 3).

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Table 3. Mean and range of model-corrected genetic distances between eight lineages identified within Sandelia from the south-western CFR.

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Fu’s F_s statistics were only computed for the ’Breede’ and ‘Agulhas’ lineages of Sandelia. Recent population expansion was detected for both lineages (Table 3). The numbers of the other lineages were too low for reliable computation of neutrality statistics.

Estimates of Divergence Times

Estimates of divergence times for the main lineages of Galaxias, Pseudobarbus and Sandelia are shown in chronograms in Fig 7. Cladogenesis in Galaxias and Pseudobarbus largely occurred within a period bounded by the Late Miocene-Early Pliocene (Fig 7a,b), a period characterised by increased sea-levels. Dating estimates suggested that the deepest split in Sandelia occurred at the end of the Pliocene, but much of the phylogeographic structuring in this genus occurred during the Pleistocene (Fig 7c).

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Figure 7. Chronograms with estimates of divergence times (Million years ago).

Values on the nodes represent the estimated mean divergence dates for major lineages of (a) Galaxias, (b) Pseudobarbus and (c) Sandelia inferred using Bayesian coalescent analyses implemented in BEAST. Bars represent 95% highest posterior densities for divergence estimates. Solid circles represent posterior probability values greater or equal to 0.95 and open circles represent values less than 0.95.

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Discussion

The study uncovered nine deeply-divergent lineages of Galaxias, four historically-isolated lineages of Pseudobarbus and at least two deeply-divergent lineages of Sandelia from the south-western CFR. All the lineages (except Galaxias sp ‘nebula’ and Galaxias sp ‘mollis’) are restricted to the south-western CFR, and we have presented in the present study their entire known ranges. Taxonomic statuses of newly identified lineages from DNA-based studies are being confirmed with additional analyses, including morphology. These results thus complement previous studies [22], [43], [44], [63] providing strong evidence that the south-western CFR represents a previously unrecognized centre of stream fish diversity and endemism in the broader CFR. The goal of the present study was to investigate the mechanisms that drove lineage diversification and shaped the geographical distribution patterns of this assemblage of stream fishes by testing three hypotheses: Refugia, Palaeoriver and Inter-drainage dispersal.

Refugia Hypothesis

Accumulating evidence indicates that fragmentation of populations into separate refugia is an important mechanism that drove lineage splitting in several primary freshwater fishes [45], [64]–[68]. Results of the present study support the Refugia hypothesis. Divergence time estimates indicate that splitting of major lineages within Galaxias, Pseudobarbus and Sandelia coincided with a period of higher sea-levels, suggesting that fragmentation of populations of these taxa in upland refugia promoted diversification. Many of the deeply divergent lineages have strong geographical affinities, with distribution ranges restricted to specific river systems that were not completely inundated during the Miocene-Pliocene marine transgression. For example, restriction of the deeply-divergent lineage, Sandelia sp. ‘Klein’, to the Klein River system is consistent with the expectation that the upper reaches of the Klein provided important refuge to freshwater taxa during the last major sea-level transgression. Similarly, restriction of Galaxias sp. ‘slender’ and Galaxias sp. ‘Goukou’ to the Uilkraals and Goukou River systems, respectively, is evidence that both river systems served as important refugia for freshwater fishes during the Miocene-Pliocene high sea-levels. The distribution limits of Galaxias sp. ‘Riviersonderend’ and Galaxias sp. ‘Breede’ suggest that these lineages could have evolved in allopatry due to vicariance caused by possible isolation of the Breede and Riviersonderend catchments during the Miocene-Pliocene marine incursion. Similarly, Pseudobarbus sp. ‘Breede’, Pseudobarbus sp. ‘Tradou’ and Pseudobarbus sp. ‘giant’ could have diverged through allopatric isolation due to possible vicariance of the Breede, Riviersonderend and Tradou Rivers, followed by post-speciation dispersal for Pseudobarbus sp. ‘Breede’ and Pseudobarbus sp. ‘giant’ to attain their present day distributions. These results are consistent with findings from other regions where marine incursions are considered to have isolated and drove diversification of freshwater taxa [45], [64]–[66].

Palaeoriver Hypothesis

The Miocene-Pliocene transgression was followed by a major regression during the last glacial maximum (LGM) [30], resulting in the confluence of several adjacent rivers before reaching the sea [8], [13], [14]. The palaeorivers of the LGM have been proposed as a plausible explanation for the common occurrence of Pseudobarbus lineages across currently-isolated river systems in the CFR [13], [14], [63]. Interconnections of rivers following exposure of the continental shelf during glacial periods [69], [70] have also been inferred to have facilitated dispersal of Percicthys trucha, a Patagonian freshwater fish with an extensive geographical range, but lacking phylogeographic structuring [71].

Results from the present study show some support for the Palaeoriver hypothesis. Occurrence of Pseudobarbus sp. ‘Breede’ and Sandelia sp. ‘Breede’ in the currently isolated Breede and Duiwenhoks River systems is consistent with the confluence of these rivers during the LGM low sea-levels. However, occurrence of these lineages in the Goukou River system is not consistent with the Palaeoriver hypothesis, because the Goukou was part of an eastern palaeoriver system (the Gouritz-Goukou). This therefore suggests the role of alternative mechanisms (see below).

The lack of sharing of lineages (except Galaxias sp. ‘nebula’) among the Breede, Duiwenhoks and Heuningnes was also surprising, because these river systems coalesced as recently as the LGM. This is perhaps a result of the extreme hydrochemical differences between inland and coastal draining river systems in the south-western CFR. Most tributaries of inland draining rivers (including the Breede and Duiwenhoks river systems) have clear, oligotrophic water with low conductivity, while the coastal-draining rivers on the Agulhas Plain (including the Heuningnes River system) have tannin stained ‘brown’ water with high conductivity due to high salt content [38]. We hypothesise that the extreme ecological gradient between the Heuningnes and the inland rivers (Breede and Duiwenhoks) may represent a physiological barrier that could have hampered exchange of lineages between these systems. This is assuming that the current ecological differences were present and persisted when the river systems shared a common confluence. This hypothesis of the role of ecological gradients is corroborated by recent findings for Amazonian fishes where extreme contrast in optical characteristics of riverine waters has been a major driver of ecological divergence, speciation and distribution of cryptic lineages and species [6], [72], [73].

Inter-drainage Dispersal Hypothesis

Galaxias sp. ‘Heuningnes’ shows no differentiation between the Heuningnes and Ratel River systems despite these systems being currently isolated. As the entire Ratel River system was under marine water during the Miocene-Pliocene transgression, it is likely that freshwater taxa in this river system were extirpated. Freshwater taxa in the Ratel are therefore likely to be recent immigrants from adjacent refugial populations. Galaxias sp. ‘Heuningnes’ is likely to have survived and evolved in the Heuningnes River system and then dispersed to the Ratel River system. Since the Ratel and Heuningnes did not share a common confluence during the LGM, dispersal via intermittent freshwater connections is the most plausible explanation for the lack of differentiation between these two river systems. The lack of a discernible drainage divide between the Ratel and a western tributary of the Heuningnes could have allowed movement following episodic connections during periods of heavy flooding.

Similarly, Galaxias sp. ‘Klein’ has closely related haplotypes across the Klein, Uilkraals and Haelkraal, despite the current hydrological isolation of these river systems. These river systems did not coalesce during the LGM low sea-levels. Overland dispersal via intermittent freshwater connections during pluvial periods is therefore the most likely explanation for the current distribution of Galaxias sp. ‘Klein’. Since the Haelkraal is likely to have been submerged during the Miocene-Pliocene transgression, Galaxias sp. ‘Klein’ is likely to have survived in either the Klein or the Uilkraals. The restriction of the genetically-distinct Galaxias sp. ‘slender’ to the Uilkraals and the relatively smaller size of this river system suggests that Galaxias sp. ‘Klein’ and Galaxias sp. ‘slender’ are likely to have evolved in allopatry, and their co-occurrence in the Uilkraals could be a result of secondary contact. It is therefore logical to suggest that Galaxias sp. ‘Klein’ could have evolved in the Klein River system due to possible vicariant isolation by the middle Miocene to early Pliocene marine incursions. This would then be consistent with the Sandelia sp. ‘Klein’ scenario discussed earlier.

Sandelia sp. ‘Agulhas’ also occurs across several currently isolated river systems that did not coalesce during the LGM regression. Low genetic differentiation between Sandelia sp. ‘Agulhas’ across the Heuningnes, Haelkraal, Uilkraals and Klein Rivers suggests either recent disruption of gene flow or recent range expansion. Historical panmixia is unlikely, particularly given the historical oscillations between extremes of dry and wet conditions that were experienced in southern Africa [36]. A more plausible explanation is, therefore, that Sandelia sp. ‘Agulhas’ could have evolved in isolation and only recently expanded its range across river systems draining the Agulhas Plain. Based on the existence of distinct lineages of Sandelia in the Klein and Uilkraals, and the fact that the Haelkraal was drowned during the Miocene-Pliocene transgression, it is more likely that Sandelia sp. ‘Agulhas’ evolved in the Heuningnes River system. The low genetic differentiation in this lineage among these river systems may be evidence for more recent dispersal via low drainage divides during wet climatic periods. This mechanism was used to explain the wide geographic range of Galaxias sp. ‘nebula’ across the CFR [8]. Thus, the sympatric occurrence of two lineages of Sandelia in the Uilkraals and the Klein could be a result of secondary contact due to post-speciation dispersal of Sandelia sp. ‘Agulhas’.

The occurrence of Pseudobarbus sp. ‘Breede’ and Sandelia sp. ‘Breede’ in the Goukou River system is not consistent with the sea-level regression hypothesis because the Goukou belonged to a different palaeoriver system. This suggests the role of alternative dispersal mechanisms such as a rare river capture event or episodic connection possibly during inundation of low drainage divides during wetter climatic periods. The upper Duiwenhoks and the Korinte River (a tributary of the Goukou) are separated by a low drainage divide which could have allowed interdrainage movement during pluvial periods. Partridge et al., [34] inferred wetter climatic conditions for coastal areas of the southern Cape occurring as recently as the Holocene Altithermal (ca. 8 000–6 000 years ago). Connections of low drainage divides during wetter climatic periods have been proposed to have facilitated interdrainage movement of obligate freshwater taxa in the CFR [8] and elsewhere [74], [75].

Human-mediated translocations could have also influenced the distribution patterns of Sandelia sp. ‘Breede’ and Pseudobarbus sp. ‘Breede’. Chakona & Swartz [76] reported that Sandelia lineages in undisturbed tributaries of the Breede River system are restricted to river reaches below 425 m elevation, while Galaxias sp. ‘nebula’ and Pseudobarbus sp. ‘Breede’ always occurred at higher elevations than the Sandelia lineages. This pattern is reversed in the Goukou, with Sandelia sp. ‘Breede’ occurring above major waterfalls that are effective barriers for both Galaxias sp. ‘nebula’ and Pseudobarbus sp. ‘Breede’. This and the fact that individuals of Sandelia sp. ‘Breede’ collected from populations above one of the major waterfalls in the Goukou contained Breede haplotypes suggests that Sandelia sp. ‘Breede’ in the Goukou could have been introduced from the Breede River system. Since Sandelia sp. ‘Breede’ and Pseudobarbus sp. ‘Breede’ co-occur in large numbers within the Breede, it is possible that they could have both been introduced into the Goukou River system. This hypothesis is subject for further investigation with additional markers such as microsatellites that will help to discriminate between natural and human aided movements. The occurrence of Galaxias sp. ‘Riviersonderend’ and Sandelia sp. ‘Riviersonderend’ in the Palmiet River system was also unexpected because the Riviersonderend and Palmiet are separated by a high mountain barrier. This suggests possible human-mediated translocation that also warrants further investigation.

Test for Shared Evolutionary History

Galaxias, Pseudobarbus and Sandelia show broad similarities in the distribution of lineages across the south-western CFR because they all have: (1) genetically-distinct lineages restricted to the coastal river systems of the Agulhas Plain and inland lineages restricted to the Breede, Duiwenhoks and Goukou River systems, (2) some lineages that show low or no differentiation across currently isolated river systems and (3) deeply divergent lineages that occur in sympatry. Galaxias and Sandelia, in particular, each have distinct lineages that largely co-occur. For example, they both have distinct lineages that are restricted to the Goukou, Riviersonderend and Palmiet, Uilkraals and Klein. Common phylogeographic patterns in multiple sympatric species across a wide geographic range may suggest similar responses to common regional scale physical processes [45], [77]. However, for patterns to maximally represent simultaneous responses to evolutionary forces, they must also be temporally concordant [78]. Temporal patterns of divergence between Galaxias and Sandelia are, however, not consistent with spatial patterns because the species showed substantial differences in the timing of cladogenesis. This may suggest the influence of similar evolutionary forces, such as historical isolation followed by subsequent range expansion, but these events could have affected the two genera at different time periods.

Alternatively, the lack of temporal concordance between Sandelia compared to Galaxias and Pseudobarbus could be a result of differences in the mutation rate of their mitochondrial DNA. Significant differences in the rates of molecular evolution have also been reported among the anabantoid fishes [1], which include the genus Sandelia. This presents an interesting case that warrants further investigation.

Conclusions

The results of the present study are consistent with palaeogeographic hypotheses invoked to explain phylogeographic patterns from other regions of the world [45], [64]–[66]. These studies provided evidence that sea-level fluctuations played a major role in driving diversification and influencing biogeographic patterns of extant freshwater taxa in the Neotropics [45], [66], North America [64] and the Indo-Australian Archipelago [65]. Along similar lines, diversification of freshwater fishes within the south-western CFR appears to have been generated predominantly by passive vicariance of river systems during the Miocene-Pliocene transgression. Coalescence of adjacent rivers due to the subsequent sea-level regression during the LGM facilitated postspeciation range expansion (dispersal) of some lineages to colonise currently isolated river systems. Dispersal could have also been facilitated by rare events such as intermittent wet connections during pluvial periods [8]. Thus, the sympatric occurrence of deeply divergent lineages in each of the three genera could be a result of secondary contact through dispersal from Miocene-Pliocene refugial populations. This paleogeographic and dispersal hypothesis for freshwater fishes of the south-western CFR is summarised in Figures S1–S3 in Appendix S3. Future studies that incorporate multiple genetic markers, as well as other freshwater-restricted taxa (for example macroinvertebrate groups with low dispersal abilities), are encouraged to further test and refine the hypotheses presented in the present study regarding the diversification and biogeographical patterns of freshwater taxa in this global biodiversity hotspot.

Supporting Information

Appendix S1.

Sampling localities in the south-western Cape Floristic Region of South Africa. Tributaries sampled for Galaxias (Gal), Pseudobarbus (Pse) and Sandelia (San) from the south-western CFR. Locality codes and geographic coordinates are given. The number of individuals that were sequenced per locality is indicated. Blank space indicates that individuals of that genus were not collected at that locality.

https://doi.org/10.1371/journal.pone.0070953.s001

(DOCX)

Appendix S2.

Distribution of Galaxias, Pseudobarbus and Sandelia lineages in the south-western Cape Floristic Region of South Africa.

https://doi.org/10.1371/journal.pone.0070953.s002

(DOCX)

Appendix S3.

Conceptual models for diversification and geographical distribution. Hypothesised processes that drove diversification and shaped the distribution of unique lineages within Galaxias, Pseudobarbus and Sandelia in the south-western Cape Floristic Region of South Africa.

https://doi.org/10.1371/journal.pone.0070953.s003

(DOCX)

Acknowledgments

We thank CapeNature for providing the permit (permit number: AAA-004-000205- 0035), land owners for access, Wilbert Kadye, James Merron, Kit Magellan, Martine Jordaan and Dean Impson for assistance in the field, and Poogendri Reddy for laboratory assistance.

Author Contributions

Conceived and designed the experiments: AC ERS GG. Analyzed the data: AC. Contributed reagents/materials/analysis tools: AC ERS GG. Wrote the paper: AC. Gained funding for the research: AC ERS GG. Collected the data: AC ERS GG.

References

1. Rüber L, Britz R, Zardoya R (2006) Molecular phylogenetics and evolutionary diversification of labyrinth fishes (Perciformes: Anabantoidei). Syst Biol 55: 374–397.
- View Article
- Google Scholar
2. Price BW, Barker NP, Villet MH (2007) Patterns and processes underlying evolutionary significant units in the Platypleura stridula L. species complex (Hemiptera: Cicadidae) in the Cape Floristic Region, South Africa. Mol Ecol 16: 2574–2588.
- View Article
- Google Scholar
3. Verboom GA, Archibald JK, Bakker FT, Bellstedt DU, Conrad F, et al. (2009) Origin and diversification of the Greater Cape flora: Ancient species repository, hot-bed of recent radiation, or both? Mol Phylogenet Evol 51: 44–53.
- View Article
- Google Scholar
4. Barber BR, Klicka J (2010) Two pulses of diversification across the Isthmus of Tehuantepec in a montane Mexican bird fauna. Proc R Soc Lond B 277: 2675–2681.
- View Article
- Google Scholar
5. Klaus S, Selvandran S, Goh JW, Wowor D, Brandis D, et al. (2013) Out of Borneo: Neogene diversification of Sundaic freshwater crabs (Crustacea: Brachyura: Gecarcinucidae: Parathelphusa). J Biogeogr 40: 63–74.
- View Article
- Google Scholar
6. Cooke GM, Chao NL, Beheregaray LB (2012a) Five cryptic species in the Amazonian catfish Centromochlus existimatus identified based on biogeographic predictions and genetic data. PlosOne 7(11).
7. Hawlitschek O, Hendrich L, Espeland M, Toussaint EFA, Genner MJ, et al. (2012) Pleistocene climate change promoted rapid diversification of aquatic invertebrates in Southeast Australia. BMC Evol Biol 12: 142.
- View Article
- Google Scholar
8. Chakona A, Swartz ER, Gouws G, Bloomer P (2013) A freshwater fish defies ancient mountain ranges and drainage divides: extrinsic and intrinsic influences on the evolutionary history of a recently identified galaxiid. J Biogeogr 40: 1399–1412.
- View Article
- Google Scholar
9. Waters JM, Allibone RM, Wallis GP (2006) Geological subsidence, river capture, and cladogenesis of galaxiid fish lineages in central New Zealand. Biol J Linn Soc 88: 367–376.
- View Article
- Google Scholar
10. Burridge CP, Craw D, Waters JM (2006) River capture, range expansion, and cladogenesis: the genetic signature of freshwater vicariance. Evolution 60: 1038–1049.
- View Article
- Google Scholar
11. Burridge CP, Craw D, Waters JM (2007) An empirical test of freshwater vicariance via river capture. Mol Ecol 16: 1883–1895.
- View Article
- Google Scholar
12. Berendzen PB, Gambles T, Simons AM (2008) Phylogeography of the bigeye chub Hybopsis amblops (Teleostei: Cypriniformes): early Pleistocene diversification and post-glacial range expansion. J Fish Biol 73: 2021–2039.
- View Article
- Google Scholar
13. Swartz ER, Skelton PH, Bloomer P (2007) Sea-level changes, river capture and the evolution of populations of the Eastern Cape and fiery redfins (Pseudobarbus afer and Pseudobarbus phlegethon, Cyprinidae), across multiple river systems in South Africa. J Biogeogr 34: 2086–2099.
- View Article
- Google Scholar
14. Swartz ER, Skelton PH, Bloomer P (2009) Phylogeny and biogeography of the genus Pseudobarbus (Cyprinidae): shedding light on the drainage history of rivers associated with the Cape Floristic Region. Mol Phylogent Evol 51: 75–84.
- View Article
- Google Scholar
15. McCulloch GA, Wallis GP, Waters JM (2010) Onset of glaciation drove simultaneous vicariant isolation of Alpine insects in New Zealand. Evolution 64–7: 2033–2043.
- View Article
- Google Scholar
16. Barber BR, Unmack PJ, Pérez-Losada M, Johnson J, Crandall K (2011) Different processes lead to similar patterns: a test of codivergence and the role of sea level and climate changes in shaping a southern temperate freshwater assemblage. BMC Evol Biol 11: 343.
- View Article
- Google Scholar
17. Goldblatt P, Manning JC (2000) Cape Plants. A Conspectus of the cape Flora of South Africa. National botanic Institute, Pretoria.
18. Linder HP (2003) The radiation of the Cape flora, southern Africa. Biol Rev 78: 597–638.
- View Article
- Google Scholar
19. Kreft H, Jetz W (2007) Global patterns and determinants of vascular plant diversity. P Natl Acad Sci USA 104: 5925–5930.
- View Article
- Google Scholar
20. Wishart MJ, Day JA (2002) Endemism of the freshwater fauna of the south-western Cape, South Africa. Verh Internat Verein Limnol 28: 1–5.
- View Article
- Google Scholar
21. Thieme ML, Abell R, Stiassny MLJ, Skelton PH, Lehner B, et al.. (2005) Freshwater Ecoregions of Africa and Madagascar. Island Press.
22. Linder HP, Johnson SD, Kuhlmann M, Matthee CA, Nyffeler R, et al. (2010) Biotic diversity in the Southern African winter-rainfall region. Curr Opin Env Sust 2: 109–116.
- View Article
- Google Scholar
23. Waters JM, Cambray JA (1997) Intraspecific phylogeography of the Cape galaxias from South Africa: evidence from mitochondrial DNA sequences. J Fish Biol 50: 1329–1338.
- View Article
- Google Scholar
24. Bloomer P, Impson ND (2000) Mitochondrial DNA differentiation in the critically endangered Berg River Redfin (Pseudobarbus burgi). J Hered 91: 122–127.
- View Article
- Google Scholar
25. Wishart M, Hughes J, Stewart B, Impson D (2006) Extreme levels of intra-specific divergence among Cape Peninsula populations of the Cape galaxias, Galaxias zebratus Castelnau 1861, reveals a possible species complex. Afr J Aquat Sci 31: 99–106.
- View Article
- Google Scholar
26. Swartz ER, Flemming AF, Mouton P le FN (2004) Contrasting genetic patterns and population histories in three threatened redfin species (Cyprinidae) from the Olifants River System, western South Africa. J Fish Biol 64: 1153–1167.
- View Article
- Google Scholar
27. Barnard KH (1943) Revision of the indigenous freshwater fishes of the S.W. Cape Region. Ann S Afr Mus 36: 101–263.
- View Article
- Google Scholar
28. Skelton PH (1986) Distribution patterns and biogeography of non-tropical southern African freshwater fishes. Palaeoecol Afr 17: 211–230.
- View Article
- Google Scholar
29. Wishart MJ, Hughes JM (2001) Exploring patterns of population subdivision in the net-winged midge, Elporia barnardi (Diptera: Blephariceridae), in mountain streams of the south-western Cape, South Africa. Freshwater Biol 46: 479–490.
- View Article
- Google Scholar
30. Siesser WG, Dingle RV (1981) Tertiary sea-level movements around southern Africa. J Geol 89: 83–96.
- View Article
- Google Scholar
31. Hendey QB (1983) Cenozoic geology and palaeogeography of the fynbos region. In: Deacon HJ, Hendey QB, Lambrechts JJN, editors. Fynbos Palaeoecology: A Preliminary Synthesis. South African National Scientific Programmes Report No. 75. CSIR, Pretoria, 35–60.
32. Partridge TC, Maud RR (1987) Geomorphic evolution of southern Africa since the Mesozoic. S Afr J Geol 90: 179–208.
- View Article
- Google Scholar
33. Partridge TC, Maud RR (2000) Macro-scale geomorphic evolution of southern Africa. In: Partridge TC, Maud RR, editors. The Cenozoic of Southern Africa. Oxford University Press, New York, 3–18.
34. Partridge TC, Scott L, Hamilton JE (1999) Synthetic reconstructions of southern African environments during the Last Glacial Maximum (21–18 kyr) and the Holocene Altithermal (8–6 kyr). Quatern Int 57/58: 207–214.
- View Article
- Google Scholar
35. Marlow JR, Lange CB, Wefer G, Rosell-Melè A (2000) Upwelling intensification as part of the Pliocene–Pleistocene climate transition. Science 290: 2288–2291.
- View Article
- Google Scholar
36. Zachos J, Pagani M, Sloan L, Thomas E, Billups K (2001) Trends, rhythms, aberrations in global climate 65 Ma to present. Science 292: 686–693.
- View Article
- Google Scholar
37. Cowling RM, Procheş Ş, Partridge TC (2009) Explaining the uniqueness of the Cape Flora: Incorporating geomorphic evolution as a factor for explaining its diversification. Mol Phylogenet Evol 51: 64–74.
- View Article
- Google Scholar
38. Deacon HJ, Jury MR, Ellis F (1992) Selective regime and time. In: Cowling RM, editor. The ecology of fynbos: Nutrients, fire and diversity. Oxford University Press, Cape Town, 6–22.
39. Tyson PD, Partridge TC (2000) Evolution of Cenozoic climates. In: Partridge TC, Maud RM, editors. Cenozoic of Southern Africa. Oxford University Press, New York, 371–387.
40. Miller KG, Kominz MA, Browning JV, Wright JD, Mountain GS, et al. (2005) The Phanerozoic record of global sea-level change. Science 310: 1293–1298.
- View Article
- Google Scholar
41. Siesser WG (1978) Leg 40 results in relation to continental shelf and onshore geology. In: Bolli HM, Ryan WBF, et al.., editors. Initial Reports of the Deep Sea Drilling Project, Volume 40: Washington, U.S. Government Printing Offi ce, 40, 965–979.
42. Skelton P (2001) A complete guide to the freshwater fishes of Southern Africa. Struik Publishers, Cape Town.
43. Roos H (2004) Genetic diversity in the anabantids Sandelia capensis and S. bainsii: A phylogeographical and phylogenetic investigation. Unpublished MSc dissertation, University of Pretoria, South Africa.
44. Van Niekerk R (2004) Phylogeography of the Cape galaxias Galaxias zebratus. Unpublished MSc dissertation, University of Pretoria, South Africa.
45. Bermingham E, Martin AP (1998) Comparative mtDNA phylogeography of neotropical freshwater fishes: testing shared history to infer the evolutionary landscape of lower Central America. Mol Ecol 7: 499–517.
- View Article
- Google Scholar
46. Machordom A, Doadrio I (2001) Evidence of a cenozoic Betic-Kabilian connection based on freshwater fish phylogeography (Luciobarbus, Cyprinidae). Mol Phylogenet Evol 18: 252–263.
- View Article
- Google Scholar
47. Kocher TD, Thomas WK, Meyer A, Edwards SV, Paabo S, et al. (1989) Dynamics in the mitochondrial DNA evolution in animals: Amplification and sequencing with conserved primers. P Natl Acad Sci USA 86: 6196–6200.
- View Article
- Google Scholar
48. Librado P, Rozas J (2009) DnaSP v5: a software for comprehensive analysis of DNA polymorphism data. Bioinformatics 25: 1451–1452.
- View Article
- Google Scholar
49. Posada D, Crandall KA (1998) MODELTEST: testing the model of DNA substitution. Bioinformatics 14: 817–818.
- View Article
- Google Scholar
50. Lanave C, Preparata G, Saccone C, Serio G (1984) A new method for calculating evolutionary substitution rates. J Mol Evol 20: 86–93.
- View Article
- Google Scholar
51. Posada D, Crandall KA (2001) Selecting Models of Nucleotide Substitution: An Application to Human Immunodeficiency Virus 1 (HIV-1). Mol Biol Evol 18: 897–906.
- View Article
- Google Scholar
52. Ronquist F, Huelsenbeck JP (2003) MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics 19: 1572–1574.
- View Article
- Google Scholar
53. Rambaut A, Drummond AJ (2007) Tracer v.1.4. Available: http://beast.bio.ed.ac.uk/Tracer/.
54. Swofford DL (2003) PAUP*. Phylogenetic Analysis Using Parsimony (*and Other Methods). Version 4. Sinauer Assoc. Inc., Sunderland, Massachusetts.
55. Clement M, Posada D, Crandall KA (2000) TCS: a computer program to estimate gene genealogies. Mol Ecol 9: 1657–1659.
- View Article
- Google Scholar
56. Fu Y-X (1997) Statistical tests of neutrality of mutations against population growth, hitchhiking, and background selection. Genetics 147: 915–925.
- View Article
- Google Scholar
57. Excoffier L, Laval G, Schneider S (2005) Arlequin (version 3.0): an integrated software package for population genetics data analysis. Evol Bioinform 1: 47–50.
- View Article
- Google Scholar
58. Drummond AJ, Rambaut A (2007) BEAST: Bayesian evolutionary analysis by sampling trees. BMC Evol Biol 7: 214.
- View Article
- Google Scholar
59. Zardoya R, Doadrio I (1999) Molecular evidence on the evolutionary and biogeographical patterns of European cyprinids. J Mol Evol 49: 227–237.
- View Article
- Google Scholar
60. Bowen BW, Bass AL, Rocha LA, Grant WS, Robertson DR (2001) Phylogeography of the trumpetfishes (Aulostomus): ring species complex on a global scale. Evolution 55: 1029–1039.
- View Article
- Google Scholar
61. Perdices A, Doadrio I (2001) The molecular systematics and biogeography of the European cobitids based on mitochondrial DNA sequences. Mol Phylogenet Evol 19: 468–478.
- View Article
- Google Scholar
62. Near TJ, Benard M (2004) Rapid allopatric speciation in logperch darters (Percidae: Percina). Evolution 58 2798–2808.
63. Swartz ER (2005) Phylogeography, phylogenetics and evolution of the redfins (Teleostei, Cyprinidae, Pseudobarbus) in southern Africa. PhD thesis, Department of Genetics, University of Pretoria, South Africa.
64. Near TJ, Kassler TW, Koppelman JB, Dillman CB, Philipp D (2003) Speciation in North American Black Basses, Micropterus (Actinopterygii: Centrachidae). Evolution 57: 1610–1621.
- View Article
- Google Scholar
65. De Bruyn M, Mather PB (2007) Molecular signatures of Pleistocene sea-level changes that affected connectivity among freshwater shrimp in Indo-Australian waters. Mol Ecol 16: 4295–4307.
- View Article
- Google Scholar
66. Cooke GM, Chao NL, Beheregaray LB (2012b) Marine incursions, cryptic species and ecological diversification in Amazonia: the biogeographic history of the croaker genus Plagioscion (Sciaenidae). J Biogeogr 39: 724–738.
- View Article
- Google Scholar
67. Ruzzante DE, Walde SJ, Gosse JC, Cussac VE, Habit E, et al. (2008) Climate control on ancestral population dynamics: insight from patagonian fish phylogeography. Mol Ecol 17: 2234–2244.
- View Article
- Google Scholar
68. Zemlak TS, Habit EM, Walde SJ, Battini MA, Adams EDM, et al. (2008) Across the southern Andes on fin: glacial refugia, drainage reversals and a secondary contact zone revealed by the phylogeographical signal of Galaxias platei in Patagonia. Mol Ecol 17: 5049–5061.
- View Article
- Google Scholar
69. Martínez OA, Kutschker A (2011) The ‘Rodados Patagónicos’ (Patagonian shingle formation) of Eastern Patagonia: environmental conditions of gravel sedimentation. Biol J Linn Soc 103: 336–345.
- View Article
- Google Scholar
70. Ponce JF, Rabassa J, Coronato A, Borromei AM (2011) Paleogeographic evolution of the Atlantic coast of Pampa and Patagonia since the Last Glacial Maximum to the Middle Holocene. Biol J Linn Soc 103: 363–379.
- View Article
- Google Scholar
71. Ruzzante DE, Walde SJ, Macchi PJ, Alonso M, Barriga JP (2011) Phylogeography and phenotypic diversification in the Patagonian fish Percichthys trucha: the roles of Quaternary glacial cycles and natural selection. Biol J Linn Soc 103: 514–529.
- View Article
- Google Scholar
72. Cooke GM, Chao NL, Beheregaray LB (2012c) Natural selection in the water: freshwater invasion and isolation by adaptation to water colour in the Amazonian pufferfish. J Evol Biol 25: 1305–132.
- View Article
- Google Scholar
73. Cooke GM, Chao NL, Beheregaray LB (2012d) Divergent natural selection with gene flow along major environmental gradients in Amazonia: insights from genome scans, population genetics and phylogeography of the characin fish Triportheus albus. Mol Ecol 21: 2410–2427.
- View Article
- Google Scholar
74. Thacker CE, Unmack PJ, Matsui L, Rifenbark N (2007) Comparative phylogeography of five sympatric Hypseleotris species (Teleostei: Eleotridae) in south-eastern Australia reveals a complex pattern of drainage basin exchanges with little congruence across species. J Biogeogr 34: 1518–1533.
- View Article
- Google Scholar
75. Craw D, Burridge CP, Upton P, Rowe DL, Waters JM (2008) Evolution of biological dispersal corridors through a tectonically active mountain range in New Zealand. J Biogeogr 35: 1790–1802.
- View Article
- Google Scholar
76. Chakona A, Swartz ER (2012) Contrasting habitat associations of imperilled endemic stream fishes from a global biodiversity hot spot. BMC Ecol 12: 19.
- View Article
- Google Scholar
77. Avise JC (2000) Phylogeography: the history and formation of species. Harvard University Press, Cambridge, MA.
78. Donoghue MJ, Moore BR (2003) Towards an integrative historical biogeography. Integr Comp Biol 43: 261–270.
- View Article
- Google Scholar

[ref1] 1. Rüber L, Britz R, Zardoya R (2006) Molecular phylogenetics and evolutionary diversification of labyrinth fishes (Perciformes: Anabantoidei). Syst Biol 55: 374–397.
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. Price BW, Barker NP, Villet MH (2007) Patterns and processes underlying evolutionary significant units in the Platypleura stridula L. species complex (Hemiptera: Cicadidae) in the Cape Floristic Region, South Africa. Mol Ecol 16: 2574–2588.
View Article
Google Scholar

[5] View Article

[6] Google Scholar

[ref3] 3. Verboom GA, Archibald JK, Bakker FT, Bellstedt DU, Conrad F, et al. (2009) Origin and diversification of the Greater Cape flora: Ancient species repository, hot-bed of recent radiation, or both? Mol Phylogenet Evol 51: 44–53.
View Article
Google Scholar

[8] View Article

[9] Google Scholar

[ref4] 4. Barber BR, Klicka J (2010) Two pulses of diversification across the Isthmus of Tehuantepec in a montane Mexican bird fauna. Proc R Soc Lond B 277: 2675–2681.
View Article
Google Scholar

[11] View Article

[12] Google Scholar

[ref5] 5. Klaus S, Selvandran S, Goh JW, Wowor D, Brandis D, et al. (2013) Out of Borneo: Neogene diversification of Sundaic freshwater crabs (Crustacea: Brachyura: Gecarcinucidae: Parathelphusa). J Biogeogr 40: 63–74.
View Article
Google Scholar

[14] View Article

[15] Google Scholar

[ref6] 6. Cooke GM, Chao NL, Beheregaray LB (2012a) Five cryptic species in the Amazonian catfish Centromochlus existimatus identified based on biogeographic predictions and genetic data. PlosOne 7(11).

[ref7] 7. Hawlitschek O, Hendrich L, Espeland M, Toussaint EFA, Genner MJ, et al. (2012) Pleistocene climate change promoted rapid diversification of aquatic invertebrates in Southeast Australia. BMC Evol Biol 12: 142.
View Article
Google Scholar

[18] View Article

[19] Google Scholar

[ref8] 8. Chakona A, Swartz ER, Gouws G, Bloomer P (2013) A freshwater fish defies ancient mountain ranges and drainage divides: extrinsic and intrinsic influences on the evolutionary history of a recently identified galaxiid. J Biogeogr 40: 1399–1412.
View Article
Google Scholar

[21] View Article

[22] Google Scholar

[ref9] 9. Waters JM, Allibone RM, Wallis GP (2006) Geological subsidence, river capture, and cladogenesis of galaxiid fish lineages in central New Zealand. Biol J Linn Soc 88: 367–376.
View Article
Google Scholar

[24] View Article

[25] Google Scholar

[ref10] 10. Burridge CP, Craw D, Waters JM (2006) River capture, range expansion, and cladogenesis: the genetic signature of freshwater vicariance. Evolution 60: 1038–1049.
View Article
Google Scholar

[27] View Article

[28] Google Scholar

[ref11] 11. Burridge CP, Craw D, Waters JM (2007) An empirical test of freshwater vicariance via river capture. Mol Ecol 16: 1883–1895.
View Article
Google Scholar

[30] View Article

[31] Google Scholar

[ref12] 12. Berendzen PB, Gambles T, Simons AM (2008) Phylogeography of the bigeye chub Hybopsis amblops (Teleostei: Cypriniformes): early Pleistocene diversification and post-glacial range expansion. J Fish Biol 73: 2021–2039.
View Article
Google Scholar

[33] View Article

[34] Google Scholar

[ref13] 13. Swartz ER, Skelton PH, Bloomer P (2007) Sea-level changes, river capture and the evolution of populations of the Eastern Cape and fiery redfins (Pseudobarbus afer and Pseudobarbus phlegethon, Cyprinidae), across multiple river systems in South Africa. J Biogeogr 34: 2086–2099.
View Article
Google Scholar

[36] View Article

[37] Google Scholar

[ref14] 14. Swartz ER, Skelton PH, Bloomer P (2009) Phylogeny and biogeography of the genus Pseudobarbus (Cyprinidae): shedding light on the drainage history of rivers associated with the Cape Floristic Region. Mol Phylogent Evol 51: 75–84.
View Article
Google Scholar

[39] View Article

[40] Google Scholar

[ref15] 15. McCulloch GA, Wallis GP, Waters JM (2010) Onset of glaciation drove simultaneous vicariant isolation of Alpine insects in New Zealand. Evolution 64–7: 2033–2043.
View Article
Google Scholar

[42] View Article

[43] Google Scholar

[ref16] 16. Barber BR, Unmack PJ, Pérez-Losada M, Johnson J, Crandall K (2011) Different processes lead to similar patterns: a test of codivergence and the role of sea level and climate changes in shaping a southern temperate freshwater assemblage. BMC Evol Biol 11: 343.
View Article
Google Scholar

[45] View Article

[46] Google Scholar

[ref17] 17. Goldblatt P, Manning JC (2000) Cape Plants. A Conspectus of the cape Flora of South Africa. National botanic Institute, Pretoria.

[ref18] 18. Linder HP (2003) The radiation of the Cape flora, southern Africa. Biol Rev 78: 597–638.
View Article
Google Scholar

[49] View Article

[50] Google Scholar

[ref19] 19. Kreft H, Jetz W (2007) Global patterns and determinants of vascular plant diversity. P Natl Acad Sci USA 104: 5925–5930.
View Article
Google Scholar

[52] View Article

[53] Google Scholar

[ref20] 20. Wishart MJ, Day JA (2002) Endemism of the freshwater fauna of the south-western Cape, South Africa. Verh Internat Verein Limnol 28: 1–5.
View Article
Google Scholar

[55] View Article

[56] Google Scholar

[ref21] 21. Thieme ML, Abell R, Stiassny MLJ, Skelton PH, Lehner B, et al.. (2005) Freshwater Ecoregions of Africa and Madagascar. Island Press.

[ref22] 22. Linder HP, Johnson SD, Kuhlmann M, Matthee CA, Nyffeler R, et al. (2010) Biotic diversity in the Southern African winter-rainfall region. Curr Opin Env Sust 2: 109–116.
View Article
Google Scholar

[59] View Article

[60] Google Scholar

[ref23] 23. Waters JM, Cambray JA (1997) Intraspecific phylogeography of the Cape galaxias from South Africa: evidence from mitochondrial DNA sequences. J Fish Biol 50: 1329–1338.
View Article
Google Scholar

[62] View Article

[63] Google Scholar

[ref24] 24. Bloomer P, Impson ND (2000) Mitochondrial DNA differentiation in the critically endangered Berg River Redfin (Pseudobarbus burgi). J Hered 91: 122–127.
View Article
Google Scholar

[65] View Article

[66] Google Scholar

[ref25] 25. Wishart M, Hughes J, Stewart B, Impson D (2006) Extreme levels of intra-specific divergence among Cape Peninsula populations of the Cape galaxias, Galaxias zebratus Castelnau 1861, reveals a possible species complex. Afr J Aquat Sci 31: 99–106.
View Article
Google Scholar

[68] View Article

[69] Google Scholar

[ref26] 26. Swartz ER, Flemming AF, Mouton P le FN (2004) Contrasting genetic patterns and population histories in three threatened redfin species (Cyprinidae) from the Olifants River System, western South Africa. J Fish Biol 64: 1153–1167.
View Article
Google Scholar

[71] View Article

[72] Google Scholar

[ref27] 27. Barnard KH (1943) Revision of the indigenous freshwater fishes of the S.W. Cape Region. Ann S Afr Mus 36: 101–263.
View Article
Google Scholar

[74] View Article

[75] Google Scholar

[ref28] 28. Skelton PH (1986) Distribution patterns and biogeography of non-tropical southern African freshwater fishes. Palaeoecol Afr 17: 211–230.
View Article
Google Scholar

[77] View Article

[78] Google Scholar

[ref29] 29. Wishart MJ, Hughes JM (2001) Exploring patterns of population subdivision in the net-winged midge, Elporia barnardi (Diptera: Blephariceridae), in mountain streams of the south-western Cape, South Africa. Freshwater Biol 46: 479–490.
View Article
Google Scholar

[80] View Article

[81] Google Scholar

[ref30] 30. Siesser WG, Dingle RV (1981) Tertiary sea-level movements around southern Africa. J Geol 89: 83–96.
View Article
Google Scholar

[83] View Article

[84] Google Scholar

[ref31] 31. Hendey QB (1983) Cenozoic geology and palaeogeography of the fynbos region. In: Deacon HJ, Hendey QB, Lambrechts JJN, editors. Fynbos Palaeoecology: A Preliminary Synthesis. South African National Scientific Programmes Report No. 75. CSIR, Pretoria, 35–60.

[ref32] 32. Partridge TC, Maud RR (1987) Geomorphic evolution of southern Africa since the Mesozoic. S Afr J Geol 90: 179–208.
View Article
Google Scholar

[87] View Article

[88] Google Scholar

[ref33] 33. Partridge TC, Maud RR (2000) Macro-scale geomorphic evolution of southern Africa. In: Partridge TC, Maud RR, editors. The Cenozoic of Southern Africa. Oxford University Press, New York, 3–18.

[ref34] 34. Partridge TC, Scott L, Hamilton JE (1999) Synthetic reconstructions of southern African environments during the Last Glacial Maximum (21–18 kyr) and the Holocene Altithermal (8–6 kyr). Quatern Int 57/58: 207–214.
View Article
Google Scholar

[91] View Article

[92] Google Scholar

[ref35] 35. Marlow JR, Lange CB, Wefer G, Rosell-Melè A (2000) Upwelling intensification as part of the Pliocene–Pleistocene climate transition. Science 290: 2288–2291.
View Article
Google Scholar

[94] View Article

[95] Google Scholar

[ref36] 36. Zachos J, Pagani M, Sloan L, Thomas E, Billups K (2001) Trends, rhythms, aberrations in global climate 65 Ma to present. Science 292: 686–693.
View Article
Google Scholar

[97] View Article

[98] Google Scholar

[ref37] 37. Cowling RM, Procheş Ş, Partridge TC (2009) Explaining the uniqueness of the Cape Flora: Incorporating geomorphic evolution as a factor for explaining its diversification. Mol Phylogenet Evol 51: 64–74.
View Article
Google Scholar

[100] View Article

[101] Google Scholar

[ref38] 38. Deacon HJ, Jury MR, Ellis F (1992) Selective regime and time. In: Cowling RM, editor. The ecology of fynbos: Nutrients, fire and diversity. Oxford University Press, Cape Town, 6–22.

[ref39] 39. Tyson PD, Partridge TC (2000) Evolution of Cenozoic climates. In: Partridge TC, Maud RM, editors. Cenozoic of Southern Africa. Oxford University Press, New York, 371–387.

[ref40] 40. Miller KG, Kominz MA, Browning JV, Wright JD, Mountain GS, et al. (2005) The Phanerozoic record of global sea-level change. Science 310: 1293–1298.
View Article
Google Scholar

[105] View Article

[106] Google Scholar

[ref41] 41. Siesser WG (1978) Leg 40 results in relation to continental shelf and onshore geology. In: Bolli HM, Ryan WBF, et al.., editors. Initial Reports of the Deep Sea Drilling Project, Volume 40: Washington, U.S. Government Printing Offi ce, 40, 965–979.

[ref42] 42. Skelton P (2001) A complete guide to the freshwater fishes of Southern Africa. Struik Publishers, Cape Town.

[ref43] 43. Roos H (2004) Genetic diversity in the anabantids Sandelia capensis and S. bainsii: A phylogeographical and phylogenetic investigation. Unpublished MSc dissertation, University of Pretoria, South Africa.

[ref44] 44. Van Niekerk R (2004) Phylogeography of the Cape galaxias Galaxias zebratus. Unpublished MSc dissertation, University of Pretoria, South Africa.

[ref45] 45. Bermingham E, Martin AP (1998) Comparative mtDNA phylogeography of neotropical freshwater fishes: testing shared history to infer the evolutionary landscape of lower Central America. Mol Ecol 7: 499–517.
View Article
Google Scholar

[112] View Article

[113] Google Scholar

[ref46] 46. Machordom A, Doadrio I (2001) Evidence of a cenozoic Betic-Kabilian connection based on freshwater fish phylogeography (Luciobarbus, Cyprinidae). Mol Phylogenet Evol 18: 252–263.
View Article
Google Scholar

[115] View Article

[116] Google Scholar

[ref47] 47. Kocher TD, Thomas WK, Meyer A, Edwards SV, Paabo S, et al. (1989) Dynamics in the mitochondrial DNA evolution in animals: Amplification and sequencing with conserved primers. P Natl Acad Sci USA 86: 6196–6200.
View Article
Google Scholar

[118] View Article

[119] Google Scholar

[ref48] 48. Librado P, Rozas J (2009) DnaSP v5: a software for comprehensive analysis of DNA polymorphism data. Bioinformatics 25: 1451–1452.
View Article
Google Scholar

[121] View Article

[122] Google Scholar

[ref49] 49. Posada D, Crandall KA (1998) MODELTEST: testing the model of DNA substitution. Bioinformatics 14: 817–818.
View Article
Google Scholar

[124] View Article

[125] Google Scholar

[ref50] 50. Lanave C, Preparata G, Saccone C, Serio G (1984) A new method for calculating evolutionary substitution rates. J Mol Evol 20: 86–93.
View Article
Google Scholar

[127] View Article

[128] Google Scholar

[ref51] 51. Posada D, Crandall KA (2001) Selecting Models of Nucleotide Substitution: An Application to Human Immunodeficiency Virus 1 (HIV-1). Mol Biol Evol 18: 897–906.
View Article
Google Scholar

[130] View Article

[131] Google Scholar

[ref52] 52. Ronquist F, Huelsenbeck JP (2003) MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics 19: 1572–1574.
View Article
Google Scholar

[133] View Article

[134] Google Scholar

[ref53] 53. Rambaut A, Drummond AJ (2007) Tracer v.1.4. Available: http://beast.bio.ed.ac.uk/Tracer/.

[ref54] 54. Swofford DL (2003) PAUP*. Phylogenetic Analysis Using Parsimony (*and Other Methods). Version 4. Sinauer Assoc. Inc., Sunderland, Massachusetts.

[ref55] 55. Clement M, Posada D, Crandall KA (2000) TCS: a computer program to estimate gene genealogies. Mol Ecol 9: 1657–1659.
View Article
Google Scholar

[138] View Article

[139] Google Scholar

[ref56] 56. Fu Y-X (1997) Statistical tests of neutrality of mutations against population growth, hitchhiking, and background selection. Genetics 147: 915–925.
View Article
Google Scholar

[141] View Article

[142] Google Scholar

[ref57] 57. Excoffier L, Laval G, Schneider S (2005) Arlequin (version 3.0): an integrated software package for population genetics data analysis. Evol Bioinform 1: 47–50.
View Article
Google Scholar

[144] View Article

[145] Google Scholar

[ref58] 58. Drummond AJ, Rambaut A (2007) BEAST: Bayesian evolutionary analysis by sampling trees. BMC Evol Biol 7: 214.
View Article
Google Scholar

[147] View Article

[148] Google Scholar

[ref59] 59. Zardoya R, Doadrio I (1999) Molecular evidence on the evolutionary and biogeographical patterns of European cyprinids. J Mol Evol 49: 227–237.
View Article
Google Scholar

[150] View Article

[151] Google Scholar

[ref60] 60. Bowen BW, Bass AL, Rocha LA, Grant WS, Robertson DR (2001) Phylogeography of the trumpetfishes (Aulostomus): ring species complex on a global scale. Evolution 55: 1029–1039.
View Article
Google Scholar

[153] View Article

[154] Google Scholar

[ref61] 61. Perdices A, Doadrio I (2001) The molecular systematics and biogeography of the European cobitids based on mitochondrial DNA sequences. Mol Phylogenet Evol 19: 468–478.
View Article
Google Scholar

[156] View Article

[157] Google Scholar

[ref62] 62. Near TJ, Benard M (2004) Rapid allopatric speciation in logperch darters (Percidae: Percina). Evolution 58 2798–2808.

[ref63] 63. Swartz ER (2005) Phylogeography, phylogenetics and evolution of the redfins (Teleostei, Cyprinidae, Pseudobarbus) in southern Africa. PhD thesis, Department of Genetics, University of Pretoria, South Africa.

[ref64] 64. Near TJ, Kassler TW, Koppelman JB, Dillman CB, Philipp D (2003) Speciation in North American Black Basses, Micropterus (Actinopterygii: Centrachidae). Evolution 57: 1610–1621.
View Article
Google Scholar

[161] View Article

[162] Google Scholar

[ref65] 65. De Bruyn M, Mather PB (2007) Molecular signatures of Pleistocene sea-level changes that affected connectivity among freshwater shrimp in Indo-Australian waters. Mol Ecol 16: 4295–4307.
View Article
Google Scholar

[164] View Article

[165] Google Scholar

[ref66] 66. Cooke GM, Chao NL, Beheregaray LB (2012b) Marine incursions, cryptic species and ecological diversification in Amazonia: the biogeographic history of the croaker genus Plagioscion (Sciaenidae). J Biogeogr 39: 724–738.
View Article
Google Scholar

[167] View Article

[168] Google Scholar

[ref67] 67. Ruzzante DE, Walde SJ, Gosse JC, Cussac VE, Habit E, et al. (2008) Climate control on ancestral population dynamics: insight from patagonian fish phylogeography. Mol Ecol 17: 2234–2244.
View Article
Google Scholar

[170] View Article

[171] Google Scholar

[ref68] 68. Zemlak TS, Habit EM, Walde SJ, Battini MA, Adams EDM, et al. (2008) Across the southern Andes on fin: glacial refugia, drainage reversals and a secondary contact zone revealed by the phylogeographical signal of Galaxias platei in Patagonia. Mol Ecol 17: 5049–5061.
View Article
Google Scholar

[173] View Article

[174] Google Scholar

[ref69] 69. Martínez OA, Kutschker A (2011) The ‘Rodados Patagónicos’ (Patagonian shingle formation) of Eastern Patagonia: environmental conditions of gravel sedimentation. Biol J Linn Soc 103: 336–345.
View Article
Google Scholar

[176] View Article

[177] Google Scholar

[ref70] 70. Ponce JF, Rabassa J, Coronato A, Borromei AM (2011) Paleogeographic evolution of the Atlantic coast of Pampa and Patagonia since the Last Glacial Maximum to the Middle Holocene. Biol J Linn Soc 103: 363–379.
View Article
Google Scholar

[179] View Article

[180] Google Scholar

[ref71] 71. Ruzzante DE, Walde SJ, Macchi PJ, Alonso M, Barriga JP (2011) Phylogeography and phenotypic diversification in the Patagonian fish Percichthys trucha: the roles of Quaternary glacial cycles and natural selection. Biol J Linn Soc 103: 514–529.
View Article
Google Scholar

[182] View Article

[183] Google Scholar

[ref72] 72. Cooke GM, Chao NL, Beheregaray LB (2012c) Natural selection in the water: freshwater invasion and isolation by adaptation to water colour in the Amazonian pufferfish. J Evol Biol 25: 1305–132.
View Article
Google Scholar

[185] View Article

[186] Google Scholar

[ref73] 73. Cooke GM, Chao NL, Beheregaray LB (2012d) Divergent natural selection with gene flow along major environmental gradients in Amazonia: insights from genome scans, population genetics and phylogeography of the characin fish Triportheus albus. Mol Ecol 21: 2410–2427.
View Article
Google Scholar

[188] View Article

[189] Google Scholar

[ref74] 74. Thacker CE, Unmack PJ, Matsui L, Rifenbark N (2007) Comparative phylogeography of five sympatric Hypseleotris species (Teleostei: Eleotridae) in south-eastern Australia reveals a complex pattern of drainage basin exchanges with little congruence across species. J Biogeogr 34: 1518–1533.
View Article
Google Scholar

[191] View Article

[192] Google Scholar

[ref75] 75. Craw D, Burridge CP, Upton P, Rowe DL, Waters JM (2008) Evolution of biological dispersal corridors through a tectonically active mountain range in New Zealand. J Biogeogr 35: 1790–1802.
View Article
Google Scholar

[194] View Article

[195] Google Scholar

[ref76] 76. Chakona A, Swartz ER (2012) Contrasting habitat associations of imperilled endemic stream fishes from a global biodiversity hot spot. BMC Ecol 12: 19.
View Article
Google Scholar

[197] View Article

[198] Google Scholar

[ref77] 77. Avise JC (2000) Phylogeography: the history and formation of species. Harvard University Press, Cambridge, MA.

[ref78] 78. Donoghue MJ, Moore BR (2003) Towards an integrative historical biogeography. Integr Comp Biol 43: 261–270.
View Article
Google Scholar

[201] View Article

[202] Google Scholar