Cryptic species of cardinalfish with evidence for old and new divergence

Larval dispersal and limited knowledge of physical boundaries challenge our understanding of the processes that drive genetic divergence and potential speciation in the marine environment. Divergence, both within and between populations of marine taxa, is not uncommon, but spatial and temporal stability of observed genetic structure is not well known. Previously, we detected large genetic differences among populations of the cardinalfish species Ostorhinchus doederleini inhabiting adjacent coral reefs. Here, we determined the spatial and temporal persistence of these genetic structures over the course of ten consecutive generations. Using microsatellite markers, we detected large changes (genetic population distance, D _est, ranged from 0.04 to 0.46) in the genetic structure in some years, but some reefs maintained the same populations for nearly all sampling years. As this species’ life span does not exceed 1 yr, persistence of distinct reef populations suggests natal homing. Mitochondrial identity based on two mtDNA markers corroborates the nuclear genetic evidence for genetic differences large enough to constitute different clades and even cryptic species in O. doederleini, which, based on gross morphology, was thought to be a single taxon. Habitat specialization was observed in one clade that exclusively inhabited reef lagoons, while all clades could be observed on reef slopes. We suggest that local habitat recognition combined with local population recognition and selection against hybrids can form barriers that maintain a cryptic species complex.     

Divergent lineages and conserved niches: using ecological niche modeling to examine the evolutionary patterns of the Nile monitor (<Emphasis Type="Italic">Varanus niloticus</Emphasis>)

Ecological niche modeling is a useful tool that can support phylogeographic analyses, offering insight into the evolutionary processes that have generated present-day patterns of biodiversity. Findings of ecological divergence across evolutionary lineages can be utilized to bolster inferences of parapatric or sympatric modes of speciation, and provide support for species-level classifications. Conversely, conserved ecological niches across evolutionary timescales are thought to have facilitated allopatric speciation. Here, we examined the climatic niche of three genetic lineages of the Nile monitor (Varanus niloticus) to better understand the processes involved in generating patterns of genetic variation, and to potentially clarify their taxonomic status. We built ecological niche models using genetically confirmed occurrence points from the three evolutionary lineages of V. niloticus, occupying the western, northern, and southern regions of Africa. Pairwise comparisons of climatic niche overlap provided evidence in support of niche conservatism across all V. niloticus lineages. These findings are consistent with an allopatric mode of differentiation. Furthermore, climatic niche conservatism could have played a role in isolating V. niloticus populations during historic climate oscillations, generating the observed genetic patterns across Africa.     

Cryptic genetic diversity and spatial patterns of admixture within Belizean marine reserves

Despite the potential for long-distance gene flow in the sea, there is growing evidence of cryptic genetic diversity in many marine taxa. Understanding the geographic distribution of cryptic lineages, as well as the spatial patterns of admixture among them, can have important implications for conservation planning. Here, we explore patterns of divergence in a coral reef fish, the neon goby Elacatinus lori, across the species’ range. First, we use targeted amplicon sequencing to describe the spatial pattern of genetic divergence using two marker types (57 anonymous ddRAD-derived loci and mtDNA cytb). Second, we quantify the degree of admixture and hybridization between two previously-unidentified divergent lineages within Belize. Third, we assess whether the existing group of marine protected areas (MPAs) in Belize protects this cryptic genetic diversity. The results provide strong evidence for two divergent genetic lineages of E. lori within Belize, separated geographically by only 30 km of low-suitability habitat. There is a sharp genetic cline across these 30 km, and evidence of admixture and introgression at the boundary regions of the habitat break. We also show that the broadly-distributed arrangement of MPAs within Belize protects both major lineages as well as subtle structure within-lineages, and therefore may confer protection to co-distributed species that exhibit similar spatial patterns of divergence.     

Divergence among generalist herbivores: the <Emphasis Type="Italic">Frankliniella schultzei</Emphasis> species complex in Australia (Thysanoptera: Thripidae)

Understanding and interpreting the host plant interactions of “generalist” herbivorous insects requires that species limits are accurately defined, as such taxa frequently harbour cryptic species with restricted host use. We tested for the presence of cryptic species across different host plant species in Australian Frankliniella schultzei using a combination of gene sequencing and newly developed microsatellite markers. We detect deep divergence between three colour morphs (black, brown and yellow) but no discordance between mitochondrial and nuclear genes in areas of sympatry, indicating the presence of at least three species in Australia (and potentially six globally). Microsatellite markers were developed for the brown species but could not be amplified in the black or yellow species because the divergence between them is too great. When applied to six populations across Queensland and New South Wales the microsatellites showed high levels of gene flow across thrips collected from Gossypium hirsutum (cotton), Hibiscus rosa-sinensis and Malvaviscus arboreus, and over distances of at least 950 km, indicating considerable movement by these insects and no host-associated genetic differentiation in the brown species. Significantly, the divergence between the three species in Australia was not associated with any noticeable host specialisation. The substantial overlap in geographical distribution and host plant range raises questions about the process of speciation in generalist insects. Our results provide the basis from which detailed quantification of relative host use can be conducted for each species within the F. schultzei complex; this next step is crucial to fully understanding the host plant relationships of each and, thus, the basis of their speciation.     

Genetic divergence within the monotypic tree genus <Emphasis Type="Italic">Platycarya</Emphasis> (Juglandaceae) and its implications for species’ past dynamics in subtropical China

Subtropical East Asia harbours a large plant diversity that is often attributed to allopatric speciation in this topographically complex region characterized by a relative climate stability. Here, we use observations of Platycarya, a widespread subtropical Asian tree genus, to explore the consequences of past climate stability on species’ evolutionary history in subtropical China. This genus has a controversial taxonomy: while it is now prevailingly treated as monotypic, two species have been originally described, Platycarya strobilacea and P. longipes. Previous information from species distribution models, fossil pollen data and genetic data based on chloroplast DNA (cpDNA) were integrated with newly obtained genetic data from the two putative species. We used both cpDNA (psbA-trnH and trnL-F intergenic spacers, including a partial trnL gene sequence) and nuclear markers. The latter included sequences of the internal transcribed spacer region (ITS1–5.8S–ITS2) of the nuclear ribosomal DNA and random genomic single nucleotide polymorphisms. Using these nuclear genetic markers, we found interspecific genetic divergence fitting with the ‘two species’ scenario and geographically structured intraspecific variation. Using cpDNA markers, we also found geographically structured intraspecific variation. Despite deep inter- and intraspecific genetic divergence, we detected genetic admixture in southwest China. Overall, our findings of genetic divergence within Platycarya support the hypothesis of allopatric speciation. However, episodes of population interconnection were identified, at least in southwest China, suggesting that the genus has had a dynamic population history.     

BIOGEOGRAPHY OF A WIDESPREAD FRESHWATER CRUSTACEAN: PSEUDOCONGRUENCE AND CRYPTIC ENDEMISM IN THE NORTH AMERICAN DAPHNIA LAEVIS COMPLEX

The lack of morphological variation in many freshwater invertebrates over vast distances has been cited as evidence for their frequent, long-distance dispersal. This scenario implies that vicariance will be an insignificant determinant of species distributions or diversity. We carried out a phylogeographic and population genetics study of one widespread crustacean group, the North American Daphnia laevis complex. Allozyme and sequence variation of two mtDNA genes (12S and 16S rRNA) clearly indicates the existence of five morphologically cryptic, largely allopatric groups (Daphnia dubia, D. laevis laevis, D. laevis gessneri, D. magniceps magniceps, and D. magniceps pacifica ssp. n.). Within each of these groups, there is weak or no genetic differentiation over large geographic areas suggesting their recent long-distance dispersal. The present-day distributions and phylogeography of the regional groups suggests the occurrence of both deep and shallow vicariance events. Although divergence times from mtDNA sequences do indicate both deep and shallow divergences, these estimates are incongruent with their proposed vicariance times. The results show that even within closely related freshwater invertebrates, a complex biogeography exists, whose analysis is made difficult by long-distance dispersal, cryptic endemism, and pseudocongruence.     

Cryptic barriers to dispersal within a lake allow genetic differentiation of Eurasian perch

Gene flow between coexisting or nearby populations normally prevents genetic divergence and local adaptation. Despite this, there are an increasing number of reports of sympatric sister taxa, indicating potential divergence and speciation in the face of gene flow. A large number of such reported cases involve lake-dwelling fish, which are expected to run into few physical barriers to dispersal within their aquatic habitat. However, such cases may not necessarily reflect sympatric speciation if cryptic dispersal barriers are common in lakes and other aquatic systems. In this study, we examined genetic differentiation in perch (Perca fluviatilis L.) from nine locations in a single, small lake (24 km(2)), using microsatellites. We detected significant genetic differentiation in all but two pairwise comparisons. These patterns were not consistent with divergence by distance or the existence of kin groups. Instead, they suggest that cryptic barriers to dispersal exist within the lake, allowing small-scale genetic divergence. Such an observation suggests that allopatric (or parapatric) divergence may be possible, even in small, apparently homogenous environments such as lakes. This has important consequences for how we currently view evidence from nature for sympatric speciation.     

Echoes of the whispering land: interacting roles of vicariance and selection in shaping the evolutionary divergence of two <Emphasis Type="Italic">Calceolaria</Emphasis> (Calceolariaceae) species from Patagonia and Malvinas/Falkland Islands

A key to understanding the origin and identity of young species lays on the knowledge of the Quaternary climatic oscillations’ effect on gene flow and vicariance. Even though the effect of climatic fluctuations is relatively well understood for southern hemisphere plant species, little is known about their effect on the evolutionary histories of species from mainland and islands. Thus, we investigated whether Quaternary climate-driven fluctuations translated into lineage divergence and speciation, followed or not by climatic niche differentiation, in two allopatric plant species, Calceolaria uniflora and C. fothergillii from Patagonia and Malvinas/Falkland islands, respectively. We sampled the range of both species, and sequenced two chloroplastic (cpDNA; trnS–trnG and trnH–psbA), and one single copy “anonymous” non-coding nuclear region (nDNA). We performed phylogeographic and dating analyses, and adjusted spatio-temporal diffusion models. We complemented molecular evidence with climatic niche differentiation analyses and species paleo-distribution projections. A species coalescent reconstruction based on multi-locus data retrieved both species as monophyletic. Estimates from cpDNA indicated the species diverged during the Great Patagonian Glaciation. Chloroplast and nuclear DNA showed east–west distribution of the main genetic groups but with contrasting spatial genetic diversity. The spatio-temporal diffusion analyses showed that between 1–0.8 Mya and 570 Kya the lineage leading to C. fothergillii diverged from C. uniflora and arrived to the islands. Climatic niche projections hindcasted range expansions during glaciations, and contractions during the interglacial periods. Comparisons of climatic niches between the two study species indicated that temperature variables show evidence of niche conservatism while precipitation regimes supported niche divergence, even when considering the background environmental divergence. Our study indicates that glacial fluctuations affected the mainland/islands connections favouring speciation mediated not only by isolation, but also by climatic niche differentiation.     

Adaptive loss of color polymorphism and character displacements in sympatric <Emphasis Type="Italic">Mnais</Emphasis> damselflies

A geographical survey of two Mnais damselfly species in the Kinki area of Japan showed evidence for character displacements when the two species were found in sympatry. Mnais costalis, a species that has polymorphic male mating types of orange-winged territorial and clear-winged non-territorial morphs (hereafter abbreviated to orange and clear morphs respectively) in allopatry often shifted to having monomorphic orange morphs in sympatry. The mean body size of orange morphs was consistently larger than that of clear morph in allopatry. The mean body size of the sympatric orange morphs was even larger than that of allopatric orange morphs. By contrast, Mnais pruinosa, a species that also has two morphs of large orange and small clear morphs in allopatry, shifted to having monomorphic clear morphs in sympatry. The mean body size of the sympatric clear morphs was smaller than that of allopatric clear morphs. Divergence was also detected in the preference for habitat insolation conditions between sympatric Mnais damselflies. Both species in allopatric regions prefer half-light forest habitats, while in sympatric regions they showed diversified habitat preference: M. costalis preferred sunny habitats while M. pruinosa preferred shady habitats. Multiple character displacements in signal traits and habitat preference emerged in heterogeneous forest light environments are likely to have synergistic effects on the reproductive isolation of the two species.     

Interseasonal and interspecies diversities of <Emphasis Type="Italic">Symbiodinium</Emphasis> density and effective photochemical efficiency in five dominant reef coral species from Luhuitou fringing reef,northern South China Sea

Although it is well established that different coral species have different susceptibilities to thermal stress, the reasons behind this variation are still unclear. In this study, 384 samples across five dominant coral species were collected seasonally between September 2013 and August 2014 at Luhuitou fringing reef in Sanya, Hainan Island, northern South China Sea, and their algal symbiont density and effective photochemical efficiency (Φ _PSII) were measured. The results indicated that both the Symbiodinium density and Φ _PSII of corals were subject to significant interspecies and seasonal variations. Stress-tolerant coral species, including massive Porites lutea and plating Pavona decussata, had higher symbiont densities but lower Φ _PSII compared to the vulnerable branching species of Acropora over the course of all four seasons. Seasonally, coral symbiont densities were the lowest during winter, while during the same period, Φ _PSII of corals was at the highest point. Further analysis suggested that dissolved inorganic nutrients and upwelling in the reef area were probably responsible for the observed seasonal variations in symbiont density. The fact that Porites lutea has the lowest Φ _PSII during all four seasons is likely related to their symbionts’ lower capacity to provide required photosynthates for calcification. These results suggest that a coral’s thermal tolerance is primarily and positively dependent on its symbiont density and is less related to its effective photochemical efficiency.     

A geometric morphometric and microsatellite analyses of <Emphasis Type="Italic">Scaptotrigona mexicana</Emphasis> and <Emphasis Type="Italic">S. pectoralis</Emphasis> (Apidae: Meliponini) sheds light on the biodiversity of Mesoamerican stingless bees

Geometric morphometrics and molecular methods are effective tools to study the variability of stingless bee populations and species that merit protection given their worldwide decline. Based on previous evidence of cryptic lineages within the Scaptotrigona genus, we tested the existence of multiple evolutionary lineages within the species S. mexicana and we investigated the status of S. pectoralis. By analyzing their population structure, we found differences between the Pacific and Atlantic populations of each of these species, although geometric morphometrics of the wing only confirmed these results in S. mexicana. There was a tendency towards enhanced genetic differentiation over larger distances in the Atlantic populations of both species but not in the Pacific populations. These results revealed a pattern of differentiation among evolutionary units and a specific distribution of genetic diversity within these Scaptotrigona species in Mesoamerica, suggesting the need for future taxonomic revisions, as well as activities aimed at management and conservation.     

Different dispersal histories of lineages of the earthworm <Emphasis Type="Italic">Aporrectodea caliginosa</Emphasis> (Lumbricidae,Annelida) in the Palearctic

Earthworms are among the most abundant and ecologically important invasive species, and are therefore a good object for studying genetic processes in invasive populations. Aporrectodea caliginosa is one of the most widespread invasive earthworms in the temperate zone. It is believed to have dispersed from Europe to all continents except Antarctica. It is known that A. caliginosa consists of three genetic lineages, and genetic diversity is high both among and between them. We attempted to use that high genetic diversity to study A. caliginosa dispersal in the Palearctic based on a sample of 40 localities ranging from eastern Europe to the Russian Far East, and to compare our data to other studies on this species in western Europe and North America. Two genetic lineages were found in the studied sample. Only negligible decrease in genetic diversity was observed for the lineage 2 of A. caliginosa from West Europe to the Far East, suggesting multiple human-mediated introductions. In contrast, lineage 3 is abundant in West Europe and Belarus, but is absent from the East European Plain, the Urals, and the Far East. However, it is present in West Siberia, where it has greatly reduced genetic diversity, indicating long-distance dispersal accompanied by a bottleneck event. Thus, although these two lineages of A. caliginosa are morphologically indistinguishable, they have dramatic differences in their distributions and dispersal histories.     

Vicariance and dispersal effects on phylogeographic structure and speciation in a widespread estuarine invertebrate

Vicariance and dispersal can strongly influence population genetic structure and allopatric speciation, but their importance in the origin of marine biodiversity is unresolved. In transitional estuarine environments, habitat discreteness and dispersal barriers could enhance divergence and provide insight to evolutionary mechanisms underlying marine and freshwater biodiversity. We examined this by assessing phylogeographic structure in the widespread amphipod Gammarus tigrinus across 13 estuaries spanning its northwest Atlantic range from Quebec to Florida. Mitochondrial cytochrome c oxidase I and nuclear internal transcribed spacer 1 phylogenies supported deep genetic structure consistent with Pliocene separation and cryptic northern and southern species. This break occurred across the Virginian-Carolinian coastal biogeographic zone, where an oceanographic discontinuity may restrict gene flow. Ten estuarine populations of the northern species occurred in four distinct clades, supportive of Pleistocene separation. Glaciation effects on genetic structure of estuarine populations are largely unknown, but analysis of molecular variance (AMOVA) supported a phylogeographic break among clades in formerly glaciated versus nonglaciated areas across Cape Cod, Massachusetts. This finding was concordant with patterns in other coastal species, though there was no significant relationship between latitude and genetic diversity. This supports Pleistocene vicariance events and divergence of clades in different northern glacial refugia. AMOVA results and private haplotypes in most populations support an allopatric distribution across estuaries. Clade mixture zones are consistent with historical colonization and human-mediated transfer. An isolation-by-distance model of divergence was detected after we excluded a suspected invasive haplotype in the St. Lawrence estuary. The occurrence of cryptic species and divergent population structure support limited dispersal, dispersed habitat distribution, and historical factors as important determinants of estuarine speciation and diversification.     

Establishing species and species boundaries in <Emphasis Type="BoldItalic">Sabellastarte</Emphasis> Krøyer, 1856 (Annelida: Sabellidae): an integrative approach

Sabellastarte Krøyer, 1856 (Sabellidae), a morphologically homogeneous group distributed in warm and temperate coasts of the Indo-Pacific and Caribbean Sea, is characterized by the presence of a unique combination of features. To date, the genus comprises eight species, but morphological characters traditionally used in diagnostics have shown intra-specific variability, making species boundaries and distributions unclear. The present study constitutes the first attempt to test the monophyly of Sabellastarte and its relationships to other sabellid genera by combining molecular (COI and 16S) and morphological data. Results include placement of a clade containing Stylomma, Sabella, Branchiomma and Bispira as the sister group to Sabellastarte. Phylogenetic analyses and genetic divergence among specimens from several localities around the world indicate the presence of at least six lineages within Sabellastarte. In the context of a discussion of species boundaries and diagnostic features, the distribution of some of those lineages can be explained by the presence of cryptic species and potential introductions.     

Diversity and succession of pelagic microorganism communities in a newly restored Illinois River floodplain lake

Stenotopic specialization to a fragmented habitat promotes the evolution of genetic structure. It is not yet clear whether small-scale population structure generally translates into large-scale intraspecific divergence. In the present survey of mitochondrial genetic structure in the Lake Tanganyika endemic Altolamprologus (Teleostei, Cichlidae), a rock-dwelling cichlid genus comprising A. compressiceps and A. calvus, habitat-induced population fragmentation contrasts with weak phylogeographic structure and recent divergence among genetic clades. Low rates of dispersal, perhaps along gastropod shell beds that connect patches of rocky habitat, and periodic secondary contact during lake level fluctuations are apparently sufficient to maintain genetic connectivity within each of the two Altolamprologus species. The picture of genetic cohesion was interrupted by a single highly divergent haplotype clade in A. compressiceps restricted to the northern part of the lake. Comparisons between mitochondrial and nuclear phylogenetic reconstructions suggested that the divergent mitochondrial clade originated from ancient interspecific introgression. Finally, ‘isolation-with-migration’ models indicated that divergence between the two Altolamprologus species was recent (67–142 KYA) and proceeded with little if any gene flow. As in other rock-dwelling cichlids, recent population expansions were inferred in both Altolamprologus species, which may be connected with drastic lake level fluctuations.     

Spawning and fertility of F<Subscript>1</Subscript> hybrids of the coral genus <Emphasis Type="Italic">Acropora</Emphasis> in the Indo-Pacific

The role of hybridization through multi-specific synchronous spawning in the evolution of reef-building corals has been discussed since the 1990s, particularly for the genus Acropora. However, F₁ hybrids have been reported as common in only one case in the Caribbean, with no evidence of mechanisms that would allow continuous reproduction of the hybrids. In this study, we report for the first time the fecundity of two F₁ hybrid colonies produced experimentally from two Indo-Pacific species, A. intermedia and A. florida. These F₁ hybrids spawned at the same time as the parental corals. Backcrossing and F₁ hybrid crossing were successful in both directions. Furthermore, more than 90% self-fertilization was achieved in an F₁ hybrid, although it was negligible in the parental corals. While it is possible that the F₁ hybrid was a chimera, these results suggest that some products of interspecific hybridization may persist as the offspring of self-fertilizing F₁ hybrids.     

Molecular evolution of glutathione peroxidase (<Emphasis Type="Italic">Gpx</Emphasis>) family genes in desert poplar (<Emphasis Type="Italic">Populus euphratica</Emphasis> Oliv.)

Populus euphratica Oliv. is a poplar species that is distributed mainly in deserts, making it an interesting model in which to investigate molecular mechanisms underlying different stress responses. Here, we used molecular population genetic methods to detect potential selection in candidate genes belonging to the P. euphratica glutathione (GSH) peroxidase (Gpx) family, which are associated with an enzymatic mechanism that combats oxidative damage caused by reactive oxygen species (ROS) in plant cells; earlier studies have shown that Gpx proteins play important roles in coping with increased ROS levels during biotic and abiotic stresses in plants. We analyzed the nucleotide diversity and divergence patterns of five loci encoding Gpx genes, and 16 reference loci used as controls, in order to detect departures from the neutral expectation. Gpx1 has an excess of mid-frequency alleles; high intraspecific nucleotide diversity, distributed in the upper tail of the simulated neutral model; and extensive LD, showing strong evidence of balancing selection/local adaptation. The Gpx3.2 gene exhibits very low nucleotide diversity and divergence, suggesting that it has evolved under strong purifying selection. We failed to detect any evidence for natural selection at the other loci (Gpx2, Gpx4, and Gpx5) compared with the reference loci. The results show that nucleotide diversity and/or divergence differ greatly between members of the Gpx gene family, resulting from differential selective pressure acting on genes, and that adaptive evolution influenced the distribution of P. euphratica in desert regions.     

An incipient invasion of brown anole lizards (<Emphasis Type="Italic">Anolis sagrei</Emphasis>) into their own native range in the Cayman Islands: a case of cryptic back-introduction

Human-mediated dispersal has reshaped distribution patterns and biogeographic relationships for many taxa. Long-distance and over-water dispersal were historically rare events for most species, but now human activities can move organisms quickly over long distances to new places. A potential consequence of human-mediated dispersal is the eventual reintroduction of individuals from an invasive population back into their native range; a dimension of biological invasion termed “cryptic back-introduction.” We investigated whether this phenomenon was occurring in the Cayman Islands where brown anole lizards (Anolis sagrei) with red dewlaps (i.e., throat fans), either native to Little Cayman or invasive on Grand Cayman, have been found on Cayman Brac where the native A. sagrei have yellow dewlaps. Our analysis of microsatellite data shows strong population-genetic structure among the three Cayman Islands, but also evidence for non-equilibrium. We found some instances of intermediate multilocus genotypes (possibly 3–9% of individuals), particularly between Grand Cayman and Cayman Brac. Furthermore, analysis of dewlap reflectance data classified six males sampled on Cayman Brac as having red dewlaps similar to lizards from Grand Cayman and Little Cayman. Lastly, one individual from Cayman Brac had an intermediate microsatellite genotype, a red dewlap, and a mtDNA haplotype from Grand Cayman. This mismatch among genetic and phenotypic data strongly suggests that invasive A. sagrei from Grand Cayman are interbreeding with native A. sagrei on Cayman Brac. To our knowledge, this is the first evidence of cryptic back-introduction. Although we demonstrate this phenomenon is occurring in the Cayman Islands, assessing its frequency there and prevalence in other systems may prove difficult due to the need for genetic data in most instances. Cryptic back-introductions may eventually provide some insight into how lineages are changed by the invasion process and may be an underappreciated way in which invasive species impact native biodiversity.