A molecular phylogenetic analysis of the Octocorallia (Cnidaria: Anthozoa) based on mitochondrial protein-coding sequences

Despite their abundance and ecological importance in a wide variety of shallow and deep water marine communities, octocorals (soft corals, sea fans, and sea pens) are a group whose taxonomy and phylogenetic relationships remain poorly known and little studied. The group is currently divided into three orders (O: Alcyonacea, Pennatulacea, and Helioporacea); the large O. Alcyonacea (soft corals and sea fans) is further subdivided into six sub-ordinal groups on the basis of skeletal composition and colony growth form. We used 1429bp of two mitochondrial protein-coding genes, ND2 and msh1, to construct a phylogeny for 103 octocoral genera representing 28 families. In agreement with a previous 18S rDNA phylogeny, our results support a division of Octocorallia into two major clades plus a third, minor clade. We found one large clade (Holaxonia-Alcyoniina) comprising the sea fan sub-order Holaxonia and the majority of soft corals, and a second clade (Calcaxonia-Pennatulacea) comprising sea pens (O. Pennatulacea) and the sea fan sub-order Calcaxonia. Taxa belonging to the sea fan group Scleraxonia and the soft coral family Alcyoniidae were divided among the Holaxonia-Alcyoniina clade and a third, small clade (Anthomastus-Corallium) whose relationship to the two major clades was unresolved. In contrast to the previous studies, we found sea pens to be monophyletic but nested within Calcaxonia; our analyses support the sea fan family Ellisellidae as the sister taxon to the sea pens. We are unable to reject the hypothesis that the calcaxonian and holaxonian skeletal axes each arose once and suggest that the skeletal axis of sea pens is derived from that of Calcaxonia. Topology tests rejected the monophyly of sub-ordinal groups Alcyoniina, Scleraxonia, and Stolonifera, as well as 9 of 14 families for which we sampled multiple genera. The much broader taxon sampling and better phylogenetic resolution afforded by our study relative to the previous efforts greatly clarify the relationships among families and sub-ordinal groups within each of the major clades. The failure of these mitochondrial genes as well as previous 18S rDNA studies to resolve many of the deeper nodes within the tree (including its root) suggest that octocorals underwent a rapid radiation and that large amounts of sequence data will be required in order to resolve the basal relationships within the clade.     

Global habitat suitability of cold‐water octocorals

Aim Three‐quarters of Octocorallia species are found in deep waters. These cold‐water octocoral colonies can form a major constituent of structurally complex habitats. The global distribution and the habitat requirements of deep‐sea octocorals are poorly understood given the expense and difficulties of sampling at depth. Habitat suitability models are useful tools to extrapolate distributions and provide an understanding of ecological requirements. Here, we present global habitat suitability models and distribution maps for seven suborders of Octocorallia: Alcyoniina, Calcaxonia, Holaxonia, Scleraxonia, Sessiliflorae, Stolonifera and Subselliflorae. Location Global. Methods We use maximum entropy modelling to predict octocoral distribution using a database of 12,508 geolocated octocoral specimens and 32 environmental grids resampled to 30 arc‐second (approximately 1 km²) resolution. Additionally, a meta‐analysis determined habitat preferences and niche overlap between the different suborders of octocorals. Results Suborder Sessiliflorae had the widest potential habitat range, but all records for all suborders implied a habitat preference for continental shelves and margins, particularly the North and West Atlantic and Western Pacific Rim. Temperature, salinity, broad scale slope, productivity, oxygen and calcite saturation state were identified as important factors for determining habitat suitability. Less than 3% of octocoral records were found in waters undersaturated for calcite, but this result is affected by a shallow‐water sampling bias. Main conclusions The logistical difficulties, expense and vast areas associated with deep‐sea sampling leads to a gap in the knowledge of faunal distributions that is difficult to fill without predictive modelling. Global distribution estimates are presented, highlighting many suitable areas which have yet to be studied. We suggest that approximately 17% of oceans are suitable for at least one suborder but 3.5% may be suitable for all seven. This is the first global habitat suitability modelling study on the distribution of octocorals and forms a useful resource for researchers, managers and conservationists.     

Phylogeny of the Rumen Ciliates Entodinium, Epidinium and Polyplastron (Litostomatea: Entodiniomorphida) Inferred from Small Subunit Ribosomal RNA Sequences

ABSTRACT. Three complete 18S ribosomal RNA gene sequences from the rumen ciliates, Entodinium coudatum (1,639 bp), Epidinium caudarum (1,638 bp), and Polyplastron multivesiculatum (1,640 bp) were determined and confrimed in the opposite direction. Trees produced using maximum parsimony and distance-matrix methods (lest squares and neighbour-joining). with strong bootstrap support, depict the rumen ciliates as a monophyletic group, Entodinium caudatum is the earliest branching rumen ciliate. However, Entodiniwn simplex does not pair with En. caudatum , but rather with Polyplastron multivesiculatum. Signature sequences for these rumen ciliates reveal that the published SSrRNA gene sequence from En. simplex is in fact a Polyoplastron species. The free-living haptorian ciliates, Loxophyllum, Homalozoon and Spathidium (Subclass Hoptoria), are monophyletic and are the sister group to the rumen cilates. The litostomes (class Litostomatea), consisting of the haptorians and the rumen ciliates, are also a monophyletic group.     

The phylogenetic relationships of cyanobacteria inferred from 16S rRNA,gyrB, rpoC1 and rpoD1 gene sequences

Phylogenetic analysis of cyanobacteria was carried out using the small subunit rRNA (16S rRNA), DNA gyrase subunit B (gyrB), DNA-dependent RNA polymerase gamma subunit (rpoC1) and a principal sigma factor of E. coli sigma(70) type for DNA-dependent RNA polymerase (rpoD1) gene sequences of 24 strains which contained 5 subgroups of cyanobacteria-3 strains of the Chroococcales, 5 strains of the Pluerocapsales, 7 strains of the Oscillatoriales, 7 strains of the Nostocales and 2 strains of the Stigonematales. Degenerated PCR primers of gyrB, rpoC1 and rpoD1 genes were designed using consensus amino acid sequences registered in GenBank. The phylogenetic positions of cyanobacteria were resolved through phylogenetic analysis based on 16S rDNA, gyrB, rpoC1 and rpoD1 gene sequences. Phylogenies of gyrB, rpoC1 and rpoD1 support 16S rRNA-based classification of cyanobacteria. Interestingly, phylogenies from amino acid sequences deduced from gyrB and combined amino acid sequences deduced from rpoC1 and rpoD1 genes strongly support that of 16S rRNA, but the branching pattens of the trees based on 16S rDNA, GyrB, rpoC1, rpoD1 and combined amino acid sequences deduced from rpoC1 and rpoD1 were not congruent. In this study, we showed the correlation among phylogenetic relationships of 16S rDNA, gyrB, rpoC1 and rpoD1 genes. The phylogenetic trees based on the sequences of 16S rDNA, GyrB, rpoC1, rpoD1 and the combined amino acid sequences deduced from rpoC1 and rpoD1 showed that the lateral gene transfer of rRNA might be suspected for Synechocystis sp. PCC 6803.     

Next generation sequencing from Hepatozoon canis (Apicomplexa: Coccidia: Adeleorina): Complete apicoplast genome and multiple mitochondrion-associated sequences

Extrachromosomal genomes of the adeleorinid parasite Hepatozoon canis infecting an Israeli dog were investigated using next-generation and standard sequencing technologies. A complete apicoplast genome and several mitochondrion-associated sequences were generated. The apicoplast genome (31,869?bp) possessed two copies of both large subunit (23S) and small subunit (16S) ribosomal RNA genes (rDNA) within an inverted repeat region, as well as 22 protein-coding sequences, 25 transfer RNA genes (tDNA) and seven open reading frames of unknown function. Although circular-mapping, the apicoplast genome was physically linear according to next-generation data. Unlike other apicoplast genomes, genes encoding ribosomal protein S19 and tDNAs for alanine, aspartic acid, histidine, threonine and valine were not identified. No complete mitochondrial genome was recovered using next-generation data or directed PCR amplifications. Eight mitochondrion-associated (215–3523?bp) contigs assembled from next-generation data encoded a complete cytochrome c oxidase subunit I coding sequence, a complete cytochrome c oxidase subunit III coding sequence, two complete cytochrome B coding sequences, a non-coding, pseudogene for cytochrome B and multiple fragmented mitochondrial rDNA genes (SSUA, SSUB, SSUD, LSUC, LSUG, RNA6, RNA10, RNA14, RNA18). The paucity of NGS reads generating each of the mitochondrion-like sequences suggested that a complete mitochondrial genome at typically high copy number was absent in H. canis. In contrast, the complete nuclear rDNA unit sequence of H. canis (18S rDNA to 28S rDNA, 6977?bp) had >1000-fold next-generation coverage. Multiple divergent (from 93.6% to 99.9% pairwise identities) nuclear 18S rDNA contigs were generated (three types with 10 subtypes total). To our knowledge this is the first apicoplast genome sequenced from any adeleorinid coccidium and the first mitochondrion-associated sequences from this serious pathogen of wild and domestic canids. These newly generated sequences may provide useful genetic loci for high-resolution species-level genotyping that is currently impossible using existing nuclear rDNA targets.     

大黄鱼16SrRNA和18SrRNA基因的测定与序列分析

利用多对引物,扩增并测定出大黄鱼16SrRNA基因和18SrRNA基因的部分序列,其长度分别为1202bp和1275bp,16SrRNA基因序列的GC含量为46．12％,18SrRNA基因的Gc含量为53．oo％。将大黄鱼16SrRNA基因序列与GenBank中15种硬骨鱼类的同源序列结合,同时将其18SrRNA基因序列与GenBank中9种脊索动物的同源序列相结合,运用软件获得各自序列间差异百分比,转换和颠换数值等信息。基于这两种基因序列,利用NJ法和BI法,分别构建16种硬骨鱼类和10种脊索动物的分子系统树。18SrRNA构建的系统树包括三大支,一支为哺乳类、鸟类和爬行类共6个物种,一支为两栖类的1个物种,另一支为2种硬骨鱼类。16SrRNA构建的系统树显示大黄鱼所在的石首鱼科与鲈科和盖刺鱼科亲缘关系较近。此外还讨论了这两个基因的序列特征。     

An alternative to ITS, a hypervariable, single-copy nuclear intron in corals, and its use in detecting cryptic species within the octocoral genus Carijoa

Here we report a highly variable nuclear marker that can be used for both soft and stony corals. Primers that amplify a ∼177 bp fragment from the nuclear gene encoding the 54 kDa subunit of the signal recognition particle (SRP54) were developed for the octocoral genus Carijoa. Cloning results from 141 individuals suggest that this hypervariable nuclear locus is a single-copy gene. Sequencing revealed a potential cryptic species previously thought to be Carijoa riisei. Results from an Analysis of Molecular Variance (AMOVA) based on mitochondrial DNA (mtDNA) explained <10% of the variation between Atlantic and Pacific samples of C. riisei (F _st = 0.47), whereas the same comparison with SRP54 explained >33% of the variation (F _st = 0.54). Using previously reported degenerate primers for SRP54, high levels of sequence variation were found at this locus across both scleractinian and octocorals. For example, pairwise sequence divergence within octocorals was ∼8–13 times greater with SRP54 than with mtDNA, and, up to 2.8% pairwise sequence divergence was found in SRP54 among individuals of Pocillopora whereas no variation at all was found in mtDNA markers. This case study with the octocoral C. riisei shows that variation in SRP54 appears sufficient to address questions of phylogeography as well as systematics of closely related species.     

Structure-function correlations (and discrepancies) in the 16S ribosomal RNA from Escherichia coli.

The published model for the three-dimensional arrangement of E coli 16S RNA is re-examined in the light of new experimental information, in particular cross-linking data with functional ligands and cross-links between the 16S and 23S RNA molecules. A growing body of evidence suggests that helix 18 (residues 500-545), helix 34 (residues 1046-1067/1189-1211) and helix 44 (residues 1409-1491) are incorrectly located in the model. It now appears that the functional sites in helices 18 and 34 may be close to the decoding site of the 30S subunit, rather than being on the opposite side of the 'head' of the subunit, as hitherto supposed. Helix 44 is now clearly located at the interface between the 30S and 50S subunits. Furthermore, almost all of the modified bases in both 16S and 23S RNA appear to form a tight cluster near to the upper end of this helix, surrounding the decoding site.     

Phylogeny of Capitata and Corynidae (Cnidaria, Hydrozoa) in light of mitochondrial 16S rDNA data

New sequences of the partial rDNA gene coding for the mitochondrial large ribosomal subunit, 16S, are derived from 47 diverse hydrozoan species and used to investigate phylogenetic relationships among families of the group Capitata and among species of the capitate family Corynidae. Our analyses identify a well-supported clade, herein named Aplanulata, of capitate hydrozoans that are united by the synapomorphy of undergoing direct development without the ciliated planula stage that is typical of cnidarians. Aplanulata includes the important model organisms of the group Hydridae, as well as species of Candelabridae, Corymorphidae, and Tubulariidae. The hypothesis that Hydridae is closely related to brackish water species of Moerisiidae is strongly controverted by 16S rDNA data, as has been shown for nuclear 18S rDNA data. The consistent phylogenetic signal derived from 16S and 18S data suggest that both markers would be useful for broad-scale multimarker analyses of hydrozoan relationships. Corynidae is revealed as paraphyletic with respect to Polyorchidae, a group for which information about the hydroid stage is lacking. Bicorona , which has been classified both within and outside of Corynidae, is shown to have a close relationship with all but one sampled species of Coryne . The corynid genera Coryne , Dipurena , and Sarsia are not revealed as monophyletic, further calling into question the morphological criteria used to classify them. The attached gonophores of the corynid species Sarsia lovenii are confirmed as being derived from an ancestral state of liberated medusae. Our results indicate that the 16S rDNA marker could be useful for a DNA-based identification system for Cnidaria, for which it has been shown that the commonly used cytochrome c oxidase subunit 1 gene does not work.     

Directed hydroxyl radical probing of the rRNA neighborhood of ribosomal protein S13 using tethered Fe(II).

Directed hydroxyl radical probing was used to probe the rRNA neighborhood around protein S13 in the 30S ribosomal subunit. The unique cysteine at position 84 of S13 served as a tethering site for attachment of Fe(II)-1-(p-bromoacetamidobenzyl)-EDTA. Derivatized S13 (Fe-C84-S13) was then assembled into 30S ribosomal subunits by in vitro reconstitution with 16S rRNA and a mixture of the remaining 30S subunit proteins. Hydroxyl radicals generated from the tethered Fe(II) resulted in cleavage of the RNA backbone in two localized regions of the 3' major domain of 16S rRNA. One region spans nt 1308-1333 and is close to a site previously crosslinked to S13. A second set of cleavages is found in the 950/1230 helix. Both regions have been implicated in binding of S13 by previous chemical footprinting studies using base-specific chemical probes and solution-based hydroxyl radical probing. These results place both regions of 16S rRNA in proximity to position C84 of S13 in the three-dimensional structure of the 30S ribosomal subunit.     

小鲵科线粒体16S rRNA基因序列分析及其系统发育

To study the phylogeny of Hynobiidae, we amplified DNA fragments of 470 bp 16S ribosomal RNA (16S rRNA) gene on mitochondrial DNA from Ranodon sibiricus and Ranodon tsinpaensis. PCR products were cloned into PMD18 T vector after purification. These sequences were determined and deposited in the GenBank (accession numbers: AY373459 for Ranodon sibiricus, AY372534 for Ranodon tsinpaensis). By comparing the nucleotide differences of 16S ribosomal RNA sequences among Liua shihi, Pseudohynobius flavomaculatus and Batrachuperus genus from GenBank database, we analyzed the divergences and base substitution among these sequences with the MEGA software. The molecular results support that B. tibetanus, B. pinchonii and B. karlschmidti are classified into three valid species. Liua shihi has closer phylogenetic relationships to Ranodon tsinpaensis than to other species. More our results reveal that Pseudohynobius flavomaculatus is not a synonym of Ranodon tsinpaensis. [Acta Zoologica Sinica 50 (3) : 464 - 469,2004].     

Higher species richness of octocorals in the upper mesophotic zone in Eilat (Gulf of Aqaba) compared to shallower reef zones

Mesophotic coral-reef ecosystems (MCEs), which comprise the light-dependent communities of corals and other organisms found at depths between 30 and ~ 150 m, have received very little study to date. However, current technological advances, such as remotely operated vehicles and closed-circuit rebreather diving, now enable their thorough investigation. Following the reef-building stony corals, octocorals are the second most common benthic component on many shallow reefs and a major component on deep reefs, the Red Sea included. This study is the first to examine octocoral community features on upper MCEs based on species-level identification and to compare them with the shallower reef zones. The study was carried out at Eilat (Gulf of Aqaba, northern Red Sea), comparing octocoral communities at two mesophotic reefs (30–45 m) and two shallow reef zones (reef flat and upper fore-reef) by belt transects. A total of 30 octocoral species were identified, with higher species richness on the upper MCEs compared to the shallower reefs. Although the MCEs were found to host a higher number of species than the shallower reefs, both featured a similar diversity. Each reef zone revealed a unique octocoral species composition and distinct community structure, with only 16% of the species shared by both the MCEs and the shallower reefs. This study has revealed an almost exclusive dominance of zooxanthellate species at the studied upper MCE reefs, thus indicating an adequate light regime for photosynthesis there. The findings should encourage similar studies on other reefs, aimed at understanding the spatiotemporal features and ecological role of octocorals in reef ecosystems down to the deepest limit of the MCEs.     

基于线粒体16S rRNA基因对中国狼蛛科(Lycosidae)系统发育研究

将自测的中国狼蛛科Lycosidae4亚科6属26种和从GenBank中检索到的北美2种豹蛛的mtD-NA-16S rRNA序列进行比较;以漏斗蛛科1种蜘蛛作为外群,对碱基序列的组成和遗传距离进行了分析,采用Bayesian方法和最大简约法(MP)构建分子系统树。研究结果表明:16SrRNA基因的部分序列为340bp到360bp,A T含量平均为75%,存在较强的A T含量偏向性;序列共有157个碱基存在变异,其中79个简约信息位点。狼蛛科各属间的遗传距离介于0.026￣0.200之间。2种建树方法均表明:科内的属及属内的种优先聚在一起;水狼蛛属相对马蛛属是狼蛛科中较为原始的类群,分化较早;獾蛛属作为1个单系群与熊蛛属合为1个并系,属于狼蛛亚科。狼蛛科6属间的分子系统关系为(Pirata(Hippasa(Trochsa Arctosa(Pardosa Wadicosa))))。     

DNA‐based phylogeny of the marine genus Heterodrilus (Annelida,Clitellata, Naididae)

Heterodrilus is a group of marine Naididae, common worldwide in subtropical and tropical areas, and unique among the oligochaetes by their tridentate chaetae. The phylogenetic relationships within the group are assessed from the nuclear 18S rDNA gene, and the mitochondrial cytochrome c oxidase subunit I (COI) and 16S rDNA genes. Sequence data were obtained from 16 Heterodrilus species and 13 out‐group taxa; 48 sequences are new for this study. The data were analysed by Bayesian inference. Monophyly of the genus is corroborated by the resulting tree, with Heterodrilus ersei (a taxon representing a small group of species with aberrant male genitalia) proposed to be outside all other sampled species. Although earlier regarded as a member of the subfamily Rhyacodrilinae, both molecular and morphological data seem to support that Heterodrilus is closely related to Phallodrilinae. However, the results are not conclusive as to whether the genus is the sister group of, or a group nested inside, or separate from this latter subfamily. The studied sample of species suggests at least two major clades in Heterodrilus with different geographical distributions, in one of the clades, most species are from the Indo‐West Pacific Ocean, while in the other, the majority are from the Western Atlantic Ocean. Morphological characters traditionally used in Heterodrilus taxonomy are optimized on the phylogenetic tree, revealing a high degree of homoplasy.     

The genetic identity of dinoflagellate symbionts in Caribbean octocorals

Many cnidarians (e.g., corals, octocorals, sea anemones) maintain a symbiosis with dinoflagellates (zooxanthellae). Zooxanthellae are grouped into clades, with studies focusing on scleractinian corals. We characterized zooxanthellae in 35 species of Caribbean octocorals. Most Caribbean octocoral species (88.6%) hosted clade B zooxanthellae, 8.6% hosted clade C, and one species (2.9%) hosted clades B and C. Erythropodium caribaeorum harbored clade C and a unique RFLP pattern, which, when sequenced, fell within clade C. Five octocoral species displayed no zooxanthella cladal variation with depth. Nine of the ten octocoral species sampled throughout the Caribbean exhibited no regional zooxanthella cladal differences. The exception, Briareum asbestinum, had some colonies from the Dry Tortugas exhibiting the E. caribaeorum RFLP pattern while elsewhere hosting clade B. In the Caribbean, octocorals show more symbiont specificity at the cladal level than scleractinian corals. Both octocorals and scleractinian corals, however, exhibited taxonomic affinity between zooxanthella clade and host suborder.Communicated by R.C. Carpenter     

Six microsatellite loci from the deep‐sea coral Corallium lauuense (Octocorallia: Coralliidae) from the islands and seamounts of the Hawaiian archipelago

Gorgonian octocorals are among the dominant deep‐sea benthic taxa of many seamounts. Seamount fauna are threatened by destructive fisheries practices, yet little is known about the physical and biological processes that maintain species on seamounts. Few informative molecular markers have been found in deep‐water corals or in gorgonian octocorals. Here we report the characterization of six highly polymorphic microsatellite loci for the deep‐sea precious coral Corallium lauuense from Hawaii using enriched genomic DNA libraries. These loci are being used to examine gene flow and stock structure among seamount and island populations to better understand dispersal and connectivity of seamount species.     

Phylogenetic hypotheses of gorgoniid octocorals according to ITS2 and their predicted RNA secondary structures

Gorgoniid octocorals taxonomy (Cnidaria; Octocorallia; Gorgoniidae) includes diagnostic characters not well defined at the generic level, and based on the family diagnosis some species could be classified in either Gorgoniidae or Plexauridae. In this study, we used sequences from the Internal Transcribed Spacer 2 (ITS2) and their predicted RNA secondary structure to both correct the alignment and reconstruct phylogenies using molecular morphometrics for 24 octocorals mostly from the Atlantic. ITS2 exhibited the six-helicoidal ring-model structure found in eukaryotes, and provided 38 parsimony-informative characters. The proposed phylogenies, though differing between sequence- and structure-base results, provided consistent support for several clades. Genera considered part of the polyphyletic genus Leptogorgia, such as Filigorgia, were distantly related to the former in all phylogenetic hypotheses. Main differences among the hypotheses consisted in the placement of Muriceopsis (previously considered from the Plexauridae family) and Filigorgia. Excluding Muriceopsis and an undescribed octocoral from Tobago, Plexaurella and Pterogorgia grouped together as a sister branch of Pinnigorgia spp. but long-branch attraction was evident for the grouping of Plexaurella nutans (another plexaurid) and Pterogorgia citrina. Unexpected results were the divergence between Caribbean genera, Gorgonia and Pseudopterogorgia, which were placed basal respect to Pacifigorgia and Leptogorgia (=Lophogorgia). ITS2 provided support to corroborate observations based on sclerite morphology: species with "capstan sclerites" (e.g., Pacifigorgia and Leptogorgia) were characterized by a long helix IV with one internal loop and a helix V with four internal loops; "scaphoid sclerites" had a predominantly long helix V if compared to helix IV; "asymmetric spiny sclerites" (Muriceopsis, Pinnigorgia and the undescribed octocoral) exhibited one or two lateral bulges in the V helix. Remarkably, Muriceopsis and Pinnigorgia were supported by a complete Compensatory Base Change (CBC) (A-U to G-C) in helix V. Filigorgia with simple "spindles" had a short helix IV and a large central ring. DNA sequences from the nuclear ITS2 region, including information from predicted RNA secondary structure, despite their reduced length, provided numerous characters and phylogenetic information among Gorgoniidae genera and species.     

Complete genome sequence of Desulfurispirillum indicum strain S5(T)

Desulfurispirillum indicum strain S5(T) is a strictly anaerobic bacterium isolated from river sediment in Chennai, India. D. indicum belongs to the deep branching phylum of Chrysiogenetes, which currently only includes three other cultured species. Strain S5(T) is the type strain of the species and it is capable of growth using selenate, selenite, arsenate, nitrate or nitrite as terminal electron acceptors. The 2,928,377 bp genome encodes 2,619 proteins and 49 RNA genes, and the information gained from its sequence will be relevant to the elucidation of microbially-mediated transformations of arsenic and selenium, in addition to deepening our knowledge of the underrepresented phylum of Chrysiogenetes.     

基于ITS2和16S rRNA的西施舌群体遗传差异分析

目前,我国西施舌群体分子遗传差异研究结果存在争议。分析我国南北沿海（9个群体）、与广西北海毗邻的越南（1个群体）西施舌核DNA的内转录间隔区2（ITS2）和线粒体DNA的16S rRNA基因（16S）片段核苷酸序列及其二级结构,为解决争议问题提供分子生物学资料。扩增获得西施舌ITS2片段和16S序列,其长度分别为389-402 bp和306 bp,加之下载序列共147条;序列分析显示,74个ITS2序列共有17种基因型,73个16S序列有15种单倍型,其中,长乐（CL）群体独享9种ITS2基因型和5种16S单倍型,非长乐群体（nCL）多数为群体间交叉共享1种或几种基因（单倍）型;基因（单倍）型核苷酸变异位点占5.7%（ITS2）和11.8%（16S）;基于ITS2和16S的CL群体和nCL群体间的遗传距离与群体内遗传距离之比分别为2.42和11.08,nCL群体间的平均遗传距离均为0.007;二级结构显示CL群体ITS2的9种基因型和16S的5种单倍型均区别于nCL群体,nCL的ITS2和16S二级结构分别相似;ITS2和16S基因的系统发育分析显示,CL西施舌形成支持率很高（98,96）的单系支,而nCL群体则交叉聚为另一支（98,96）。研究结果揭示,福建西施舌是腔蛤蜊属（Coelomactra）的一个新种。