scholarly journals Digging deeper: new gene order rearrangements and distinct patterns of codons usage in mitochondrial genomes among shrimps from the Axiidea, Gebiidea and Caridea (Crustacea: Decapoda)

PeerJ ◽  
2017 ◽  
Vol 5 ◽  
pp. e2982 ◽  
Author(s):  
Mun Hua Tan ◽  
Han Ming Gan ◽  
Yin Peng Lee ◽  
Gary C.B. Poore ◽  
Christopher M. Austin
Keyword(s):  
Codon Usage ◽  
Gene Order ◽  
Phylogenetic Relationships ◽  
Decapod Crustacean ◽  
Illumina Miseq ◽  
Comparative Genomic ◽  
Decapod Crustaceans ◽  
Phylogenetic Studies ◽  
Significant Gene ◽  
Taxonomic Groups

BackgroundWhole mitochondrial DNA is being increasingly utilized for comparative genomic and phylogenetic studies at deep and shallow evolutionary levels for a range of taxonomic groups. Although mitogenome sequences are deposited at an increasing rate into public databases, their taxonomic representation is unequal across major taxonomic groups. In the case of decapod crustaceans, several infraorders, including Axiidea (ghost shrimps, sponge shrimps, and mud lobsters) and Caridea (true shrimps) are still under-represented, limiting comprehensive phylogenetic studies that utilize mitogenomic information.MethodsSequence reads from partial genome scans were generated using the Illumina MiSeq platform and mitogenome sequences were assembled from these low coverage reads. In addition to examining phylogenetic relationships within the three infraorders, Axiidea, Gebiidea, and Caridea, we also investigated the diversity and frequency of codon usage bias and mitogenome gene order rearrangements.ResultsWe present new mitogenome sequences for five shrimp species from Australia that includes two ghost shrimps,Callianassa ceramicaandTrypaea australiensis, along with three caridean shrimps,Macrobrachium bullatum,Alpheus lobidens, andCaridinacf.nilotica. Strong differences in codon usage were discovered among the three infraorders and significant gene order rearrangements were observed. While the gene order rearrangements are congruent with the inferred phylogenetic relationships and consistent with taxonomic classification, they are unevenly distributed within and among the three infraorders.DiscussionOur findings suggest potential for mitogenome rearrangements to be useful phylogenetic markers for decapod crustaceans and at the same time raise important questions concerning the drivers of mitogenome evolution in different decapod crustacean lineages.

Complete chloroplast genomes of Leptodermis scabrida complex: comparative genomic analyses and phylogenetic relationships

Gene ◽  
2021 ◽  
pp. 145715
Author(s):  
Ying Zhang ◽  
Zhengfeng Wang ◽  
Yanan Guo ◽  
Sheng Chen ◽  
Xianyi Xu ◽  
...  
Keyword(s):  
Phylogenetic Relationships ◽  
Comparative Genomic ◽  
Chloroplast Genomes ◽  
Genomic Analyses

scholarly journals The chloroplast genome evolution of Venus slipper (Paphiopedilum): IR expansion, SSC contraction, and highly rearranged SSC regions

2021 ◽  
Vol 21 (1) ◽  
Author(s):  
Yan-Yan Guo ◽  
Jia-Xing Yang ◽  
Ming-Zhu Bai ◽  
Guo-Qiang Zhang ◽  
Zhong-Jian Liu
Keyword(s):  
Gene Order ◽  
Inverted Repeat ◽  
Single Copy ◽  
Gene Content ◽  
Comparative Genomic ◽  
Substitution Rates ◽  
Plastome Evolution ◽  
Chloroplast Genomes ◽  
Ideal System ◽  
Small Single Copy

Abstract Background Paphiopedilum is the largest genus of slipper orchids. Previous studies showed that the phylogenetic relationships of this genus are not well resolved, and sparse taxon sampling documented inverted repeat (IR) expansion and small single copy (SSC) contraction of the chloroplast genomes of Paphiopedilum. Results Here, we sequenced, assembled, and annotated 77 plastomes of Paphiopedilum species (size range of 152,130 – 164,092 bp). The phylogeny based on the plastome resolved the relationships of the genus except for the phylogenetic position of two unstable species. We used phylogenetic and comparative genomic approaches to elucidate the plastome evolution of Paphiopedilum. The plastomes of Paphiopedilum have a conserved genome structure and gene content except in the SSC region. The large single copy/inverted repeat (LSC/IR) boundaries are relatively stable, while the boundaries of the inverted repeat and small single copy region (IR/SSC) varied among species. Corresponding to the IR/SSC boundary shifts, the chloroplast genomes of the genus experienced IR expansion and SSC contraction. The IR region incorporated one to six genes of the SSC region. Unexpectedly, great variation in the size, gene order, and gene content of the SSC regions was found, especially in the subg. Parvisepalum. Furthermore, Paphiopedilum provides evidence for the ongoing degradation of the ndh genes in the photoautotrophic plants. The estimated substitution rates of the protein coding genes show accelerated rates of evolution in clpP, psbH, and psbZ. Genes transferred to the IR region due to the boundary shift also have higher substitution rates. Conclusions We found IR expansion and SSC contraction in the chloroplast genomes of Paphiopedilum with dense sampling, and the genus shows variation in the size, gene order, and gene content of the SSC region. This genus provides an ideal system to investigate the dynamics of plastome evolution.

Rediscovery of Rhacophorus yaoshanensis and Theloderma kwangsiensis at their type localities after five decades

Zootaxa ◽  
2018 ◽  
Vol 4379 (4) ◽  
pp. 484 ◽  
Author(s):  
WEICAI CHEN ◽  
XIAOWEN LIAO ◽  
SHICHU ZHOU ◽  
YUNMING MO ◽  
YONG HUANG
Keyword(s):  
Mitochondrial Dna ◽  
16S Rrna ◽  
Phylogenetic Relationships ◽  
New Record ◽  
Nature Reserve ◽  
Guangxi Province ◽  
Preliminary Assessment ◽  
Phylogenetic Studies ◽  
Pairwise Divergence ◽  
High Support

Rhacophorus yaoshanensis Liu & Hu, 1962 and Theloderma kwangsiensis Liu & Hu, 1962 were described by Liu & Hu (1962) based on two specimens and one specimen, respectively, from the Dayaoshan Ranges, Guangxi, China. Since these two species were described, no additional specimens have been collected from their type localities, presenting an issue for phylogenetic studies of the genera. Five decades later, we have rediscovered R. yaoshanensis and T. kwangsiensis from their type localities. In this paper, we re-describe the two species and conduct a preliminary assessment of their phylogenetic relationships using two mitochondrial DNA genes (12S and 16S rRNA). The results indicate with high support that R. yaoshanensis is closely related to Rhacophorus pinglongensis. Theloderma kwangsiensis is nested within Theloderma corticale, with only 0.0–0.6% pairwise divergence, a level typical of intraspecific variation. Based on both molecular and morphological analyses, we further confirm that T. kwangsiensis is a synonym of T. corticale. Shiwandashan National Nature Reserve, Guangxi Province, China, is a new record for T. corticale. 

scholarly journals The first mitochondrial genome of the genus Exhippolysmata (Decapoda: Caridea: Lysmatidae), with gene rearrangements and phylogenetic associations in Caridea

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Ying-ying Ye ◽  
Jing Miao ◽  
Ya-hong Guo ◽  
Li Gong ◽  
Li-hua Jiang ◽  
...  
Keyword(s):  
Mitochondrial Genome ◽  
Gene Order ◽  
Phylogenetic Analyses ◽  
Complete Mitochondrial Genome ◽  
Bootstrap Support ◽  
Trna Genes ◽  
Gene Rearrangements ◽  
Phylogenetic Studies ◽  
Gc Skew ◽  
Strong Bootstrap Support

AbstractThe complete mitochondrial genome (mitogenome) of animals can provide useful information for evolutionary and phylogenetic analyses. The mitogenome of the genus Exhippolysmata (i.e., Exhippolysmata ensirostris) was sequenced and annotated for the first time, its phylogenetic relationship with selected members from the infraorder Caridea was investigated. The 16,350 bp mitogenome contains the entire set of 37 common genes. The mitogenome composition was highly A + T biased at 64.43% with positive AT skew (0.009) and negative GC skew (− 0.199). All tRNA genes in the E. ensirostris mitogenome had a typical cloverleaf secondary structure, except for trnS1 (AGN), which appeared to lack the dihydrouridine arm. The gene order in the E. ensirostris mitogenome was rearranged compared with those of ancestral decapod taxa, the gene order of trnL2-cox2 changed to cox2-trnL2. The tandem duplication-random loss model is the most likely mechanism for the observed gene rearrangement of E. ensirostris. The ML and BI phylogenetic analyses place all Caridea species into one group with strong bootstrap support. The family Lysmatidae is most closely related to Alpheidae and Palaemonidae. These results will help to better understand the gene rearrangements and evolutionary position of E. ensirostris and lay a foundation for further phylogenetic studies of Caridea.

Morphological and phylogenetical analyses of pathogenic Hypomyces perniciosus isolates from Agaricus bisporus causing wet bubble disease in China

Phytotaxa ◽  
2021 ◽  
Vol 491 (2) ◽  
pp. 115-130
Author(s):  
CHUN-LAN ZHANG ◽  
ZHENG-WEN JIN ◽  
CAN SUN ◽  
ODESHNEE MOODLEY ◽  
JI-ZE XU ◽  
...  
Keyword(s):  
Phylogenetic Relationships ◽  
Agaricus Bisporus ◽  
Morphological Characteristics ◽  
Pathogenicity Test ◽  
Test Results ◽  
Phylogenetic Studies ◽  
Group Ii

Hypomyces perniciosus is a destructive pathogen of Agaricus bisporus. The disease has been known to occur wherever A. bisporus is cultivated. Morphological characteristics have shown differences between reported isolates of H. perniciosus. However, clarification is needed to determine whether those isolates are the same species and an investigation of the phylogenetic relationships among them is warranted. Here, taxonomic and phylogenetic studies were carried out on 29 wet bubble disease pathogen isolates from China. Our analyses of the morphological characteristics and phylogenetic results support that they are the same H. perniciosus. Moreover, they are separated into two groups, groups ⅰ and groups ii. Pathogenicity test results inferred that group ii had weaker pathogenicity than group ⅰ. Consequently, we can deduce that wet bubble disease is still caused by H. perniciosus and isolates from two distinct groups.

Mitogenome of Alaudala cheleensis (Passeriformes: Alaudidae) and comparative analyses of Sylvioidea mitogenomes

Zootaxa ◽  
2021 ◽  
Vol 4952 (2) ◽  
pp. 331-353
Author(s):  
CHAO YANG ◽  
LE ZHAO ◽  
QINGXIONG WANG ◽  
HAO YUAN ◽  
XUEJUAN LI ◽  
...  
Keyword(s):  
Secondary Structure ◽  
Gene Order ◽  
Phylogenetic Relationships ◽  
Gene Rearrangement ◽  
Phylogenetic Analyses ◽  
Protein Coding ◽  
Comparative Analyses ◽  
Protein Coding Genes ◽  
Basal Position

To gain a better understanding of mitogenome features and phylogenetic relationships in Sylvioidea, a superfamily of Passerida, suborder Passeri, Passeriformes, the whole mitogenome of Alaudala cheleensis Swinhoe (Alaudidae) was sequenced, a comparative mitogenomic analysis of 18 Sylvioidea species was carried out, and finally, a phylogeny was reconstructed based on the mitochondrial dataset. Gene order of the A. cheleensis mitogenome was similar to that of other Sylvioidea species, including the gene rearrangement of cytb-trnT-CR1-trnP-nad6-trnE-remnant CR2-trnF-rrnS. There was slightly higher A+T content than that of G+C in the mitogenome, with an obvious C skew. The ATG codon initiated all protein-coding genes, while six terminating codons were used. The secondary structure of rrnS contained three domains and 47 helices, whereas rrnL included six domains and 60 helices. All tRNAs could be folded into a classic clover-leaf secondary structure except for trnS (AGY). The CR1 could be divided into three domains, including several conserved boxes (C-string, F, E, D, C and B-box, Bird similarity box, CSB1). Comparative analyses within Sylvioidea mitogenomes showed that most mitochondrial features were consistent with that of the A. cheleensis mitogenome. The basal position of the Alaudidae within the Sylvioidea in our phylogenetic analyses is consistent with other recent studies. 

scholarly journals Diversity and distribution patterns of the Oligocene and Miocene decapod crustaceans (Crustacea: Malacostraca) of the Western and Central Paratethys

2016 ◽  
Vol 67 (5) ◽  
pp. 471-494 ◽  
Author(s):  
Matúš Hyžný
Keyword(s):  
Spatial Scales ◽  
Three Dimensional ◽  
Decapod Crustacean ◽  
Distribution Patterns ◽  
Mediterranean Area ◽  
Homogeneous Distribution ◽  
Decapod Crustaceans ◽  
Central Paratethys ◽  
The North ◽  
Marine Habitats

AbstractDecapod associations have been significant components of marine habitats throughout the Cenozoic when the major diversification of the group occurred. In this respect, the circum-Mediterranean area is of particular interest due to its complex palaeogeographic history. During the Oligo-Miocene, it was divided in two major areas, Mediterranean and Paratethys. Decapod crustaceans from the Paratethys Sea have been reported in the literature since the 19thcentury, but only recent research advances allow evaluation of the diversity and distribution patterns of the group. Altogether 176 species-level taxa have been identified from the Oligocene and Miocene of the Western and Central Paratethys. Using the three-dimensional NMDS analysis, the composition of decapod crustacean faunas of the Paratethys shows significant differences through time. The Ottnangian and Karpatian decapod associations were similar to each other both taxonomically and in the mode of preservation, and they differed taxonomically from the Badenian ones. The Early Badenian assemblages also differed taxonomically from the Late Badenian ones. The time factor, including speciation, immigration from other provinces and/or (local or global) extinction, can explain temporal differences among assemblages within the same environment. High decapod diversity during the Badenian was correlated with the presence of reefal settings. The Badenian was the time with the highest decapod diversity, which can, however, be a consequence of undersampling of other time slices. Whereas the Ottnangian and Karpatian decapod assemblages are preserved virtually exclusively in the siliciclastic “Schlier”-type facies that originated in non-reefal offshore environments, carbonate sedimentation and the presence of reefal environments during the Badenian in the Central Paratethys promoted thriving of more diverse reef-associated assemblages. In general, Paratethyan decapods exhibited homogeneous distribution during the Oligo-Miocene among the basins in the Paratethys. Based on the co-occurrence of certain decapod species, migration between the Paratethys and the North Sea during the Early Miocene probably occurred via the Rhine Graben. At larger spatial scales, our results suggest that the circum-Mediterranean marine decapod taxa migrated in an easterly direction during the Oligocene and/or Miocene, establishing present-day decapod communities in the Indo-West Pacific.

scholarly journals The Mitochondrial Genomes of 18 New Pleurosticti (Coleoptera: Scarabaeidae) Exhibit a Novel trnQ-NCR-trnI-trnM Gene Rearrangement and Clarify Phylogenetic Relationships of Subfamilies within Scarabaeidae

Insects ◽  
2021 ◽  
Vol 12 (11) ◽  
pp. 1025
Author(s):  
Sam Pedro Galilee Ayivi ◽  
Yao Tong ◽  
Kenneth B. Storey ◽  
Dan-Na Yu ◽  
Jia-Yong Zhang
Keyword(s):  
Next Generation Sequencing ◽  
Gene Order ◽  
Phylogenetic Relationships ◽  
Gene Rearrangement ◽  
Next Generation ◽  
Protein Coding ◽  
Protein Coding Genes ◽  
Next Generation Sequencing Ngs ◽  
Mt Genome ◽  
Generation Sequencing

The availability of next-generation sequencing (NGS) in recent years has facilitated a revolution in the availability of mitochondrial (mt) genome sequences. The mt genome is a powerful tool for comparative studies and resolving the phylogenetic relationships among insect lineages. The mt genomes of phytophagous scarabs of the subfamilies Cetoniinae and Dynastinae were under-represented in GenBank. Previous research found that the subfamily Rutelinae was recovered as a paraphyletic group because the few representatives of the subfamily Dynastinae clustered into Rutelinae, but the subfamily position of Dynastinae was still unclear. In the present study, we sequenced 18 mt genomes from Dynastinae and Cetoniinae using next-generation sequencing (NGS) to re-assess the phylogenetic relationships within Scarabaeidae. All sequenced mt genomes contained 37 sets of genes (13 protein-coding genes, 22 tRNAs, and two ribosomal RNAs), with one long control region, but the gene order was not the same between Cetoniinae and Dynastinae species. All mt genomes of Dynastinae species showed the same gene rearrangement of trnQ-NCR-trnI-trnM, whereas all mt genomes of Cetoniinae species showed the ancestral insect gene order of trnI-trnQ-trnM. Phylogenetic analyses (IQ-tree and MrBayes) were conducted using 13 protein-coding genes based on nucleotide and amino acid datasets. In the ML and BI trees, we recovered the monophyly of Rutelinae, Cetoniinae, Dynastinae, and Sericinae, and the non-monophyly of Melolonthinae. Cetoniinae was shown to be a sister clade to (Dynastinae + Rutelinae).

Primary chaetotaxy of the larval head capsule and head appendages of the Hydrophilidae (Coleoptera) based on larva of Hydrobius fuscipes (Linnaeus, 1758)

Zootaxa ◽  
2008 ◽  
Vol 1874 (1) ◽  
pp. 16 ◽  
Author(s):  
MARTIN FIKÁČEK ◽  
MIGUEL ARCHANGELSKY ◽  
PATRICIA L. M. TORRES
Keyword(s):  
Head Capsule ◽  
Phylogenetic Studies ◽  
The Family ◽  
Taxonomic Groups

The primary chaetotaxy of the larval head capsule and head appendages of the family Hydrophilidae (Insecta: Coleoptera) is described and illustrated using the larva of Hydrobius fuscipes (Linnaeus, 1758) as a model, and compared with fifteen hydrophilid taxa representing all main taxonomic groups within the family; brief comparative notes with representatives of the families Helophoridae, Spercheidae, Hydrochidae and Histeridae are also provided. Primary chaetotaxic nomenclature is developed for the Hydrophilidae, allowing the use of chaetotaxic characters for phylogenetic studies as well as diagnostic purposes. The study of representatives of the families Helophoridae, Hydrochidae and Spercheidae suggests that this nomenclature can also be effectively applied to other hydrophiloid families. Chaetotaxic nomenclature systems used in larvae of other groups of Coleoptera are briefly reviewed.

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