Gene Order Research Articles

The complete mitochondrial DNA of the carnivorous sponge Lycopodina hypogea is putatively complemented by microDNAs

Carnivorous sponges (Porifera, Demospongiae, Cladorhizidae), contrary to the usual filter-feeding mechanism of sponges, are specialized in catching larger prey through adhesive surfaces or hook-like spicules. The mitochondrial DNA of sponges overall present several divergences from other metazoans, and while presenting unique features among major transitions, such as in calcarean and glass sponges, poriferan mitogenomes are relatively stable within their groups. Here, we report and discuss the mitogenome of Lycopodina hypogea (Vacelet & Boury-Esnault, 1996), which greatly vary from its subordinal counterparts in both structure and gene order. This mitogenome is seemingly multipartite into three chromosomes, two of them as microDNAs. The main chromosome, chrM1, is unusually large, 31,099 bp in length, has a unique gene order within Poecilosclerida, and presents two rRNA, 13 protein and 19 tRNA coding genes. Intergenic regions comprise approximately 40% of chrM1, bearing several terminal direct and inverted repeats (TDRr and TIRs) but holding no vestiges of former mitochondrial sequences, pseudogenes, or transposable elements. The nd4l and trnI(gau) genes are likely located in microDNAs thus comprising putative mitochondrial chromosomes chrM2, 291 bp, and chrM3, 140 bp, respectively. It is unclear which processes are responsible for the remarkable features of the of L. hypogea mitogenome, including a generalized gene rearrangement, long IGRs, and putative extrachromosomal genes in microDNAs.

Insights into brachyuran crab phylogeny: exploring the mitochondrial genome of Arcotheres sinensis (Brachyura, Pinnotheridae)

Abstract The phylogeny of species of Brachyura, particularly within the family Pinnotheridae, remains incompletely understood. To enhance the taxonomy and systematics of the Pinnotheridae, we conducted a comprehensive study aimed at elucidating the phylogenetic position of Arcotheres sinensis. Consequently, we sequenced and annotated the complete mitochondrial genome of A. sinensis, The results revealed that the circular mitogenome of A. sinensis spans 16 520 bp in length. Distinct from typical mitogenomes, A. sinensis contains 13 protein-coding genes (PCGs), 2 ribosomal RNA genes and 23 transfer RNA genes. The A + T content of the A. sinensis mitogenome is 71.63%, with both AT-skew and GC-skew being negative. The lengths of the 23 tRNA genes range from 62 to 72 bp. All tRNA genes exhibit typical cloverleaf structures, except for the trnS1 gene, which lacks the dihydrouridine (DHU) arm. Selection pressure analysis revealed that all PCGs are under evolutionary selection, with cox1 experiencing strongest purifying selection and atp8 undergoing weakest purifying selection. Compared to ancestral Brachyura, the gene order of A. sinensis has been rearranged from R-N--E to -E-N-R and the sequence I-Q-M has transitioned to Q-I-M. Phylogenetic analysis unequivocally positions A. sinensis within the taxonomic framework of the family Pinnotheridae, highlighting its intimate phylogenetic relationship with congeners within the same familial clade, notably Arcotheres purpureus and Pinnotheres excussus. These findings contribute to a better understanding of the status and evolutionary history of Pinnotheridae species.

Frequent genetic exchanges revealed by a pan-mitogenome graph of a fungal plant pathogen.

Mitochondria are present in almost all eukaryotic lineages. The mitochondrial genomes (mitogenomes) evolve separately from nuclear genomes, and they can therefore provide relevant insights into the evolution of their host species. Fusarium oxysporum is a major fungal plant pathogen that is assumed to reproduce clonally. However, horizontal chromosome transfer between strains can occur through heterokaryon formation, and recently, signs of sexual recombination have been observed. Similarly, signs of recombination in F. oxysporum mitogenomes challenged the prevailing assumption of clonal reproduction in this species. Here, we construct, to our knowledge, the first fungal pan-mitogenome graph of nearly 500 F. oxysporum mitogenome assemblies to uncover the variation and evolution. In general, the gene order of fungal mitogenomes is not well conserved, yet the mitogenome of F. oxysporum and related species are highly colinear. We observed two strikingly contrasting regions in the F. oxysporum pan-mitogenome, comprising a highly conserved core mitogenome and a long variable region (6-16 kb in size), of which we identified three distinct types. The pan-mitogenome graph reveals that only five intron insertions occurred in the core mitogenome and that the long variable regions drive the difference between mitogenomes. Moreover, we observed that their evolution is neither concurrent with the core mitogenome nor with the nuclear genome. Our large-scale analysis of long variable regions uncovers frequent recombination between mitogenomes, even between strains that belong to different taxonomic clades. This challenges the common assumption of incompatibility between genetically diverse F. oxysporum strains and provides new insights into the evolution of this fungal species.IMPORTANCEInsights into plant pathogen evolution is essential for the understanding and management of disease. Fusarium oxysporum is a major fungal pathogen that can infect many economically important crops. Pathogenicity can be transferred between strains by the horizontal transfer of pathogenicity chromosomes. The fungus has been thought to evolve clonally, yet recent evidence suggests active sexual recombination between related isolates, which could at least partially explain the horizontal transfer of pathogenicity chromosomes. By constructing a pan-genome graph of nearly 500 mitochondrial genomes, we describe the genetic variation of mitochondria in unprecedented detail and demonstrate frequent mitochondrial recombination. Importantly, recombination can occur between genetically diverse isolates from distinct taxonomic clades and thus can shed light on genetic exchange between fungal strains.

Phylogenetic analysis of the complete mitochondrial genome of the orange-winged sulphur butterfly Dercas nina Mell 1913 (Insecta: Lepidoptera: Pieridae: Coliadinae)

Dercas nina Mell 1913 (Pieridae) is a little-studied butterfly species endemic to China that flies primarily in the forest canopy. Genome skimming by Illumina sequencing allowed assembly of 146,702 reads for complete 1471.3-fold mean coverage of the circular 15,264 bp mitogenome from D. nina consisting of 82.1% AT nucleotides. A gene order typical of butterflies was recovered consisting of 13 protein-coding genes, 22 tRNAs, two rRNAs, and a predicted control region. The Dercas nina COX1 open reading frame begins with atypical start codon CGA. Six protein-coding genes (COX1, COX2, ND2, ND3, ND4, ND5) with single-nucleotide (T) stop codons, and two protein-coding genes (ATP6, ATP8) with two-nucleotide (TA) stop codons encoded in the DNA were inferred to be completed by adenine nucleotides from the Poly-A tail of the mRNA. Bayesian’s phylogenetic reconstruction places the D. nina and D. lycorias mitogenomes as sister clades. Dercas mitogenomes were sister to those from genus Colias in the monophyletic subfamily Coliadinae. The mitogenome phylogeny is consistent with previous molecular phylogenetic hypotheses based on other markers, but differs somewhat from a morphology-based hypothesis that suggested that Dercas was more closely related to genus Gonepteryx. This may falsify the hypothesis or may instead reflect mitochondrial-nuclear phylogenetic discordance.

Complete Chloroplast Genome of Crassula aquatica: Comparative Genomic Analysis and Phylogenetic Relationships

Background/Objectives: Crassula aquatica (L.) Schonl. is a very small annual plant growing along riverbanks. Chloroplast (cp) genomes, crucial for photosynthesis, are highly conserved and play a key role in understanding plant evolution. In this study, we conducted cp genome analysis of C. aquatica, aiming to elucidate its phylogenetic position and structural variations. We analyzed and described the features of the complete cp genome of C. aquatica and conducted comparative analysis with the cp genomes of closely related taxa. Rsults: The cp genome was 144,503 bp in length and exhibited the typical quadripartite structure, consisting of a large single-copy region (LSC; 77,993 bp), a small single-copy region (SSC; 16,784 bp), and two inverted repeats (24,863 bp). The cp genome of C. aquatica comprised 113 unique genes, including 79 protein-coding genes (PCGs), 30 tRNAs, and 4 rRNA genes. Comparative genomic analysis of 13 other Crassula species and six outgroups demonstrated highly conserved gene content and order among Crassula species. However, notable differences were observed, including the complete loss of the rpoC1 intron in C. aquatica and several closely related species, which may serve as a synapomorphic trait supporting the monophyly of the subgenus Disporocarpa. We analyzed the nucleotide diversity among 14 Crassula cp genomes and identified five highly variable regions (pi > 0.08) in the IGS regions. Phylogenetic analysis based on 78 PCGs confirmed the monophyly of Crassula and its division into two subgenera: Crassula and Disporocarpa. Although the phylogenetic tree supported the subgeneric classification system, the sectional classification system requires reassessment. Conclusions: In this study, we conducted a comparative analysis of the cp genome of the genus Crassula. We inferred evolutionary trends within the Crassula cp genome and provided molecular evidence supporting the integration of the genus Tillaea into the genus Crassula. However, as this study does not represent all species within the genus Tillaea, further comprehensive phylogenetic analyses are requrired.

Comparative linkage mapping to investigate synteny and recombination in social Vespidae

Abstract Genetic linkage maps are valuable resources for investigating chromosomal structure, quantifying karyotype, estimating recombination rates, and improving preexisting genome assemblies. Comparative linkage mapping, in turn, broadens our understanding of the phylogenetic history of these genomic features. Through an assessment of synteny (the conservation of gene order on homologous chromosomes in different species) and variation in recombination rate, we can begin to understand how genomic features change during the evolution of distinct species. Here, we construct high-density genetic linkage maps for 3 Vespidae wasp species from the Vespula genus: Vespula consobrina, Vespula pensylvanica, and Vespula vidua to investigate shared genomic architecture between these 3 yellowjacket wasp species. We show that these species exhibit high levels of collinearity, often in chromosome-length blocks of synteny, with some evidence for small interchromosomal rearrangements. We also identify 2 “inversions” in all 3 species that are likely artifacts from the genome assembly process. In addition, we map genome-wide recombination rates and reveal the recombination landscape to be highly variable on intrachromosomal, interchromosomal, and interspecific scales. Genome-wide recombination rates are high for all three Vespula species, (V. pensylvanica: 22.7 cM/Mb, V. consobrina: 24.3 cM/Mb, and V. vidua: 24.7 cM/Mb), which is consistent with findings of high recombination rates for other eusocial species. Our high-quality linkage maps will be resources for ongoing evolutionary genetics studies interested in the genome evolution of social wasps.

The Complete Mitochondrial Genome of Nephropsis grandis: Insights into the Phylogeny of Nephropidae Mitochondrial Genome.

The systematic phylogeny of Pleocyemata species, particularly within the family Nephropidae, remains incomplete. In order to enhance the taxonomy and systematics of Nephropidae within the evolutionary context of Pleocyemata, we embarked upon a comprehensive study aiming to elucidate the phylogenetic position of Nephropsis grandis. Consequently, we determined the complete mitochondrial DNA sequence for N. grandis. The circular genome spans a length of 15,344bp and exhibits a gene composition analogous to that observed in other metazoans, encompassing a comprehensive set of 37 genes. Additionally, the genome features an AT-rich region. The rRNAs exhibited the highest AT content among the 37 genes (70.41%), followed by tRNAs (67.42%) and protein-coding genes (PCGs) (62.76%). The absence of a dihydrouracil arm in trnS1 prevented the formation of the canonical cloverleaf secondary structure. Selective pressure analysis indicated that the PCGs underwent purifying selection. The Ka/Ks ratios for cox1, cox2, cox3, and cob were considerably lower compared to other PCGs, implying strong purifying selection acting upon these particular genes. The mitochondrial gene order in N. grandis was consistent with the reported order in ancestral Pleocyemata. Phylogenetic revealed that N. grandis forms a cluster with the genus Metanephrops, and this cluster further groups with Homarus and the genus Nephrops within the Nephropidae family. These findings provide robust support for N. grandis as an ancestral member of the Nephropidae family. This study highlights the significance of employing complete mitochondrial genomes in phylogenetic analysis and deepens our understanding of the evolution of the Nephropidae family.

The mitochondrial genome sequences of eleven leafhopper species of Batracomorphus (Hemiptera: Cicadellidae: Iassinae) reveal new gene rearrangements and phylogenetic implications.

Batracomorphus is the most diverse and widely distributed genus of Iassinae. Nevertheless, there has been no systematic analysis of the genome structure and phylogenetic relationships of the genus. To determine the characteristics of the mitogenomes of Batracomorphus species as well as the phylogenetic relationships between them, we sequenced and compared the mitogenomes of 11 representative Batracomorphus species. The results revealed that the mitogenomes of the 11 Batracomorphus species exhibited highly similar gene and nucleotide composition, and codon usage compared with other reported mitogenomes of Iassinae. Of these 11 species, we found that the mitogenomes of four species were rearranged in the region from trnI-trnQ-trnM to trnQ-trnI-trnM, whereas the remaining species presented a typical gene order. The topologies of six phylogenetic trees were in agreement. Eurymelinae consistently formed paraphyletic groups. Ledrinae and Evacanthinae formed sister taxa within the same clade. Similarly, Typhlocybinae and Mileewinae consistently clustered together. All phylogenetic trees supported the monophyly of Iassinae, indicating its evolutionary distinctiveness while also revealing its sister relationship with Coelidiinae. Notably, the nodes for all species of the genus Batracomorphus were well supported and these taxa clustered into a large branch that indicated monophyly. Within this large branch, four Batracomorphus species with a gene rearrangement (trnQ-trnI-trnM) exhibited distinctive clustering, which divided the large branch into three minor branches. These findings expand our understanding of the taxonomy, evolution, genetics, and systematics of the genus Batracomorphus and broader Iassinae groups.

New mitochondrial gene order arrangements and evolutionary implications in the class Octocorallia.

The complete mitochondrial genomes of octocorals typically range from 18.5 kb to 20.5 kb in length and include 14 protein-coding genes (PCGs), two ribosomal RNA genes and one tRNA. To date, seven different gene orders (A-G) have been described, yet comprehensive investigations of the actual number of arrangements, as well as comparative analyses and evolutionary reconstructions of mitochondrial genome evolution within the whole class Octocorallia, have been often overlooked. Here, we considered the complete mitochondrial genomes available for octocorals and explored their structure and gene order variability. Our results updated the actual number of mitochondrial gene order arrangements so far known for octocorals from 7 to 14 and allowed us to explore and preliminarily discuss the role of some of the structural and functional factors in the mitogenomes. We performed comparative mitogenomic analyses on the existing and novel octocoral gene orders, considering different mitogenomic structural features such as genome size, GC percentage, AT and GC skewness. The mitochondrial gene order history mapped on a recently published nuclear loci phylogeny showed that the most common rearrangement events in octocorals are inversions, inverted transpositions and transpositions. Furthermore, gene order rearrangement events were restricted only to some regions of the tree. Overall, different rearrangement events arose independently and from the ancestral and most common gene order, instead of being derived from other rearranged orders. Finally, our data demonstrate how the study of mitochondrial gene orders can be used to explore the evolution of octocorals and in some cases can be used to assess the phylogenetic placement of certain taxa.

Insights into phylogenetic relationships and gene rearrangements: complete mitogenomes of two sympatric species in the genus Rana (Anura, Ranidae).

Mitochondrial genomes (also known as mitogenomes) serve as valuable molecular markers and have found widespread applications in molecular biology and ecology. There is abundant sequence variation in vertebrate mitogenomes, and occasionally, they exhibit gene rearrangements. In this study, two Chinese endemic Rana species, Ranajiemuxiensis and Ranahanluica, were sequenced and analyzed to obtain their complete mitogenomes. The two species were sympatrically distributed in the Zhangjiajie National Forest Park, in Wulingyuan District, Zhangjiajie City, Hunan Province, China. The mitogenome of R.jiemuxiensis was 17,506 bp, while that of R.hanluica was 17,505 bp, each comprising 13 protein-coding genes (PCGs), 22 transfer RNA genes (tRNAs), two ribosomal RNA genes (rRNAs), and a non-coding control region (D-loop). The gene content, nucleotide composition, and evolutionary rates of each mitogenome were analyzed and compared with those of congeners. A phylogenetic analysis based on 22 mitogenomes in Rana revealed that the two sympatric species were in two different lineages, indicating that they were genetically separated to a certain extent. Three types of gene rearrangement patterns were identified when examining the gene orders of the 22 Rana mitogenomes. Most of the species shared a second and dominant gene rearrangement pattern that originated from the first ancient pattern. A "tandem duplication - multiple deletion" hypothesis was proposed to explain the evolution of these different gene rearrangement patterns. This study provided valuable data references and enhanced our understanding of the phylogenetic implications and gene rearrangements of Rana species.

Leveraging Synthetic Virology for the Rapid Engineering of Vesicular Stomatitis Virus (VSV)

Vesicular stomatitis virus (VSV) is a prototype RNA virus that has been instrumental in advancing our understanding of viral molecular biology and has applications in vaccine development, cancer therapy, antiviral screening, and more. Current VSV genome plasmids for purchase or contract virus services provide limited options for modification, restricted to predefined cloning sites and insert locations. Improved methods and tools to engineer VSV will unlock further insights into long-standing virology questions and new opportunities for innovative therapies. Here, we report the design and construction of a full-length VSV genome. The 11,161 base pair synthetic VSV (synVSV) was assembled from four modularized DNA fragments. Following rescue and titration, phenotypic analysis showed no significant differences between natural and synthetic viruses. To demonstrate the utility of a synthetic virology platform, we then engineered VSV with a foreign glycoprotein, a common use case for studying viral entry and developing anti-virals. To show the freedom of design afforded by this platform, we then modified the genome of VSV by rearranging the gene order, switching the positions of VSV-P and VSV-M genes. This work represents a significant technical advance, providing a flexible, cost-efficient platform for the rapid construction of VSV genomes, facilitating the development of innovative therapies.

Complementing aculiferan mitogenomics: comparative characterization of mitochondrial genomes of Solenogastres (Mollusca, Aplacophora).

With the advances in high-throughput sequencing and bioinformatic pipelines, mitochondrial genomes have become increasingly popular for phylogenetic analyses across different clades of invertebrates. Despite the vast rise in available mitogenomic datasets of molluscs, one class of aplacophoran molluscs - Solenogastres (or Neomeniomorpha) - is still neglected. Here, we present six new mitochondrial genomes from five families of Solenogastres (Amphimeniidae, Gymnomeniidae, Proneomeniidae, Pruvotinidae, Simrothiellidae), including the first complete mitogenomes, thereby now representing three of the four traditional orders. Solenogaster mitogenomes are variable in size (ranging from approximately 15,000bp to over 17,000bp). The gene order of the 13 protein coding genes and two rRNA genes is conserved in three blocks, but considerable variation occurs in the order of the 22 tRNA genes. Based on phylogenetic analyses and reconstruction of ancestral mitochondrial genomes of Aculifera, the position of (1) trnD gene between atp8 and atp6, (2) trnT and P genes between atp6 and nad5, and (3) trnL1 gene between G and E, resulting in a 'MCYWQGL1E'-block of tRNA genes, are all three considered synapomorphies for Solenogastres. The tRNA gene block 'KARNI' present in Polyplacophora and several conchiferan taxa is dissolved in Solenogastres. Our study shows that mitogenomes are suitable to resolve the phylogenetic relationships among Aculifera and within Solenogastres, thus presenting a cost and time efficient compromise to approach evolutionary history in these clades.

KEGG: biological systems database as a model of the real world.

KEGG (https://www.kegg.jp/) is a database resource for representation and analysis of biological systems. Pathway maps are the primary dataset in KEGG representing systemic functions of the cell and the organism in terms of molecular interaction and reaction networks. The KEGG Orthology (KO) system is a mechanism for linking genes and proteins to pathway maps and other molecular networks. Each KO is a generic gene identifier and each pathway map is created as a network of KO nodes. This architecture enables KEGG pathway mapping to uncover systemic features from KO assigned genomes and metagenomes. Additional roles of KOs include characterization of conserved genes and conserved units of genes in organism groups, which can be done by taxonomy mapping. A new tool has been developed for identifying conserved gene orders in chromosomes, in which gene orders are treated as sequences of KOs. Furthermore, a new dataset called VOG (virus ortholog group) is computationally generated from virus proteins and expanded to proteins of cellular organisms, allowing gene orders to be compared as VOG sequences as well. Together with these datasets and analysis tools, new types of pathway maps are being developed to present a global view of biological processes involving multiple organism groups.

Identification of a new Clostridium perfringens variant with a chromosomally encoded enterotoxin gene in a suspected persistent food poisoning outbreak in Eritrea.

Clostridium perfringens is a causative agent of various human and animal enteric diseases including food poisoning. In this study, we describe an interesting case of a persistent food poisoning outbreak among Finnish peacekeepers in Eritrea, possibly caused by Clostridium perfringens carrying a new variant of the chromosomally encoded enterotoxin gene. C. perfringens strains causing food poisoning carry the enterotoxin gene, cpe, in its chromosome (c-cpe) or on a plasmid (p-cpe). PCR assays are widely used for toxinotype C. perfringens strains. The integration sites for the cpe gene are highly conserved, and PCR assays targeting the cpe gene and the adjacent IS elements (the IS1470 in c-cpe and the IS1470-like or IS1151 in p-cpe strains) are used to further determine the genetic location of the cpe gene. We sequenced nine enteropathogenic C. perfringens strains related to a persistent food poisoning outbreak among Finnish peacekeepers in Eritrea. Six of these strains produced non-typeable cpe results in the standard PCR assay due to divergence in the enterotoxin integration site. The gene order of the new variant of the chromosomal cpe insertion site with an additional IS1470 element impairing genotyping PCR assay for the location of cpe is described. In addition, variant c-cpe strains carried 58-81 copies of IS1470 in their genomes, compared to 9-23 copies found in previously described c-cpe strains. Thus, the present study represents an untraditional type of C. perfringens food poisoning caused by variant c-cpe strains, and the sequenced strains bring geographic variation to the existing strain collection of sequenced C. perfringens.

Long range segmentation of prokaryotic genomes by gene age and functionality.

Bacterial and archaeal genomes encompass numerous operons that typically consist of two to five genes. On larger scales, however, gene order is poorly conserved through the evolution of prokaryotes. Nevertheless, non-random localization of different classes of genes on prokaryotic chromosomes could reflect important functional and evolutionary constraints. We explored the patterns of genomic localization of evolutionarily conserved (ancient) and variable (young) genes across the diversity of bacteria and archaea. Nearly all bacterial and archaeal chromosomes were found to encompass large segments of 100-300 kb that were significantly enriched in either ancient or young genes. Similar clustering of genes with lethal knockout phenotype (essential genes) was observed as well. Mathematical modeling of genome evolution suggests that this long-range gene clustering in prokaryotic chromosomes reflects perpetual genome rearrangement driven by a combination of selective and neutral processes rather than evolutionary conservation.

Complete chloroplast genomes of Desmidorchis penicillata (Deflers) plowes and Desmidorchis retrospiciens Ehrenb.: comparative and phylogenetic analyses among subtribe Stapeliinae (Ceropegieae, Asclepiadoideae, Apocynaceae)

The succulent shrubs Desmidorchis penicillata and D. retrospiciens, part of the taxonomically challenging genus Desmidorchis, are well‐known for their ecological resilience and medicinal significance. This study sequences the first complete chloroplast genomes of these species, shedding light on their genomic characteristics and evolutionary relationships. The circular genomes of D. penicillata (161 776 bp) and D. retrospiciens (162 277 bp) display a quadripartite structure typical of Angiosperms. Gene content, order, and GC content are consistent, featuring 114 unique genes, including 80 protein‐coding, 30 transfer RNAs, and four ribosomal RNAs genes. Codon usage analysis underscores A/U‐rich preferences, while RNA editing sites, predominantly in ndhB and ndhD genes, suggest post‐transcriptional modifications. Analysis of long repeated sequences reveals a predominance of forward and palindromic repeats. Simple sequence repeats (SSRs), particularly A/T motifs, are abundant, with high presence of mononucleotide, offering potential molecular markers. Comparative analysis with their relatives in subtribe Stapeliinae identifies mutational hotspots such as ycf1, ndhF, trnG(GCC)‐trnfM(CGA) and ndhG‐ndhI that could be potential DNA barcoding markers. The inverted repeat (IR) boundaries analysis revealed an expansion of IR on the small single copy region, leading to the formation of a pseudogene. Overall, substitution rate analysis indicated purifying selection, with a few genes (rpl22, clpP and rps11) showing signatures of positive selection. Additionally, the phylogenetic analysis positioned Desmidorchis within the Stapeliinae clade and strongly supported the sister relationship between D. penicillata and D. retrospiciens. This study provides comprehensive molecular data for future research in Desmidorchis.

The complete mitogenome and phylogenetic analysis of Thalassa montezumae Mulsant, 1850 (Coleoptera: coccinellidae)

Thalassa montezumae Mulsant is a coccinellid species recently discovered as predator of the pine tortoise scale Toumeyella parvicornis. In this study, the complete mitochondrial genome of T. montezumae collected in Turks and Caicos Islands in 2023 was sequenced using next-generation sequencing techniques. The circular mitochondrial genome is 16,981 bp long and contains 13 protein coding genes, 22 transfer RNA, and 2 rRNA genes. Gene order is identical to that of other Coccinellidae. Phylogenetic analysis confirms structure of Coccinellidae families and tribes.

The complete mitochondrial genome of the shining leaf chafer Mimela junii (Duftschmidt, 1805) (Coleoptera: Scarabaeidae)

The complete mitochondrial genome of the shining leaf chafer Mimela junii was sequenced and is herein described. The mitogenome consists of a circular molecule of 16,805 bp, with an overall AT content of 75.7%. It encodes for 13 protein-coding genes (PCGs), 22 transfer RNA genes (tRNAs), two ribosomal RNA genes (rRNAs) and contains a non-coding Control Region (CR) characterized by the presence of tandem repeats. The gene order corresponds to the ancestral Pancrustacea model and mitogenome characteristics are congruous with those of hexapods. In the phylogenetic analysis, M. junii is nested within a paraphyletic Anomala with high support, and is herein associated with Anomala corpulenta with medium/low support.

Drivers of interlineage variability in mitogenomic evolutionary rates in Platyhelminthes.

Studies of forces driving interlineage variability in the evolutionary rates (both sequence and architecture) of mitochondrial genomes often produce contradictory results. Flatworms (Platyhelminthes) exhibit the fastest-evolving mitogenomic sequences among all bilaterian phyla. To test the effects of multiple factors previously associated with different aspects of mitogenomic evolution, we used mitogenomes of 223 flatworm species, phylogenetic multilevel regression models, and causal inference. Thermic host environment (endothermic vs. ectothermic) had nonsignificant impacts on both sequence evolution and mitogenomic size. Mitogenomic gene order rearrangements (GORR) were mostly positively correlated with mitogenomic size (R2 ≈ 20-30%). Longevity was not (negatively) correlated with sequence evolution in flatworms. The predominantly free-living "turbellaria" exhibited much shorter branches and faster-evolving mitogenomic architecture than parasitic Neodermata. As a result, "parasitism" had a strong explanatory power on the branch length variability (>90%), and there was a negative correlation between GORR and branch length. However, the stem branch of Neodermata comprised 63.6% of the total average branch length. This evolutionary period was also marked by a high rate of gene order rearrangements in the ancestral Neodermata. We discuss how this period of rapid evolution deep in the evolutionary history may have decoupled sequence evolution rates from longevity and GORR, and overestimated the explanatory power of "parasitism". This study shows that impacts of variables often vary across lineages, and stresses the importance accounting for the episodic nature of evolutionary patterns in studies of mitogenomic evolution.

Genomes of Alphanucleorhabdovirus Physostegiae Isolates from Two Different Cultivar Groups of Solanum melongena

Plant rhabdoviruses cause considerable economic losses and are a threat to the agriculture of Solanaceae plants. Two novel virus isolates belonging to the family Rhabdoviridae are identified by high-throughput sequencing (HTS) in Russian eggplant cultivars grown in the Volga river delta region for the first time. The phylogenetic inference of L protein (polymerase) shows that these virus isolates belong to Alphanucleorhabdovirus physostegia (Physostegia chlorotic mottle virus—PhCMoV), and their minus-sense RNA genomes have the typical gene order 3′-nucleocapsid (N)—X protein (X)—phosphoprotein (P)—Y protein (Y)—matrix protein (M)—glycoprotein (G)—polymerase (L)-5′ observed in some plant-infecting alphanucleorhabdoviruses. One of the PhCMoV isolates from the eggplant cultivar Almaz is genetically very similar to the Russian PhCMoV isolate from tomato and grouped in a subclade together with four isolates from Belgium, Germany, the Netherlands, and France. However, another eggplant-infecting isolate from the Russian cultivar Boggart is the most divergent compared with the other 45 virus genomes of European PhCMoV isolates. Thus, our comparative analysis reveals that two virus isolates from Russia may either share a close evolutionary relationship with European isolates or significantly diverge from all known virus isolates. The potential to use the protein sequence comparative analysis of accessory polypeptides, along with the early developed strategy of the nucleotide sequence comparison of the RNA genomes, is shown.