Search Results (59)

Solitary living is an evolutionarily widespread yet comparatively under-theorized social system, despite its occurrence across diverse animal taxa. Shrikes (family Laniidae) are small predatory passerines that combine raptorial behavior, strong territoriality, and predominantly solitary space use, making them a powerful model for examining the ecology and evolution of solitary living. Here, I synthesize published work on shrike behavioral ecology and explicitly link these traits to the costs and benefits of a solitary lifestyle. I argue that shrikes exemplify how solitary species can offset the absence of social buffering through cognitive innovation, finetuned habitat selection, and flexible yet tightly bounded sociality. I then compare shrike ecology to solitary mammals and reptiles, highlighting convergent patterns in resource dispersion, spatial memory, risk management, and juvenile dispersal. I further examine how anthropogenic pressures, such as habitat fragmentation, climatic instability, and urbanization, interact with solitary life histories and review evidence from management interventions in both European farmland and North American systems that demographic recovery is achievable but remains contingent on addressing broader land-use conflicts and sources of adult mortality. Finally, I outline five interconnected research priorities—spanning cognitive ecology, trophic interactions, movement ecology, genomics, and formal comparative analyses—that would move shrike research from its current observational foundation toward a more experimental, mechanistic, and phylogenetically informed programme. By reframing shrikes as a model taxon for solitary living, this review aims to integrate avian behavioral ecology into broader comparative frameworks of social organization, cognition, and resilience under global change. Full article

The family Capitellidae performs critical roles in bioturbation and sediment remediation within global marine benthic ecosystems. However, they are a taxonomically challenging group due to their simple morphology and a ‘morphological mosaic’, where traditional classificatory traits, such as thoracic chaetiger counts, appear convergently across genera. Previous multi-locus studies (using 18S, 28S, H3, and COI) first highlighted this conflict, revealing the polyphyly of major genera like Notomastus and even Leiochrides itself (based on unidentified specimens). More recently, mitogenomic studies uncovered massive gene order rearrangements and a conflicting topology but did not include Leiochrides. Critically, with no complete mitogenome reported for a formally identified Leiochrides species, its true phylogenetic position and the validity of its polyphyly remain unresolved. To address this critical gap, we sequenced and characterized the first complete mitochondrial genome from a formally identified species, Leiochrides yokjidoensis, recently described from Korean waters. The complete mitogenome was 17,933 bp in length and included the typical 13 protein-coding genes (PCGs), 2 ribosomal RNAs (rRNAs), and 22 transfer RNAs (tRNAs). Gene order (GO) analysis revealed the occurrence of gene rearrangements in Capitellidae and in its sister clade, Opheliidae. A phylogenomic analysis using the amino acid sequences of 13 PCGs from 30 species established the first robust systematic position for the genus Leiochrides (based on this formally identified species). Phylogenetic results recovered Leiochrides as a sister group to the clade comprising Mediomastus, Barantolla, Heteromastus, and Notomastus hemipodus (BS 99%). This distinct placement confirms that Leiochrides represents an independent evolutionary lineage, phylogenetically separate from the polyphyletic Notomastus complex, despite their morphological similarities. Furthermore, our analysis confirmed the polyphyly of Notomastus, with N. hemipodus clustering distinctly from other Notomastus species. Additionally, signatures of positive selection were detected in ND4, and ND5 genes, suggesting potential adaptive evolution to the subtidal environment. This placement provides a critical, high-confidence anchor point for the genus Leiochrides. It provides a reliable reference to investigate the unresolved polyphyly suggested by previous multi-locus studies and provides compelling evidence for the hypothesis that thoracic chaetiger counts are of limited value for inferring phylogenetic relationships. This study provides the foundational genomic cornerstone for Leiochrides, representing an essential first step toward resolving the systematics of this taxonomically challenging family. Full article

Background: The enhanced sensitivity of next-generation sequencing (NGS) for assessing hepatitis B virus (HBV) quasispecies heterogeneity over clone-based sequencing (CBS) is well documented. However, its comparative reliability for genotype determination remains an open question. Objective: This study aimed to directly compare the performance of NGS and CBS for genotyping HBV using the entire viral genome. Methods: We selected five challenging clinical samples that previously could not be subgenotyped or showed conflicting results when using direct sequencing of the S open reading frame (ORF). The full HBV genome from these subjects was amplified and then analyzed in parallel by both NGS and CBS. Phylogenetic analysis was subsequently used to assign genotypes. Results: Both methods identified a range of genotypes, including B, C, and I, as well as aberrant and recombinant forms. For three of the five subjects, genotyping results were identical between the two platforms. In the remaining two cases, however, CBS revealed greater complexity, identifying additional subgenotypes and recombinant/aberrant strains not detected by NGS. Notably, for three individuals, the genotypes determined by both modern methods contradicted earlier results from 2011 based on direct S ORF sequencing. Furthermore, the specific mutations detected were incongruent between the platforms, with CBS identifying a higher number of variants than NGS. Conclusions: Our findings indicate that genotyping results from NGS and CBS can be discordant. Contrary to expectations, CBS may uncover more genetic diversity, including a greater number of subgenotypes and mutations, than NGS in certain contexts. The study also confirms that genotyping based solely on direct sequencing of the S ORF can be unreliable and lead to misclassification. Full article

The taxonomy of Tettigometra Latreille, 1804 s.l. (Hemiptera, Tettigometridae, Tettigometrini) has long remained unstable due to weak diagnostic characters, conflicting interpretations, and frequent misidentifications. Based on extensive examination of the illustrated literature and major museum collections, a new generic framework is proposed, relying primarily on comparative analyses of male genital morphology (particularly the mediodorsal aedeagal process and paired ventral anal processes) while external morphology alone is shown to be unreliable for stable delimitation. In discussing the need for a taxonomy that is both phylogenetically grounded and operational, allowing reliable identifications, preserving compatibility with past determinations despite the lack of molecular evidence, and remaining flexible enough to accommodate future results, we recognize two informal taxonomic groups and fourteen genera. The tettigometrinan group includes Tettigometra, Brachyceps, Metroplaca, Mimarada, Mediodentometragen. nov., and Persiametragen. nov.; the apexometrinan group includes Apexometragen. nov., Erratometragen. nov., Eurychila, Hystrigonia, Micracanthometragen. nov., Mitricephalus, Stirometra, and Macrometrina. Following a conservative and operational taxonomic approach, we refrained from describing new species or accepting unsubstantiated synonymies, preferring to retain potentially distinct forms as provisionally valid species pending molecular confirmation. Each taxon is listed with its taxonomic and nomenclatural status, diagnosis, species composition, and distribution. Problematic taxa and misapplied names are clarified, and a key to genera is provided. Full article

Background/Objectives: Fissidens crispulus Brid. is a dioicous moss with conspicuous axillary hyaline nodules and serrulate leaf margins. It features Neoamblyothallia-type peristome teeth and serves as an ecologically significant model for studying adaptation in the hyperdiverse genus Fissidens (>440 species). Methods: In this study, the complete chloroplast genome of F. crispulus was sequenced and de novo assembled, enabling detailed comparative genomic, phylogenetic, and codon usage bias studies. Results: As the third fully sequenced member of Fissidentaceae, this study deciphers its 124,264–124,440 bp quadripartite genome encoding 129 genes (83 CDS, 32 tRNAs, 8 rRNAs). Repeat analysis identified 125–127 SSRs, dominated by mono-/di-nucleotide A/T repeats (>70%), and dispersed repeats predominantly forward (F) and palindromic (P) (>85%), confirming profound AT-biased composition (GC content: 28.7%). We established 7 hypervariable loci (matK, ycf2, etc.) as novel Dicranidae-wide phylogenetic markers. Codon usage exhibited significant A/U-ending preference, with 12 optimal codons (e.g., GCA, UGU, UUU) determined. Maximum likelihood analyses resolved F. crispulus and F. protonematicola as sister groups with high support value (MBP = 100%). Conclusions: This work provides the foundational cpDNA resource for Fissidens, filling a major gap in bryophyte chloroplast genomics and establishing a framework for resolving the genus’s infrageneric conflicts. Furthermore, it offers critical insights into bryophyte plastome evolution and enables future codon-optimized biotechnological applications. Full article

As apex predators, felids (Felidae) face unresolved phylogenetic controversies due to their recent rapid speciation and remarkable morphological conservatism. Previous studies, often relying on a limited number of genetic markers, were constrained by insufficient data and conflicting phylogenetic signals, leaving these disputes unresolved. Therefore, establishing a robust phylogenetic framework based on larger-scale genomic data is crucial. This study integrated complete mitogenomes from 37 species representing all major felid genera to characterize genomic diversity, selection pressures, and phylogenetic relationships. Results revealed conserved gene content and arrangement patterns but significant intergenic variation in nucleotide composition, with the light-strand encoded ND6 exhibiting pronounced strand-specific bias. Nucleotide diversity was highest in ND4L (Pi = 0.132) and ATP6 (Pi = 0.131), suggesting their utility as novel markers for species delimitation and population studies. Selection pressure analysis indicated strong purifying selection on cytochrome oxidase subunits (e.g., COX1 Ka/Ks = 0.00327) but relaxed constraints on ATP8 (Ka/Ks = 0.12304). Phylogenies reconstructed from the complete 13PCGs + 2rRNAs dataset (showing high congruence between maximum likelihood and Bayesian methods) clearly delineated Felidae into two primary clades (Pantherinae and Felinae), confirming monophyly of all genera and positioning Neofelis nebulosa as the basal lineage within Pantherinae. Crucially, exclusion of ND6 (12PCGs + 2rRNAs) yielded topologies congruent with the complete 13PCGs + 2rRNAs dataset, whereas single-gene or limited multi-gene datasets produced inconsistent trees (particularly at genus-level nodes). This demonstrates that near-complete mitogenomic data (≥12PCGs + 2rRNAs) are essential for reconstructing robust felid phylogenetic frameworks. Our study provides insights into carnivoran mitogenome evolution. Full article

Species characterized by undetermined clade affiliations, limited research coverage, and deficient systematic investigation serve as enigmatic entities in plant and animal taxonomy, yet hold critical significance for exploring phylogenetic relationships and evolutionary trajectories. Subgenus Cyathophora (Allium, Amayllidaceae), a small taxon comprising approximately five species distributed in the Qinghai–Tibet Plateau (QTP) and adjacent regions might contain an enigmatic species that has long remained unexplored. In this study, we collected data on species from subgenus Cyathophora and its close relatives in subgenus Rhizirideum, as well as the enigmatic species Allium siphonanthum. Combining phylogenomic datasets and morphological evidence, we investigated species relationships and the underlying mechanism of phylogenetic discordance. A total of 1662 single-copy genes (SCGs) and 150 plastid loci were filtered and used for phylogenetic analyses based on concatenated and coalescent-based methods. Furthermore, to systematically evaluate phylogenetic discordance and decipher its underlying drivers, we implemented integrative analyses using multiple approaches, such as coalescent simulation, Quartet Sampling (QS), and MSCquartets. Our phylogenetic analyses robustly resolve A. siphonanthum as a member of subg. Cyathophora, forming a sister clade with A. spicatum. This relationship was further corroborated by their shared morphological characteristics. Despite the robust phylogenies inferred, extensive phylogenetic conflicts were detected not only among gene trees but also between SCGs and plastid-derived species trees. These significant phylogenetic incongruences in subg. Cyathophora predominantly stem from incomplete lineage sorting (ILS) and reticulate evolutionary processes, with historical hybridization events likely correlated with the past orogenic dynamics and paleoclimatic oscillations in the QTP and adjacent regions. Our findings not only provide new insights into the phylogeny of subg. Cyathophora but also significantly enhance our understanding of the evolution of species in this subgenus. Full article

Millipedes (Diplopoda) are crucial decomposers in soil ecosystems, as they play a vital role in organic matter degradation while also holding potential as bioindicators of environmental health. This study deciphered the complete mitogenomes of four millipede species (Diplopoda: Spirostreptida and Spirobolida) using next-generation sequencing technology, thus revealing evolutionary relationships among diplopod taxa and characterizing mitochondrial genomic features. The full mitochondrial sequences of Agaricogonopus acrotrifoliolatus, Bilingulus sinicus, Paraspirobolus lucifugus, and Trigoniulus corallinus, ranged in size from 14,906 to 15,879 bp, with each containing 37 typical genes and one D-loop region. Notably, the D-loop regions of A. acrotrifoliolatus and B. sinicus were positioned atypically, thus indicating structural rearrangements. A nucleotide composition analysis revealed pronounced AT-skews, with tRNA sequences exhibiting the highest A+T content. Ka/Ks ratios demonstrated that the ND5 gene experienced the weakest purifying selection pressure, thus suggesting its potential role in adaptive evolution. The results of the phylogenetic analysis showed genetic relationships between the three orders of ((Julida, Spirostreptida), Spirobolida), which was inconsistent with the previous conclusion regarding the three orders, obtained through morphological studies: ((Julida, Spirobolida), Spirostreptida). These findings highlight the role of the mitochondrial genome in resolving phylogenetic conflicts and provide important insights for further studies on millipedes. Full article

Insect mitochondrial genomes are vital to understanding evolutionary relationships and identifying species. This study focused on Microtendipes (Chironomidae), a genus with unresolved phylogenetic positioning and cryptic species challenges. We sequenced and analyzed eight mitogenomes from five Microtendipes species, integrating 23 published Chironominae mitogenomes to reconstruct phylogenies using Maximum Likelihood and Bayesian Inference. The mitogenomes exhibited conserved gene arrangements but variable control region lengths (338–1266 bp) and high AT content (94.14–96.42% in control regions). Our results show that Microtendipes species may be a separate group within the subfamily, while also supporting the monophyly of the Harnischia, Polypedilum, and Chironomus complexes. The monophyly of Microtendipes bimaculus was weakly supported, which may demonstrate the presence of two potential cryptic species. Notably, larval morphology-based species groupings conflicted with the molecular data, suggesting that classifications derived from larval morphological traits may be unreliable. This study advances the evolutionary understanding of Chironomidae and underscores the limitations of single-gene barcodes in species-rich genera. Full article

Rubus is a genus of small berry-producing shrubs, valued for their medicinal properties and as a food source. This genus is a large, globally distributed group that includes over 700 species. Despite numerous plastid and nuclear genomes having been reported for Rubus, there is a notable lack of research on its mitogenomes. We utilized PMAT to assemble the mitogenomes of six Rubus species according to long-read HiFi reads and annotated them through homologous alignment. Subsequently, we compared their characteristic differences within Rubus mitogenomes. The complete mitogenomes of R. parviflorus, R. spectabilis, R. idaeus, R. armeniacus, and R. caesius all exhibit master circle structures, with lengths ranging from 360,869 bp to 447,754 bp. However, R. chamaemorus displays a double-circle structure composed of two small circular molecules, spanning 392,134 bp. These mitogenomes encode a total of 54–61 genes, including 33–34 PCGs, 17–24 tRNAs, and 3 rRNA genes. Compared to the other five Rubus species, R. chamaemorus has fewer sequence repeats. These six species exhibit similar codon usage patterns. A large number of gene transfers were detected between organellar genomes of six Rubus species. Additionally, two phylogenetic trees were constructed using 31 mitogenomes and 94 chloroplast genomes, revealing a minor conflict within Rubus. Overall, this study clarifies the mitogenome characteristics of Rubus and provides valuable insights into the evolution of the genus. Full article

Background/Objectives: Freshwater shrimps of the family Atyidae, particularly the hyperdiverse genus Caridina, are keystone decomposers in tropical aquatic ecosystems and valuable aquaculture resources. However, their evolutionary relationships remain unresolved due to conflicting morphological and molecular evidence. Here, we sequenced and characterized the complete mitochondrial genome of Caridina mariae (Tiger Shrimp), aiming to (1) elucidate its genomic architecture, and (2) reconstruct a robust phylogeny of Caridea using 155 decapod species to address long-standing taxonomic uncertainties. Methods: Muscle tissue from wild-caught C. mariae (voucher ID: KIZ-2023-001, Guangdong, China) was subjected to Illumina NovaSeq 6000 sequencing (150 bp paired-end). The mitogenome was assembled using MITObim v1.9, annotated via MITOS2, and validated by PCR. Phylogenetic analyses employed 13 protein-coding genes under Bayesian inference (MrBayes v3.2.7; 10⁶ generations, ESS > 200) and maximum likelihood (RAxML v8.2.12; 1000 bootstraps), with Harpiosquilla harpax as the outgroup. The best-fit substitution model (MtZoa + F + I + G4) was selected via jModelTest v2.1.10. Results: The 15,581 bp circular mitogenome encodes 37 genes (13 PCGs, 22 tRNAs, and 2 rRNAs) and an A + T-rich control region (86.7%). Notably, trnS1 lacks the dihydrouracil arm—a rare structural deviation in Decapoda. The 13 PCGs exhibit moderate nucleotide skew (AT = 0.030; GC = −0.214), while nad5, nad4, and nad6 show significant GC-skew. Phylogenomic analyses strongly support (PP = 1.0; BS = 95) a novel sister-group relationship between Halocaridinidae and Typhlatyinae, contradicting prior morphology-based classifications. The monophyly of Penaeoidea, Astacidea, and Caridea was confirmed, but Eryonoidea and Crangonoidea formed an unexpected clade. Conclusions: This study provides the first mitogenomic framework for C. mariae, revealing both conserved features (e.g., PCG content) and lineage-specific innovations (e.g., tRNA truncation). The resolved phylogeny challenges traditional Caridea classifications and highlights convergent adaptation in freshwater lineages. These findings offer molecular tools for the conservation prioritization of threatened Caridina species and underscore the utility of mitogenomics in decapod systematics. Full article

Ancient introgression is an infrequent evolutionary process often associated with conflicts between nuclear and organellar phylogenies. Determining whether such conflicts arise from introgression, incomplete lineage sorting (ILS), or other processes is essential to understanding plant diversification. Previous studies have reported phylogenetic discordance in the placement of Xanthoceras, but its causes remain unclear. Here, we analyzed transcriptome data from 41 Sapindaceae samples to reconstruct phylogenies and investigate this discordance. While nuclear phylogenies consistently placed Xanthoceras as sister to subfam. Hippocastanoideae, plastid data positioned it as the earliest-diverging lineage within Sapindaceae. Our coalescent simulations suggest that this cyto-nuclear discordance is unlikely to be explained by ILS alone. HyDe and PhyloNet analyses provided strong evidence that Xanthoceras experienced ancient introgression, incorporating approximately 16% of its genetic material from ancestral subfam. Sapindoideae lineages. Morphological traits further support this evolutionary history, reflecting characteristics of both contributing subfamilies. Likely occurring during the Paleogene, this introgression represents a rare instance of cross-subfamily gene flow shaping the evolutionary trajectory of a major plant lineage. Our findings clarify the evolutionary history of Xanthoceras and underscore the role of ancient introgression in driving phylogenetic conflicts, offering a rare example of introgression-driven diversification in angiosperms. Full article

Melliodendron xylocarpum is a member of the Styracaceae family, which is well-known for its remarkable ornamental and medicinal properties. In this research, we conducted comparative analysis of the chloroplast genomes from four samples of M. xylocarpum, representing Melliodendron. The results demonstrated that the chloroplast genome of four M. xylocarpum samples ranging from 157,103 bp to 158,357 bp exhibited a typical quadripartite structure, including one large single-copy (LSC) region (90,131 bp to 90,342 bp), one small single-copy (SSC) region (18,467 bp to 18,785 bp), and two inverted repeat regions (IRs) (24,115 bp to 24,261 bp). Different levels of expansion and contraction were observed in the IR region of four M. xylocarpum samples. Besides, accD and ycf1 have been identified under positive selection, potentially linked to the adaptive response of Melliodendron to various environmental changes. Conflicting phylogenetic relationships were identified among various genera within the Styracaceae family in the phylogenetic tree constructed using CDS sequences and complete chloroplast genomes. Furthermore, the significance of a large sample size was also highlighted in this study for enhancing the accuracy of findings from phylogenetic analyses. The findings of this research will provide significant insights for future investigations into the evolutionary trends and conservation of the Melliodendron species. Full article

Fishes in the cypriniform family Catostomidae (suckers) are evolutionary tetraploids. The use of nuclear markers in the phylogenetic study of this important group has been greatly hindered by the challenge of identifying paralogous copies of genes. In the present study, we used two different methods to separate the gene copies of five single-copy nuclear genes (i.e., RAG1, EGR2B, EGR3, IRBP2, and RAG2). For each gene, all sequences of Copy I formed a clade that was sister to the clade formed by all sequences of Copy II in the phylogenetic trees. The maternal and paternal progenitor of the tetraploid ancestor of the Catostomidae could not be determined. We also constructed a mitochondrial tree to reflect the maternal relationships among major catostomid lineages. Our data appear to support a sister relationship between Catostominae and a monophyletic group composed of Myxocyprininae, Cycleptinae, and Ictiobinae. However, within Catostominae, there is significant conflict between mitochondrial and nuclear data regarding the relationships among Erimyzonini, Catostomini, and Moxostomatini/Thoburnini. Many indels, unexpected stop codons, and possible gene loss were identified in one gene copy of RAG1, RAG2, and IRBP2. We believe that additional nuclear genome data are needed to better resolve the phylogenetic relationships within the family Catostomidae. Full article

The complex phylogenetic relationship of polyploid species provides an opportunity for a comprehensive study of gene introgression. Oil camellias refer to a class of important woody oil plant in the camellia genus, including octoploid, hexaploid, tetraploid, and diploid plants, but the phylogeny relationship of these species remains poorly investigated. Here, based on multiple types of evidence, including phylogenetic conflict, gene flow analysis, and representative metabolite, we reconstructed the phylogenetic relationship of oil camellias. Camellia shensiensis and C. grijsii formed a distinct branch. Phylogenetic conflict suggested that hexaploid C. oleifera probably originated from hybridization and clustered with diploid C. kissi and tetraploid C. meiocarpa. Tetraploid C. confusa probably originated from crossing the ancestor of C. kissi and C. brevistyla, and C. brevistyla probably was the maternal progenitor of hexaploid C. sasanqua. Furthermore, the composition of anthocyanin in tender leaves showed a strong correlation with phylogenetic distinctions. This study proves the feasibility of using iconic metabolic components to solve phylogenetic relationships and lays a foundation for analyzing genetic breeding and utilizing oil camellia resources. Full article