Search Results (749)

Liverwort organellar genomes are generally highly conserved, but the subclass Pellidae (simple thalloids) shows unusual variation. This ancient yet unexplored lineage of simple thalloid liverworts provides an excellent model for investigating organellar genome evolution. In this study, we assembled four new plastid and four new mitochondrial Pellidae genomes using Oxford Nanopore sequencing, supplementing 86 plastomes and 82 mitogenomes from databases. We assessed nucleotide diversity and codon usage, and inferred phylogenies using IQ-TREE with fossil-calibrated dating. Plastomes ranged 120.6–126.5 kb, and mitogenomes 109–180 kb, with Apopellia endiviifolia featuring an exceptionally reduced mitogenome (~109 kb). Native RNA sequencing enabled a revised annotation of the mitochondrial atp1 gene in Apopellia, revealing two introns (previously thought absent) and reducing the intergenic region share to 36.26%, the lowest known among liverworts. Comparative analyses revealed contrasting evolutionary dynamics between organelles: Plastomes displayed higher nucleotide diversity and phylogenetically inconsistent codon usage patterns, likely influenced by compositional bias, whereas mitogenomes were more conserved and largely consistent with established phylogenetic relationships among the orders. Phylogenomic analyses yielded discordant topologies: Chloroplast data recovered Pellidae as a monophyletic clade, whereas mitochondrial data placed Pelliales (Pellia/Apopellia) as basal Jungermanniopsida, rendering Pellidae paraphyletic. Within Pellidae-relevant clades, several major divergences were dated to the Carboniferous–Permian, but with systematic chloroplast–mitochondrial offsets. These results highlight recurrent organellar incongruence and the dynamic evolutionary history of Pellidae organellar genomes. Full article

The Balkan Peninsula is a biodiversity hotspot where topographic and habitat heterogeneity have shaped genetic differentiation. Polyploidization significantly contributes to diversification within plant lineages, including the allopolyploid complex of the Austrian speedwell, which comprises diploid, tetraploid and hexaploid lineages. We sampled 751 individuals from 50 populations belonging to this complex across the Balkan Peninsula and Central Europe. Diversity patterns were investigated through microsatellite markers (SSRs), plastid DNA sequences, ploidy estimations, morphological data and climatic niche differentiation analysis. Five lineages were detected within the complex according to nuclear DNA data. The plastid DNA haplotypes form two main groups that overall match those detected by SSR data and could suggest that the hexaploid lineage resulted from two different allopolyploid events. The hexaploid shows higher nuclear genetic diversity and morphological variation than its lower-ploidy relatives, which might allow the species to respond to a wider range of environmental conditions and be responsible for its success (i.e., a broader geographic range and ecological niche). Style length is a crucial character to distinguish diploids from polyploids, which may affect pollination biology within the complex. Full article

Juncus (Juncaceae) comprises over 300 species with high morphological plasticity, and its systematics remain incompletely resolved due to limited genomic resources. Here, we generated complete plastid genomes for two Korean Juncus species (J. decipiens and J. gracillimus) and incorporated plastid coding genes from an additional species to reconstruct phylogenetic relationships and examine plastome evolution within Juncaceae. Comparative analyses revealed substantial plastome size variation across Juncus and Luzula, largely driven by changes in inverted repeat (IR) length, with Luzula plastomes showing pronounced IR expansion. Within Juncus, extensive structural rearrangements were detected, including multiple inversion events, and closely related taxa shared conserved inversion patterns. Phylogenomic analyses recovered well-supported clades that were associated with structural traits such as extreme small single-copy (SSC) contraction and consistent loss of the plastid ndh, some rps and rpl gene families, indicating clade-specific plastome evolution in Juncaceae. To support applied molecular identification, we identified J. decipiens-specific plastid diagnostic SNPs (matK, rpl2) and validated allele-specific PCR markers using individuals from different species within the Juncus genus. In parallel, transcriptome sequencing of J. decipiens generated 133,559 transcripts and 66,324 unigenes, enabling discovery of high-confidence nuclear exonic SNP loci by mapping reads to a J. effusus nuclear genome. Collectively, our results provide new insights into plastome structural evolution and gene loss in Juncus and deliver validated plastid and nuclear markers for authentication and future conservation or utilisation studies on J. decipiens. Full article

Hybridization is considered an important process in plant evolution, especially in the origins of domesticated plant taxa, with many crop species being the result of interspecific hybridization events. There are several unidentified lineages of Spondias in the northeastern region of Brazil known only by vernacular names such as ‘cajaguela’, ‘umbu-cajá’, and ‘umbuguela’. These taxa are often regarded as being of hybrid origin, based on supposedly intermediate morphological features. However, the morphology-based hypotheses of hybrid origin and parentage of these Spondias taxa remain largely untested experimentally. We collected 355 accessions of Spondias, including S. bahiensis, other putative hybrid taxa, and both native (S. mombin, S. tuberosa, and S. venulosa) and introduced (S. purpurea) species believed to be the parental taxa. We then reconstructed phylogenies of plastid and nuclear markers and haplotype networks in order to ascertain the genetic affinities between putative hybrids and other Spondias species. All taxa with intermediate morphology were confirmed as hybrids between their putative parental species. All hybrids involving S. purpurea (native to Mexico) appear to be F₁ generation. The recently described S. bahiensis is shown to have originated from hybridization between S. tuberosa and S. venulosa. The other ‘umbu-cajá’ taxon found in Northeastern Brazil is revealed to be the result of hybridization between S. mombin and S. tuberosa. Both the northern ‘umbu-cajá’ taxon and S. bahiensis appear to be well-established hybrid lineages and not early-generation hybrids. Additionally, some introgression and backcrossing processes between S. bahiensis and one of the parents was also observed. Our findings confirm the hybrid origins of the domesticated Spondias taxa found in Northeastern Brazil. Full article

Flemingia philippinensis Merr. et Rolfe (F. philippinensis) is a Chinese herbal medicine rich in polyphenols, especially isoflavone derivatives. It exhibits potent anti-inflammatory properties and is widely used in the treatment of various diseases. In this study, we aim to sequence, assemble, and analyze the mitogenome of F. philippinensis in detail to understand the genetic structure of their organelles and their gene expression. The results showed that the mitogenome of F. philippinensis possesses a circular architecture with a total length of 427,353 bp and a GC content of 44.90%. Annotation results revealed 33 unique protein-coding genes (PCGs), 16 transfer RNA (tRNA), and 3 ribosomal RNA (rRNA) genes in the mitogenome. Furthermore, comparative analysis of mitogenome andchloroplast gemone (cpgemone) sequences identified six mitochondrial plastid sequences (MTPTs), including one partial PCG and five complete tRNA genes. Subsequent collinearity analysis indicated that numerous homologous collinear blocks were detected between F. philippinensis and its closely related species, and have undergone a large number of genomic rearrangements in the F. philippinensis mitogenome. Finally, RNA editing analysis identified 498 C -to- U editing sites, notably enriched in nad4 (44 sites) and ccmB (33 sites). Codon usage bias analysis indicated that leucine (Leu 10.66%) and serine (Ser 9.19%) were the most frequently used amino acids. This study lays a theoretical foundation for further elucidating the structural characteristics and understanding the evolution, classification, and identification of F. philippinensis. Full article

Dinophysis acuminata, the main agent of diarrhetic shellfish poisoning (DSP) worldwide, shows a high variability in morphology and toxin content between strains from contrasting habitats. Most frequent uncertainties in morphological discrimination are within the “D. acuminata complex”, but confusion with other species (e.g., D. norvegica, D. fortii) also occurs. Here we describe a unique PTX2-containing population of Dinophysis cf acuminata observed during opportunistic samplings in San Rafael Lagoon (Chilean Patagonia), the only tidewater glacier lagoon remaining in the glacier with the world’s lowest latitude. Dinophysis acuminata was the only Dinophysis species observed during three seasonal surveys in the well-mixed cold (4–7° C) and brackish (salinity 14–15) waters of the lagoon. Cell densities ranged from 500 cells L⁻¹ (winter) to 2800 cells L⁻¹ (summer). Partial sequences of their ITS rDNA aligned them with D. acuminata strains from Europe and North America, and sequences of their stolen plastids 23S rDNA confirmed ciliates of the Mesodinium rubrum + major complex as their prey and plastid source. All these reasons make this lagoon a highly sensitive area and natural laboratory for climate change-related topics and Dinophysis issues related to (i) the effect of long-term exposure of marine fauna to pectenotoxins and (ii) the adaptations of D. cf acuminata to persist in a unique ecosystem with austral water characteristics located in a warm temperate latitude light regime. Results here add knowledge to the biogeography and habitat ranges of D. acuminata and the problems faced to monitor and provide early warning of its distribution. Full article

The taxonomic status of Arbutus pavarii Pamp., a rare and geographically restricted species endemic to northeastern Libya, has long been debated, with some treatments considering it a synonym of A. unedo. To resolve this uncertainty, we applied an integrative molecular framework that combined multilocus DNA barcoding, phylogenetic inference, and multivariate statistical analyses. Five barcode loci—nrITS, matK, rbcL, trnH–psbA, and rps16—were analyzed using barcode-gap diagnostics, TaxonDNA identification tests, and single-locus and concatenated phylogenetic analyses. Barcode-gap analyses based on Kimura 2-parameter distances revealed clear and reproducible separation between intra- and interspecific variation for A. pavarii, particularly for nrITS and the concatenated multilocus dataset, whereas conserved plastid loci showed limited discriminatory power when used individually. Phylogenetic reconstructions consistently recovered A. pavarii as a strongly supported monophyletic lineage, distinct from A. unedo and other Mediterranean congeners, with congruent topologies across the nuclear, plastid, and combined datasets. Multivariate analyses, including principal component analysis and heatmap clustering, further corroborate the genetic cohesion and distinctiveness of A. pavarii samples. Collectively, these results provide robust molecular evidence supporting the recognition of Arbutus pavarii as a distinct evolutionary lineage, rather than an intraspecific variant of A. unedo. This study established a reproducible multilocus framework for species delimitation in Arbutus and highlighted the importance of integrating nuclear and plastid markers to resolve complex taxonomic relationships. The clarified taxonomic status of A. pavarii has important implications for biodiversity assessment and conservation planning in the Mediterranean region, particularly in the Cyrenaican floristic province. Full article

Background: Plant mitochondrial genomes exhibit extreme variation in size and structure while maintaining a conserved set of core protein-coding genes. This combination of structural diversity and functional conservation provides valuable insights into evolutionary processes such as genome expansion, rearrangement, and intracellular DNA transfer. Curcuma longa, an economically and medicinally important species in the genus Curcuma (Zingiberaceae), has not yet been studied in terms of the organization and evolution of its mitochondrial genome. Methods: In this study, we assembled and annotated the mitochondrial and plastid genomes of C. longa using third-generation HiFi sequencing data, systematically analyzing their genomic structure, repetitive sequence content, and features of sequence transfer between nuclear and organellar genomes. Results: The mitochondrial genome of C. longa was assembled as a complex, network-like structure consisting of 12 contigs with a total length of approximately 7.7 Mb, making it one of the largest mitochondrial genomes reported in monocots to date. Comparative analysis revealed significant differences in repeat types, abundance, and length distribution between the two organellar genomes. Additionally, extensive intracellular DNA transfer events were identified among the nuclear, mitochondrial, and plastid genomes. Conclusions: Overall, this study provides the first comprehensive report on the giant mitochondrial genome of C. longa, detailing its structural organization, repeat content, and intergenomic transfers. These findings lay a foundation for understanding mitochondrial genome evolution in Curcuma and offer broader insights into the mechanisms driving extreme mitochondrial genome expansion in angiosperms and monocots specifically. Full article

Leaf color mutants are key resources for uncovering the molecular mechanisms of chloroplast development and photosynthesis. Here, we identified a novel yellow-green melon mutant, ‘ygp2’, which displays yellow-green leaves and dwarfism throughout development. Genetic analysis indicated that the trait is controlled by a single recessive nuclear gene. Map-based cloning delimited the candidate region to an 805 kb interval on chromosome 11, within which only one missense mutation was identified in MELO13C_11G242690, encoding a triosephosphate isomerase (CmpdTPI). Phylogenetic analysis suggested its plastid localization, which was confirmed by transient expression of CmpdTPI-GFP in tobacco. The ‘ygp2’ mutant exhibited significantly reduced TPI enzyme activity and net photosynthetic rate. Transcriptome analysis revealed downregulation of genes related to light-harvesting complexes, cell division, and the cell cycle. These results demonstrate that the point mutation in CmpdTPI impairs chloroplast function and photosynthesis, leading to the yellow-green phenotype in melon. This study provides insight into the role of plastidial TPI in chlorophyll metabolism and chloroplast development. Full article

Background: Hemiboea yongfuensis is a recently discovered critically endangered species. It is exclusive to the limestone regions of Yongfu County, Guilin, Guangxi. Currently, there is a lack of mitogenome data for Hemiboea species, hindering the potential of disclosing the evolutionary processes of the mitochondrial genome, which has been far less assembled and shown to be complex in the plant kingdom. Moreover, it prevents potential applications of mitochondrial genome data in phylogenetics and plant adaption, breeding, and conservation. Results: In order to reveal the mitochondrial features and variations and explore the usefulness of mitochondrial genes in phylogenetics, in this study, we assembled the complete mitogenome of H. yongfuensis using PacBio HiFi long reads, and analyzed its codon usage bias, RNA editing sites, repetitive sequences, sequence lateral transfer, phylogenetic relationships, and synteny. The linear mitochondrial genome assembly we obtained has a length of 619,997 bp and a GC content of 43.63%. The assembly encompasses 61 genes, which include 37 protein-coding genes (PCGs), 21 transfer RNA (tRNA) genes, and 3 ribosomal RNA (rRNA) genes. Importantly, our analysis uncovered a significant presence of repetitive sequences with a high proportion of forward repeats in the mitogenome and significant transposition of sequences from the chloroplast to mitochondrion. Additionally, we revealed the codon usage characteristics of protein-coding genes and identified numerous RNA editing events. Furthermore, we assessed the collinearity of the species in the Gesneriaceae family and found rampant reorganizations. The phylogenetic analyses based on the mitochondrial PCGs for the entire Lamiales order show the monophyly of Gesneriaceae as well as other families and a general high phylogenetic resolution. Conclusions: Our study provides the first mitogenome data for H. yongfuensis and the genus Hemiboea, expanding the rapidly increasing but yet limited plant mitogenome resources. It enhances our understanding of the mitogenome and Lamiales evolution, whereas more potentials of the mitogenome data, such as its possible functions in adaptation to limestone habitats, conservation, and germplasm breeding, remain under-exploited. This first reported Hemiboea mitogenome in addition to more mitogenomes from the same and related species would shed further light on these unresolved issues in future studies. Full article

Orbea is a morphologically diverse lineage within the subtribe Stapeliinae, yet plastome evolution in Arabian taxa remains insufficiently characterized. This study reports the first complete chloroplast genomes of Orbea sprengeri subsp. commutata and O. wissmannii var. eremastrum and investigates plastome structure, sequence variability, and phylogenetic relationships across tribe Ceropegieae. Chloroplast genomes were assembled, annotated, and compared with 13 published plastomes representing major Ceropegieae lineages. Both Arabian plastomes displayed the typical quadripartite structure and identical gene content of 114 unique genes, including 80 protein-coding genes, 30 transfer RNA genes, and four ribosomal RNA genes. However, O. wissmannii var. eremastrum exhibited pronounced structural divergence, possessing the largest plastome recorded for the tribe (170,054 bp), an 8.9 kb expansion of the inverted repeat regions, and an 8.4 kb inversion spanning the ndhG–ndhF region. Comparative analyses revealed conserved gene order across Ceropegieae but identified six highly variable loci (accD, clpP, ndhF, ycf1, psbM–trnD, and rpl32–trnL) as potential DNA barcodes. Selection pressure analyses indicated strong purifying selection across most genes, with localized adaptive signals in accD, ndhE, ycf1, and ycf2. Phylogenomic reconstruction consistently resolved the two Arabian Orbea taxa as a distinct clade separate from the African O. variegata. This study fills a gap in Ceropegieae plastid genomics and underscores the importance of sequencing additional Orbea species to capture the full extent of genomic variation within this diverse genus. Full article

AIG1 (avrRpt2-induced gene 1)-like proteins are a class of GTPases that play crucial roles in plants, functioning both in chloroplast protein import and disease resistance. However, their evolutionary history and the mechanisms driving this functional diversification remain poorly understood. Here, we performed a comprehensive genomic and evolutionary analysis of this gene family across the plant kingdom. We identified 90 AIG1-like genes from 11 sequenced plant species, representing major lineages from green algae to angiosperms. Phylogenetic analysis revealed that plant AIG1-like proteins form three monophyletic lineages corresponding to the Toc34, Toc159, and IAN subfamilies, which originated via two ancient duplications predating the divergence of green algae and land plants. These lineages exhibit dramatically divergent evolutionary patterns. The Toc34 subfamily is evolutionarily conserved, maintaining stable copy numbers and gene structure, indicative of strong functional constraints in its core role in plastid import. In contrast, the Toc159 and IAN subfamilies have undergone dynamic expansion via lineage-specific duplication mechanisms, including segmental duplication and prolific tandem duplication, respectively. Notably, we uncovered a novel mechanism for generating head-to-head tandem duplicates in the IAN subfamily, mediated by recombination between inverted repeats. Our analysis of ancestral gene numbers and gene gain/loss dynamics further highlights that functional diversification was driven by both the acquisition of distinct C-terminal targeting domains (M and TM domains) and profound differences in evolutionary rates and duplication modes among subfamilies. This study provides the first full-scale evolutionary framework for plant AIG1-like genes, establishing that functional specialization is rooted in distinct modes of sequence and genomic evolution. Full article

Leaf color mutants are commonly characterized by altered chlorophyll content and aberrant chloroplast development, making them valuable models for investigating photosynthetic mechanisms and chloroplast biogenesis. In this study, an albino mutant was isolated from a population of transgenic maize breeding lines. Genetic analysis indicated that the mutant phenotype is inherited in a Mendelian manner and is controlled by a single nuclear locus. This was supported by a χ² test performed on the T₂ generation, which confirmed a segregation ratio consistent with 3:1 (176:68, χ² = 1.07 < χ²_0.05 = 3.84, p > 0.05). Microscopic examination revealed the absence of normally developed chloroplasts in mutant cells. Further expression analysis of chloroplast genes via Northern blotting and quantitative real-time PCR (qRT-PCR) suggested that the mutation impairs the regulation of plastid-encoded polymerase (PEP)-dependent chloroplast gene expression. Notably, PCR-based co-segregation analysis indicated that the mutant phenotype is associated with the entire inserted vector sequence, rather than a point mutation or a small genomic deletion. In conclusion, this paper reports the isolation and phenotypic characterization of an etiolated mutant from a transgenic maize breeding population, including comparative ultrastructural analysis of chloroplasts, co-segregation validation, and chloroplast gene expression profiling. These results enhance our understanding of the physiological and molecular mechanisms underlying chlorophyll-deficient mutations in plants. Full article

Leaves are the primary photosynthetic organs, and alterations in leaf color can affect photosynthesis and plant biomass. In an EMS-mutagenized SN9816 population, we identified two white-striped mutants, ws21-1 and ws21-2. Both mutants showed severely reduced pigment content, defective chloroplasts, and elevated reactive oxygen species. The ws21-2 allele caused a near-complete albino phenotype, while ws21-1 resulted in milder striping. Genetic mapping and cloning identified causal mutations in OsRNRS1, encoding the small subunit of ribonucleotide reductase. The G583R (ws21-1) and Y365F (ws21-2) mutations likely impair enzyme activity, disrupting the dNTP pool for plastid genome replication and causing aberrant chloroplast development. Correspondingly, the expression of genes for chlorophyll synthesis, photosynthesis, and ROS metabolism was altered. Our findings directly link nuclear-encoded nucleotide metabolism to chloroplast biogenesis and demonstrate that dNTP homeostasis is critical for maintaining photosynthetic capacity and redox balance in plants. Full article

The genus Satyrium (Orchidaceae) is a large, mostly sub-Saharan genus with a single species reported from Madagascar and Asia. Taxonomical complexity and high morphological diversity make the classification within the genus difficult to handle. In this study, we attempted to solve this problem using a comprehensive approach based on data from multiple sources. We combined morphological data from vegetative parts with data on flower structure using timescale phylogenetics conducted for both nuclear internal transcribed spacer (ITS) and plastid markers (matK, trnS-trnG, trnL, trnL-trnF). Phylogenetic studies confirmed most of the results of previous studies and led to the identification of six potential hybridization events within the genus. Morphological diversity often does not correspond to phylogenetic relationships within the genus, and many evolutionary lineages began to diverge only at the end of the early Miocene and in the late Miocene. The development of similar characteristics is the result of this diversification under the influence of similar environmental pressures. Reconstruction of the historical geographical range of Satyrium showed that the regions of South Africa and the mountainous areas of Eastern Africa played the most important role in the diversification of the genus. Full article