Comparative analysis of chloroplast genomes and phylogenetic relationships in the endemic Chinese bamboo (Bambusoideae).

Introduction: Wen is a small yet taxonomically challenging genus within the Arundinarieae tribe. Recent molecular studies have suggested it may not be monophyletic. However, limited species sampling and insufficient molecular marker information have resulted in poorly resolved phylogenetic relationships within this genus.

Spatiotemporal transcriptome atlas reveals gene regulatory patterns during the organogenesis of the rapid growing bamboo shoots.

Bamboo with its remarkable growth rate and economic significance, offers an ideal system to investigate the molecular basis of organogenesis in rapidly growing plants, particular in monocots, where gene regulatory networks governing the maintenance and differentiation of shoot apical and intercalary meristems remain a subject of controversy. We employed both spatial and single-nucleus transcriptome sequencing on 10× platform to precisely dissect the gene functions in various tissues and early developmental stages of bamboo shoots. Our comprehensive analysis reveals distinct cell trajectories during shoot development, uncovering critical genes and pathways involved in procambium differentiation, intercalary meristem formation, and vascular tissue development.

 (Poaceae, Bambusoideae, Arundinarieae), a new species from southern China revealed by morphological and molecular evidence.

The genus T. H. Wen, endemic to southern China, is a small but taxonomically problematic genus of Arundinarieae (Poaceae, Bambusoideae).

Comparative phylogenomic analyses and co-expression gene network reveal insights in flowering time and aborted meiosis in woody bamboo, 'Xia Zao' ZSX.

Woody bamboos have peculiar flowering characteristics with intervals ranging from several years to more than 100 years. Elucidating flowering time and reproductive development in bamboo could be beneficial for both humans and wildlife. To identity the mechanisms responsible for flowering time and embryo abortion in 'Xia Zao' ZSX, a transcriptome sequencing project was initiated to characterize the genes involved in developing flowers in this bamboo species.

A spatiotemporal atlas of organogenesis in the development of orchid flowers.

Development of floral organs exhibits complex molecular mechanisms involving the co-regulation of many genes specialized and precisely functioning in various tissues and developing stages. Advance in spatial transcriptome technologies allows for quantitative measurement of spatially localized gene abundance making it possible to bridge complex scenario of flower organogenesis with genome-wide molecular phenotypes. Here, we apply the 10× Visium technology in the study of the formation of floral organs through development in an orchid plant, Phalaenopsis Big Chili.

The nearly complete assembly of the Cercis chinensis genome and Fabaceae phylogenomic studies provide insights into new gene evolution.

Fabaceae is a large family of angiosperms with high biodiversity that contains a variety of economically important crops and model plants for the study of biological nitrogen fixation. Polyploidization events have been extensively studied in some Fabaceae plants, but the occurrence of new genes is still concealed, owing to a lack of genomic information on certain species of the basal clade of Fabaceae. Cercis chinensis (Cercidoideae) is one such species; it diverged earliest from Fabaceae and is essential for phylogenomic studies and new gene predictions in Fabaceae.

The complete chloroplast genome of (Bambusoideae), a dominant bamboo species in limestone mountains endemic to China.

is a dominant species in limestone mountains endemic to China. Here, we characterized its complete chloroplast genome. It is a circular DNA molecule of 139,689 bp in length, including a pair of 21,798 bp inverted repeats (IRs), a 12,872 bp small single-copy (SSC) region and an 83221 bp large single-copy (LSC) region.

The complete chloroplast genome sequence of (Bambusoideae: Arundinarieae): a shrubby bamboo endemic to China.

The complete chloroplast genome sequence of , firstly determined here, is 139,705 bp in length, inclusive of a pair of inverted repeat (IR, 21,817 bp) regions separated by a small single copy (SSC, 12,803 bp) and a large single copy (LSC, 83,268 bp). It contains 132 genes, such as 85 CDS, 8 rRNA genes, and 39 tRNA genes, respectively. The phylogenetic analysis shows that is highly clustered in the clade (III) of Arundinarieae, sister to the clade of .

Complete chloroplast genome of a rare deciduous tree species, (Magnoliaceae).

The complete chloroplast genome of a rare deciduous tree species with ornamental value, , was first determined. It was 160,170 bp in length, including a pair of inverted repeat (IR, 26,567 bp) regions separated by a small single copy (SSC, 18,842 bp) sequence and a large single copy (LSC, 88,194 bp) sequence. The chloroplast genome contained 132 genes, consisting of 87 CDS, 8 rRNA genes, and 37 tRNA genes.

Chloroplast genomic data provide new and robust insights into the phylogeny and evolution of the Ranunculaceae.

The family Ranunculaceae, a member of early-diverging eudicots that is increasingly being used as a model for the study of plant developmental evolution, has been the focus of systematic studies for centuries. Recent studies showed that the family can be divided into 14 tribes, with Glaucideae, Hydrastideae, and Coptideae being the successive basal-most lineages. The relationships among the remaining 11 tribes, however, remain controversial, so that a clear picture of character evolution within the family is still lacking.

A well-resolved fern nuclear phylogeny reveals the evolution history of numerous transcription factor families.

Ferns account for 80% of nonflowering vascular plant species and are the sister lineage of seed plants. Recent molecular phylogenetics have greatly advanced understanding of fern tree of life, but relationships among some major lineages remain unclear. To better resolve the phylogenetic relationships of ferns, we generated transcriptomes from 125 ferns and two lycophytes, with three additional public datasets, to represent all 11 orders and 85% of families of ferns.

Degradation of unmethylated miRNA/miRNA*s by a DEDDy-type 3' to 5' exoribonuclease Atrimmer 2 in .

The 3' end methylation catalyzed by HUA Enhancer 1 (HEN1) is a crucial step of small RNA stabilization in plants, yet how unmethylated small RNAs undergo degradation remains largely unknown. Using a reverse genetic approach, we here show that Atrimmer 2 (ATRM2), a DEDDy-type 3' to 5' exoribonuclease, acts in the degradation of unmethylated miRNAs and miRNA*s in Loss-of-function mutations in ATRM2 partially suppress the morphological defects caused by HEN1 malfunction, with restored levels of a subset of miRNAs and receded expression of corresponding miRNA targets. Dysfunction of ATRM2 has negligible effect on miRNA trimming, and further increase the fertility of , a mutant with an almost complete abolishment of miRNA uridylation, indicating that ATRM2 may neither be involved in 3' to 5' trimming nor be the enzyme that specifically degrades uridylated miRNAs.

Widespread Whole Genome Duplications Contribute to Genome Complexity and Species Diversity in Angiosperms.

Gene duplications provide evolutionary potentials for generating novel functions, while polyploidization or whole genome duplication (WGD) doubles the chromosomes initially and results in hundreds to thousands of retained duplicates. WGDs are strongly supported by evidence commonly found in many species-rich lineages of eukaryotes, and thus are considered as a major driving force in species diversification. We performed comparative genomic and phylogenomic analyses of 59 public genomes/transcriptomes and 46 newly sequenced transcriptomes covering major lineages of angiosperms to detect large-scale gene duplication events by surveying tens of thousands of gene family trees.

MeioBase: a comprehensive database for meiosis.

Meiosis is a special type of cell division process necessary for the sexual reproduction of all eukaryotes. The ever expanding meiosis research calls for an effective and specialized database that is not readily available yet. To fill this gap, we have developed a knowledge database MeioBase (http://meiosis.

Disruption of the petal identity gene APETALA3-3 is highly correlated with loss of petals within the buttercup family (Ranunculaceae).

Absence of petals, or being apetalous, is usually one of the most important features that characterizes a group of flowering plants at high taxonomic ranks (i.e., family and above).

Divergence of duplicate genes in exon-intron structure.

Gene duplication plays key roles in organismal evolution. Duplicate genes, if they survive, tend to diverge in regulatory and coding regions. Divergences in coding regions, especially those that can change the function of the gene, can be caused by amino acid-altering substitutions and/or alterations in exon-intron structure.

Petal-specific subfunctionalization of an APETALA3 paralog in the Ranunculales and its implications for petal evolution.

• The petals of the lower eudicot family Ranunculaceae are thought to have been derived many times independently from stamens. However, investigation of the genetic basis of their identity has suggested an alternative hypothesis: that they share a commonly inherited petal identity program. This theory is based on the fact that an ancient paralogous lineage of APETALA3 (AP3) in the Ranunculaceae appears to have a conserved, petal-specific expression pattern.

The SEPALLATA-like gene OsMADS34 is required for rice inflorescence and spikelet development.

Grass plants develop distinct inflorescences and spikelets that determine grain yields. However, the mechanisms underlying the specification of inflorescences and spikelets in grasses remain largely unknown. Here, we report the biological role of one SEPALLATA (SEP)-like gene, OsMADS34, in controlling the development of inflorescences and spikelets in rice (Oryza sativa).