Search Results (3,053)

This study conducted a genome-wide identification and functional analysis of the glutathione S-transferase (GST) gene family in the xerophytic desert shrub Reaumuria soongorica. A total of 67 GST genes were identified, classified into seven subfamilies, including Phi and Tau, with family expansion primarily attributed to small-scale duplication events. The findings revealed that ResoGST52, a member of the Tau subfamily, serves as a core gene in drought response, exhibiting significant upregulation of 2.40-fold in leaves and 9.01-fold in roots under drought stress. Mechanistic investigations indicated that the expression of ResoGST52 is likely directly regulated by the transcription factor ResoDof17, with specific hydrogen bonding interactions identified between the two. Co-expression network analysis further demonstrated that ResoGST52 cooperates with key pathways such as plant hormone signaling, MAPK cascades, and glutathione metabolism to collectively respond to drought stress. Notably, evolutionary analysis revealed that ResoGST52 has undergone positive selection, with three positively selected sites identified. Among these, the p.Ala115Ser mutation increases the volume of the protein’s active site pocket, while the remaining mutations enhance surface hydrophobicity, thereby improving protein stability and catalytic efficiency under extreme drought conditions. In summary, this study not only systematically identifies the GST gene family in R. soongorica but also elucidates the central role of ResoGST52 in drought adaptation through multiple layers—from transcriptional regulation and co-expression networks to protein structural adaptive evolution—providing valuable candidate genes and theoretical insights for genetic improvement of drought tolerance in crops. Full article

CCCH zinc-finger proteins constitute a unique class of transcription factors that play vital roles in mediating plant tolerance to biotic and abiotic stresses and regulating various physiological and developmental processes. This study systematically identified and characterized the apple (Malus domestica) CCCH (MdC3H) gene family, aiming to elucidate its evolutionary patterns, functional characteristics, and regulatory mechanisms under drought stress. Genome-wide analysis revealed 85 MdC3H genes, which were unevenly distributed across chromosomes and exhibited significant differences in physiochemical properties, suggesting functional divergence. Phylogenetic analysis classified these genes into 9 subfamilies with distinct conservation. Collinearity analysis indicated a close evolutionary relationship between apple and Malus sieversii, with 150 collinear gene pairs identified, highlighting the conservation of the C3H gene family during speciation. Cis-acting element prediction in promoter regions uncovered abundant stress-responsive elements (e.g., ABRE, DRE, MYB), implying the potential of MdC3H genes in coordinating environmental signals. Functional verification demonstrated that MdC3H49, a key member of the family, is localized in the nucleus and possesses transcriptional activation activity. Overexpression of MdC3H49 in Arabidopsis and apple calli significantly enhanced drought tolerance, characterized by reduced malondialdehyde (MDA) content, relative electrical conductivity, and increased proline accumulation. Mechanistic studies revealed that MdC3H49 directly regulates the expression of MdP5CS, a core gene in proline biosynthesis, thereby strengthening the cellular antioxidant capacity and mitigating drought-induced damage. Collectively, this study establishes MdC3H49 as a critical regulator in apple drought stress response, providing valuable insights into the molecular mechanisms underlying abiotic stress tolerance in perennial plants and laying a foundation for genetic improvement of drought resistance in apple breeding. Full article

Salt stress is a major abiotic factor that significantly limits crop yields worldwide. Late embryogenesis abundant (LEA) proteins, which are widely present across diverse organisms, play critical and multifaceted roles in plant responses to abiotic stress. However, only a few salt tolerance-related HvLEA genes have been identified in barley. In this study, we characterized 107 HvLEA proteins in barley, which were classified into eight groups and found to be distributed across all seven chromosomes. RNA-Seq analysis of root and leaf tissues from the cultivar “Golden Promise” at 12, 48, and 120 h after salt stress treatment identified 69 differentially expressed HvLEA genes across both tissues. Among these, 41 HvLEA genes were commonly differentially expressed in leaves and roots. Six genes (HvDHN2, HvDHN5, HvDHN10, HvLEA1.1, HvLEA1.6, and HvSMP2) were extremely up-regulated after salt stress in both roots and leaves, with log2FC values exceeding 10, indicating their potential key roles in salt stress response. qPCR validation of selected genes confirmed expression trends consistent with the RNA-Seq data. Database predictions and co-expression network analysis suggested that, in addition to potential protein interactions within the same family, these genes may interact with partners such as cysteine-rich receptor kinases, zinc finger proteins, calcium-binding EF-hand family proteins, NAC domain-containing proteins, and glycosyltransferases. This study identified key HvLEA genes involved in salt stress response and provided valuable genetic resources for improving barley tolerance through molecular breeding. Full article

Background: INDETERMINATE DOMAIN proteins (IDDs) are a plant-specific transcription factor family, and members of this family play crucial roles in regulating growth and development as well as environmental adaptation. However, a comprehensive analysis of the IDD family in soybean [Glycine max (L.) Merrill] is limited. Methods and Results: A total of 27 GmIDD genes were identified in the soybean genome, unevenly distributed across 14 chromosomes, and their encoded proteins all harbor a conserved INDETERMINATE (ID) domain with two Cys2His2 (C2H2) and two Cys2HisCys (C2HC) zinc finger motifs. Phylogenetic analysis classified these GmIDD genes into three subgroups. Soybean GmIDD genes exhibit high homology with their Arabidopsis thaliana IDD counterparts. Cis-acting element analysis indicated that the promoters of GmIDD genes are enriched in light-responsive elements (such as Box4), hormone-responsive elements (such as ABRE and AuxRR-core), and abiotic stress-responsive elements (such as MBS and LTR). The qRT-PCR results showed that GmIDD3/5/14/22/26 were upregulated under salt stress, while GmIDD8/9/10/12/16/17/19/20/23/24/25/27 were obviously downregulated during treatment. Under drought stress, the expression levels of GmIDD4/6/7/10/14/16/19/22/24/25/26/27 were upregulated during the treatment. The expression levels of GmIDD1/2/3/4/12/14/15/16/17/18/22/23/25/26 were induced by short-day conditions, whereas GmIDD9/13/19/21 were induced by long-day conditions in soybean leaves. Conclusions: This study provides a theoretical basis for further understanding the functions of the soybean IDD gene family in abiotic stress tolerance and photoperiod adaptability. Full article

Bacterial stem and root rot (BSRR), caused by Dickeya dadantii, poses a severe threat to global sweetpotato production, yet the genetic architecture underlying resistance remains elusive. To dissect these mechanisms, we conducted a high-resolution genome-wide association study (GWAS) on 135 diverse accessions, integrating two-year field phenotyping with best linear unbiased prediction (BLUP) and 6.8 million single-nucleotide polymorphism (SNP) markers. This approach mapped nine quantitative trait loci (QTLs) exhibiting significant allelic dosage-dependent effects, with the major locus, qBSRR.6.1 was the primary discriminator between resistant and susceptible genotypes. Crucially, transcriptomic profiling within these loci revealed distinct expression patterns: IbTCP5 and IbERF003 (located in qBSRR.5.1 and qBSRR.6.2) were highly expressed in the susceptible cultivar ‘Xinxiang’ but suppressed in the resistant ‘Guangshu87’. Furthermore, BSRR challenge identified IbPUB4, IbKCS5, and IbLig1 as priority candidate genes involved in defense, with expression patterns suggesting roles in ubiquitin-mediated protein turnover, cuticular wax biosynthesis, and DNA repair, respectively. In stark contrast, IbPUB25 was constitutively upregulated in ‘Xinxiang’, potentially acting as a negative regulator of immunity via degradation of target proteins. These findings elucidate the polygenic, dosage-sensitive nature of BSRR resistance and prioritize specific targets for future functional characterization. Pyramiding favorable alleles of positive candidates while silencing potential negative regulators like IbPUB25 offers a promising avenue for developing durable, high-resistance sweetpotato varieties. Full article

Single-cell RNA-sequencing (scRNA-seq) studies over the past several years have provided unprecedented resolution into the transcriptomic landscape of both major and minor salivary glands. This technology enables the identification of diverse and functionally specialized cell populations that underlie glandular architecture and physiology. Increasingly, scRNA-seq has become an integral component of experimental design, used not only to validate prior observations but also to uncover novel cell types, pathways, and molecular regulatory mechanisms. As a result, a growing number of publicly available datasets now encompass a wide spectrum of biological contexts including homeostasis, disease, and regeneration. However, inconsistencies in data processing and incomplete reporting of experimental methods pose challenges for reproducibility and limit the ability to distinguish high-quality datasets. As single-cell technologies continue to evolve and become more accessible, their application in salivary gland research is expected to expand, offering deeper insight into both basic biology and clinical translation. This review compiles and summarizes findings from a growing body of scRNA-seq studies of the salivary glands, highlights current limitations, provides methodological considerations, and expounds on key cellular and genomic discoveries to help guide future investigations. Full article

Background: Tartary buckwheat (Fagopyrum tataricum) serves as an excellent model for studying plant water adaptation mechanisms due to its exceptional drought tolerance. While aquaporins (AQPs) mediate the transmembrane transport of water and solutes in plants, their fine-tuned regulatory networks underlying stress resilience in Tartary buckwheat remain largely elusive. Methods: Here, we combined bioinformatics and transcriptomics to systematically identify 30 highly conserved FtAQP genes at the genome-wide level. Results: Cross-validated by qRT-PCR, our analysis revealed their distinct expression patterns across different organs. Based on our transcriptomic data, we hypothesize that FtAQP family members potentially participate in a coordinated whole-plant water management network through differential spatiotemporal expression. Specifically, the robust transcription of FtAQP8, FtAQP12, and FtAQP28 in roots is associated with the initial water uptake process. As water undergoes long-distance transport, the synergistic upregulation of FtAQP13, FtAQP17, FtAQP20, and FtAQP29 in the stem suggests a potential role in facilitating critical lateral water flow. Furthermore, during reproductive development, FtAQP27 exhibits extreme tissue specificity in floral organs, implying its possible involvement in maintaining local osmotic homeostasis. Furthermore, the promoter regions of FtAQPs are highly enriched with cis-acting elements responsive to light, abscisic acid (ABA), and cold stress, suggesting they are intimately regulated by a coupling of endogenous phytohormones and environmental cues. Conclusions: Ultimately, this study provides valuable insights into the potential molecular basis of multidimensional water regulation in Tartary buckwheat, and identifies candidate genetic targets for improving water use efficiency in dryland agriculture through the precise manipulation of aquaporins. Collectively, while these observational findings provide valuable predictive models, future in vivo experimental validations are required to confirm their exact biological functions. Full article

Objective: In this study, the heat shock transcription factor (HSF) gene family in Ganoderma lucidum was systematically characterized. Using genomic and transcriptomic data, we identified HSF family members and investigated their expression patterns under temperature stress and their potential regulatory roles in triterpenoid biosynthesis. Methods: A genome-wide identification of HSF genes in G. lucidum was performed using bioinformatic approaches. A phylogenetic tree was constructed, and conserved motifs, gene structures, and protein tertiary structures were predicted. The relative expression levels of HSF genes and key mevalonate (MVA) pathway enzyme genes were examined by a quantitative real-time reverse transcription polymerase chain reaction (qRT-PCR) in mycelia subjected to temperature stress. Total triterpenoid content in fermented mycelia under temperature stress was determined using the vanillin–glacial acetic acid method. Results: Eight HSF family members (GlHSF1–GlHSF8) were identified in G. lucidum. Phylogenetic analysis revealed that GlHSF proteins were closely related to PoHSF from Pleurotus ostreatus. Transcriptomic analysis showed that HSF genes exhibited relatively high expression levels during the mature stage while being barely expressed during the mycelial stage. Under heat stress (42 °C), most GlHSF genes peaked at 18 h, with GlHSF2 showing the most pronounced response (approximately 13-fold upregulation). Downstream MVA pathway genes, including IDI, PMK, and MVD, were significantly upregulated at 24 h, whereas the upstream rate-limiting enzyme gene HMGR was continuously suppressed. Despite HMGR suppression, total triterpenoid content did not decrease significantly, likely due to the activation of downstream genes. Under cold stress (14 °C), the expression of most GlHSF and MVA pathway genes decreased, accompanied by a significant reduction in total triterpenoid content. Conclusions: The HSF gene family was identified in the G. lucidum genome. Based on expression analysis, GlHSF2 showed the strongest response under heat stress, and its expression peak was correlated with the sequential activation of downstream genes in the MVA pathway. This suggests that GlHSF2 acts as a potential key regulatory node, differentially regulating upstream and downstream MVA pathway genes to influence triterpenoid biosynthesis under heat stress. These findings provide a theoretical basis for future research on the biological functions of GlHSF homeostasis. Full article

Pigeonpox is a significant infectious disease caused by Pigeonpox virus (PPV), which severely impacts the pigeon industry. Current control methods primarily rely on heterologous vaccines, such as those derived from avian poxviruses, but their protection is limited, creating an urgent need for the development of a specific vaccine. In this study, 720 samples collected from several regions of China between 2022 and 2023 were tested for PPV, followed by virus isolation, identification, and genetic evolutionary analysis. Based on these findings, complete genome sequencing and attenuation of the representative BJ-02 isolate were conducted, and the potential of this strain as a candidate for an attenuated vaccine was preliminarily evaluated. The survey showed PCR positive rates of 9.05%, 16.11%, and 12.50% in samples from Beijing, Guangdong, and Hainan, respectively. Six viral strains were isolated, all of which produced typical lesions on chorioallantoic membranes (CAM) and chicken embryo fibroblasts (CEF). Phylogenetic analysis based on the P4b gene revealed that the six viruses clustered within the same evolutionary branch, closely related to PPV and penguinpox virus strains from South Africa, India, and Taiwan, China. Complete genome sequencing of the BJ-02 strain showed its genomic structure to be similar to that of other fowlpox viruses, with some differences. After serial passage in CAM, PEF and CEF, the BJ-02 SD55 high-passage strain adapted well to in vitro culture, exhibited significantly reduced pathogenicity in chicken embryos and pigeons, and showed no reversion to virulence after five consecutive back-passages. Animal immunization tests demonstrated that the BJ-02 SD55 suspected attenuated strain induced specific antibodies and provided 100% protection against challenge with the virulent strain. In conclusion, PPV is widely prevalent in China. The BJ-02 strain, successfully isolated and attenuated through serial passage, demonstrates excellent immunogenicity and high safety, making it a promising candidate for a specific pigeonpox vaccine. Additionally, the complete genome characterization of BJ-02 contributes to the avian poxvirus genome database and provides critical data to support research on viral pathogenesis and the development of viral vector vaccines for avian and potentially mammalian species. Full article

Background: Fruit texture is a major component of plum quality, affecting both consumer acceptance and postharvest behavior. Pectin methylesterases (PMEs) play important roles in cell-wall pectin modification and are therefore likely to contribute to plum fruit texture development and ripening-associated softening. However, the PME gene family has not yet been comprehensively investigated in plum (Prunus salicina L.). Methods: In the present study, a chromosome-level plum genome was used to survey this gene family at the whole-genome scale. Phylogenetic relationships, chromosomal positions, exon–intron organization, conserved motifs, domain architectures, gene duplication, and cis-elements were analyzed. Four flesh texture traits were measured in 55 plum accessions to characterize texture variation and select two representative cultivars with contrasting flesh textures for further molecular analysis. Based on the clustering results, ‘WSCL’ and ‘FR’ were selected for expression profiling during fruit development and subsequent correlation analysis with texture traits. Results: A total of 46 PsPME genes were identified. Phylogenetic analysis classified them into four major subgroups. Structural analyses indicated an overall conserved family framework, although noticeable variation was retained among individual members. Dispersed duplication made the largest contribution to family expansion, and most duplicated pairs appeared to have evolved under purifying selection. Correlation analysis showed that PsPME20, PsPME22, and PsPME25 were significantly negatively correlated with flesh firmness, while PsPME20 was additionally linked to flesh compactness and flesh fragility. Conclusions: Overall, this study clarifies the structural and evolutionary characteristics of the PsPME family and identifies candidate genes that may contribute to texture differences in plum, offering a basis for future functional studies and breeding programs. Full article

C3H-type zinc finger proteins play essential roles in plant responses to abiotic stresses, as well as in the regulation of growth, development, and signal transduction. Birch (Betula platyphylla Suk.), an ecologically adaptable tree species widely distributed in northern regions, has not yet been systematically characterized for its C3H gene family. In this study, a total of 15 BpC3Hs were identified from a genome-wide analysis of birch. Their physiochemical properties, gene structures, conserved motifs and domains were systematically analyzed. Promoter analysis identified cis-acting elements associated with stress responses, hormone signaling, and developmental regulation. Transcriptome data further showed that most BpC3Hs were responsive to salt, drought, high/low-temperature stresses, and light/dark treatment, and showed differential expression patterns in tension wood and opposite wood. Additionally, they displayed stage-specific expression patterns during male inflorescence development. This study lays a foundation for future functional characterization of the C3H gene family in birch and its application in molecular breeding for stress resistance. Full article

The sucrose synthase (SUS) gene family plays a pivotal role in plant carbon metabolism, growth, and development. In this study, we identified 65 SUS genes across six Brassica species (B. rapa, B. nigra, B. oleracea, B. juncea, B. napus, and B. carinata), and systematically analyzed their structural characteristics, evolutionary history, and expression profiles. Phylogenetic analysis classified these genes into three subfamilies (SUSI, SUSII, and SUSIII). SUS4 orthologs (from SUSI subfamily) are completely lost in Brassica, and total SUS gene numbers are just 6–7 in Brassica diploid species, though the SUSIII subfamily exhibits significant expansion in Brassica polyploid species. Selection pressure analysis (Ka/Ks) revealed that the Brassica SUS family has primarily undergone purifying selection, although certain members show evidence of adaptive evolution. Comprehensive expression profiling and qRT-PCR validation demonstrated the functional diversification of BnSUS genes in tissue specificity and responses to hormonal and abiotic stimuli. SUSI genes BnSUS1-1/2/3/4 are predominantly expressed in vegetative tissues and flowers; SUSII genes BnSUS2-1/2 and BnSUS3-1/2 are reproductive-organ-specific, while SUSIII genes BnSUS5-1/2 and BnSUS6-1/2/3/4 show young-plant-specific weak expression. BnSUS family genes are generally upregulated by ABA, TZ and GA but downregulated by IAA, ACC, BL and JA. Salt, drought, freezing and cold mainly upregulate the BnSUS family, heat downregulates it, and osmotic stress exerts both effects. Correspondingly, Brassica SUS promoters are enriched with light-responsive (G-box, Box-4), hormone-responsive (ABRE, CGTCA-motif) and anaerobic-induction (ARE) elements. Functional characterization demonstrated that the ABA-responsive gene BnSUS3-2 significantly improved tolerance to osmotic and ionic stresses by promoting root growth in transgenic A. thaliana seedlings. These findings underscore the essential roles of BnSUS genes in maintaining cellular homeostasis and provide a theoretical foundation for the genetic improvement of carbon metabolism and stress resilience in Brassica crops. Full article

At present, the characteristics of key enzyme genes in the upstream pathway for triterpenoid saponin biosynthesis in P. grandiflorum, as well as their expression patterns over the growth duration, have not been systematically analyzed. This study, at the whole-genome level, conducts the first bioinformatics and expression analyses of the SS and SE gene families in P. grandiflorum. Four PgSS and seven PgSE genes were identified and distributed across six chromosomes. Members within the same subfamily exhibited highly conserved sequences and structures, while distinct structural divergence was observed between different subfamilies. Phylogenetic analysis showed that PgSS and PgSE genes were closely related to those of dicotyledons such as Panax ginseng and Polygala tenuifolia, suggesting high evolutionary conservation. Promoter analysis revealed abundant light- and hormone-responsive elements and MYB/MYC binding sites, indicating regulation by multiple signals. Protein secondary structures were dominated by the Alpha helix and were structurally stable. Quantitative real-time polymerase chain reaction (qPCR) demonstrated that expression levels of PgSS and PgSE in one-year-old Platycodonis Radix were significantly higher than in perennial Platycodonis Radix, especially for the PgSE family. This study characterized the basic biological features and growth-stage-dependent expression patterns of the SS and SE gene families in P. grandiflorum. The results identify key candidate genes and molecular targets for regulating triterpenoid saponin biosynthesis, and provide data supporting quality improvement and active metabolite research in this medicinal plant. Full article

Secondary cell wall (SCW) formation and lignin biosynthesis are critical biological processes that determine wood properties. Masson pine (Pinus massoniana Lamb) is a fast-growing conifer species with significant economic value for the pulp and paper industry. While R2R3-MYB transcription factors are known as master regulators of SCW biosynthesis, the specific R2R3-MYB members regulating lignin formation in Masson pine remain largely uncharacterized. In this study, we identified 317 R2R3-MYB genes in the Masson pine genome. Phylogenetic analysis revealed that PmMYB289, a member of the P20 subgroup, is highly homologous to the Arabidopsis SCW regulators AtMYB52 and AtMYB54. Expression profiling demonstrated that PmMYB289 is predominantly expressed in highly lignified old stems. Transcriptional activation assays confirmed that PmMYB289 lacks autoactivation activity. Subcellular localization analysis revealed that PmMYB289 was localized to the nucleus. Ectopic overexpression of PmMYB289 in tobacco (Nicotiana benthamiana) resulted in dwarfed plant growth, reduced stem diameter, and curled leaves. Molecular analysis of these transgenic lines showed a significant downregulation of most key SCW biosynthetic genes, with the exception of NbPAL1. These findings indicate that PmMYB289 acts as a crucial transcriptional repressor in SCW biosynthesis, providing valuable genetic resources for the molecular breeding of superior Masson pine varieties. Full article

Soybean (Glycine max L. Merr.) is one of the most important legume crops globally, providing high-quality plant protein and oil for humans and livestock, and playing a crucial role in nitrogen fixation within agricultural ecosystems. The seeds contain about 35–40% protein by dry weight, with 65–80% of this being seed storage proteins (SSPs). These proteins mainly consist of 11S globulin (glycinin) and 7S β-conglycinin, which accumulate significantly in protein bodies during seed development, providing essential nitrogen and amino acids for seed germination and early seedling growth. Additionally, the composition and structure of SSPs directly determine the nutritional value, processing functionalities (such as emulsification, gelation, and solubility), and potential allergenicity of soybean products. In this study, we conducted a detailed analysis of the structural characteristics, chromosomal localization, phylogenetic relationships, and tissue expression patterns of members of the soybean Gy gene family, laying a theoretical foundation for further exploration of the biological functions of Gy genes in soybeans. We performed comprehensive genomic identification, expression analysis, and subcellular localization of the soybean Gy gene family. The results showed that the seven soybean Gy genes are unevenly distributed across different chromosomes and exhibit distinct expression patterns in soybean seeds, suggesting they may have different roles during seed development. Subcellular localization experiments indicated that the GmGy1 gene might play an important role during seed development. These findings provide significant insights into the functions of the Gy gene family in soybean growth and development and offer potential candidate gene targets for soybean molecular breeding. Full article