Global analysis of seed transcriptomes reveals a novel PLATZ regulator for seed size and weight control in soybean

RcPLATZ8 as a novel negative regulator of flowering in Rosa chinensis

KEY MESSAGE

Comprehensive analysis of the RcPLATZ gene family in Rosa chinensis reveals RcPLATZ8 as a novel negative regulator of flowering, offering insights for targeted breeding to manipulate flowering traits. Flowering regulation in Rosa chinensis is essential for improving ornamental and commercial traits, but its molecular mechanisms remain poorly understood. In this study, we identified and characterized ten members of the PLANT AT-RICH SEQUENCE AND ZINC-BINDING (PLATZ) protein family in R. chinensis through genome-wide analysis and protein domain validation using the Pfam database. Among these, we focused on RcPLATZ8, a novel negative regulator of flowering. Expression analysis via RT-qPCR revealed that RcPLATZ8 is predominantly expressed in floral organs, including stamens, pistils, and petals, and exhibits significant responsiveness to key plant hormones, such as abscisic acid (ABA), gibberellins (GA), and jasmonic acid (JA). Functional assays showed that overexpression of RcPLATZ8 in Arabidopsis resulted in delayed flowering and increased leaf number, whereas silencing RcPLATZ8 in R. chinensis led to early flowering. Furthermore, Weighted Gene Co-expression Network Analysis (WGCNA) identified that RcPLATZ8 is part of the 'red module,' which is strongly associated with flowering-time regulatory genes, including SHORT VEGETATIVE PHASE (SVP). These findings provide new insights into the molecular regulation of flowering in roses, demonstrating that RcPLATZ8 may plays a key role in integrating hormonal signals and floral development. Our study not only expands the functional understanding of the PLATZ family but also offers potential strategies for molecular breeding aimed at improving flowering traits for horticultural applications.

PLATZ transcription factors and their emerging roles in plant responses to environmental stresses

Plant A/T-rich sequence- and zinc-binding (PLATZ) family proteins represent a novel class of plant-specific transcription factors that bind to A/T-rich sequences. Advances in high-throughput sequencing and bioinformatics analyses have facilitated the identification of numerous PLATZ proteins across various plant species. Over the last decade, accumulating evidence from omics analyses, genetics studies, and gain- and loss-of function investigations has indicated that PLATZ proteins play crucial roles in the complex regulatory networks governing plant development and adaptation to environmental stress. Recently, an excellent review has been published highlighting the roles of PLATZ proteins in controlling plant developmental processes. However, a comprehensive review specifically addressing the molecular mechanisms by which these proteins drive their functions in plant responses to environmental cues is currently lacking. In this review, we summarize the characteristics and identification of PLATZ proteins, emphasizing their significance in stress responses. We also highlight the crosstalk between PLATZ proteins and phytohormones. Furthermore, we discuss the downstream target genes, interacting partners, and upstream regulatory mechanisms associated with PLATZ proteins, providing a thorough understanding of their multifaceted roles in plants.

Unlocking soybean potential: genetic resources and omics for breeding

Soybean (Glycine max) is a vital foundation of global food security, providing a primary source of high-quality protein and oil for human consumption and animal feed. The rising global population has significantly increased the demand for soybeans, emphasizing the urgency of developing high-yield, stress-tolerant, and nutritionally superior cultivars. The extensive collection of soybean germplasm resources-including wild relatives, landraces, and cultivars-represents a valuable reservoir of genetic diversity critical for breeding advancements. Recent breakthroughs in genomic technologies, particularly high-throughput sequencing and multi-omics approaches, have revolutionized the identification of key genes associated with essential agronomic traits within these resources. These innovations enable precise and strategic utilization of genetic diversity, empowering breeders to integrate traits that improve yield potential, resilience to biotic and abiotic stresses, and nutritional quality. This review highlights the critical role of genetic resources and omics-driven innovations in soybean breeding. It also offers insights into strategies for accelerating the development of elite soybean cultivars to meet the growing demands of global soybean production.

Soybean2035: A decadal vision for soybean functional genomics and breeding

Soybean, the fourth most important crop in the world, uniquely serves as a source of both plant oil and plant protein for the world's food and animal feed. Although soybean production has increased approximately 13-fold over the past 60 years, the continually growing global population necessitates further increases in soybean production. In the past, especially in the last decade, significant progress has been made in both functional genomics and molecular breeding. However, many more challenges should be overcome to meet the anticipated future demand. Here, we summarize past achievements in the areas of soybean omics, functional genomics, and molecular breeding. Furthermore, we analyze trends in these areas, including shortages and challenges, and propose new directions, potential approaches, and possible outputs toward 2035. Our views and perspectives provide insight into accelerating the development of elite soybean varieties to meet the increasing demands of soybean production.

Genome-Wide Study of Plant-Specific PLATZ Transcription Factors and Functional Analysis of OsPLATZ1 in Regulating Caryopsis Development of Rice (Oryza sativa L.)

Plant A/T-rich sequence- and zinc-binding protein (PLATZ) is a type of plant-specific zinc-dependent DNA-binding protein that binds to A/T-rich DNA sequences. This family is essential for plant growth, development, and stress response. In this study, 15 OsPLATZs were identified in the rice genome with complete PLATZ-conserved domains by CD-search, similar to those found in angiosperms. Multi-species phylogenetic analysis showed that PLATZs were conserved in photosynthetic organisms, and an evolutionary branch unique to angiosperms was identified among members of the PLATZ family. Fifteen OsPLATZs were represented by five groups, each with distinct characteristics. An analysis of protein structures and sequence motifs showed that OsPLATZs were similar within groups, but varied between them. The expression profile and qRT-PCR results showed that OsPLATZs had distinct expression patterns in different tissues, with some responding to stress induction. Most of the OsPLATZs localized to the nuclei, and were predicted to bind to DNA sequences by AlphaFold3, suggesting that they likely function as conventional transcription factors. We also identified OsPLATZ1, a caryopsis-specific gene that regulates grain filling and caryopsis development in rice. This research lays the foundation for exploring the structural diversity, evolutionary traits, expression profile, and possible roles of PLATZ transcription factors in rice.

Genome-wide identification and salt stress expression analysis of the PLATZ transcription factor genes in Betula platyphylla

The PLATZ (Plant AT rich protein and zinc binding protein) transcription factor, which is a type of plant specific zinc dependent DNA binding protein, participates in regulating the process of plant growth and environmental stress responses. In order to clarify the characteristics of the PLATZ family genes in birch (Betula platyphylla), the members of the PLATZ family were screened and analyzed in this study. Totals of ten BpPLATZ genes were identified in birch genome and classified into five groups base on phylogenetic relationship, BpPLATZ genes in the same group usually possess a similar motif composition, exon or intron number. These ten genes distributed on eight chromosomes of fourteen chromosomes of birch. In addition, various cis-elements were distributed in the promoter regions of BpPLATZs, especially with abundant MYC, ABRE and MYB, which were reported to be involved in salt stress responses. The RT-qPCR analysis results show that most genes have the higher expression levels in the roots compared to leaves and stems in birch. BpPLATZ3, BpPLATZ5, BpPLATZ6, BpPLATZ7 and BpPLATZ8 are significantly induced expressed response to salt stress. These studies provide a basis for the further functional study of the BpPLATZ genes.

Comprehensive analysis of PLATZ family genes and their responses to abiotic stresses in Barley

BACKGROUND

Plant A/T-rich protein and zinc-binding protein (PLATZ) transcription factors are pivotal regulators in various aspects of plant biology, including growth, development, and responses to environmental stresses. While PLATZ genes have been extensively studied and functionally characterized in various plants, limited information is available for these genes in barley.

RESULTS

Here, we discovered a total of 11 PLATZ genes distributed across seven chromosomes in barley. Based on phylogenetic and conserved motif analysis, we classified PLATZ into five subfamilies, comprising 3, 1, 2, 1 and 4 genes, respectively. Analysis of gene structure demonstrated that these 11 HvPLATZ genes typically possessed two to four exons. Most HvPLATZ genes were found to possess at least one ABRE cis-element in their promoter regions, and a few of them also contained LTR, CAT-box, MRE, and DRE cis-elements. Then, we conducted an exploration of the expression patterns of HvPLATZs, which displayed notable differences across various tissues and in response to abiotic stresses. Functional analysis of HvPLATZ6 and HvPLATZ8 in yeast cells showed that they may be involved in drought tolerance. Additionally, we constructed a regulatory network including miRNA-targeted gene predictions and identified two miRNAs targeting two HvPLATZs, such as hvu-miR5053 and hvu-miR6184 targeting HvPLATZ2, hvu-miR6184 targeting HvPLATZ10.

CONCLUSION

In summary, these findings provide valuable insights for future functional verification of HvPLATZs and contribute to a deeper understanding of the role of HvPLATZs in response to stress conditions in barley.

Identification and Functional Characterization of Abiotic Stress Tolerance-Related PLATZ Transcription Factor Family in Barley (Hordeum vulgare L.)

Plant AT-rich sequence and zinc-binding proteins (PLATZs) are a novel category of plant-specific transcription factors involved in growth, development, and abiotic stress responses. However, the PLATZ gene family has not been identified in barley. In this study, a total of 11 HvPLATZs were identified in barley, and they were unevenly distributed on five of the seven chromosomes. The phylogenetic tree, incorporating PLATZs from Arabidopsis, rice, maize, wheat, and barley, could be classified into six clusters, in which HvPLATZs are absent in Cluster VI. HvPLATZs exhibited conserved motif arrangements with a characteristic PLATZ domain. Two segmental duplication events were observed among HvPLATZs. All HvPLATZs were core genes present in 20 genotypes of the barley pan-genome. The HvPLATZ5 coding sequences were conserved among 20 barley genotypes, whereas HvPLATZ4/9/10 exhibited synonymous single nucleotide polymorphisms (SNPs); the remaining ones showed nonsynonymous variations. The expression of HvPLATZ2/3/8 was ubiquitous in various tissues, whereas HvPLATZ7 appeared transcriptionally silent; the remaining genes displayed tissue-specific expression. The expression of HvPLATZs was modulated by salt stress, potassium deficiency, and osmotic stress, with response patterns being time-, tissue-, and stress type-dependent. The heterologous expression of HvPLATZ3/5/6/8/9/10/11 in yeast enhanced tolerance to salt and osmotic stress, whereas the expression of HvPLATZ2 compromised tolerance. These results advance our comprehension and facilitate further functional characterization of HvPLATZs.

Knockout of miR396 genes increases seed size and yield in soybean

Yield improvement has long been an important task for soybean breeding in the world in order to meet the increasing demand for food and animal feed. miR396 genes have been shown to negatively regulate grain size in rice, but whether miR396 family members may function in a similar manner in soybean is unknown. Here, we generated eight soybean mutants harboring different combinations of homozygous mutations in the six soybean miR396 genes through genome editing with clustered regularly interspaced palindromic repeats (CRISPR)/CRISPR-associated nuclease (Cas)12SF01 in the elite soybean cultivar Zhonghuang 302 (ZH302). Four triple mutants (mir396aci, mir396acd, mir396adf, and mir396cdf), two quadruple mutants (mir396abcd and mir396acfi), and two quintuple mutants (mir396abcdf and mir396bcdfi) were characterized. We found that plants of all the mir396 mutants produced larger seeds compared to ZH302 plants. Field tests showed that mir396adf and mir396cdf plants have significantly increased yield in growth zones with relatively high latitude which are suited for ZH302 and moderately increased yield in lower latitude. In contrast, mir396abcdf and mir396bcdfi plants have increased plant height and decreased yield in growth zones with relatively high latitude due to lodging issues, but they are suited for low latitude growth zones with increased yield without lodging problems. Taken together, our study demonstrated that loss-of-function of miR396 genes leads to significantly enlarged seed size and increased yield in soybean, providing valuable germplasms for breeding high-yield soybean.

Evidence for poplar PtaPLATZ18 in the regulation of plant growth and vascular tissues development

Introduction

Plant A/T-rich protein and zinc-binding protein (PLATZ) are plant-specific transcription factors playing a role in plant development and stress response. To assess the role of PLATZs in vascular system development and wood formation in poplar, a functional study for PtaPLATZ18, whose expression was associated with the xylem, was carried out.

Methods

Poplar dominant repressor lines for PtaPLATZ18 were produced by overexpressing a PtaPLATZ18-SRDX fusion. The phenotype of three independent transgenic lines was evaluated at morphological, biochemical, and molecular levels and compared to the wild type.

Results

The PtaPLATZ18-SRDX lines showed increased plant height resulting from higher internode length. Besides, a higher secondary xylem thickness was also evidenced in these dominant repression lines as compared to the wild type suggesting an activation of cambial activity. A higher amount of lignin was evidenced within wood tissue as compared to the wild type, indicating an alteration in cell wall composition within xylem cell types. This latter phenotype was linked to an increased expression of genes involved in lignin biosynthesis and polymerization.

Discussion

The phenotype observed in the PtaPLATZ18-SRDX lines argues that this transcription factor targets key regulators of plant growth and vascular tissues development.

Regulation of seed traits in soybean

Soybean (Glycine max) is an essential economic crop that provides vegetative oil and protein for humans, worldwide. Increasing soybean yield as well as improving seed quality is of great importance. Seed weight/size, oil and protein content are the three major traits determining seed quality, and seed weight also influences soybean yield. In recent years, the availability of soybean omics data and the development of related techniques have paved the way for better research on soybean functional genomics, providing a comprehensive understanding of gene functions. This review summarizes the regulatory genes that influence seed size/weight, oil content and protein content in soybean. We also provided a general overview of the pleiotropic effect for the genes in controlling seed traits and environmental stresses. Ultimately, it is expected that this review will be beneficial in breeding improved traits in soybean.