Genome-wide analysis and identification of stress-responsive genes of the CCCH zinc finger family in Solanum lycopersicum

Zinc finger genes comprise a large and diverse gene family. Based on their individual finger structures and spacing, zinc finger proteins are further divided into different families according to their specific molecular functions. Genes in the CCCH family encode zinc finger proteins containing a motif with three cysteines and one histidine. They play important roles in plant growth and development, and in response to biotic and abiotic stresses. However, the limited analysis of the genome sequence has meant that there is no detailed information concerning the CCCH zinc finger family in tomato (Solanum lycopersicum). Here, we identified 80 CCCH zinc finger protein genes in the tomato genome. A complete overview of this gene family in tomato was presented, including the chromosome locations, gene duplications, phylogeny, gene structures and protein motifs. Promoter sequences and expression profiles of putative stress-responsive members were also investigated. These results revealed that, with the exception of four genes, the 80 CCCH genes are distributed over all 12 chromosomes with different densities, and include six segmental duplication events. The CCCH family in tomato could be divided into 12 groups based on their different CCCH motifs and into eight subfamilies by phylogenetic analysis. Analysis showed that almost all CCCH genes contain putative stress-responsive cis-elements in their promoter regions. Nine CCCH genes chosen for further quantitative real-time PCR analysis showed differential expression patterns in three representative tomato tissues. In addition, their expression levels indicated that these genes are mostly involved in the response to mannitol, heat, salicylic acid, ethylene or methyl jasmonate treatments. To the best of our knowledge, this is the first report of a genome-wide analysis of the tomato CCCH zinc finger family. Our data provided valuable information on tomato CCCH proteins and form a foundation for future studies of these proteins, especially for those members that may play important roles in stress responses.     

Genome-wide analysis and stress-responsive expression of CCCH zinc finger family genes in <Emphasis Type="Italic">Brassica rapa</Emphasis>

Background

Ubiquitous CCCH nucleic acid-binding motif is found in a wide-variety of organisms. CCCH genes are involved in plant developmental processes and biotic and abiotic stress responses. Brassica rapa is a vital economic crop and classical model plant of polyploidy evolution, but the functions of CCCH genes in B. rapa are unclear.

Results

In this study, 103 CCCH genes in B. rapa were identified. A comparative analysis of the chromosomal position, gene structure, domain organization and duplication event between B. rapa and Arabidopsis thaliana were performed. Results showed that CCCH genes could be divided into 18 subfamilies, and segmental duplication might mainly contribute to this family expansion. C-X_7/8-C-X₅-C₃-H was the most commonly found motif, but some novel CCCH motifs were also found, along with some loses of typical CCCH motifs widespread in other plant species. The multifarious gene structures and domain organizations implicated functional diversity of CCCH genes in B. rapa. Evidence also suggested functional redundancy in at least one subfamily due to high conservation between members. Finally, the expression profiles of subfamily-IX genes indicated that they are likely involved in various stress responses.

Conclusion

This study provides the first genome-wide characterization of the CCCH genes in B. rapa. The results suggest that B. rapa CCCH genes are likely functionally divergent, but mostly involved in plant development and stress response. These results are expected to facilitate future functional characterization of this potential RNA-binding protein family in Brassica crops.

     

CCCH-type zinc finger family in maize: genome-wide identification, classification and expression profiling under abscisic acid and drought treatments

Background

CCCH-type zinc finger proteins comprise a large protein family. Increasing evidence suggests that members of this family are RNA-binding proteins with regulatory functions in mRNA processing. Compared with those in animals, functions of CCCH-type zinc finger proteins involved in plant growth and development are poorly understood.

Methodology/Principal Findings

Here, we performed a genome-wide survey of CCCH-type zinc finger genes in maize (Zea mays L.) by describing the gene structure, phylogenetic relationships and chromosomal location of each family member. Promoter sequences and expression profiles of putative stress-responsive members were also investigated. A total of 68 CCCH genes (ZmC3H1-68) were identified in maize and divided into seven groups by phylogenetic analysis. These 68 genes were found to be unevenly distributed on 10 chromosomes with 15 segmental duplication events, suggesting that segmental duplication played a major role in expansion of the maize CCCH family. The Ka/Ks ratios suggested that the duplicated genes of the CCCH family mainly experienced purifying selection with limited functional divergence after duplication events. Twelve maize CCCH genes grouped with other known stress-responsive genes from Arabidopsis were found to contain putative stress-responsive cis-elements in their promoter regions. Seven of these genes chosen for further quantitative real-time PCR analysis showed differential expression patterns among five representative maize tissues and over time in response to abscisic acid and drought treatments.

Conclusions

The results presented in this study provide basic information on maize CCCH proteins and form the foundation for future functional studies of these proteins, especially for those members of which may play important roles in response to abiotic stresses.     

A genome-wide analysis of the expansin genes in Malus × Domestica

Expansins were first identified as cell wall-loosening proteins; they are involved in regulating cell expansion, fruits softening and many other physiological processes. However, our knowledge about the expansin family members and their evolutionary relationships in fruit trees, such as apple, is limited. In this study, we identified 41 members of the expansin gene family in the genome of apple (Malus × Domestica L. Borkh). Phylogenetic analysis revealed that expansin genes in apple could be divided into four subfamilies according to their gene structures and protein motifs. By phylogenetic analysis of the expansins in five plants (Arabidopsis, rice, poplar, grape and apple), the expansins were divided into 17 subgroups. Our gene duplication analysis revealed that whole-genome and chromosomal-segment duplications contributed to the expansion of Mdexpansins. The microarray and expressed sequence tag (EST) data showed that 34 Mdexpansin genes could be divided into five groups by the EST analysis; they may also play different roles during fruit development. An expression model for MdEXPA16 and MdEXPA20 showed their potential role in developing fruit. Overall, our study provides useful data and novel insights into the functions and regulatory mechanisms of the expansin genes in apple, as well as their evolution and divergence. As the first step towards genome-wide analysis of the expansin genes in apple, our results have established a solid foundation for future studies on the function of the expansin genes in fruit development.     

Complex evolutionary history and diverse domain organization of SET proteins suggest divergent regulatory interactions

? Plants and animals possess very different developmental processes, yet share conserved epigenetic regulatory mechanisms, such as histone modifications. One of the most important forms of histone modification is methylation on lysine residues of the tails, carried out by members of the SET protein family, which are widespread in eukaryotes. ? We analyzed molecular evolution by comparative genomics and phylogenetics of the SET genes from plant and animal genomes, grouping SET genes into several subfamilies and uncovering numerous gene duplications, particularly in the Suv, Ash, Trx and E(z) subfamilies. ? Domain organizations differ between different subfamilies and between plant and animal SET proteins in some subfamilies, and support the grouping of SET genes into seven main subfamilies, suggesting that SET proteins have acquired distinctive regulatory interactions during evolution. We detected evidence for independent evolution of domain organization in different lineages, including recruitment of new domains following some duplications. ? More recent duplications in both vertebrates and land plants are probably the result of whole-genome or segmental duplications. The evolution of the SET gene family shows that gene duplications caused by segmental duplications and other mechanisms have probably contributed to the complexity of epigenetic regulation, providing insights into the evolution of the regulation of chromatin structure.     

A betaine aldehyde dehydrogenase gene from <Emphasis Type="Italic">Ammopiptanthus nanus</Emphasis> enhances tolerance of <Emphasis Type="Italic">Arabidopsis</Emphasis> to high salt and drought stresses

YUCCA is an important enzyme which catalyzes a key rate-limiting step in the tryptophan-dependent pathway for auxin biosynthesis and implicated in several processes during plant growth and development. Genome wide analyses of YUCCA genes have been performed in Arabidopsis, rice, tomato, and Populus, but have never been characterized in soybean, one of the most important oil crops in the world. In this study, 22 GmYUCCA genes (GmYUCCA1-22) were identified and named based on soybean whole-genome sequence. Phylogenetic analysis of YUCCA proteins from Glycine max, Arabidopsis, Oryza sativa, tomato, and Populus euphratica revealed that GmYUCCA proteins could be divided into four subfamilies. Quantitative real-time RT-PCR (qRT-PCR) analysis showed that GmYUCCA genes have diverse expression patterns in different tissues and under various stress treatments. Compared to the wild type (WT), the transgenic GmYUCCA5 Arabidopsis plants displayed downward curling of the leaf blade margin, evident apical dominance, higher plant height, and shorter length of siliques. Our results provide a comprehensive analysis of the soybean YUCCA gene family and lay a solid foundation for further experiments in order to functionally characterize these gene members during soybean growth and development.     

Genome-wide identification of the BURP domain-containing genes in Phaseolus vulgaris

Plant-specific BURP domain-containing proteins have an essential role in the plant''s development and stress responses. Although BURP domain-containing proteins have been identified in several plant species, genome-wide analysis of the BURP gene family has not been investigated in the common bean. In the present study, we identified 11 BURP family members in the common bean (Phaseolus vulgaris) genome with a comprehensive in silico analysis. Pairwise alignment and phylogenetic analyses grouped PvBURP members into four subfamilies [RD-22 like (3), PG1β-like (4), BNM2-like (3), and USP-like (1)] according to their amino acid motifs, protein domains and intron–exon structure. The physical and biochemical characteristics of amino acids, motif and intron–exon structure, and cis-regulatory elements of BURPs members were determined. Promoter regions of BURP members included stress, light, and hormone response-related cis-elements. Therefore, expression profiles of PvBURP genes were identified with in silico tools and qRT-PCR analyses under stress (salt and drought) and hormone treatment (ABA, IAA) in the current study. While significant activity changes were not observed in BURP genes in RNA-seq data sets related to salt stress, it was determined that some BURP genes were expressed differently in those with drought stress. We identified 12 different miRNA, including miRNA395, miRNA156, miRNA169, miRNA171, miRNA319, and miRNA390, targeting the nine PvBURP genes using two different in silico tools based on perfect or near‐perfect complementarity to their targets. Here we present the first study to identify and characterize the BURP genes in common bean using whole-genome analysis, and the findings may serve as a reference for future functional research in common bean.Supplementary InformationThe online version contains supplementary material available at 10.1007/s12298-021-01052-9.