The maize (Zea mays L.) husk consists of multiple leaf layers and plays an important role in grain growth and development. Despite significant achievements in physiological and morphological research, few studies have focused on the detection of genetic loci underlying husk-related traits due to the lack of efficient tools. In this study, we constructed an ultra-high-density linkage map using genotyping-by-sequence (GBS) based on a recombinant inbred line (RIL) population to estimate the genetic variance and heritability of three husk traits, i.e.,, husk width (HL), husk width (HW), and husk layer number (HN) in three field environments and the combined environment. The three husk traits showed broad phenotypic variation and high heritability, the broad-sense heritability (H2) was 0.92, 0.84 and 0.86, respectively. Twenty QTLs were consistently detected more than one environment; these viewed as stable QTLs include nine influence HL; six, HW; and five, HN. Based on the QTL mapping in the RIL population, qHL6 and qHN4 were detected across all environments and inferred to be reliable and major-effect QTLs for HL and HN, respectively. Additionally, several predicted candidate genes were identified in the region of qHL6 and qHN4, of which 17 candidate genes potentially play a role in biological processes related to development process and energy metabolism. These results will be as a useful resource for performing functional studies aimed at understanding the molecular pathways involved in husk growth and development.
Phenylalanine ammonia-lyase (PAL) is a key enzyme and rate-limiting enzyme of phenylpropanoid metabolism, which is a very important pathway in plants, and the secondary products it produces play an important role in plant growth and development, disease resistance, and stress resistance responses. However, PALs still lack systematic characterization in tomato. Based on a bioinformatics methods, PAL family genes were identified and characterized from tomato. qRT-PCR was used to study the expression of PAL genes in cultivated tomato after root-knot nematode infection. In this study, 14 and 11 PAL genes were identified in cultivated and wild tomatoes, and phylogenetic analysis classified them into three subfamilies, with different subfamilies of PAL proteins evolving in different directions in monocotyledonous and dicotyledonous plants. The extensive presence of stress, growth, hormone, and light response elements in the promoter sequences of SlPAL (Solanum lycopersicum) and SpenPAL (Solanum pennellii) genes suggests that this family has a critical role in abiotic stress. Collinearity indicates that members of the tomato and Arabidopsis PAL genes family are from the same ancestor, and the SlPAL10 gene is directly homologous to monocotyledonous rice and maize, suggesting that the SlPAL10 gene was present before monocotyledonous differentiation. Two co-expressed gene modules containing PAL genes were screened by WGCNA, and the core genes in the network were mined and functionally annotated by calculating the connectivity of genes within the modules. In addition, the expression of some genes changed significantly after root-knot nematode infection, with up-regulation of 4 genes and down-regulation of 3 genes. This result provides a data reference for the study of PAL family gene functions in tomato, and also provides a potential application for the subsequent selection of PAL genes in tomato for root-knot nematode resistance.
Heterosis, known as one of the most successful strategies for increasing grain yield and abiotic/biotic stress tolerance, has been widely exploited in maize breeding. However, the underlying molecular processes are still to be elucidated. The maize hybrid “Zhengdan538” shows high tolerance to drought stress. The transcriptomes of the seedling leaves of its parents, “ZhengA88” and “ZhengT22” and their reciprocal F1 hybrid under well‐watered and water deficit conditions, were analyzed by RNA sequencing (RNA‐Seq). Transcriptome profiling of the reciprocal hybrid revealed 2994–4692 differentially expressed genes (DEGs) under well‐watered and water‐deficit conditions, which were identified by comparing with their parents. The reciprocal hybrid was more closely related to the parental line “ZhengT22” than to the parental line “ZhengA88” in terms of gene expression patterns under water‐deficit condition. Furthermore, genes showed expression level dominance (ELD), especially the high‐parental ELD (Class 3 and 5), accounted for the largest proportion of DEGs between the reciprocal F1 hybrid and their parental lines under water deficit. These ELD genes mainly participated in photosynthesis, energy biosynthesis, and metabolism processes. The results indicated that ELD genes played important roles in hybrid tolerance to water deficit. Moreover, a set of important drought‐responsive transcription factors were found to be encoded by the identified ELD genes and are thought to function in improving drought tolerance in maize hybrid plants. Our results provide a better understanding of the molecular mechanism of drought tolerance in hybrid maize.
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