Orf165 is associated with cytoplasmic male sterility in pepper.

Cytoplasmic male sterility (CMS) is a maternally inherited trait that derives from the inability to produce functional pollen in higher plants. CMS results from recombination of the mitochondrial genome. However, understanding of the molecular mechanism of CMS in pepper is limited. In this study, comparative transcriptomic analyses were performed using a near-isogenic CMS line 14A (CMS-14A) and a maintainer line 14B (ML-14B) as experimental materials. A total of 17,349 differentially expressed genes were detected between CMS-14A and ML-14B at the PMC meiosis stage. Among them, six unigenes associated with CMS and 108 unigenes involved in energy metabolism were identified. The gene orf165 was found in CMS-14A. When orf165 was introduced into ML-14B, almost 30% of transgenic plants were CMS. In addition, orf165 expression in transgenic CMS plants resulted in abnormal function of some genes involved in energy metabolism. When orf165 in transgenic CMS plant was silenced, the resulted orf165-silenced plant was male fertile and the expression patterns of some genes associated with energy metabolism were similar to ML-14B. Thus, we confirmed that orf165 influenced CMS in pepper.

Flower transcriptome dynamics during nectary development in pepper (Capsicum annuum L.).

The measurement of gene expression can provide important information about gene function and the molecular basis for developmental processes. We analyzed the transcriptomes at three different developmental stages of pepper flower [sporogenous cell division, stage (B1); pollen mother cell meiosis, stage (B2); and open flower (B3)]. In the cDNA libraries for B1, B2, and B3: 82718, 77061, and 91491 unigenes were assembled, respectively. A total of 34,445 unigene sequences and 128 pathways were annotated by KEGG pathway analysis. Several genes associated with nectar biosynthesis and nectary development were identified, and 8,955, 12,182, and 23,667 DEGs were identified in the B2 vs B1, B3 vs B1, and B3 vs. B2 comparisons. DEGs were involved in various metabolic processes, including flower development, nectar biosynthesis, and nectary development. According to the RNA-seq data, all 13 selected DEGs showed similar expression patterns after q-PCR analysis. Sucrose-phosphatase, galactinol-sucrose galactosyltransferase, and sucrose synthase played very important roles in nectar biosynthesis, and CRABS CLAW could potentially be involved in mediating nectary development. A significant number of simple sequence repeat and single nucleotide polymorphism markers were predicted in the Capsicum annuum sequences. The new results provide valuable genetic information about flower development in pepper.

Two promoter regions confer heat-induced activation of SlDREBA4 in Solanum lycopersicum.

Dehydration-responsive element binding (DREB) transcription factors activate the expression of downstream functional genes in combination with a dehydration-responsive element (DRE), and thereby improve the resistance of plants to abiotic stresses such as heat. However, the upstream regulatory mechanism of DREB genes under heat is unclear. A DREBA4 subfamily transcription factor (SlDREBA4), which is heat-responsive and improves heat resistance, was isolated from Solanum lycopersicum 'Microtom'. In this study, promoter truncation experiments were performed to verify changes in ß-glucuronidase (GUS) enzyme activity and GUS gene expression levels in transgenic plants with different lengths of promoter fragments under heat and to identify specific regions in the promoter that respond to heat. Our results showed that the GUS reporter gene was constitutively expressed in tissues of the full-length promoter transgenic 'Microtom' plants, with higher expression in conducting tissues of root, stem, and leaf, as well as sepals of flowers and fruits. Under heat treatment, GUS enzyme activity and GUS gene expression levels in tissues of the full-length promoter transgenic plants increased. Promoter deletion analysis identified two positive regulatory regions (-1095 to -730 bp and -162 to -38 bp) responsible for the promoter's response to heat. These results indicated that the heat shock element (HSE) and MYC recognition sequences may cooperate in heat-induced activation of SlDREBA4 promoter.

A Gene Expression Profiling of Early Rice Stamen Development that Reveals Inhibition of Photosynthetic Genes by OsMADS58.

Stamen is a unique plant organ wherein germ cells or microsporocytes that commit to meiosis are initiated from somatic cells during its early developmental process. While genes determining stamen identity are known according to the ABC model of floral development, little information is available on how these genes affect germ cell initiation. By using the Affymetrix GeneChip Rice Genome Array to assess 51 279 transcripts, we established a dynamic gene expression profile (GEP) of the early developmental process of rice (Oryza sativa) stamen. Systematic analysis of the GEP data revealed novel expression patterns of some developmentally important genes including meiosis-, tapetum-, and phytohormone-related genes. Following the finding that a substantial amount of nuclear genes encoding photosynthetic proteins are expressed at the low levels in early rice stamen, through the ChIP-seq analysis we found that a C-class MADS box protein, OsMADS58, binds many nuclear-encoded genes participated in photosystem and light reactions and the expression levels of most of them are increased when expression of OsMADS58 is downregulated in the osmads58 mutant. Furthermore, more pro-chloroplasts are observed and increased signals of reactive oxygen species are detected in the osmads58 mutant anthers. These findings implicate a novel link between stamen identity determination and hypoxia status establishment.

[Advances on bioinformatic research in transcription factor binding sites].

Transcription regulation is carried out by the interactions between transcription factors and their binding sites in DNA. Transcription factor binding sites (TFBS) are short, degenerate nucleotide sequences, and usually are 6-20 bp long. Accurate prediction of TFBSs is a crucial step towards understanding the regulation mechanism of transcription and constructing transcriptional regulatory networks. Currently, high-throughput technologies, such as ChIP-chip, are producing a large amount of data for TFBS study. TFBS prediction using either ChIP-chip data or multiple genome information is becoming a hot topic in bioinformatics. In this review, we summarize experimental techniques for locating TFBS and databases for TFBS study and further statistical survey models for TFBS description and software for TFBS prediction. As a consequence, we believe that bioinformatical and experimental studies of TFBS will promote each other in the future to understand the nature of transcriptional regulation.