Project description:fermented glutinous rice sequencing

Project description:fermented black glutinous rice sequencing

Project description:Fermentation black glutinous rice sample sequencing

Project description:The microbial community and enzymes in fermented rice using defined microbial starter, containing Rhizopus oryzae, Saccharomycopsis fibuligera, Saccharomyces cerevisiae and Pediococcus pentosaceus, play an important role in quality of the fermented rice product and its biological activities including melanogenesis inhibitory activity. The microbial metaproteome revealed large-scale proteins expressed by the microbial community to better understand the role of microbiota in the fermented rice.

Project description:Fermented grains sample sequencing

Project description:we studied the gene expression conditions while Pestalotiopsis fici . The perpose of this study is to find the expressed secondary metabolism genes when P. fici was fermented. Detection of gene expression of P . Fici on rice as substrate after 20 days when Natural products were reached to the peak.

Project description:Analysis of starch properties in glutinous rice cultivars in Hokkaido.

Project description:Fermented grains sample sequencing for fungal

Project description:fermented grains sample sequenceing

Project description:In this study, we aim to generate genome-scale DNA methylation profiles at single-base resolution in different rice cultivars (IR64, Nagina 22 and Pokkali) under control and stress conditions. Using high-throughput whole genome bisulfite Sequencing, we generated DNA methylation maps covering the vast majority of cytosines in the rice genome. More than 152 million high quality reads were obtained for each tissue sample using Illumina platform. We discovered extensive DNA methylation in rice cultivars, identified the context and level of methylation at each site.Numerous differentially methylated regions (DMRs) among different cultivars under control and stress conditions were identified and many of them were associated with differential gene expression. The high resolution methylome maps of different rice genotypes and differentially methylated regions will serve as reference for understanding the epigenetic regulation of stress responses in plants. Whole genome bisulfite sequencing of seven control/stressed samples from three rice cultivars (IR64, N22 and Pokkali)