Project description:Cultivated soybean has domesticated in China for a long history, and there are several significant phenotypic differences between wild and cultivated soybeans. Seed of cultivar is generally larger than wild soybean, therefore here we comprehensively analyzed transcriptomes of thirteen soybean accessions seeds including seven wild soybeans and six landraces through applying strand-specific RNA sequencing. Differential expressed genes related seed weight were identified, some of them were known to be associated with seed development in Arabidopsis. Noncoding RNAs are known to play important roles in plant development, and we profiled the expression pattern of long noncoding RNA (lncRNA) in cultivated and wild soybean seeds. We have identified 1,251 long intergenic noncoding RNA, 243 intronic RNA and 81 antisense lncRNA, transcriptional levels of a number of lncRNAs were significantly different between cultivated and wild soybeans, suggesting that lncRNA may be involved in soybean seed development.

Project description:<p>Facing the severe challenge of global soil potassium deficiency on crop production, two different ecological row types of wild soybean [ Glycine soja sieb. &amp; Zucc. In order to reveal the physiological and molecular mechanisms of tolerance to low potassium stress in glycine soja, we compared the differences in transcriptional and physiological responses to low potassium stress between the common type (GS1) and the barren tolerant Type (GS2) . Growth parameters and ion content determination found that GS2 exhibited higher root biomass and K+/Na+&nbsp;ratio. Combined metabolomic and transcriptomic analysis found that sugar metabolism was enhanced in GS2, manifested by the accumulation of soluble sugars such as sucrose and fructose and the maintenance of a stable TCA cycle. The increase of shikimic acid, proline and unsaturated fat constitutes the efficient antioxidant defense system and cell membrane stability maintenance mechanism of GS2. This study not only clarified the key regulatory network of wild soybean tolerance to low potassium stress, but also provided valuable genetic resources and technical support for genetic improvement of crop stress resistance.</p>

Project description:cultivated soybeans and wild soybeans transcriptome

Project description:Analysis of gene expression data from four genetically diverse wild soybean accessions helps reveal both sensitive and resistant responses of the plants to increased ozone levels. Results help characterize genetic response of wild soybean to ozone stress and could help provide information on genetic resources for creating ozone-tolerant soybean breeding lines.

Project description:Various species of rhizobium establish compatible symbiotic relationships with soybean (Glycine max) leading to the formation of nitrogen-fixing nodules in roots. The formation of functional nodules is mediated through complex developmental and transcriptional reprogramming that involves the activity of thousands of plant genes. However, host transcriptome responses that determine the outcome of the symbiotic interactions leading to the formation of functional or non-functional nodules remain unexplored. In this study, we investigated differential compatibilities between rhizobium strains (Bradyrhizobium diazoefficiens USDA 110Bradyrhizobium sp. strain LVM 105) and cultivated and wild soybeans. The nodulation assays revealed that both USDA 110 and LVM 105 strains effectively nodulate G. soja but only USDA 110 can form symbiotic relationships with Williams 82. RNA-seq data revealed that USDA 110 and LVM 105 induce distinct transcriptome programming in functional mature nodules formed on G. soja roots where genes involved in nucleosome assembly, DNA replication, regulation of cell cycle, and defense responses play key roles. Transcriptome comparison also suggested that activation of genes associated with cell wall biogenesis and organization and defense responses together with downregulation of genes involved in the biosynthesis of isoprenoids and antioxidant stress are associated with the formation of non-functional nodules on Williams 82 roots. Moreover, our analysis implies that increased activity of genes involved in oxygen binding, amino acid transport, and nitrate transport differentiates between fully-developed nodules in cultivated versus wild soybeans.

Project description:Heat shock protein 70 (HSP70) usually functions in maintaining protein homeostasis, and is also involved in regulating plant immunity, but mediation of plant-parasitic nematode resistance by HSP70s has rarely been reported. In this work, two high similarity soybean GmHSP70s [GmHSP70-13a (Glyma.13g254900) and GmHSP70-15a (Glyma.15g059900)] were studied in soybean cyst nematode (SCN) resistance, which is a devastating pathogen in soybean. Both GmHSP70-13a and GmHSP70-15a were significantly suppressed in resistant soybeans, compared to susceptible soybeans, at 0 day and 3 days post inoculation (dpi) of SCN. In soybean hairy roots, CRISPR/Cas9-editing of these two genes resulted in enhanced SCN resistance; accordingly, overexpressing either GmHSP70-13a or GmHSP70-15a suppressed SCN resistance. Both GmHSP70-13a and GmHSP70-15a interacted with GmSHMT08, which is one major SCN-resistant protein in soybeans and a key enzyme in one-carbon metabolism pathway. Compared to 0 dpi of SCN, at 3 dpi, GmHSP70-13a overexpression did not alter and GmHSP70-15a overexpression significantly suppressed, in contrast, the control remarkably promoted, GmSHMT08 expression in soybean. Furthermore, either GmHSP70-13a or GmHSP70-15a overexpression abnormally down-regulated expression of 4 one-carbon metabolism-associated genes (Glyma.06g235500, Glyma.12g015300, Glyma.15g071000, and Glyma.15g071200). Taken together, both GmHSP70-13a and GmHSP70-15a negatively mediated soybean SCN resistance likely by interacting with GmSHMT08, leading to GmSHMT08 suppression, along with impact of one-carbon metabolism pathway in soybean. This work provides 2 GmHSP70s gene-editing targets for soybean SCN resistance breeding.

Project description:Research conducted, including the rationale: Weeds reduce yield in soybeans through incompletely defined mechanisms. The effects of weeds on the soybean transcriptome were evaluated in field conditions during four separate gR1.fastqing seasons. Methods: RNASeq data were collected from 6 biological samples of soybeans gR1.fastqing with or without weeds. Weed species and the methods to maintain weed free controls varied between years to mitigate treatment effects and to allow detection of general soybeans weed responses. Key results: Soybean plants were not visibly nutrient or water stressed. We identified 55 consistently down-regulated genes in weedy plots. Many of the down-regulated genes were heat shock genes. Fourteen genes were consistently up-regulated. Several transcription factors including a PHYTOCHROME INTERACTING FACTOR 3-like gene (PIF3) were included among the up-regulated genes. Gene set enrichment analysis indicated roles for increased oxidative stress and jasmonic acid signaling responses during weed stress. Main conclusion: The relationship of this weed-induced PIF3 gene to genes involved in shade avoidance responses in arabidopsis provide evidence that this gene may be important in the response of soybean to weeds. These results suggest the weed-induced PIF3 gene will be a target for manipulating weed tolerance in soybean. Samples were collected from two treatments (&quot;Control&quot; and &quot;Weedy&quot;) with six biological replicates (2008, 2009, and twop each for 2010 and 2011) for each treatment.

Project description:Research conducted, including the rationale: Weeds reduce yield in soybeans through incompletely defined mechanisms. The effects of weeds on the soybean transcriptome were evaluated in field conditions during four separate gR1.fastqing seasons. Methods: RNASeq data were collected from 6 biological samples of soybeans gR1.fastqing with or without weeds. Weed species and the methods to maintain weed free controls varied between years to mitigate treatment effects and to allow detection of general soybeans weed responses. Key results: Soybean plants were not visibly nutrient or water stressed. We identified 55 consistently down-regulated genes in weedy plots. Many of the down-regulated genes were heat shock genes. Fourteen genes were consistently up-regulated. Several transcription factors including a PHYTOCHROME INTERACTING FACTOR 3-like gene (PIF3) were included among the up-regulated genes. Gene set enrichment analysis indicated roles for increased oxidative stress and jasmonic acid signaling responses during weed stress. Main conclusion: The relationship of this weed-induced PIF3 gene to genes involved in shade avoidance responses in arabidopsis provide evidence that this gene may be important in the response of soybean to weeds. These results suggest the weed-induced PIF3 gene will be a target for manipulating weed tolerance in soybean.

Project description:Aluminum (Al) toxicity is an important restraint to soybean (Glycine max L. Merr.) production on acid soils. However, little is known about the genes underlying Al tolerance in soybean. We used microarrays to detail the global programme of gene expression under control and Al stress in two soybean at 6, 12, and 24 h.

Project description:Flooding stress has a negative impact on soybean cultivation because it severely impairs growth and development. To understand the flooding responsive mechanism in early stage soybeans, a glycoproteomic technique was used