Project description:Phytophthora root and stem rot (PRR) of soybean, caused by Phytophthora sojae, is effectively controlled by Rps genes in soybean. Rps genes are race-specific, yet the mechanism of resistance, as well as susceptibility, remains largely unclear. Taking advantage of RNA-seq technology, we sequenced the transcriptomes of 10 near isogenic lines (NIL), each with a unique Rps gene, and the recurrent susceptible parent ‘Williams’. A total of 4330 differentially expressed genes (DEGs) were identified in ‘Williams’ while 2075 to 5499 DEGs were identified in each NIL. Comparisons between the NILs and ‘Williams’ allowed classification of two major groups of DEGs of interest: incompatible reaction associated genes (IRAGs) and compatible reaction associated genes (CRAGs). Hierarchical cluster analysis divided NILs into three clusters: Cluster I (Rps1-a), Cluster II (Rps1-b, 1-c and 1-k) and Cluster III (Rps3-a, 3-b, 3-c, 4, 5, and 6). Heatmap analysis, along with GO analysis suggested that the diversity of clusters for NILs were likely due to variation of the number of DEGs and the intensity of gene expression, rather than functional differentiation. Further analysis suggested that transcription factors might play pivotal role in determination of the cluster pattern, and that WRKY family were strongly associated with incompatible reactions. Analysis of IRAGs and CRAGs with putative functions suggested that the regulation of many phytohormone signaling pathways were associated with incompatible or compatible interactions with potential crosstalk between each other. As such, our study provides an in depth view of both incompatible and compatible interactions between soybean and P. sojae, which provides further insight into the mechanisms involved in host-pathogen interactions. 22 samples were sequenced, 11 inoculated with P. sojae, the other 11 were mock-inoculated

Project description:Transcriptome Analysis of Wild Type and Histone H1.2(MeH1.2) Transgenic Plants by RNA-seq in Cassava.The goal of this study was to compare the phenotypic and transcriptome differences between transgenic and WT plants, and to analyze how overexpression of MeH1.2 gene changed the expression patterns. MeH1.2 overexpressed transgenic cassava plant (HOE) were was made. The 2-month-old seedlings of HOE were significantly smaller and weaker than of the wild type (WT) under Murashige and Skoog (MS) medium, while, the leave leaf became yellow senescence and the number of branch root increased significantly in HOE than in WT. We found a total of 1670 down-regulated differentially expressed genes (DEGs) and 891 up-regulated DEGs in HOE leave of 2-months-old bottled seedling as indicated by RNA-seq. Many of DEGs were associated with growth metabolism and stress response, such as different amino acids metabolic genes, wound-responsive family genes and peroxidase superfamily genes. We hypothesized the overexpression of MeH1.2 may be similar to mild abiotic stress to retard the growth of HOE, the increased proline content and root-shoot ratio of HOE also support the hypothesis.

Project description:The experiments were performed to monitor dynamics in WRKY transcription factor abundancies upon treatment with flg22, a peptide derived from the bacterial flagella. Mock-treated or WT seedlings treated for 2 h with flg22 were used to prepare crude nuclear lysates. Then pull downs were performed with an anti-all-WRKY antiserum to enrich for WRKY transcription factor proteins prior to MS.

Project description:Embryonic survival rate is an important factor for the fecundity of sows, and it is affected by endometrium secreting histotroph. A higher concentration of calcium ion has been observed in the uterus of the high prolific Erhualian sows (EH) compared with low prolific ones (EL), which suggests EH sows had a greater establishment and maintenance of pregnancy, and thus increase embryonic survival rate during peri-implantation period. In order to understand the mechanisms of endometrium secreting histotroph affecting embryonic survival rate during Erhualian peri-implantation period, the expression patterns of endometrial mRNA in the EH and EL on day 12 of gestation were analyzed using RNA sequencing technology. 164 differentially expressed genes (DEGs) were identified (Padj < 0.05, |log2(FC)| ≥ 1)，including 46 upregulated and 118 downregulated genes in the EH group compared with EL group. Among these DEGs, 17 DEGs have been previously reported as DEGs in other pig breeds for litter size. Gene Ontology (GO) enrichment indicated that a subset of DEGs were involved in the calcium ion binding and cell adhesion. Solute carrier family 8 member A3 (SLC8A3) and solute carrier family 24 member 4 (SLC24A4) were upregulated genes (Padj < 0.05) in EH group and they were considered as key candidate genes expressed in endometrium to affect embryonic survival rate during peri-implantation period. The present results will aid in understanding the variation of litter size in Erhualian breed during peri-implantation period.

Project description:Purpose: To further identify the genes and pathways involved in the necrotic phenotype of NtCBL5A-OE lines, the leaf transcriptome profiling of WT and OE-2 lines grown under control conditions and salt stress (100 mM NaCl) at 4 DAT were sequenced and compared. Methods: Two datasets of differentially expressed genes (DEGs) were made in which we identified the genes that were differentially expressed as a result of the overexpression of NtCBL5A: Control-WT vs Control-OE2 (C-WT/C-OE2), Salt-WT vs Salt-OE2 (S-WT/S-OE2). Another two datasets were also used to identify the transcripts that were responsive to the salt treatments: Control-WT vs Salt-WT (C-WT/S-WT) and Control-OE2 vs Salt-OE2 (C-OE2/S-OE2). DEGs from C-WT/C-OE2 and S-WT/S-OE2 were compared to select the transcripts affected by NtCBL5A overexpression only under salt stress. We also compared DEGs from C-WT/S-WT and C-OE2/S-OE2 to identify the specific transcripts affected by salt stress and only in NtCBL5A-OE lines. This procedure was done for two independent experiments, and only DEGs that were identified in both experiments were considered. Results: The OE-affected DEGs and salt-affected DEGs together resulted in 2079 up-regulated DEGs and 1154 down-regulated DEGs, strongly affected by the combination of NtCBL5A overexpression and salt stress.

Project description:We used a next-generation sequencing approach, Illumina Digital Gene Expression II (DGEII) technology, to Genome-wide profiling of gene expression during somatic (SE) and zygotic embryo (ZE) development. As a result, 4242 differentially expressed genes (DEGs) were identified between SE and ZE. Expression pattern cluster and functional classification analysis of the differentially expressed genes revealed that large number of genes indicative of response to stress highly expressed in somatic embryos. Combined with KEGG analysis and BLAST annotation, genes related to stress response in DEGs have been comprehensively analyzed, mainly including: ABA biosynthesis, ABA and JA (jasmonic acid) response, LEA (late embryogenesis abundant protein) family members, RD (responsive to dehydration) and ERD (early responsive to dehydration) family members, Hot Shock Proteins, WRKY family members and NAC family members. Semi-quantitative Reverse Transcriptase-PCR (RT-PCR) analysis was performed on 27 selected genes and and the results enhance that genes related to stress response were involved in SE development. Our main goal is to adapt the RNA-Seq technology to this notable development process and to analyse the gene expression profile. This is a systematical expression analysis focusing on somatic embryo development, and also a global comparison between somatic and zygotic embryo at transcript level. Therefore, this study might bring new insights into the regulation of somatic embryo development. An analysis of differentially expressed genes at 3 parallel stages during somatic and zygotic embryo development in cotton by next-generation sequencing, using Illumina Digital Gene Expression II (DGE II) .

Project description:Previous studies have shown that methane (CH4) has promoting roles in the adventitious root (AR) and lateral root formation in plants. However, whether CH4 could trigger the bulblet formation in scale cutting of Lilium davidii var. unicolor has not been elucidated. To gain insight into the effect of CH4 on the bulblet formation, different concentrations (1%, 10%，50% and 100%) of methane-rich water (MRW) and distilled water were applied to treat the scale cuttings of Lilium. We observed that treatment with 100% MRW obviously induced the bulblet formation in scale cuttings. To explore the mechanism of CH4-induced the bulblet formation, the transcriptome of scales was analyzed. A total of 2078 differentially expressed genes (DEGs) were identified. The DEGs were classified into different metabolism pathways, especially phenylpropanoid biosynthesis, starch and sucrose metabolism and plant signal transduction. Of these, approximately 38 candidate DEGs involved in the plant signal transduction were further studied. In addition, the expression of AP2-ERF/ERF, WRKY, GRAS, ARF and NAC transcription factors were changed by MRW treatment, suggesting their potential involvement in bulblet formation. As for hormones, exogenous IAA, GA and ABA could indue the bulblet formation. Additional experiments suggested that MRW could increase the endogenous IAA, GA, and JA levels, but decrease the levels of ABA during bulblet formation, which showed that higher IAA, GA, JA levels and lower ABA content might facilitate bulblet formation. In addition, the levels of endogenous hormone were consistent with the expression level of genes involved in phytohormone signal transduction. Overall, this study has revealed that CH4 might improve the bulblet formation of cutting scales in Lilium by regulating the expression of genes related to phytohormone signal transduction and transcription factors, as well as by changing the endogenous hormone levels.

Project description:The WRKY gene family has a very ancient origin but has faced extensive duplication only in the plant kingdom so much that Arabidopsis (Arabidopsis thaliana) has 74 copies of WRKY genes encoding transcription factors while 109 can be found in Rice (Oryza sativa L.). Several studies in the last decade has pointed their involvement in an heterogeneous number of biological processes, from development to hormone signalling, dormancy and senescence, but a wide number of WRKY genes are transcriptionally regulated during biotic or abiotic stresses. To investigate involvement of WRKY genes upon host and non-host infection (different strain of Magnaporthe grisea) and osmotic stress in Rice, we performed a gene family transcription analysis using custom microarray. Results indicate that a relevant part of WRKY genes are involved during at least one of these stresses, that there is little difference in transcriptional regulation between host and non-host infection or between different tissues upon the same osmotic stress. Moreover, are evident groups of genes that, often with opposite behaviour, are co-regulated in all or most of the studied conditions. We thus formulated the hypothesis that WRKY genes might be part of co-regulatory networks with other WRKY genes. Keywords: stress response We analyzed 40 arrays and tested 6 conditions: BR29 (Non-host Pathogen), BR32 (Non-host Pathogen), FR13 (Host pathogen), Osmotic leaves 5 hours, Osmotic roots 1 hour and Osmotic roots 5 hours. 2 biological replicated were analyzed and between 2 to 4 technical replicates applied for each biological sample.

Project description:Phytophthora root and stem rot (PRR) of soybean, caused by Phytophthora sojae, is effectively controlled by Rps genes in soybean. Rps genes are race-specific, yet the mechanism of resistance, as well as susceptibility, remains largely unclear. Taking advantage of RNA-seq technology, we sequenced the transcriptomes of 10 near isogenic lines (NIL), each with a unique Rps gene, and the recurrent susceptible parent ‘Williams’. A total of 4330 differentially expressed genes (DEGs) were identified in ‘Williams’ while 2075 to 5499 DEGs were identified in each NIL. Comparisons between the NILs and ‘Williams’ allowed classification of two major groups of DEGs of interest: incompatible reaction associated genes (IRAGs) and compatible reaction associated genes (CRAGs). Hierarchical cluster analysis divided NILs into three clusters: Cluster I (Rps1-a), Cluster II (Rps1-b, 1-c and 1-k) and Cluster III (Rps3-a, 3-b, 3-c, 4, 5, and 6). Heatmap analysis, along with GO analysis suggested that the diversity of clusters for NILs were likely due to variation of the number of DEGs and the intensity of gene expression, rather than functional differentiation. Further analysis suggested that transcription factors might play pivotal role in determination of the cluster pattern, and that WRKY family were strongly associated with incompatible reactions. Analysis of IRAGs and CRAGs with putative functions suggested that the regulation of many phytohormone signaling pathways were associated with incompatible or compatible interactions with potential crosstalk between each other. As such, our study provides an in depth view of both incompatible and compatible interactions between soybean and P. sojae, which provides further insight into the mechanisms involved in host-pathogen interactions.

Project description:RNA sequencing was used to identify alternative splicing events and differentially expressed genes (DEG) in 35S:HIN1 stable transgenic line compared to Col-0 wild type. Two treatments were analyzed for each genotype: unstressed control and a 96 hours moderate severity low water potential (-0.7 MPa) treatment. RNA sequencing analysis found that overexpression of HIN1 in unstressed plants was sufficient to duplicate the effects of stress on nearly 40% of the genes where intron retention was normally suppressed by stress in wild type. Differentially expressed genes (DEGs) were also analyzed (P < 0.05 and fold change ≥ 1.5 used as cut off values for DEGs). Differentially expressed genes in 35S:HIN1has limited overlap of DEGs between 35S:HIN1and wild type. This indicated that HIN1 plays a lesser role in stress-regulated gene expression than in splicing regulation.