Project description:General translational repression is predicted as a key process to reduce energy consumption under hypoxia. We have previously showed that mRNA loading onto polysome is reduced in Arabidopsis under submergence. Here, we showed that plant stress activated GCN2 (general control nonderepressible 2) can phosphorylate eIF2a (Eukaryotic Initiation Factor 2a) in Arabidopsis under submergence, and this process is reversible after desubmergence. Compared to the wild-type, the reduction in polysome loading during submergence was less severe in the gcn2 mutant. Transgenic lines overexpressing GCN2 had more ATP and conferred better tolerance under submergence, suggesting that GCN2 might modulate the dynamics of translation to adjust the energy homeostasis under hypoxia. Interestingly, GCN2-eIF2a signaling was activated by ethylene under submergence. However, GCN2 activity was not affected in ein2-5 and eil1ein3 under submergence, suggesting that GCN2 activity was regulated by noncanonical ethylene signaling. In addition, the polysome loading was retained in both ein2-5 and etr1-1 under submergence, implying that ethylene modulated the dynamic translation under submergence via EIN2 and GCN2. Notably, our NGS analysis also demonstrated that EIN2 and GCN2 regulated the translation of 23 core hypoxia genes as well as 53% translational repressed genes under submergence. On the other hand, EIN2 and GCN2 also affected the expression of genes involved in hypoxic response, ethylene response, biotic stress and negative regulation of cytokinin signaling. Taken together, these demonstrated that entrapped ethylene triggers GCN2 and EIN2 to ensure the translation of stress required proteins under submergence and also provide a step stone for future investigation how eukaryotic cells modulate the translation to response for the changeable environments.

Project description:Rice NSF45K microarray experiment to dissect submergence tolerance response in submergence tolerant rice plant, M202(Sub1): We previously characterized the rice (Oryza sativa L.) Sub1 locus encoding three Ethylene Responsive Factor (ERF) transcriptional regulators. Genotypes carrying the Sub1A-1 allele are tolerant of prolonged submergence. To elucidate the mechanism of Sub1A-1 mediated tolerance, we performed transcriptome analyses comparing the temporal submergence response of Sub1A-1 containing tolerant M202(Sub1) with the intolerant isoline M202 lacking this gene at three duration of submergence (0d, 1d, and 6d) with two biological replicates and one or two dye-swaps. We identified 898 genes displaying Sub1A-1-dependent regulation. Keywords: Abiotic stress tolerance response

Project description:Rice NSF45K microarray experiment to dissect submergence tolerance response in submergence tolerant rice plant, M202(Sub1): We previously characterized the rice (Oryza sativa L.) Sub1 locus encoding three Ethylene Responsive Factor (ERF) transcriptional regulators. Genotypes carrying the Sub1A-1 allele are tolerant of prolonged submergence. To elucidate the mechanism of Sub1A-1 mediated tolerance, we performed transcriptome analyses comparing the temporal submergence response of Sub1A-1 containing tolerant M202(Sub1) with the intolerant isoline M202 lacking this gene at three duration of submergence (0d, 1d, and 6d) with two biological replicates and one or two dye-swaps. We identified 898 genes displaying Sub1A-1-dependent regulation. Keywords: Abiotic stress tolerance response Three-condition experiment, M202(Sub1) vs wild type control (M202) at three durations of submergence (0d, 1d and 6d). Biological replicates: 2, independently grown and harvested. Technical replicates replicates: 1-2 control.

Project description:To identify binding sites and nodule SAGs that are directly targeted by NAC094, we used DAP-seq, which allows the capture of the NAC094 regulatory targets at the whole-genome scale. A total of 2,819 binding peaks corresponding to 2,721 genes were identified from two repeats of the DAP-seq experiment.

Project description:A ChIP-Seq was performed using 35S::PIF7-Flash and 35S::bHLH60-Flag transgenic plants after 1 hr shade treatment. Approximately 6374 peaks (5262 genes) were considered as high-confidence of PIF7 binding peaks (Fold change > 2, q-value < 0.05). And 2278 peaks (2143 genes) were considered as high-confidence of bHLH60 binding peaks. The bound genes of PIF7 significantly overlapped with bHLH60-bound genes. And, the transcriptional levels of PIF7 and bHLH60 co-bound genes were also regulated by PIF7 and bHLH48/60. Our results indicated PIF7 and bHLH60 form a heterodimer to bind to promoters of the common target genes and regulate their expressions.

Project description:In rice (Oryza sativa L.), the haplotype at the multigenic SUBMERGENCE 1 (SUB1) locus determines survival of prolonged submergence. SUB1 encodes two or three group VII Ethylene Response Factor (ERF) family transcription factors, SUB1A, SUB1B and SUB1C. A highly submergence-inducible SUB1A allele is present in lines that are submergence tolerant. This gene is the determinant of submergence tolerance. Here, the heterologous ectopic expression of rice SUB1A and SUB1C in Arabidopsis thaliana was employed to assess the transcriptional network mobilized by ectopic expression of SUB1A and SUB1C.

Project description:DAPseq was performed to confirm the target genes of ClNAC56. DAP-seq results showed that there were 3646 peaks (p<0.05) identified and among these peaks, 45.4% peaks identified in 5’UTR region, 12% peaks identified in genomic DNA region, 39.2% peaks in distal intergenic and 3.4% in downstream. The top motifs for ClNAC56 binding was confirmed as ‘(A/G)(G/A)(T/A)(T/G)(A/G/C)CGT(G/A)(T/C/A)’ which showed high similarity to ANACs in Arabidopisis.

Project description:As 5-15% of higher eukaryotes genes are transcription factors (TFs), the lack of transcription factor binding site (TFBS) information for most factors in most organisms limits the study of gene regulation. Here we describe a next-generation sequencing method, DNA affinity purification (DAP-Seq), an in vitro gDNA/TF interaction assay that produces whole-genome TFBS annotation for any factor from any organism. Like ChIP-Seq, DAP-Seq resolves TFBS as discrete peaks at genomic locations which allows for accurate motif prediction direct assignment of functionally relevant target genes, and shows better overlap with ChIP-Seq peaks than indirect motif assignment approaches. We applied DAP-Seq to a set of 50 transcription factors in eight Arabidopsis thaliana and one Zea Mays families to gain novel biological insight into TFBS architectures, functions, evolution and methylation-sensitivity. Overall, DAP-Seq offers a low-cost high-throughput approach to identify TFBS in native sequence context for any organism complete with all DNA chemical modifications.

Project description:Most crop species cannot survive flooding events for a long period of time. However, within the Cardamineae tribe of the Brassicaceae family, there exist several wild species with high flooding tolerance. Here, Rorippa islandica was identified as a genetically accessible diploid species with high submergence tolerance. Another diploid species from the same genus, R. stylosa, showed similar submergence sensitivity compared with Arabidopsis. Both species exhibited a strong and partially overlapping transcriptomic response to submergence within the first 48 hours of stress, including carbon-starvation and ethylene-responsive marker genes. We demonstrate that R. islandica can be transformed via floral dip, but with rather low frequency. The successful CRISPR-Cas9-mediated knockout of RiBCA3 confirms the suitability of this species for genetic transformation. However, although it was hypothesized that RiBCA3 might have an important function in carbon fixation under water, no differences in submergence survival or underwater photosynthesis were observed between wildtype and bca3 knockout lines. The molecular mechanisms of submergence tolerance of Rorippa islandica are therefore not understood yet. The data indicate that illumination and therefore photosynthesis-associated processes must be the basis for superior submergence survival. This work suggests that Rorippa islandica is a promising dicot model to further investigate the underlying tolerance mechanisms.

Project description:The stilbenoid pathway is responsible for the production of resveratrol in grapevine (Vitis vinifera L.). A few transcription factors (TFs) have been identified as regulators of this pathway, but the extent of this control has not been deeply studied. Here we demonstrate how DNA affinity purification sequencing (DAP-Seq) allows for genome-wide TF binding site interrogation in grape. We obtained 5,190 and 4,443 binding events assigned to 4,041 and 3,626 genes for MYB14 and MYB15, respectively (around 40% of peaks located within -10kb of transcription start sites). DAP-Seq of MYB14/MYB15 was combined with aggregate gene co-expression networks (GCNs) built from more than 1,400 transcriptomic datasets from leaves, fruits and flowers to narrow down bound genes to a set of high confidence targets. The analysis of MYB14, MYB15 and MYB13, a third uncharacterized member of Subgroup 2 (S2), showed that in addition to the few previously known stilbene synthase (STS) targets, these regulators bind to 30 out of 47 STS family genes. Moreover, all three MYBs bind to several PAL, C4H and 4CL genes, in addition to shikimate pathway genes, the WRKY03 stilbenoid co-regulator and resveratrol-modifying gene candidates amongst which ROMT2-3 were validated enzymatically. A high proportion of DAP-Seq bound genes was induced in the activated transcriptomes of transient MYB15-overexpressing grapevine leaves, validating our methodological approach for delimiting TF targets. Overall, Subgroup 2 R2R3-MYBs appear to play a key role in binding and directly regulating several primary and secondary metabolic steps leading to an increased flux towards stilbenoid production. The integration of DAP-Seq and reciprocal GCNs offers a rapid framework for gene function characterization using genome-wide approaches in the context of non-model plant species and stands up as a valid first approach for identifying gene regulatory networks of specialized metabolism.