Bistable Behavior of the Cylindrical Origami Structure With Kresling Pattern

Nutrient stresses induce foliar chlorosis and growth defects. Here we propose heterotrimeric G proteins as signaling mediators of various nutrient stresses, through meta-analyses of >20 transcriptomic data sets associated with nutrient stresses or G protein mutations. Systematic comparison of transcriptomic data yielded 104 genes regulated by G protein subunits under common nutrient stresses: 69 genes under Gβ subunit (AGB1) control and 35 genes under Gα subunit (GPA1) control. Quantitative real-time PCR experiments validate that several transcription factors and metal transporters changed in expression level under suboptimal iron, zinc, and/or copper concentrations, while being misregulated in the Arabidopsis Gβ-null (agb1) mutant. The agb1 mutant had altered metal ion profiles and exhibited severe growth arrest under zinc stress, and aberrant root waving under iron and zinc stresses, while the Gα-null mutation attenuated leaf chlorosis under iron deficiency in both Arabidopsis and rice. Our transcriptional network analysis inferred computationally that WRKY-family transcription factors mediate the AGB1-dependent nutrient responses. As corroborating evidence of our inference, ectopic expression of WRKY25 or WRKY33 rescued the zinc stress phenotypes and the expression of zinc transporters in the agb1-2 background. These results, together with Gene Ontology analyses, suggest two contrasting roles for G protein-coupled signaling pathways in micronutrient stress responses: one enhancing general stress tolerance and the other modulating ion homeostasis through WRKY transcriptional regulatory networks. In addition, tolerance to iron stress in the rice Gα mutant provides an inroad to improve nutrient stress tolerance of agricultural crops by manipulating G protein signaling.

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Diversification of heat shock transcription factors expanded thermal stress responses during early plant evolution

Hoh

Boonyaves

et al. 2022

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The copy numbers of many plant transcription factor (TF) genes substantially increased during terrestrialization. This allowed TFs to acquire new specificities and thus create gene regulatory networks (GRNs) with new biological functions to help plants adapt to terrestrial environments. Through characterizing Heat Shock Factor (HSF) genes MpHSFA1 and MpHSFB1 in the liverwort Marchantia polymorpha, we explored how heat-responsive GRNs widened their functions in M. polymorpha and Arabidopsis thaliana. An interspecies comparison of heat-induced transcriptomes and the evolutionary rates of HSFs demonstrated the emergence and subsequent rapid evolution of HSFB prior to terrestrialization. Transcriptome and metabolome analyses of M. polymorpha HSF-null mutants revealed that MpHSFA1 controls canonical heat responses such as thermotolerance and metabolic changes. MpHSFB1 also plays essential roles in heat responses, as well as regulating developmental processes including meristem branching and antheridiophore formation. Analysis of cis-regulatory elements revealed development- and stress-related TFs that function directly or indirectly downstream of HSFB. Male gametophytes of M. polymorpha showed higher levels of thermotolerance than female gametophytes, which could be explained by different expression levels of MpHSFA1U and MpHSFA1V on sex chromosome. We propose that the diversification of HSFs is linked to the expansion of HS responses, which enabled coordinated multicellular reactions in land plants.

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Emerging techniques to decipher microRNAs (miRNAs) and their regulatory role in conferring abiotic stress tolerance of plants

Banerjee

Roychoudhury

Krishnamoorthi

2016

Plant Biotechnol Rep

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MicroRNAs (miRNAs) are a distinct class of non-coding, small regulatory RNAs which have evolved significantly in generating abiotic stress tolerance across a variety of model plants and crop species. These miRNAs, while undergoing post-transcriptional modifications, have often been found to be linked with epigenetic regulations of stress-responsive gene expression. The discovery of isomers of miRNAs (isomiRs) is also a remarkable event, as some schools of scientists believe them to be regulatory molecules distinct from the conventional miRNAs. The link between isomiRs and abiotic stress responses in plants is now a field of intense research. In this review, we have highlighted the mechanism of various tools and techniques which are essential to visualize high-throughput data analysis. Such data are required for generating large-scale libraries of small RNAs, from which stress-responsive miRNAs are conventionally screened. The concluding part of the review especially contains an exhaustive discussion on the recent developments of miRNA-mediated tolerance towards multiple stresses, such as nutrient deficiency, salinity, drought, oxidative stress, hypoxia, temperature stress, radiation, and heavy metal toxicity. Both transgenic as well as miRNAome approaches have been focussed in this section of the review.

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Shalini Krishnamoorthi

Evolutionarily conserved hierarchical gene regulatory networks for plant salt stress response

Crosstalk between heterotrimeric G protein-coupled signaling pathways and WRKY transcription factors modulating plant responses to suboptimal micronutrient conditions

Diversification of heat shock transcription factors expanded thermal stress responses during early plant evolution

Emerging techniques to decipher microRNAs (miRNAs) and their regulatory role in conferring abiotic stress tolerance of plants

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