Inter- and intra-molecular interactions of Arabidopsis thaliana DELLA protein RGL1

The phytohormone gibberellin and the DELLA proteins act together to control key aspects of plant development. Gibberellin induces degradation of DELLA proteins by recruitment of an F-box protein using a molecular switch: a gibberellin-bound nuclear receptor interacts with the N-terminal domain of DELLA proteins, and this event primes the DELLA C-terminal domain for interaction with the F-box protein. However, the mechanism of signalling between the N- and C-terminal domains of DELLA proteins is unresolved. In the present study, we used in vivo and in vitro approaches to characterize di- and tri-partite interactions of the DELLA protein RGL1 (REPRESSOR OF GA1-3-LIKE 1) of Arabidopsis thaliana with the gibberellin receptor GID1A (GIBBERELLIC ACID-INSENSITIVE DWARF-1A) and the F-box protein SLY1 (SLEEPY1). Deuterium-exchange MS unequivocally showed that the entire N-terminal domain of RGL1 is disordered prior to interaction with the GID1A; furthermore, association/dissociation kinetics, determined by surface plasmon resonance, predicts a two-state conformational change of the RGL1 N-terminal domain upon interaction with GID1A. Additionally, competition assays with monoclonal antibodies revealed that contacts mediated by the short helix Asp-Glu-Leu-Leu of the hallmark DELLA motif are not essential for the GID1A–RGL1 N-terminal domain interaction. Finally, yeast two- and three-hybrid experiments determined that unabated communication between N- and C-terminal domains of RGL1 is required for recruitment of the F-box protein SLY1

A Novel Dwarfing Mutation in a Green Revolution Gene from Brassica rapa

Mutations in the biosynthesis or signaling pathways of gibberellin (GA) can cause dwarfing phenotypes in plants, and the use of such mutations in plant breeding was a major factor in the success of the Green Revolution. DELLA proteins are GA signaling repressors whose functions are conserved in different plant species. Recent studies show that GA promotes stem growth by causing degradation of DELLA proteins via the ubiquitin-proteasome pathway. The most widely utilized dwarfing alleles in wheat (Triticum aestivum; e.g. Rht-B1b and Rht-D1b) encode GA-resistant forms of a DELLA protein that function as dominant and constitutively active repressors of stem growth. All of the previously identified dominant DELLA repressors from several plant species contain N-terminal mutations. Here we report on a novel dwarf mutant from Brassica rapa (Brrga1-d) that is caused by substitution of a conserved amino acid in the C-terminal domain of a DELLA protein. Brrga1-d, like N-terminal DELLA mutants, retains its repressor function and accumulates to high levels, even in the presence of GA. However, unlike wild-type and N-terminal DELLA mutants, Brrga1-d does not interact with a protein component required for degradation, suggesting that the mutated amino acid causes dwarfism by preventing an interaction needed for its degradation. This novel mutation confers nondeleterious dwarf phenotypes when transferred to Arabidopsis (Arabidopsis thaliana) and oilseed rape (Brassica napus), indicating its potential usefulness in other crop species

Effects of GS3 Editing in japonica Rice ‘Nipponbare’ on Grain Morphology, Yield Components, and Response to Heat Stress at the Reproductive Stage

Rice (Oryza sativa), particularly the japonica subspecies, is a vital global food source but often suffers from short grain length and heat sensitivity, highlighting the need for genetic improvement. This study employed CRISPR/Cas9 technology to investigate the effects of Grain Size3 (GS3) gene editing in the japonica cultivar, ‘Nipponbare’. Successful GS3 editing increased grain size across stable T3 and T4 generations. Importantly, different GS3-edited lines, even when all targeted within exon 1, resulted in varied effects on grain length and other yield components. Transcriptomic analyses revealed unique gene expression profiles for each edited line, highlighting the fact that subtle GS3 mutations trigger diverse transcriptional cascades. While common differentially expressed genes (DEGs) were enriched in ethylene signaling and chitinase activity, line-specific KEGG analyses showed distinct pathway enrichments. Crucially, the CR-L5 line exhibited significantly enhanced heat tolerance at heading stage. Under high-temperature stress, CR-L5 maintained a higher relative seed setting rate and a 15% greater grain yield than the wild type. This enhanced thermotolerance in CR-L5 correlated with differing expressions of several wax biosynthesis and chitinase-related genes. Our study provides evidence that specific gs3 mutations can confer enhanced reproductive-stage thermotolerance, offering a strategy for breeding climate-resilient japonica rice with improved grain quality and yield under stress

Investigating cold tolerance mechanisms in rice seedlings: Alternative splicing, promoter analysis, and their applications for marker development

Cold stress harms rice seedlings, causing yield reduction. Enhancing cold tolerance at the seedling stage is crucial for rice breeding. OsFH10, OsFER1, ONAC045, and OsProT were selected to study gene expression including alternative splicing and promoter sequence analysis in rice seedlings. Under cold stress, the four genes exhibited alternative splicing showing intron retention isoforms, and displayed a consistent pattern of upregulation in a group of cold-tolerant varieties, while no isoforms were presented in a group of sensitive varieties. These intron retention isoforms might play a role in facilitating improved cold adaptation in rice seedlings. Promoter sequence analysis revealed polymorphisms of Single nucleotide polymorphisms (SNPs) or Insertions and Deletions (InDels) in ONAC045 and OsProT that distinguished cold-tolerant from cold-sensitive varieties. ONAC045 SNP and OsProT InDel markers were developed and validated using 159 rice lines. These markers were associated with cold tolerance (P < 0.05) and practical to use with general agarose gel. The ONAC045 marker showed high efficacy in predicting tolerance in rice germplasm seedlings, achieving an accuracy of 43.8%. Furthermore, the OsProT marker exhibited greater sensitivity towards cold-tolerant indica seedlings. Both markers have a wide distribution in all rice subspecies. Our findings elucidate the cold response mechanisms and provide insights into potential application in developing cold-tolerant indica rice varieties

RNA Sequencing Reveals Rice Genes Involved in Male Reproductive Development under Temperature Alteration

Rice (Oryza sativa L.) is one of the most important food crops, providing food for nearly half of the world population. Rice grain yields are affected by temperature changes. Temperature stresses, both low and high, affect male reproductive development, resulting in yield reduction. Thermosensitive genic male sterility (TGMS) rice is sterile at high temperature and fertile at low temperature conditions, facilitating hybrid production, and is a good model to study effects of temperatures on male development. Semithin sections of the anthers of a TGMS rice line under low (fertile) and high (sterile) temperature conditions showed differences starting from the dyad stage, suggesting that genes involved in male development play a role during postmeiotic microspore development. Using RNA sequencing (RNA-Seq), transcriptional profiling of TGMS rice panicles at the dyad stage revealed 232 genes showing differential expression (DEGs) in a sterile, compared to a fertile, condition. Using qRT-PCR to study expression of 20 selected DEGs using panicles of TGMS and wild type rice plants grown under low and high temperature conditions, revealed that six out of the 20 selected genes may be unique to TGMS, while the other 14 genes showed common responses to temperatures in both TGMS and wild-type rice plants. The results presented here would be useful for further investigation into molecular mechanisms controlling TGMS and rice responses to temperature alteration.</jats:p