Decoding Groundwater Level Patterns and Abrupt Changes in Central and Southern California’s Alluvial Regions

Groundwater for Sustainable Development, Journal Year: 2025, Volume and Issue: 28, P. 101409 - 101409

Published: Jan. 10, 2025

Language: Английский

Integrative Omics reveals genetic basis and TaMYB7-A1’s function in wheat WUE and drought resilience

Research Square (Research Square), Journal Year: 2024, Volume and Issue: unknown

Published: Dec. 23, 2024

Improving water use efficiency (WUE) and drought resistance in wheat is critical for ensuring global food security under changing climate conditions. Here, we integrated multi-omic data, including population-scale phenotyping, transcriptomics, genomics, to dissect the genetic molecular mechanisms underlying WUE resilience wheat. Genome-wide association studies (GWAS) revealed 8,135 SNPs associated with WUE-related traits, identifying 258 conditional non-conditional QTLs, many of which co-localized known drought-resistance genes. Pan-transcriptome analysis uncovered tissue-specific expression patterns, core unique gene functions, dynamic sub-genomic biases response drought. eQTL mapping pinpointed 146,966 regulatory loci, condition-specific hotspots enriched genes involved regulation, osmoregulation, photosynthesis. Integration Weighted co-expression network (WGCNA), Summary-data-based Mendelian Randomization (SMR) GWAS, eQTLs identified 207 candidate causal as key regulators traits wheat, such TaMYB7-A1. Functional analyses found that TaMYB7-A1 enhances tolerance by promoting root growth, reducing oxidative stress, improving osmotic enabling better access survival stress. It also increases photosynthesis WUE, boosting yield without compromising performance well-watered conditions, making it ideal target breeding. Our findings provide a comprehensive omic framework understanding architecture resistance, offering valuable targets breeding resilient varieties.

Language: Английский

Integrative Omics reveals genetic basis and TaMYB7-A1's function in wheat WUE and drought resilience

bioRxiv (Cold Spring Harbor Laboratory), Journal Year: 2024, Volume and Issue: unknown

Published: Dec. 13, 2024

Improving water use efficiency (WUE) and drought resistance in wheat is critical for ensuring global food security under changing climate conditions. Here, we integrated multi-omic data, including population-scale phenotyping, transcriptomics, genomics, to dissect the genetic molecular mechanisms underlying WUE resilience wheat. Genome-wide association studies (GWAS) revealed 8,135 SNPs associated with WUE-related traits, identifying 258 conditional non-conditional QTLs, many of which co-localized known drought-resistance genes. Pan-transcriptome analysis uncovered tissue-specific expression patterns, core unique gene functions, dynamic sub-genomic biases response drought. eQTL mapping pinpointed 146,966 regulatory loci, condition-specific hotspots enriched genes involved regulation, osmoregulation, photosynthesis. Integration Weighted co-expression network (WGCNA), Summary-data-based Mendelian Randomization (SMR) GWAS, eQTLs identified 207 candidate causal as key regulators traits wheat, such TaMYB7-A1. Functional analyses found that TaMYB7-A1 enhances tolerance by promoting root growth, reducing oxidative stress, improving osmotic enabling better access survival stress. It also increases photosynthesis WUE, boosting yield without compromising performance well-watered conditions, making it ideal target breeding. Our findings provide a comprehensive omic framework understanding architecture resistance, offering valuable targets breeding resilient varieties.

Language: Английский