Enhanced HSP70 Binding to MA-methylated RNAs Facilitates Cold Stress Adaptation in Mango Seedlings

Overview

Journal BMC Plant Biol

Publisher Biomed Central

Specialty Biology

Date 2024 Nov 23

PMID 39578738

Authors

Yongxiang Huang

Mingming Chen

Daming Chen

Haomin Chen

Zhihao Xie

Shuangfeng Dai

Affiliations

Soon will be listed here.

Abstract

Background: Cold stress poses a serious challenge to tropical fruit production, particularly in mango. N-methyladenosine (mA) modifications are key regulators of gene expression, enabling plants to respond to stress responses, enhance adaptation and improve resilience to environmental challenges.

Results: In our study, transcriptome-wide mA methylation profiling under cold stress identified 6,499 differentially methylated mA peaks and 2,164 differentially expressed genes (DEGs) in mango seedlings. Among these genes, six exhibited both significant increases in mA modification levels and gene expression, 21 showed a significant increase in mA levels but a concurrent downregulation of gene expression, and 26 showed reduced mA levels but exhibited increased gene expression, highlighting distinct regulatory patterns in mA-mediated gene expression control. Gene Ontology (GO) enrichment analysis revealed significant involvement in pathways such as potassium ion import, nitrate response, and transcription regulation. Notably, HSP70 was one of the upregulated genes in response to cold stress. RNA immunoprecipitation (RNA-IP) assays confirmed the association of HSP70 with mA-modified RNAs in vivo, supporting its role in regulating stress-responsive transcripts. Additionally, immunofluorescence analysis demonstrated the formation of HSP70 condensates in plant cells under cold stress, indicating a potential mechanism for localized RNA stabilization. Fluorescence polarization assays demonstrated that HSP70 binds preferentially to mA-modified RNAs, suggesting its role in forming protective condensates under cold conditions. This interaction between mA modification and HSP70 points to a potential mechanism that helps stabilize stress-responsive transcripts, contributing to the plant's enhanced cold tolerance.

Conclusions: mA modifications play a vital role in regulating gene expression under cold stress, offering new insights into mango's stress responses and potential breeding strategies for cold tolerance.

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