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1. N ⁶ ‐methyladenosine and RNA secondary structure affect transcript stability and protein abundance during systemic salt stress in Arabidopsis

   https://doi.org/10.1002/pld3.239  

   Kramer, Marianne C.; Janssen, Kevin A.; Palos, Kyle; Nelson, Andrew D. L.; Vandivier, Lee E.; Garcia, Benjamin A.; Lyons, Eric; Beilstein, Mark A.; Gregory, Brian D. (July 2020, Plant Direct)

   Abstract After transcription, a messenger RNA (mRNA) is further post‐transcriptionally regulated by several features including RNA secondary structure and covalent RNA modifications (specifically N⁶‐methyladenosine, m⁶A). Both RNA secondary structure and m⁶A have been demonstrated to regulate mRNA stability and translation and have been independently linked to plant responses to soil salinity levels. However, the effect of m⁶A on regulating RNA secondary structure and the combinatorial interplay between these two RNA features during salt stress response has yet to be studied. Here, we globally identify RNA‐protein interactions and RNA secondary structure during systemic salt stress. This analysis reveals that RNA secondary structure changes significantly during salt stress, and that it is independent of global changes in RNA‐protein interactions. Conversely, we find that m⁶A is anti‐correlated with RNA secondary structure in a condition‐dependent manner, with salt‐specific m⁶A correlated with a decrease in mRNA secondary structure during salt stress. Taken together, we suggest that salt‐specific m⁶A deposition and the associated loss of RNA secondary structure results in increases in mRNA stability for transcripts encoding abiotic stress response proteins and ultimately increases in protein levels from these stabilized transcripts. In total, our comprehensive analyses reveal important post‐transcriptional regulatory mechanisms involved in plant long‐term salt stress response and adaptation. 

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2. mRNA N⁶ ‐methyladenosine is critical for cold tolerance in Arabidopsis

   https://doi.org/10.1111/tpj.15872  

   Govindan, Ganesan; Sharma, Bishwas; Li, Yong‐Fang; Armstrong, Christopher D.; Merum, Pandrangaiah; Rohila, Jai S.; Gregory, Brian D.; Sunkar, Ramanjulu (July 2022, The Plant Journal)

   SUMMARY Plants respond to low temperatures by altering the mRNA abundance of thousands of genes contributing to numerous physiological and metabolic processes that allow them to adapt. At the post‐transcriptional level, these cold stress‐responsive transcripts undergo alternative splicing, microRNA‐mediated regulation and alternative polyadenylation, amongst others. Recently, m⁶A, m⁵C and other mRNA modifications that can affect the regulation and stability of RNA were discovered, thus revealing another layer of post‐transcriptional regulation that plays an important role in modulating gene expression. The importance of m⁶A in plant growth and development has been appreciated, although its significance under stress conditions is still underexplored. To assess the role of m⁶A modifications during cold stress responses, methylated RNA immunoprecipitation sequencing was performed in Arabidopsis seedlings esposed to low temperature stress (4°C) for 24 h. This transcriptome‐wide m⁶A analysis revealed large‐scale shifts in this modification in response to low temperature stress. Because m⁶A is known to affect transcript stability/degradation and translation, we investigated these possibilities. Interestingly, we found that cold‐enriched m⁶A‐containing transcripts demonstrated the largest increases in transcript abundance coupled with increased ribosome occupancy under cold stress. The significance of the m⁶A epitranscriptome on plant cold tolerance was further assessed using themtamutant in which the major m⁶A methyltransferase gene was mutated. Compared to the wild‐type, along with the differences inCBFsandCORgene expression levels, themtamutant exhibited hypersensitivity to cold treatment as determined by primary root growth, biomass, and reactive oxygen species accumulation. Furthermore, and most importantly, both non‐acclimated and cold‐acclimatedmtamutant demonstrated hypersensitivity to freezing tolerance. Taken together, these findings suggest a critical role for the epitranscriptome in cold tolerance of Arabidopsis. 

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3. m ⁶ A modification plays an integral role in mRNA stability and translation during pattern-triggered immunity

   https://doi.org/10.1073/pnas.2411100121  

   Chen, Tianyuan; Greene, George H; Motley, Jonathan; Mwimba, Musoki; Luo, Guan-Zheng; Xu, Guoyong; Karapetyan, Sargis; Xiang, Yezi; Liu, Chang; He, Chuan; et al (August 2024, Proceedings of the National Academy of Sciences)

   Plants employ distinct mechanisms to respond to environmental changes. Modification of mRNA byN⁶-methyladenosine (m⁶A), known to affect the fate of mRNA, may be one such mechanism to reprogram mRNA processing and translatability upon stress. However, it is difficult to distinguish a direct role from a pleiotropic effect for this modification due to its prevalence in RNA. Through characterization of the transient knockdown-mutants of m⁶A writer components and mutants of specific m⁶A readers, we demonstrate the essential role that m⁶A plays in basal resistance and pattern-triggered immunity (PTI). A global m⁶A profiling of mock and PTI-inducedArabidopsisplants as well as formaldehyde fixation and cross-linking immunoprecipitation-sequencing of the m⁶A reader, EVOLUTIONARILY CONSERVED C-TERMINAL REGION2 (ECT2) showed that while dynamic changes in m⁶A modification and binding by ECT2 were detected upon PTI induction, most of the m⁶A sites and their association with ECT2 remained static. Interestingly, RNA degradation assay identified a dual role of m⁶A in stabilizing the overall transcriptome while facilitating rapid turnover of immune-induced mRNAs during PTI. Moreover, polysome profiling showed that m⁶A enhances immune-associated translation by binding to the ECT2/3/4 readers. We propose that m⁶A plays a positive role in plant immunity by destabilizing defense mRNAs while enhancing their translation efficiency to create a transient surge in the production of defense proteins. 

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4. mRNA ADENOSINE METHYLASE promotes drought tolerance through N⁶ ‐methyladenosine‐dependent and independent impacts on mRNA regulation in Arabidopsis

   https://doi.org/10.1111/nph.20227  

   Ganguly, Diep_R; Li, Yongfang; Bhat, Susheel_Sagar; Tiwari, Shalini; Ng, Pei_Jia; Gregory, Brian_D; Sunkar, Ramanjulu (October 2024, New Phytologist)

   Summary Among many mRNA modifications, adenine methylation at the N⁶position (N⁶‐methyladenosine, m⁶A) is known to affect mRNA biology extensively. The influence of m⁶A has yet to be assessed under drought, one of the most impactful abiotic stresses.We show thatArabidopsis thaliana(L.) Heynh. (Arabidopsis) plants lacking mRNA ADENOSINE METHYLASE (MTA) are drought‐sensitive. Subsequently, we comprehensively assess the impacts of MTA‐dependent m⁶A changes during drought on mRNA abundance, stability, and translation in Arabidopsis.During drought, there is a global trend toward hypermethylation of many protein‐coding transcripts that does not occur inmta. We also observe complex regulation of m⁶A at a transcript‐specific level, possibly reflecting compensation by other m⁶A components. Importantly, a subset of transcripts that are hypermethylated in an MTA‐dependent manner exhibited reduced turnover and translation inmta, compared with wild‐type (WT) plants, during drought. Additionally, MTA impacts transcript stability and translation independently of m⁶A. We also correlate drought‐associated deposition of m⁶A with increased translation of modulators of drought response, such asRD29A,COR47,COR413,ALDH2B,ERD7, andABF4in WT, which is impaired inmta.m⁶A is dynamic during drought and, alongside MTA, promotes tolerance by regulating drought‐responsive changes in transcript turnover and translation. 

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5. Effects of Epitranscriptomic RNA Modifications on the Catalytic Activity of the SARS‐CoV‐2 Replication Complex**

   https://doi.org/10.1002/cbic.202300095  

   Apostle, Alexander; Yin, Yipeng; Chillar, Komal; Eriyagama, Adikari_M_D_N; Arneson, Reed; Burke, Emma; Fang, Shiyue; Yuan, Yinan (March 2023, ChemBioChem)

   Abstract SARS‐CoV‐2 causes individualized symptoms. Many reasons have been given. We propose that an individual's epitranscriptomic system could be responsible as well. The viral RNA genome can be subject to epitranscriptomic modifications, which can be different for different individuals, and thus epitranscriptomics can affect many events including RNA replication differently. In this context, we studied the effects of modifications including pseudouridine (Ψ), 5‐methylcytosine (m⁵C),N6‐methyladenosine (m⁶A),N1‐methyladenosine (m¹A) andN3‐methylcytosine (m³C) on the activity of SARS‐CoV‐2 replication complex (SC2RC). We found that Ψ, m⁵C, m⁶A and m³C had little effect, whereas m¹A inhibited the enzyme. Both m¹A and m³C disrupt canonical base pairing, but they had different effects. The fact that m¹A inhibits SC2RC implies that the modification can be difficult to detect. This fact also implies that individuals with upregulated m¹A including cancer, obesity and diabetes patients might have milder symptoms. However, this contradicts clinical observations. Relevant discussions are provided. 

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