Glycine-Rich RNA-Binding Protein AtGRP7 Functions in Nickel and Lead Tolerance in Arabidopsis.

Plant glycine-rich RNA-binding proteins (GRPs) play crucial roles in the response to environmental stresses. However, the functions of AtGRP7 in plants under heavy metal stress remain unclear. In the present study, in Arabidopsis, the transcript level of AtGRP7 was markedly increased by Ni but was decreased by Pb. AtGRP7-overexpressing plants improved Ni tolerance, whereas the knockout mutant (grp7) was more susceptible than the wild type to Ni. In addition, grp7 showed greatly enhanced Pb tolerance, whereas overexpression lines showed high Pb sensitivity. Ni accumulation was reduced in overexpression lines but increased in grp7, whereas Pb accumulation in grp7 was lower than that in overexpression lines. Ni induced glutathione synthase genes GS1 and GS2 in overexpression lines, whereas Pb increased metallothionein genes MT4a and MT4b and phytochelatin synthase genes PCS1 and PCS2 in grp7. Furthermore, Ni increased CuSOD1 and GR1 in grp7, whereas Pb significantly induced FeSOD1 and FeSOD2 in overexpression lines. The mRNA stability of GS2 and PCS1 was directly regulated by AtGRP7 under Ni and Pb, respectively. Collectively, these results indicate that AtGRP7 plays a crucial role in Ni and Pb tolerance by reducing Ni and Pb accumulation and the direct or indirect post-transcriptional regulation of genes related to heavy metal chelators and antioxidant enzymes.

FIONA1-mediated mRNA m6 A methylation regulates the response of Arabidopsis to salt stress.

N6 -methyladenosine (m6 A) is an mRNA modification widely found in eukaryotes and plays a crucial role in plant development and stress responses. FIONA1 (FIO1) is a recently identified m6 A methyltransferase that regulates Arabidopsis (Arabidopsis thaliana) floral transition; however, its role in stress response remains unknown. In this study, we demonstrate that FIO1-mediated m6 A methylation plays a vital role in salt stress response in Arabidopsis. The loss-of-function fio1 mutant was sensitive to salt stress. Importantly, the complementation lines expressing the wild-type FIO1 exhibited the wild-type phenotype, whereas the complementation lines expressing the mutant FIO1m , in which two critical amino acid residues essential for methyltransferase activity were mutated, did not recover the wild-type phenotype under salt stress, indicating that the salt sensitivity is associated with FIO1 methyltransferase activity. Furthermore, FIO1-mediated m6 A methylation regulated ROS production and affected the transcript level of several salt stress-responsive genes via modulating their mRNA stability in an m6 A-dependent manner in response to salt stress. Importantly, FIO1 is associated with salt stress response by specifically targeting and differentially modulating several salt stress-responsive genes compared with other m6 A writer. Collectively, our findings highlight the molecular mechanism of FIO1-mediated m6 A methylation in the salt stress adaptation.

Phylogenetic and functional analyses of N6-methyladenosine RNA methylation factors in the wheat scab fungus Fusarium graminearum.

In eukaryotes, N6-methyladenosine (m6A) RNA modification plays a crucial role in governing the fate of RNA molecules and has been linked to various developmental processes. However, the phyletic distribution and functions of genetic factors responsible for m6A modification remain largely unexplored in fungi. To get insights into the evolution of m6A machineries, we reconstructed global phylogenies of potential m6A writers, readers, and erasers in fungi. Substantial copy number variations were observed, ranging from up to five m6A writers in early-diverging fungi to a single copy in the subphylum Pezizomycotina, which primarily comprises filamentous fungi. To characterize m6A factors in a phytopathogenic fungus Fusarium graminearum, we generated knockout mutants lacking potential m6A factors including the sole m6A writer MTA1. However, the resulting knockouts did not exhibit any noticeable phenotypic changes during vegetative and sexual growth stages. As obtaining a homozygous knockout lacking MTA1 was likely hindered by its essential role, we generated MTA1-overexpressing strains (MTA1-OE). The MTA1-OE5 strain showed delayed conidial germination and reduced hyphal branching, suggesting its involvement during vegetative growth. Consistent with these findings, the expression levels of MTA1 and a potential m6A reader YTH1 were dramatically induced in germinating conidia, followed by the expression of potential m6A erasers at later vegetative stages. Several genes including transcription factors, transporters, and various enzymes were found to be significantly upregulated and downregulated in the MTA1-OE5 strain. Overall, our study highlights the functional importance of the m6A methylation during conidial germination in F. graminearum and provides a foundation for future investigations into m6A modification sites in filamentous fungi.IMPORTANCEN6-methyladenosine (m6A) RNA methylation is a reversible posttranscriptional modification that regulates RNA function and plays a crucial role in diverse developmental processes. This study addresses the knowledge gap regarding phyletic distribution and functions of m6A factors in fungi. The identification of copy number variations among fungal groups enriches our knowledge regarding the evolution of m6A machinery in fungi. Functional characterization of m6A factors in a phytopathogenic filamentous fungus Fusarium graminearum provides insights into the essential role of the m6A writer MTA1 in conidial germination and hyphal branching. The observed effects of overexpressing MTA1 on fungal growth and gene expression patterns of m6A factors throughout the life cycle of F. graminearum further underscore the importance of m6A modification in conidial germination. Overall, this study significantly advances our understanding of m6A modification in fungi, paving the way for future research into its roles in filamentous growth and potential applications in disease control.

ECT12, an YTH-domain protein, is a potential mRNA m6A reader that affects abiotic stress responses by modulating mRNA stability in Arabidopsis.

N6-methyladenosine (m6A), the most abundant modification found in eukaryotic mRNAs, is interpreted by m6A "readers," thus playing a crucial role in regulating RNA metabolism. The YT521-B homology-domain (YTHD) proteins, also known as EVOLUTIONARILY CONSERVED C-TERMINAL REGION (ECT), are recognized as m6A reader proteins in plants and animals. Among the 13 potential YTHD family proteins in Arabidopsis thaliana, the functions of only a few members are known. In this study, we determined the function of ECT12 (YTH11) as a potential m6A reader that plays a crucial role in response to abiotic stresses. The loss-of-function ect12 mutants showed no noticeable developmental defects under normal conditions but displayed hypersensitivity to salt or dehydration stress. The salt- or dehydration-hypersensitive phenotypes were correlated with altered levels of several m6A-modified stress-responsive transcripts. Notably, the increased or decreased transcript levels were associated with each transcript's reduced or enhanced decay, respectively. Electrophoretic mobility shift and RNA-immunoprecipitation assays showed that ECT12 binds to m6A-modified RNAs both in vitro and in planta, suggesting its role as an m6A reader. Collectively, these results indicate that the potential m6A reader ECT12 regulates the stability of m6A-modified RNA transcripts, thereby facilitating the response of Arabidopsis to abiotic stresses.

FLK is an mRNA m6A reader that regulates floral transition by modulating the stability and splicing of FLC in Arabidopsis.

N6-methyladenosine (m6A), which is added, removed, and interpreted by m6A writers, erasers, and readers, respectively, is the most abundant modification in eukaryotic mRNAs. The m6A marks play a pivotal role in the regulation of floral transition in plants. FLOWERING LOCUS K (FLK), an RNA-binding protein harboring K-homology (KH) motifs, is known to regulate floral transition by repressing the levels of a key floral repressor FLOWERING LOCUS C (FLC) in Arabidopsis. However, the molecular mechanism underlying FLK-mediated FLC regulation remains unclear. In this study, we identified FLK as a novel mRNA m6A reader protein that directly binds the m6A site in the 3'-untranslated region of FLC transcripts to repressing FLC levels by reducing its stability and splicing. Importantly, FLK binding of FLC transcripts was abolished in vir-1, an m6A writer mutant, and the late-flowering phenotype of the flk mutant could not be rescued by genetic complementation using the mutant FLKm gene, in which the m6A reader encoding function was eliminated, indicating that FLK binds and regulates FLC expression in an m6A-dependent manner. Collectively, our study has addressed a long-standing question of how FLK regulates FLC transcript levels and established a molecular link between the FLK-mediated recognition of m6A modifications on FLC transcripts and floral transition in Arabidopsis.

N6-methyladenosine RNA methylation modulates liquid‒liquid phase separation in plants.

Membraneless biomolecular condensates form distinct subcellular compartments that enable a cell to orchestrate numerous biochemical reactions in a spatiotemporal-specific and dynamic manner. Liquid‒liquid phase separation (LLPS) facilitates the formation of membraneless biomolecular condensates, which are crucial for many cellular processes in plants, including embryogenesis, the floral transition, photosynthesis, pathogen defense, and stress responses. The main component required for LLPS is a protein harboring key characteristic features, such as intrinsically disordered regions, low-complexity sequence domains, and prion-like domains. RNA is an additional component involved in LLPS. Increasing evidence indicates that modifications in proteins and RNAs play pivotal roles in LLPS. In particular, recent studies have indicated that N6-methyladenosine (m6A) modification of messenger RNA is crucial for LLPS in plants and animals. In this review, we provide an overview of recent developments in the role of mRNA methylation in LLPS in plant cells. Moreover, we highlight the major challenges in understanding the pivotal roles of RNA modifications and elucidating how m6A marks are interpreted by RNA-binding proteins crucial for LLPS.

Beyond transcription: compelling open questions in plant RNA biology.

The study of RNAs has become one of the most influential research fields in contemporary biology and biomedicine. In the last few years, new sequencing technologies have produced an explosion of new and exciting discoveries in the field but have also given rise to many open questions. Defining these questions, together with old, long-standing gaps in our knowledge, is the spirit of this article. The breadth of topics within RNA biology research is vast, and every aspect of the biology of these molecules contains countless exciting open questions. Here, we asked 12 groups to discuss their most compelling question among some plant RNA biology topics. The following vignettes cover RNA alternative splicing; RNA dynamics; RNA translation; RNA structures; R-loops; epitranscriptomics; long non-coding RNAs; small RNA production and their functions in crops; small RNAs during gametogenesis and in cross-kingdom RNA interference; and RNA-directed DNA methylation. In each section, we will present the current state-of-the-art in plant RNA biology research before asking the questions that will surely motivate future discoveries in the field. We hope this article will spark a debate about the future perspective on RNA biology and provoke novel reflections in the reader.

Arabidopsis N6-methyladenosine methyltransferase FIONA1 regulates floral transition by affecting the splicing of FLC and the stability of floral activators SPL3 and SEP3.

N 6-methyladenosine (m6A) RNA methylation has been shown to play a crucial role in plant development and floral transition. Two recent studies have identified FIONA1 as an m6A methyltransferase that regulates the floral transition in Arabidopsis through influencing the stability of CONSTANS (CO), SUPPRESSOR OF OVEREXPRESSION OF CONSTANS 1 (SOC1), and FLOWERING LOCUS C (FLC). In this study, we confirmed that FIONA1 is an m6A methyltransferase that installs m6A marks in a small group of mRNAs. Furthermore, we show that, in addition to its role in influencing the stability of CO, SOC1, and FLC, FIONA1-mediated m6A methylation influences the splicing of FLC, a key floral repressor, and the stability of SQUAMOSA PROMOTER-BINDING PROTEIN-LIKE 3 (SPL3) and SEPALLATA3 (SEP3), floral activators, which together play a vital role in floral transition in Arabidopsis. Our study confirms the function of FIONA1 as an m6A methyltransferase and suggests a close molecular link between FIONA1-mediated m6A methylation and the splicing of FLC and the destabilization of SPL3 and SEP3 in flowering time control.

ALKBH9C, a potential RNA m6 A demethylase, regulates the response of Arabidopsis to abiotic stresses and abscisic acid.

Although several studies have shown that AlkB homolog (ALKBH) proteins are potential RNA demethylases (referred to as 'erasers'), biological functions of only a few ALKBH proteins have been characterized to date. In this study, we determined the function of ALKBH9C (At4g36090) in seed germination and seedling growth of Arabidopsis thaliana in response to abiotic stress and abscisic acid (ABA). Seed germination of the alkbh9c mutant was delayed in response to salt, drought, cold and ABA. Moreover, seedling growth of the mutant was repressed under salt stress or ABA but enhanced under drought conditions. Notably, the stress-responsive phenotypes were associated with the altered expression of several m6 A-modified transcripts related to salt, drought or ABA response. Global m6 A levels were increased in the alkbh9c mutant, and ALKBH9C bound to m6 A-modified RNAs and had in vitro m6 A demethylase activity, suggesting its potential role as an m6 A eraser. The m6 A levels in several stress-responsive genes were increased in the alkbh9c mutant, and the stability of m6 A-modified transcripts was altered in the mutant. Collectively, our results suggest that m6 A eraser ALKBH9C is crucial for seed germination and seedling growth of Arabidopsis in response to abiotic stresses or ABA via affecting the stability of stress-responsive transcripts.

Epitranscriptomic mRNA modifications governing plant stress responses: underlying mechanism and potential application.

Plants inevitably encounter environmental adversities, including abiotic and biotic stresses, which significantly impede plant growth and reduce crop yield. Thus, fine-tuning the fate and function of stress-responsive RNAs is indispensable for plant survival under such adverse conditions. Recently, post-transcriptional RNA modifications have been studied as a potent route to regulate plant gene expression under stress. Among over 160 mRNA modifications identified to date, N6 -methyladenosine (m6 A) in mRNAs is notable because of its multifaceted roles in plant development and stress response. Recent transcriptome-wide mapping has revealed the distribution and patterns of m6 A in diverse stress-responsive mRNAs in plants, building a foundation for elucidating the molecular link between m6 A and stress response. Moreover, the identification and characterization of m6 A writers, readers and erasers in Arabidopsis and other model crops have offered insights into the biological roles of m6 A in plant abiotic stress responses. Here, we review the recent progress of research on mRNA modifications, particularly m6 A, and their dynamics, distribution, regulation and biological functions in plant stress responses. Further, we posit potential strategies for breeding stress-tolerant crops by engineering mRNA modifications and propose the future direction of research on RNA modifications to gain a much deeper understanding of plant stress biology.

Epitranscriptomics: An Additional Regulatory Layer in Plants' Development and Stress Response.

Epitranscriptomics has added a new layer of regulatory machinery to eukaryotes, and the advancement of sequencing technology has revealed more than 170 post-transcriptional modifications in various types of RNAs, including messenger RNA (mRNA), transfer RNA (tRNA), ribosomal RNA (rRNA), and long non-coding RNA (lncRNA). Among these, N6-methyladenosine (m6A) and N5-methylcytidine (m5C) are the most prevalent internal mRNA modifications. These regulate various aspects of RNA metabolism, mainly mRNA degradation and translation. Recent advances have shown that regulation of RNA fate mediated by these epitranscriptomic marks has pervasive effects on a plant's development and responses to various biotic and abiotic stresses. Recently, it was demonstrated that the removal of human-FTO-mediated m6A from transcripts in transgenic rice and potatoes caused a dramatic increase in their yield, and that the m6A reader protein mediates stress responses in wheat and apple, indicating that regulation of m6A levels could be an efficient strategy for crop improvement. However, changing the overall m6A levels might have unpredictable effects; therefore, the identification of precise m6A levels at a single-base resolution is essential. In this review, we emphasize the roles of epitranscriptomic modifications in modulating molecular, physiological, and stress responses in plants, and provide an outlook on epitranscriptome engineering as a promising tool to ensure food security by editing specific m6A and m5C sites through robust genome-editing technology.

Unique features of mRNA m6A methylomes during expansion of tomato (Solanum lycopersicum) fruits.

N6-methyladenosine (m6A) is the most abundant internal modification in eukaryotic messenger RNA. Although the role of m6A has been demonstrated in many biological processes, including embryonic development, flowering time control, microspore generation, fruit ripening, and stress responses, its contribution to other aspects of plant development still needs to be explored. Herein, we show the potential link between m6A deposition and the expansion of tomato (Solanum lycopersicum) fruits through parallel m6A-immunoprecipitation-sequencing (m6A-seq) and RNA-seq analyses. We found that global m6A levels increased during tomato fruit expansion from immature green to mature green stage. m6A-seq revealed that thousands of protein-coding genes are m6A-modified mainly in the 3'-untranslated regions. m6A-seq and RNA-seq analyses showed a positive association between m6A methylation and mRNA abundance. In particular, a large number of fruit expansion-related genes involved in hormone responses and endoreduplication were m6A modified and expressed more actively than the non-m6A-modified genes, suggesting a potential role of m6A modification in tomato fruit expansion. Importantly, altering m6A levels by direct injection of 3-deazaneplanocin A (DA; m6A writer inhibitor) or meclofenamic acid (MA; m6A eraser inhibitor) into tomato fruits suppressed fruit expansion; however, injection of exogenous DA or MA accelerated or delayed fruit ripening, respectively. Collectively, these results suggest a dynamic role of m6A methylation in the expansion and ripening of tomato fruits.

Alpha-ketoglutarate-dependent dioxygenase homolog 10B, an N6 -methyladenosine mRNA demethylase, plays a role in salt stress and abscisic acid responses in Arabidopsis thaliana.

N6 -methyladenosine (m6 A) is an abundant methylation mark in eukaryotic mRNAs. It is installed and removed by methyltransferases ("writers") and demethylases ("erasers"), respectively. A recent study has demonstrated that alpha-ketoglutarate-dependent dioxygenase homolog 10B (ALKBH10B) is an mRNA m6 A eraser affecting floral transition in Arabidopsis thaliana. However, the roles of m6 A eraser proteins, including ALKHB10B, in plant adaptation to abiotic stresses are largely unknown. In this study, we aimed to determine the role of ALKBH10B in the response of A. thaliana to abiotic stresses and abscisic acid (ABA). The m6 A level increased in response to salt stress, and m6 A levels in alkbh10b mutants were higher than those in the wild-type under both normal and salt stress conditions. Germination of alkbh10b mutant seeds was markedly delayed under salt stress but not under dehydration, cold, or ABA conditions. Seedling growth and survival rate of alkbh10b mutants were enhanced under salt stress. Notably, salt-tolerant phenotypes of alkbh10b mutants were correlated with decreased levels of several m6 A-modified genes, including ATAF1, BGLU22, and MYB73, which are negative effectors of salt stress tolerance. In response to ABA, both seedling and root growth of alkbh10b mutants were inhibited via upregulating ABA signaling-related genes, including ABI3 and ABI4. Collectively, these findings indicate that ALKBH10B-mediated m6 A demethylation affects the transcript levels of stress-responsive genes, which are important for seed germination, seedling growth, and survival of Arabidopsis thaliana in response to salt stress or ABA.

RsmD, a Chloroplast rRNA m2G Methyltransferase, Plays a Role in Cold Stress Tolerance by Possibly Affecting Chloroplast Translation in Arabidopsis.

Ribosomal RNA (rRNA) methylation is a pivotal process in the assembly and activity of ribosomes, which in turn play vital roles in the growth, development and stress responses of plants. Although few methyltransferases responsible for rRNA methylation have been identified in plant chloroplasts, the nature and function of these enzymes in chloroplasts remain largely unknown. In this study, we characterized ArabidopsisRsmD (At3g28460), an ortholog of the methyltransferase responsible for N2-methylguanosine (m2G) modification of 16S rRNA in Escherichia coli. Confocal microscopic analysis of an RsmD- green fluorescent protein fusion protein revealed that RsmD is localized to chloroplasts. Primer extension analysis indicated that RsmD is responsible for m2G methylation at position 915 in the 16S rRNA of Arabidopsis chloroplasts. Under cold stress, rsmd mutant plants exhibited retarded growth, i.e. had shorter roots, lower fresh weight and pale-green leaves, compared with wild-type (WT) plants. However, these phenotypes were not detected in response to drought or salt stress. Notably, the rsmd mutant was hypersensitive to erythromycin or lincomycin and accumulated fewer chloroplast proteins compared with the WT, suggesting that RsmD influences translation in chloroplasts. Complementation lines expressing RsmD in the rsmd mutant background recovered WT phenotypes. Importantly, RsmD harbored RNA methyltransferase activity. Collectively, the findings of this study indicate that RsmD is a chloroplast 16S rRNA methyltransferase responsible for m2G915 modification that plays a role in the adaptation of Arabidopsisto cold stress.

N6 -Methyladenosine mRNA methylation is important for salt stress tolerance in Arabidopsis.

As the most abundant internal modification of mRNA, N6 -methyladenosine (m6 A) methylation of RNA is emerging as a new layer of epitranscriptomic gene regulation in cellular processes, including embryo development, flowering-time control, microspore generation and fruit ripening, in plants. However, the cellular role of m6 A in plant responses to environmental stimuli remains largely unexplored. In this study, we show that m6 A methylation plays an important role in salt stress tolerance in Arabidopsis. All mutants of m6 A writer components, including MTA, MTB, VIRILIZER (VIR) and HAKAI, displayed salt-sensitive phenotypes in an m6 A-dependent manner. The vir mutant, in which the level of m6 A was most highly reduced, exhibited salt-hypersensitive phenotypes. Analysis of the m6 A methylome in the vir mutant revealed a transcriptome-wide loss of m6 A modification in the 3' untranslated region (3'-UTR). We demonstrated further that VIR-mediated m6 A methylation modulates reactive oxygen species homeostasis by negatively regulating the mRNA stability of several salt stress negative regulators, including ATAF1, GI and GSTU17, through affecting 3'-UTR lengthening linked to alternative polyadenylation. Our results highlight the important role played by epitranscriptomic mRNA methylation in the salt stress response of Arabidopsis and indicate a strong link between m6 A methylation and 3'-UTR length and mRNA stability during stress adaptation.

RNA methylation in chloroplasts or mitochondria in plants.

Recent advances in our understanding of epitranscriptomic RNA methylation have expanded the complexity of gene expression regulation beyond epigenetic regulation involving DNA methylation and histone modifications. The instalment, removal, and interpretation of methylation marks on RNAs are carried out by writers (methyltransferases), erasers (demethylases), and readers (RNA-binding proteins), respectively. Contrary to an emerging body of evidence demonstrating the importance of RNA methylation in the diverse fates of RNA molecules, including splicing, export, translation, and decay in the nucleus and cytoplasm, their roles in plant organelles remain largely unclear and are only now being discovered. In particular, extremely high levels of methylation marks in chloroplast and mitochondrial RNAs suggest that RNA methylation plays essential roles in organellar biogenesis and functions in plants that are crucial for plant development and responses to environmental stimuli. Thus, unveiling the cellular components involved in RNA methylation in cell organelles is essential to better understand plant biology.

N4-methylcytidine ribosomal RNA methylation in chloroplasts is crucial for chloroplast function, development, and abscisic acid response in Arabidopsis.

Although the essential role of messenger RNA methylation in the nucleus is increasingly understood, the nature of ribosomal RNA (rRNA) methyltransferases and the role of rRNA methylation in chloroplasts remain largely unknown. A recent study revealed that CMAL (for Chloroplast mr aW- Like) is a chloroplast-localized rRNA methyltransferase that is responsible for N4-methylcytidine (m4 C) in 16S chloroplast rRNA in Arabidopsis thaliana. In this study, we further examined the role of CMAL in chloroplast biogenesis and function, development, and hormone response. The cmal mutant showed reduced chlorophyll biosynthesis, photosynthetic activity, and growth-defect phenotypes, including severely stunted stems, fewer siliques, and lower seed yield. The cmal mutant was hypersensitive to chloroplast translation inhibitors, such as lincomycin and erythromycin, indicating that the m4 C-methylation defect in the 16S rRNA leads to a reduced translational activity in chloroplasts. Importantly, the stunted stem of the cmal mutant was partially rescued by exogenous gibberellic acid or auxin. The cmal mutant grew poorer than wild type, whereas the CMAL-overexpressing transgenic Arabidopsis plants grew better than wild type in the presence of abscisic acid. Altogether, these results indicate that CMAL is an indispensable rRNA methyltransferase in chloroplasts and is crucial for chloroplast biogenesis and function, photosynthesis, and hormone response during plant growth and development.

Functional Characterization of a Putative RNA Demethylase ALKBH6 in Arabidopsis Growth and Abiotic Stress Responses.

RNA methylation and demethylation, which is mediated by RNA methyltransferases (referred to as "writers") and demethylases (referred to as "erasers"), respectively, are emerging as a key regulatory process in plant development and stress responses. Although several studies have shown that AlkB homolog (ALKBH) proteins are potential RNA demethylases, the function of most ALKBHs is yet to be determined. The Arabidopsis thaliana genome contains thirteen genes encoding ALKBH proteins, the functions of which are largely unknown. In this study, we characterized the function of a potential eraser protein, ALKBH6 (At4g20350), during seed germination and seedling growth in Arabidopsis under abiotic stresses. The seeds of T-DNA insertion alkbh6 knockdown mutants germinated faster than the wild-type seeds under cold, salt, or abscisic acid (ABA) treatment conditions but not under dehydration stress conditions. Although no differences in seedling and root growth were observed between the alkbh6 mutant and wild-type under normal conditions, the alkbh6 mutant showed a much lower survival rate than the wild-type under salt, drought, or heat stress. Cotyledon greening of the alkbh6 mutants was much higher than that of the wild-type upon ABA application. Moreover, the transcript levels of ABA signaling-related genes, including ABI3 and ABI4, were down-regulated in the alkbh6 mutant compared to wild-type plants. Importantly, the ALKBH6 protein had an ability to bind to both m6A-labeled and m5C-labeled RNAs. Collectively, these results indicate that the potential eraser ALKBH6 plays important roles in seed germination, seedling growth, and survival of Arabidopsis under abiotic stresses.

Roles of Organellar RNA-Binding Proteins in Plant Growth, Development, and Abiotic Stress Responses.

Organellar gene expression (OGE) in chloroplasts and mitochondria is primarily modulated at post-transcriptional levels, including RNA processing, intron splicing, RNA stability, editing, and translational control. Nucleus-encoded Chloroplast or Mitochondrial RNA-Binding Proteins (nCMRBPs) are key regulatory factors that are crucial for the fine-tuned regulation of post-transcriptional RNA metabolism in organelles. Although the functional roles of nCMRBPs have been studied in plants, their cellular and physiological functions remain largely unknown. Nevertheless, existing studies that have characterized the functions of nCMRBP families, such as chloroplast ribosome maturation and splicing domain (CRM) proteins, pentatricopeptide repeat (PPR) proteins, DEAD-Box RNA helicase (DBRH) proteins, and S1-domain containing proteins (SDPs), have begun to shed light on the role of nCMRBPs in plant growth, development, and stress responses. Here, we review the latest research developments regarding the functional roles of organellar RBPs in RNA metabolism during growth, development, and abiotic stress responses in plants.