OsWHY1/OsTRXz/OsMORFs complex is essential for RNA modification and early chloroplast development in rice

WHIRLY (WHY) proteins are single-stranded DNA/RNA-binding proteins that play multifaceted roles in various plant species. The regulatory mechanisms of WHY proteins in rice remains blank. Here we demonstrate that OsWHY1 in rice is required for early chloroplast development. CRISPR/Cas9-generated oswhy1 knockout lines displayed albino seedling phenotypes, abnormal chloroplast structure and comprised redox balance in leaves. OsWHY1 interacts with multiple plastid proteins, including the thioredoxin OsTRXz and two multiple organellar RNA editing factors (OsMORF8 and OsMORF9) in chloroplasts. Accordingly, several plastid genes dependent on plastid-encoded RNA polymerase (PEP) in the oswhy1 mutants were significantly depressed at both transcript and protein levels. The editing of rps14 transcripts and splicing of rpl2, along with their protein expression, were defective in the oswhy1 mutants. OsWHY1 exhibited RNA-binding activity, specifically binding to rps14 and rpl2 precursor RNAs, which underscores its role as a post-transcriptional regulator essential for normal protein synthesis in chloroplasts. Loss-of- function mutants of either OsWHY1 or OsMORF9 and OsTRXz displayed albino phenotypes, disrupted H ₂ O ₂ homeostasis, and defective RNA processing in rps14 and rpl2 , suggesting the OsWHY1-OsTRXz-OsMORFs regulatory module is vital for maintaining chloroplast stability and integrity through its RNA-binding activity and its role in recruiting OsTRXz and OsMORFs to ensure proper RNA modification.