Abstract
Though it is an essential process, transcription can be a source of genomic instability. For instance, it may generate RNA:DNA hybrids as the nascent transcript hybridizes with the complementary DNA template. These hybrids, called R-loops, act as a major cause of replication fork stalling and DNA breaks. In this study, we show that lowering transcription and R-loop levels in plastids of Arabidopsis thaliana reduces DNA rearrangements and mitigates plastid genome instability phenotypes. This effect can be observed on a genome-wide scale, as the loss of the plastid sigma transcription factor SIG6 prevents DNA rearrangements by favoring conservative repair in the presence of ciprofloxacin-induced DNA damage or in the absence of plastid genome maintenance actors such as WHY1/WHY3, RECA1 and POLIB. Additionally, resolving R-loops by the expression of a plastid-targeted exogenous RNAse H1 produces similar results. We also show that highly-transcribed genes are more susceptible to DNA rearrangements, as increased transcription of the psbD operon by SIG5 correlates with more locus-specific rearrangements. The effect of transcription is not specific to Sigma factors, as decreased global transcription levels by mutation of heat-stress-induced factor HSP21, mutation of nuclear-encoded polymerase RPOTp, or treatment with transcription-inhibitor rifampicin all prevent the formation of plastid genome rearrangements, especially under induced DNA damage conditions.
Highlights
Plastids form a large family of cellular organelles in plants and algae that includes chloroplasts, which are responsible for photosynthesis
We have previously shown that replication stress can induce rearrangements in the plastid genome [18], leading to a severe photosynthetic electron transport chain (PET) imbalance and elevated reactive oxygen species (ROS) production, triggering plastid-to-nucleus retrograde signaling pathways to reprogram the nuclear transcriptome [43]
The authors observed that mutational ablation of the DNA-binding domains of three studied transcription factors abolished the induction of SOS DNA-damage and fork reversal foci
Summary
Plastids form a large family of cellular organelles in plants and algae that includes chloroplasts, which are responsible for photosynthesis. Plastids of vascular plants originated from an ancestral cyanobacterial endosymbiont, and possess their own genome [1]. The presentday genome of the plant Arabidopsis harbors only 133 genes coding for 37 tRNAs, 8 rRNAs and 88 proteins that are involved in plastid gene expression, photosynthesis, biosynthesis of fatty acids, pigments and amino acids, or with yet unknown functions [2]. Plastids contain multiple copies of the plastid chromosome, folded together with proteins and RNA into nucleoids [3]. Despite their small genomes (~0.15 Mbp in land plant plastids versus 3 Mbp in cyanobacteria), plastids possess complex hybrid gene expression systems composed of both prokaryotic.
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