Natural tuning of restriction endonuclease synthesis by cluster of rare arginine codons.
Iwona MrukTadeusz KaczorowskiAgata WitczakPublished in: Scientific reports (2019)
Restriction-modification (R-M) systems are highly widespread among bacteria and archaea, and they appear to play a pivotal role in modulating horizontal gene transfer, as well as in protecting the host organism against viruses and other invasive DNA particles. Type II R-M systems specify two independent enzymes: a restriction endonuclease (REase) and protective DNA methyltransferase (MTase). If the cell is to survive, the counteracting activities as toxin and antitoxin, must be finely balanced in vivo. The molecular basis of this regulatory process remains unclear and current searches for regulatory elements in R-M modules are focused mainly at the transcription step. In this report, we show new aspects of REase control that are linked to translation. We used the EcoVIII R-M system as a model. Both, the REase and MTase genes for this R-M system contain an unusually high number of rare arginine codons (AGA and AGG) when compared to the rest of the E. coli K-12 genome. Clusters of these codons near the N-terminus of the REase greatly affect the translational efficiency. Changing these to higher frequency codons for E. coli (CGC) improves the REase synthesis, making the R-M system more potent to defend its host against bacteriophages. However, this improved efficiency in synthesis reduces host fitness due to increased autorestriction. We hypothesize that expression of the endonuclease gene can be modulated depending on the host genetic context and we propose a novel post-transcriptional mode of R-M system regulation that alleviates the potential lethal action of the restriction enzyme.
Keyphrases
- genome wide
- escherichia coli
- transcription factor
- genome wide identification
- copy number
- dna repair
- nitric oxide
- circulating tumor
- single molecule
- cell free
- dna methylation
- poor prognosis
- physical activity
- single cell
- body composition
- binding protein
- mouse model
- oxidative stress
- genome wide analysis
- circulating tumor cells
- climate change
- heat shock protein