Does mRNA structure contain genetic information for regulating co-translational protein folding？

Currently many facets of genetic information are illdefined. In particular, how protein folding is genetically regulated has been a long-standing issue for genetics and protein biology. And a generic mechanistic model with supports of genomic data is still lacking. Recent technological advances have enabled much needed genome-wide experiments. While putting the effect of codon optimality on debate, these studies have supplied mounting evidence suggesting a role of m RNA structure in the regulation of protein folding by modulating translational elongation rate. In conjunctions with previous theories, this mechanistic model of protein folding guided by m RNA structure shall expand our understandings of genetic information and offer new insights into various biomedical puzzles.

Control of ribosome synthesis in bacteria:the important role of rRNA chain elongation rate

Bacteria growth depends crucially on protein synthesis,which is limited by ribosome synthesis.Ribosomal RNA(rRNA)transcription is the rate-limiting step of ribosome synthesis.It is generally proposed that the transcriptional initiation rate of rRNA operon is the primary factor that controls the r RNA synthesis.In this study,we established a convenient GFP-based reporter approach for measuring the bacterial rRNA chain elongation rate.We showed that the rRNA chain elongation rate of Escherichia coli remains constant under nutrient limitation and chloramphenicol inhibition.In contrast,rRNA chain elongation rate decreases dramatically under low temperatures.Strikingly,we found that Vibrio natriegens,the fastest growing bacteria known,has a 50%higher rRNA chain elongation rate than E.coli,which contributes to its rapid ribosome synthesis.Our study demonstrates that r RNA chain elongation rate is another important factor that affects the bacterial ribosome synthesis capacity.