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Nascent chains can form co-translational folding intermediates that promote post-translational folding outcomes in a disease-causing protein.

Elena PlessaLien P ChuSammy H S ChanOliver L ThomasAnaïs M E CassaignauChristopher A WaudbyJohn ChristodoulouLisa D Cabrita
Published in: Nature communications (2021)
During biosynthesis, proteins can begin folding co-translationally to acquire their biologically-active structures. Folding, however, is an imperfect process and in many cases misfolding results in disease. Less is understood of how misfolding begins during biosynthesis. The human protein, alpha-1-antitrypsin (AAT) folds under kinetic control via a folding intermediate; its pathological variants readily form self-associated polymers at the site of synthesis, leading to alpha-1-antitrypsin deficiency. We observe that AAT nascent polypeptides stall during their biosynthesis, resulting in full-length nascent chains that remain bound to ribosome, forming a persistent ribosome-nascent chain complex (RNC) prior to release. We analyse the structure of these RNCs, which reveals compacted, partially-folded co-translational folding intermediates possessing molten-globule characteristics. We find that the highly-polymerogenic mutant, Z AAT, forms a distinct co-translational folding intermediate relative to wild-type. Its very modest structural differences suggests that the ribosome uniquely tempers the impact of deleterious mutations during nascent chain emergence. Following nascent chain release however, these co-translational folding intermediates guide post-translational folding outcomes thus suggesting that Z's misfolding is initiated from co-translational structure. Our findings demonstrate that co-translational folding intermediates drive how some proteins fold under kinetic control, and may thus also serve as tractable therapeutic targets for human disease.
Keyphrases
  • single molecule
  • molecular dynamics simulations
  • wild type
  • endothelial cells
  • gene expression
  • type diabetes
  • induced pluripotent stem cells
  • small molecule
  • dna methylation
  • genome wide
  • replacement therapy