Litcius/Paper detail

Oxiforms: Unique cysteine residue‐ and chemotype‐specified chemical combinations can produce functionally‐distinct proteoforms

James N. Cobley

2023BioEssays19 citationsDOIOpen Access PDF

Abstract

A single protein molecule with one or more cysteine residues can occupy a plurality of unique residue and oxidation-chemotype specified proteoforms that I term oxiforms. In binary reduced or oxidised terms, one molecule with three cysteines will adopt one of eight unique oxiforms. Residue-defined sulfur chemistry endows specific oxiforms with distinct functionally-relevant biophysical properties (e.g., steric effects). Their emergent complexity means a functionally-relevant effect may only manifest when multiple cysteines are oxidised. Like how mixing colours makes new shades, combining discrete redox chemistries-colours-can create a kaleidoscope of oxiform hues. The sheer diversity of oxiforms co-existing within the human body provides a biological basis for redox heterogeneity. Of evolutionary significance, oxiforms may enable individual cells to mount a broad spectrum of responses to the same stimulus. Their biological significance, however plausible, is speculative because protein-specific oxiforms remain essentially unexplored. Excitingly, pioneering new techniques can push the field into uncharted territory by quantifying oxiforms. The oxiform concept can advance our understanding of redox-regulation in health and disease.

Topics & Concepts

CysteineChemotypeResidue (chemistry)Computational biologyChemistryRedoxBiologyBiochemistryOrganic chemistryChromatographyEssential oilEnzymeClick Chemistry and ApplicationsRedox biology and oxidative stressChemical Synthesis and Analysis