Our two recent reports on the high resolution NMR structure and conformational dynamics of G57W variant of human γS-crystallin (abbreviated as γS-G57W) causing severe infantile cataracts, revealed slackening of its N-terminal domain with enhanced local conformational dynamics attributed to mutation. Exploring the biochemistry of infantile cataracts in detail, here we studied structural unfolding in both human γS-WT and γS-G57W at residue level resolution using solution NMR spectroscopy and chemical kinetics and characterized the molecular intermediates with functional consequences. We report, for the first time, that human γS-crystallin unfolds sequentially under H/D exchange. This communication forms the first experimental evidence for non-concerted destabilization of structural foldon units in human γS-G57W. Residues contributing to the compact fold and structural stability exchanged their amide protons with deuterons more readily in γS-G57W compared to γS-WT, displaying differential free energies of exchange. Overall, our results establish a direct conformational link between the structure, dynamics, design and function in human γS-crystallin such that the G57W cataract variant promotes enhanced structural excursions concomitant with increased instability, elucidating very crucial molecular details of cataract formation affecting infants across the globe.