Priyadarshini, A.; Cullen, P. J.

Signaling pathways often share components yet produce highly specialized biological responses. How signaling specificity is achieved between pathways utilizing common components is a fundamental question. In budding yeast, the same transmembrane mucin, Msb2, regulates two Mitogen-Activated Protein Kinase (MAPK) pathways controlling filamentous growth (fMAPK) and the response to osmotic stress (HOG). How this shared sensor distinguishes between stimuli and regulates different pathways is not clear. Using structure-guided analysis, we identified a conserved SEA (Sea urchin sperm protein, Enterokinase, Agrin) domain in fungal mucins and found that mutations disrupting protein folding selectively impair one pathway (fMAPK) but were tolerated by another (HOG). Mechanistically, these differences revealed distinct modes of signal transmission. The fMAPK pathway required an intact SEA domain and the cytosolic tail, consistent with a cis signaling mechanism that required structural coupling across the membrane. In contrast, the HOG pathway functioned independently of the cytosolic tail and tolerated misfolded SEA domain variants, consistent with trans signaling mediated by extracellular domains of interacting partners. The HOG pathway may detect misfolding as part of its sensing mechanism, as stressors that induce protein misfolding required Msb2 for survival. This work reveals how differential tolerance to protein deformation confers signaling specificity and identifies sensor deformation as a general feature of mechanosensory pathways that respond to environmental stress.