Cysteine dependent conformation heterogeneity of Shigella flexneri autotransporter IcsA and implications in its function

Abstract

AbstractShigella IcsA is a versatile surface virulence factor required for both early and late pathogenesis stages, extracellularly to intracellularly. Despite IcsA serving as a model Type V secretion system (T5SS) autotransporter to study host pathogen interactions, its detailed molecular architecture is poorly understood. Recently, IcsA was found to switch to a different conformation for its adhesin activity upon sensing of the host stimuli by Shigella Type III secretion system (T3SS). Here, we report that the single cysteine residue (C130) near the N-terminus of IcsA passenger has a role in IcsA adhesin activity. We also show that the IcsA passenger (IcsAp) exists in multiple conformations, and the conformation populations are influenced by a central pair of cysteine residues (C375 and C379), which is not previously reported for any Type V autotransporter passengers. Disruption of either or both central cysteine residues alters the exposure of IcsA epitopes to polyclonal anti-IcsA antibodies previously shown to block Shigella adherence, yet without loss of IcsA intracellular functions in actin-based motility (ABM). Anti-IcsA antibody reactivity was restored when the IcsA paired cysteine substitution mutants were expressed in a ∆ipaD background with a constitutively active T3SS, highlighting an interplay between T3SS and T5SS. The work here uncovers a novel molecular switch empowered by a centrally localised, short-spaced cysteine pair in the Type V autotransporter IcsA that ensures conformational heterogeneity to aid IcsA evasion of host immunity.ImportanceShigella species are the leading cause of diarrheal related death globally by causing bacillary dysentery. The surface virulence factor IcsA which is essential for Shigella pathogenesis is a unique multi-functional autotransporter that is responsible for cell adhesion, and actin-based motility, yet detailed mechanistic understanding is lacking. Here, we show that the three cysteine residues in IcsA contribute to the protein’s distinct functions. The N terminus cysteine residue within the IcsA passenger domain plays a role in adhesin function, while a centrally localised cysteine pair provides conformational heterogeneity resulting in IcsA molecules with different reactivity to adhesion-blocking anti-IcsA antibodies. In synergy with the Type III secretion system, this molecular switch preserves biological function in distinct IcsA conformations for cell adhesion, actin-based motility and autophagy escape, providing a potential strategy by which Shigella evade host immunity targeting of this essential virulence factor.