Abstract
Development of viable therapeutics to effectively combat tier I pneumopathogens such as Yersinia pestis requires a thorough understanding of proteins vital for pathogenicity. The host invasion protein Ail, although indispensable for Yersinia pathogenesis, has evaded detailed characterization, as it is an outer membrane protein with intrinsically low stability and high aggregation propensity. Here, we identify molecular elements of the metastable Ail structure that considerably alter protein-lipid and intraprotein thermodynamics. In addition, we find that four residues Q(50), L(88), L(92), and A(94) contribute additively to the lowered stability of Ail, and their conserved substitution is sufficient to re-engineer Ail to Out14, a thermodynamically hyperstable low-aggregation variant with a functional scaffold. Interestingly, Ail also shows two (parallel) folding pathways, which has not yet been reported for β-barrel membrane proteins. Additionally, we identify the molecular mechanism of enhanced thermodynamic stability of Out14. We show that this enhanced stability of Out14 is due to a favorable change in the nonpolar accessible surface, and the accumulation of a kinetically accelerated off-pathway folding intermediate, which is absent in wild-type Ail. Such engineered hyperstable Ail β-barrels can be harnessed for targeted drug screening and developing medical countermeasures against Yersiniae. Application of similar strategies will help design effective translational therapeutics to combat biopathogens.