Characterization of the specificity of human neutrophil elastase for Shigella flexneri virulence factors

1 Abstract Abstract Neutrophil granulocytes are one of the first lines of defense of the mammalian innate immune system against invading microorganisms. In response to inflammatory stimuli, neutrophils migrate from the blood stream to infected tissues where they bind, engulf and inactivate microorganisms efficiently. Human neutrophil elastase (NE), a neutrophil granule component, is a key host defense protein that rapidly destroys virulence factors of enteroinvasive pathogens including IpaB (invasion plasmid antigen B) and IcsA (intracellular spread A) from Shigella. The structural basis of the exquisite sensitivity of virulence proteins to NE is not known. Our analysis suggests that the primary structure of IpaB is not important for NE specificity. Using a series of IpaB mutants that contained deletions in the coiled-coil region, as well as in the putative transmembrane domains of the hydrophobic region, we observed that the susceptibility of the IpaB mutants to NE was similar to that of the wildtype IpaB. Secondary or tertiary structures of the substrate are also unlikely to play a role in the recognition of virulence factors by NE since heat-denatured and native IpaB were equally well targeted by NE. NE belongs to the family of chymotrypsin-like serine proteases with sequence and structural similarity but with very different biological functions. Cathepsin G (CG) is another abundant chymotrypsin-like serine protease in neutrophil granules. However, in contrast to NE, CG does not cleave virulence factors of Shigella. The crystallographic structures of NE and CG are very similar but we identified single or multiple residues in the substrate-binding cleft to differ in these two enzymes. We hypothesized that NE specificity for bacterial virulence factors resides within these structural differences. Therefore these specific residues in NE were replaced with the analogous amino acids of CG or with alanine. By comparing the functional properties of these NE mutants to wildtype NE we were able to show that the amino acids at position 98 and 216-224 are crucial for the substrate specificity of NE. The NE mutants N98A, 216-218 and 216-224 did not cleave the virulence factors IcsA and IpaB as well as the NE peptide substrate but cleaved the CG peptide substrate. In summary, we identified residues in NE that determine the specificity of NE for the peptide substrate and for the Shigella flexneri virulence factors.