Identification of functional regions of herpes simplex virus glycoprotein gD by using linker-insertion mutagenesis

Abstract

Glycoprotein gD is a component of the herpes simplex virus (HSV) envelope essential for virus entry into susceptible cells. Previous studies using deletion and point mutations identified a functional domain of HSV-1 gD (gD-1) from residues 231 to 244. However, many of the deletion mutations had global effects on gD-1 structure, thus precluding assessment of the functional role of large portions of the protein. In this study, we constructed a large panel of linker-insertion mutants in the genes for gD-1 and HSV-2 gD (gD-2). The object was to create mutations which would have only localized effects on protein structure but might have profound effects on gD function. The mutant proteins were expressed in transiently transfected L cells. Monoclonal antibodies (MAbs) were used as probes of gD structure. We also examined protein aggregation and appearance of the mutant glycoproteins on the transfected cell surface. A complementation assay measured the ability of the mutant proteins to rescue the infectivity of the gD-null virus, FgD beta, in trans. Most of the mutants were recognized by one or more MAbs to discontinuous epitopes, were transported to the transfected cell surface, and rescued FgD beta virus infectivity. However, some mutants which retained structure were unable to complement FgD beta. These mutants were clustered in four regions of gD. Region III (amino acids 222 to 246) overlaps the region previously defined by gD-1 deletion mutants. The others, from 27 through 43 (region I), from 125 through 161 (region II), and from 277 to 310 (region IV), are newly described. Region IV, immediately upstream of the transmembrane anchor sequence, was previously postulated to be part of a putative stalk structure. However, residues 277 to 300 are directly involved in gD function. The linker-insertion mutants were useful for mapping MAb AP7, a previously ungrouped neutralizing MAb, and provided further information concerning other discontinuous epitopes. The mapping data suggest that regions I through IV are physically near each other in the folded structure of gD and may form a single functional domain.