Gly-Leu-OH

Nucleoporin Nup98, an essential component of the nuclear pore complex, has multifunctional roles in nuclear functions including transcriptional regulation and nucleocytoplasmic transport. These functions mostly depend on a Gly-Leu-Phe-Gly (GLFG) sequence appearing repetitively in the N-terminal region of Nup98. As the GLFG sequence is well conserved among Nup98s from a wide variety of species including humans, yeasts, and ciliates such as Tetrahymena thermophila, a specific antibody that recognizes the GLFG sequence is expected to detect various Nup98s from a wide-range of species. To generate monoclonal antibodies specific to the GLFG repeat of Nup98, we used two synthetic polypeptides derived from the macronuclear Nup98 of T. thermophila as an antigen. We obtained two monoclonal antibodies (MAbs), 13C2 and 21A10, that recognize Nup98s in indirect immunofluorescence staining and Western blot analysis of T. thermophila. Peptide array analysis of these monoclonal antibodies located the position of their epitopes at or near GLFG residues: the epitope recognized by the 13C2 MAb is FGxxN (x being any amino acid), and the epitope recognized by the 21A10 MAb is GLF. As expected by their epitopes, these monoclonal antibodies also recognize Nup98 homologs expressed by human cells and the yeasts Schizosaccharomyces pombe and Saccharomyces cerevisiae, indicating that 13C2 and 21A10 MAbs recognize Nup98 epitopes common to phylogenetically distinct organisms. Thus, these MAbs are useful in studying a wide variety of biological phenomena that involve Nup98, ranging from ciliate nuclear dimorphism to NUP98-related human leukemia.

The hepatitis C virus (HCV) glycoproteins E1 and E2 form a heterodimer that mediates CD81 receptor binding and viral entry. In this study, we used site-directed mutagenesis to examine the functional role of a conserved G436WLAGLFY motif of E2. The mutants could be placed into two groups based on the ability of mature virion-incorporated E1E2 to bind the large extracellular loop (LEL) of CD81 versus the ability to mediate cellular entry of pseudotyped retroviral particles. Group 1 comprised E2 mutants where LEL binding ability largely correlated with viral entry ability, with conservative and nonconservative substitutions (W437 L/A, L438A, L441V/F, and F442A) inhibiting both functions. These data suggest that Trp-437, Leu-438, Leu-441, and Phe-442 directly interact with the LEL. Group 2 comprised E2 glycoproteins with more conservative substitutions that lacked LEL binding but retained between 20% and 60% of wild-type viral entry competence. The viral entry competence displayed by group 2 mutants was explained by residual binding by the E2 receptor binding domain to cellular full-length CD81. A subset of mutants maintained LEL binding ability in the context of intracellular E1E2 forms, but this function was largely lost in virion-incorporated glycoproteins. These data suggest that the CD81 binding site undergoes a conformational transition during glycoprotein maturation through the secretory pathway. The G436P mutant was an outlier, retaining near-wild-type levels of CD81 binding but lacking significant viral entry ability. These findings indicate that the G436WLAGLFY motif of E2 functions in CD81 binding and in pre- or post-CD81-dependent stages of viral entry.

The vertebrate nucleoporin Nup98 can be expressed in two distinct forms from differentially spliced mRNAs, either as a 98-kDa protein or as the 195-kDa Nup98/Nup96 polyprotein. Both forms undergo autoproteolytic processing to generate the 90-kDa Nup98 and either an 8-kDa tail or the nucleoporin Nup96. An equivalent cleavage event occurs in one yeast ortholog, Nup145, to produce Nup145N and Nup145C. We previously proposed that Nup145N, and possibly the other orthologs Nup116 and Nup100, might bind to Nup145C as demonstrated for Nup98 and Nup96. Here we have further investigated the interaction of both yeast and vertebrate Gly-Leu-Phe-Gly nucleoporins with the nuclear pore. We find that dynamic Nup98 binding can be recapitulated in vitro and that simultaneous translation and folding as a polyprotein are not required to allow subsequent binding between Nup98 and Nup96. We show that Nup145N and Nup145C do indeed bind to each other, and we have determined the dissociation constants for these interactions in vitro. Additionally, we characterize two sites of molecular interaction for each binding pair. Of the yeast orthologs, Nup116 binds far less robustly to Nup145C than does Nup145N, and Nup100 binding is barely detectable. Thus, we conclude that Nup116 and Nup100 likely use means of incorporation into the nuclear pore complex that are distinct from those used by Nup145N.