Binding of hepatitis C virus E2 glycoprotein to CD81 does not correlate with species permissiveness to infection.

Hepatitis C virus (HCV) glycoprotein E2 binds to human cells by interacting with the CD81 molecule, which has been proposed to be the viral receptor. A correlation between binding to CD81 and species permissiveness to HCV infection has also been reported. We have determined the sequence of CD81 from the tamarin, a primate species known to be refractory to HCV infection. Tamarin CD81 (t-CD81) differs from the human molecule at 5 amino acid positions (155, 163, 169, 180, and 196) within the large extracellular loop (LEL), where the binding site for E2 has been located. Soluble recombinant forms of human CD81 (h-CD81), t-CD81, and African green monkey CD81 (agm-CD81) LEL molecules were analyzed by enzyme-linked immunosorbent assay for binding to E2 glycoprotein. Both h-CD81 and t-CD81 molecules were able to bind E2. Competition experiments showed that the two receptors cross-compete and that the t-CD81 binds with stronger affinity than the human molecule. Recently, h-CD81 residue 186 has been characterized as the critical residue involved in the interaction with E2. Recombinant CD81 mutant proteins were expressed to test whether human and tamarin receptors interacted with E2 in a comparable manner. Mutation of residue 186 (F186L) dramatically reduced the binding capability of t-CD81, a result that has already been demonstrated for the human receptor, whereas the opposite mutation (L186F) in agm-CD81 resulted in a neat gain of binding activity. Finally, the in vitro data were confirmed by detection of E2 binding to cotton-top tamarin (Saguinus oedipus) cell line B95-8 expressing endogenous CD81. These results indicate that the binding of E2 to CD81 is not predictive of an infection-producing interaction between HCV and host cells.

A high-throughput radiometric assay for hepatitis C virus NS3 protease.

A novel radiometric in vitro assay for discovery of inhibitors of hepatitis C viral protease activity, suitable for high-throughput screening, was developed. The NS3 protein of hepatitis C virus (HCV) contains a serine protease, whose function is to process the majority of the nonstructural proteins of the viral polyprotein. The viral NS4A protein is a cofactor of NS3 protease activity in the cleavage of NS3-NS4A, NS4A-NS4B, NS4B-NS5A, and NS5A-NS5B junctions. To establish an in vitro assay system we used NS3 proteases from different HCV strains, purified from Escherichia coli and a synthetic radiolabeled peptide substrate that mimics the NS4A-NS4B junction. Upon incubation with the enzyme the substrate was separated from the radiolabeled cleavage product by addition of an ion exchange resin. The assay was performed in a microtiter plate format and offered the potential for assaying numerous samples using a laboratory robot. Taking advantage of these features, we used the assay to optimize reaction conditions by simultaneously varying different buffer components. We showed that physicochemical conditions affect NS3 protease activity in a strain-specific way. Furthermore, the sensitivity of the assay makes it suitable for detection and detailed mechanistic characterization of inhibitors with low-nanomolar affinities for the HCV serine protease.

Engineering human interleukin-6 to obtain variants with strongly enhanced bioactivity.

Interleukin-6 (IL-6) triggers the formation of a high affinity receptor complex with the ligand binding subunit IL-6Ralpha and the signal transducing chain gp130. Since the intracytoplasmic region of the IL-6Ralpha does not contribute to signaling, soluble forms of the extracytoplasmic domain (sIL-6Ralpha), potentiate IL-6 bioactivity and induce a cytokine-responsive status in cells expressing gp130 only. This observation, together with the detection of high levels of circulating soluble human IL-6Ralpha (shIL-6Ralpha) in sera, suggests that the hIL-6-shIL-6Ralpha complex is an alternative form of the cytokine. Here we describe the generation of human IL-6 (hIL-6) variants with strongly enhanced shIL-6Ralpha binding activity and bioactivity. Homology modeling and site-directed mutagenesis of hIL-6 suggested that the binding interface for hIL-6Ralpha is constituted by the C-terminal portion of the D-helix and residues contained in the AB loop. Four libraries of hIL-6 mutants were generated by each time fully randomizing four different amino acids in the predicted AB loop. These libraries were displayed monovalently on filamentous phage surface and sorted separately for binding to immobilized shIL-6Ralpha. Mutants were selected which, when expressed as soluble proteins, showed a 10- to 40-fold improvement in shIL-6Ralpha binding; a further increase (up to 70-fold) was achieved by combining variants isolated from different libraries. Interestingly, high affinity hIL-6 variants show strongly enhanced bioactivity on cells expressing gp13O in the presence of shIL-6Ralpha at concentrations similar to those normally found in human sera.