Qing-xin Hua

The A-chain of Insulin Contacts the Insert Domain of the Insulin Receptor: PHOTO-CROSS-LINKING AND MUTAGENESIS OF A DIABETES-RELATED CREVICE.

The contribution of the insulin A-chain to receptor binding is investigated by photo-cross-linking and nonstandard mutagenesis. Studies focus on the role of ValA3, which projects within a crevice between the A- and B-chains. Engineered receptor α-subunits containing specific protease sites (“midi-receptors”) are employed to map the site of photo-cross-linking by an analog containing a photoactivable A3 side chain (para-azido-Phe (Pap)). The probe cross-links to a C-terminal peptide (residues 703-719 of the receptor A isoform, KTFEDYLHNVVFVPRPS) containing side chains critical for hormone binding (underlined); the corresponding segment of the holoreceptor was shown previously to cross-link to a PapB25-insulin analog. Because Pap is larger than Val and so may protrude beyond the A3-associated crevice, we investigated analogs containing A3 substitutions comparable in size to Val as follows: Thr, allo-Thr, and α-aminobutyric acid (Aba). Substitutions were introduced within an engineered monomer. Whereas previous studies of smaller substitutions (GlyA3 and SerA3) encountered nonlocal conformational perturbations, NMR structures of the present analogs are similar to wild-type insulin; the variant side chains are accommodated within a native-like crevice with minimal distortion. Receptor binding activities of AbaA3 and allo-ThrA3 analogs are reduced at least 10-fold; the activity of ThrA3-DKP-insulin is reduced 5-fold. The hormone-receptor interface is presumably destabilized either by a packing defect (AbaA3) or by altered polarity (allo-ThrA3 and ThrA3). Our results provide evidence that ValA3, a site of mutation causing diabetes mellitus, contacts the insert domain-derived tail of the α-subunit in a hormone-receptor complex.

An Achilles' Heel in an Amyloidogenic Protein and Its Repair INSULIN FIBRILLATION AND THERAPEUTIC DESIGN

Insulin fibrillation provides a model for a broad class of amyloidogenic diseases. Conformational distortion of the native monomer leads to aggregation-coupled misfolding. Whereas β-cells are protected from proteotoxicity by hexamer assembly, fibrillation limits the storage and use of insulin at elevated temperatures. Here, we have investigated conformational distortions of an engineered insulin monomer in relation to the structure of an insulin fibril. Anomalous 13C NMR chemical shifts and rapid 15N-detected 1H-2H amide-proton exchange were observed in one of the three classical α-helices (residues A1–A8) of the hormone, suggesting a conformational equilibrium between locally folded and unfolded A-chain segments. Whereas hexamer assembly resolves these anomalies in accordance with its protective role, solid-state 13C NMR studies suggest that the A-chain segment participates in a fibril-specific β-sheet. Accordingly, we investigated whether helicogenic substitutions in the A1–A8 segment might delay fibrillation. Simultaneous substitution of three β-branched residues (IleA2 → Leu, ValA3 → Leu, and ThrA8 → His) yielded an analog with reduced thermodynamic stability but marked resistance to fibrillation. Whereas amide-proton exchange in the A1–A8 segment remained rapid, 13Cα chemical shifts exhibited a more helical pattern. This analog is essentially without activity, however, as IleA2 and ValA3 define conserved receptor contacts. To obtain active analogs, substitutions were restricted to A8. These analogs exhibit high receptor-binding affinity; representative potency in a rodent model of diabetes mellitus was similar to wild-type insulin. Although 13Cα chemical shifts remain anomalous, significant protection from fibrillation is retained. Together, our studies define an “Achilles heel” in a globular protein whose repair may enhance the stability of pharmaceutical formulations and broaden their therapeutic deployment in the developing world.

Secondary structure and structure-activity relationships of peptides corresponding to the subunit interface of herpes simplex virus DNA polymerase

The interaction of the catalytic subunit of herpes simplex virus DNA polymerase with the processivity subunit, UL42, is essential for viral replication and is thus a potential target for antiviral drug discovery. We have previously reported that a peptide analogous to the C-terminal 36 residues of the catalytic subunit, which are necessary and sufficient for its interaction with UL42, forms a monomeric structure with partial α-helical character. This peptide and one analogous to the C-terminal 18 residues specifically inhibit UL42-dependent long chain DNA synthesis. Using multidimensional 1H nuclear magnetic resonance spectroscopy, we have found that the 36-residue peptide contains partially ordered N- and C-terminal α-helices separated by a less ordered region. A series of “alanine scan” peptides derived from the C-terminal 18 residues of the catalytic subunit were tested for their ability to inhibit long-chain DNA synthesis and by circular dichroism for secondary structure. The results identify structural aspects and specific side chains that appear to be crucial for interacting with UL42. These findings may aid in the rational design of new drugs for the treatment of herpesvirus infections.