Harmon J. Zuccola

The Crystal Structure of an Unusual Processivity Factor, Herpes Simplex Virus UL42, Bound to the C Terminus of Its Cognate Polymerase

Herpes simplex virus DNA polymerase is a heterodimer composed of a catalytic subunit, Pol, and an unusual processivity subunit, UL42, which, unlike processivity factors such as PCNA, directly binds DNA. The crystal structure of a complex of the C-terminal 36 residues of Pol bound to residues 1-319 of UL42 reveals remarkable similarities between UL42 and PCNA despite contrasting biochemical properties and lack of sequence homology. Moreover, the Pol-UL42 interaction resembles the interaction between the cell cycle regulator p21 and PCNA. The structure and previous data suggest that the UL42 monomer interacts with DNA quite differently than does multimeric toroidal PCNA. The details of the structure lead to a model for the mechanism of UL42, provide the basis for drug design, and allow modeling of other proteins that lack sequence homology with UL42 or PCNA.

Structural basis of the oligomerization of hepatitis delta antigen

BACKGROUND The hepatitis D virus (HDV) is a small satellite virus of hepatitis B virus (HBV). Coinfection with HBV and HDV causes severe liver disease in humans. The small 195 amino-acid form of the hepatitis delta antigen (HDAg) functions as a trans activator of HDV replication. A larger form of the protein containing a 19 amino acid C-terminal extension inhibits viral replication. Both of these functions are mediated in part by a stretch of amino acids predicted to form a coiled coil (residues 13-48) that is common to both forms. It is believed that HDAg forms dimers and higher ordered structures through this coiled-coil region. RESULTS The high-resolution crystal structure of a synthetic peptide corresponding to residues 12 to 60 of HDAg has been solved. The peptide forms an antiparallel coiled coil, with hydrophobic residues near the termini of each peptide forming an extensive hydrophobic core with residues C-terminal to the coiled-coil domain in the dimer protein. The structure shows how HDAg forms dimers, but also shows the dimers forming an octamer that forms a 50 A ring lined with basic sidechains. This is confirmed by cross-linking studies of full-length recombinant small HDAg. CONCLUSIONS HDAg dimerizes through an antiparallel coiled coil. Dimers then associate further to form octamers through residues in the coiled-coil domain and residues C-terminal to this region. Our findings suggest that the structure of HDAg represents a previously unseen organization of a nucleocapsid protein and raise the possibility that the N terminus may play a role in binding the viral RNA.

A Point Mutation within Conserved Region VI of Herpes Simplex Virus Type 1 DNA Polymerase Confers Altered Drug Sensitivity and Enhances Replication Fidelity

ABSTRACT Herpes simplex virus type 1 (HSV-1) DNA polymerase contains several conserved regions within the polymerase domain. The conserved regions I, II, III, V, and VII have been shown to have functional roles in the interaction with deoxynucleoside triphosphates (dNTPs) and DNA. However, the role of conserved region VI in DNA replication has remained unclear due, in part, to the lack of a well-characterized region VI mutant. In this report, recombinant viruses containing a point mutation (L774F) within the conserved region VI were constructed. These recombinant viruses were more susceptible to aphidicolin and resistant to both foscarnet and acyclovir, compared to the wild-type KOS strain. Marker transfer experiments demonstrated that the L774F mutation conferred the altered drug sensitivities. Furthermore, mutagenesis assays demonstrated that L774F recombinant viruses containing the supF marker gene, which was integrated within the thymidine kinase locus (tk), exhibited increased fidelity of DNA replication. These data indicate that conserved region VI, together with other conserved regions, forms the polymerase active site, has a role in the interaction with deoxyribonucleotides, and regulates DNA replication fidelity. The possible effect of the L774F mutation in altering the polymerase structure and activity is discussed.

Interactions between hepatitis delta virus proteins.

ABSTRACT The 195- and 214-amino-acid (aa) forms of the delta protein (δAg-S and δAg-L, respectively) of hepatitis delta virus (HDV) differ only in the 19-aa C-terminal extension unique to δAg-L. δAg-S is needed for genome replication, while δAg-L is needed for particle assembly. These proteins share a region at aa 12 to 60, which mediates protein-protein interactions essential for HDV replication. H. Zuccola et al. (Structure 6:821–830, 1998) reported a crystal structure for a peptide spanning this region which demonstrates an antiparallel coiled-coil dimer interaction with the potential to form tetramers of dimers. Our studies tested whether predictions based on this structure could be extrapolated to conditions where the peptide was replaced by full-length δAg-S or δAg-L, and when the assays were not in vitro but in vivo. Nine amino acids that are conserved between several isolates of HDV and predicted to be important in multimerization were mutated to alanine on both δAg-S and δAg-L. We found that the predicted hierarchy of importance of these nine mutations correlated to a significant extent with the observed in vivo effects on the ability of these proteins to (i) support intrans the replication of the HDV genome when expressed on δAg-S and (ii) act as dominant-negative inhibitors of replication when expressed on δAg-L. We thus infer that these biological activities of δAg depend on ordered protein-protein interactions.

Computational design of d-peptide inhibitors of hepatitis delta antigen dimerization

Hepatitis delta virus (HDV) encodes a single polypeptide called hepatitis delta antigen (DAg). Dimerization of DAg is required for viral replication. The structure of the dimerization region, residues 12 to 60, consists of an anti-parallel coiled coil [Zuccola et al., Structure, 6 (1998) 821]. Multiple Copy Simultaneous Searches (MCSS) of the hydrophobic core region formed by the bend in the helix of one monomer of this structure were carried out for many diverse functional groups. Six critical interaction sites were identified. The Protein Data Bank was searched for backbone templates to use in the subsequent design process by matching to these sites. A 14 residue helix expected to bind to the d-isomer of the target structure was selected as the template. Over 200 000 mutant sequences of this peptide were generated based on the MCSS results. A secondary structure prediction algorithm was used to screen all sequences, and in general only those that were predicted to be highly helical were retained. Approximately 100 of these 14-mers were model built as d-peptides and docked with the l-isomer of the target monomer. Based on calculated interaction energies, predicted helicity, and intrahelical salt bridge patterns, a small number of peptides were selected as the most promising candidates. The ligand design approach presented here is the computational analogue of mirror image phage display. The results have been used to characterize the interactions responsible for formation of this model anti-parallel coiled coil and to suggest potential ligands to disrupt it.