Christine A. Franke

Neomycin resistance as a dominant selectable marker for selection and isolation of vaccinia virus recombinants.

The antibiotic G418 was shown to be an effective inhibitor of vaccinia virus replication when an appropriate concentration of it was added to cell monolayers 48 h before infection. Genetic engineering techniques were used in concert with DNA transfection protocols to construct vaccinia virus recombinants containing the neomycin resistance gene (neo) from transposon Tn5. These recombinants contained the neo gene linked in either the correct or incorrect orientation relative to the vaccinia virus 7.5-kilodalton gene promoter which is expressed constitutively throughout the course of infection. The vaccinia virus recombinant containing the chimeric neo gene in the proper orientation was able to grow and form plaques in the presence of G418, whereas both the wild-type and the recombinant virus with the neo gene in the opposite polarity were inhibited by more than 98%. The effect of G418 on virus growth may be mediated at least in part by selective inhibition of the synthesis of a subset of late viral proteins. These results are discussed with reference to using this system, the conferral of resistance to G418 with neo as a positive selectable marker, to facilitate constructing vaccinia virus recombinants which contain foreign genes of interest.

Inactivation of the srtA Gene in Streptococcus gordonii Inhibits Cell Wall Anchoring of Surface Proteins and Decreases In Vitro and In Vivo Adhesion

ABSTRACT The srtA gene product, SrtA, has been shown to be required for cell wall anchoring of protein A as well as virulence in the pathogenic bacterium Staphylococcus aureus. There are five major mechanisms for displaying proteins at the surface of gram-positive bacteria (P. Cossart and R. Jonquieres, Proc. Natl. Acad. Sci. USA 97:5013–5015, 2000). However, since many of the known surface proteins of gram-positive bacteria are believed to be exported and anchored via the sortase pathway, it was of interest to determine ifsrtA plays a similar role in other gram-positive bacteria. To that end, the srtA gene in the human oral commensal organism Streptococcus gordonii was insertionally inactivated. The srtA mutant S. gordoniiexhibited a marked reduction in quantity of a specific anchored surface protein. Furthermore, the srtA mutant had reduced binding to immobilized human fibronectin and had a decreased ability to colonize the oral mucosa of mice. Taken together, these results suggest that the activity of SrtA plays an important role in the biology of nonpathogenic as well as pathogenic gram-positive cocci.

Proteolytic maturation of vaccinia virus core proteins: identification of a conserved motif at the N termini of the 4b and 25K virion proteins

Three structural proteins (4a, 4b and 25K) located within the virion core of vaccinia virus are cleavage products of precursor polypeptides (P4a, P4b and P25K) synthesized late in viral infection. Pulse-chase labelling experiments revealed that cleavage of the core proteins lags considerably behind precursor synthesis and that processing requires continuous protein synthesis. The N-terminal sequences of 4b and 25K, but not 4a, were determined by microsequencing core proteins isolated from purified virions. Comparison of these data with the predicted amino acid sequence of P4b and P25K revealed a conserved Ala-Gly-Ala motif flanking the apparent N termini of both proteins, as well as several additional sequence similarities between the P4b and P25K precursors both upstream and downstream of the putative cleavage site. The Ala-Gly-Ala tripeptide signal was also found in the same region of the amino acid sequences of the homologous proteins of fowlpox virus.

Clinical and Microbiological Responses of Volunteers to Combined Intranasal and Oral Inoculation with a Streptococcus gordonii Carrier Strain Intended for Future Use as a Group A Streptococcus Vaccine

ABSTRACT Streptococcus gordonii shows promise as a live mucosal vaccine vector for immunization against respiratory pathogens. In preparation for clinical trials to evaluate S. gordonii engineered to express group A streptococcal M protein antigens, we characterized the responses of 150 healthy volunteers to combined nasal and oral inoculation with approximately 1.5 × 109 CFU of SP204(1-1), an S. gordonii strain not bearing vaccine antigens. SP204(1-1) was selected for resistance to streptomycin and 5-fluoro-2-deoxyuridine to distinguish it from indigenous flora. In two antibiotic treatment studies, we performed serial culturing of nose, mouth, and saliva samples from 120 subjects treated with azithromycin beginning 5 days after inoculation to determine whether SP204(1-1) could be rapidly eliminated should safety concerns arise. A natural history study was performed to assess the time until spontaneous eradication in the remaining 30 subjects, who did not receive the antibiotic and who were monitored with repeated culturing for 14 weeks after inoculation. SP204(1-1) was generally well tolerated. Symptoms reported most often within 5 days of inoculation were nasal congestion (36%), headache (30%), and sore throat (19%). The strain was detected by culturing in 98% of subjects. A single dose of azithromycin eliminated colonization in 95% of subjects; all subjects receiving a 5-day course of an antibiotic showed clearance by day 11. Without the antibiotic, 82% of subjects showed spontaneous eradication of the implanted strain within 7 days, and all showed clearance by 35 days. The results of these clinical trials provide encouragement that the use of S. gordonii as a live mucosal vaccine vector is a feasible strategy.

Viral acylproteins: greasing the wheels of assembly

Viruses take advantage of the hosts protein modification and targeting pathways to modify their own proteins and to ensure that they assume active configurations and locate appropriately for assembly. In many viruses, one recurrent theme in such processes is exploitation of cellular protein acylation pathways for the addition of myristic and palmitic acid to capsid or envelope proteins.

Association of non-viral proteins with recombinant vaccinia virus virions.

SummaryEvidence is presented which suggests that recombinant vaccinia virus particles (VV : CAT), containing the bacterial chloramphenicol acetyl transferase gene, are capable of encapsidating both the foreign protein which they encode (CAT) as well as cellular enzymes such as thymidine kinase. These results are discussed with respect to using VV to passively introduce biologically-active proteins into cells or organisms.

Analysis of Factors Affecting Surface Expression and Immunogenicity of Recombinant Proteins Expressed by Gram-Positive Commensal Vectors

ABSTRACT Several key protein structural attributes were altered in an effort to optimize expression and immunogenicity of a foreign protein (M protein from Streptococcus pyogenes) exposed on the surface of Streptococcus gordonii commensal bacterial vectors: (i) a shorter N-terminal region, (ii) the addition of a 94-amino-acid spacer, and (iii) the addition of extra C-repeat regions (CRR) from the M6 protein. A decrease in the amount of cell surface M6 was observed upon deletion of 10 or more amino acid residues at the N terminus. On the other hand, reactivity of monoclonal antibody to surface M6 increased with the addition of the spacer adjacent to the proline- and glycine-rich region, and an increase in epitope dosage was obtained by adding another CRR immediately downstream of the original CRR. The results obtained should facilitate the design of improved vaccine candidates using this antigen delivery technology.

Inhibition of vaccinia virus replication by nicotinamide: evidence for ADP-ribosylation of viral proteins.

Replication of vaccinia virus (VV) in monolayers of BSC40 cells was inhibited 99.9% in the presence of 60 mM nicotinamide (NIC), a competitive inhibitor of ADP-ribosylation reactions. Dot-blot hybridization analysis of infected cell extracts utilizing a VV DNA-specific probe indicated that the drug had only minimal effects on viral DNA synthesis. SDS-polyacrylamide gel electrophoresis of newly synthesized VV proteins pulse-labeled at early (2 h) or late (8 h) times post-infection revealed that although the full spectrum of expected viral polypeptides was evident, quantitative differences in the levels of expression of a distinct subset of viral proteins were observed in the presence of the drug. Velocity sedimentation of virus-infected cell lysates established that no mature particles were assembled in drug treated cells. Additional evidence suggesting that VV morphogenesis was abortive in the presence of NIC was obtained by pulse-chase labeling experiments that demonstrated that the two VV major late core polypeptide precursors P94 and P65, whose proteolytic processing to VP62 and VP60 is intimately associated with viral assembly, were not cleaved in the presence of NIC. Interestingly, growth of VV in the presence of [3H]adenosine resulted in the metabolic labeling of eight proteins that were associated with purified virions. These proteins co-migrated with proteins labeled with [3H]adenosine that were present in extracts of VV-infected, but not uninfected, cells. These analyses also revealed that the [3H]adenosine-labeling of a subset of cellular proteins (MW 18-20 kDa, possibly histones) was increased 4-fold by VV infection. The observed induction of either increased synthesis or hyper-modification of these 18-20 kDa proteins was inhibited by NIC. These results are discussed with respect to whether one or more VV polypeptides are subject to obligatory ADP-ribosylation modification reactions in order to attain their active configuration, and if so, whether the enzymes catalyzing these reactions are specified by the virus or host cell.

Novel acylation of poxvirus A-type inclusion proteins.

Myristylation is one of several post-translational modifications that occur on vaccinia virus (VV) proteins. Previously, time course labeling of VV-infected cells with myristic acid had indicated that five late proteins (17, 25, 36, 38 and 92 kDa) are myristylated. Four of these proteins were mapped to the E7R, L1R, AI6L and G9R open-reading frames, respectively, because of the predicted presence of the N-myristyltransferase recognition sequence (M-G-X-X-X-S/T/A) at their amino termini. In contrast, computer analyses of large (80-100 kDa) VV open reading frames did not reveal any predicted species with this N-terminal motif. By immunoprecipitation with monospecific sera and transient expression of cloned gene products, the myristylated 92-kDa protein has been demonstrated to be the A-type inclusion protein encoded by the Western Reserve (WR) strain of VV. Labeling of cowpox virus (CPV) infected cells with myristic acid indicated that the 160-kDa A-type inclusion protein appears to be myristylated as well. Both the VV 92-kDa and the CPV 160-kDa A-type inclusion proteins labeled with myristic acid were stable to hydroxylamine treatment, suggesting an amide linkage between the fatty acid and the acceptor protein. HPLC analysis confirmed that the 92-kDa protein was in fact myristylated. This data suggests that poxvirus ATI proteins may be subject to a novel type of internal myristylation modification, and the roles such modifications may play in the replication cycles of these viruses is discussed.

Expression and regulation of the vaccinia virus thymidine kinase gene in non-permissive cells

The expression and regulation of the vaccinia virus (VV) thymidine kinase (tk) gene was examined in two non-permissive cell lines, CHO and MDBK, which restrict VV development at different stages of the viral replication cycle. The VV tk gene was expressed in these two cell lines with kinetics similar to a fully permissive cell line BSC40. These results are consistent with the hypothesis that inhibition of tk mRNA translation by another viral early gene product is a normal component of the overall strategy employed to express and regulate the VV tk gene during a productive infection.