Productive replication of human adenovirus type 5 in canine cells

Development of immunocompetent patient-like models that allow direct analysis of human adenovirus-based conditionally replicative adenoviruses (CRAds) would be beneficial for the advancement of these oncolytic agents. To this end, we explored the possibility of cross-species replication of human adenovirus type 5 (Ad5) in canine cells. With a panel of canine tumor cell lines of both epithelial and mesenchymal derivations, we demonstrate that human Ad5 can productively infect canine cells. Since the biological behavior and clinical presentation of certain dog tumors closely resemble those of their human counterparts, our results raise the possibility of exploiting canine models for preclinical analysis of candidate CRAd agents designed for human virotherapy.     

Adenovirus Serotype 5 Variants Defective in Early Genes: Selective Replication in p53-Deficient Human Tumor Cells

Site-directed mutagenesis was used to construct human adenovirus serotype 5 (Ad5) variants defective in E1A or E1B. Mutant Adel3 with deletion from E1A was markedly attenuated in permissive cell cultures regardless of the p53 status, and replicated efficiently only in cells of the complementing 293 line. Mutant Adel2 with deletion from E1B55K infected the 293 line cells and p53-deficient human tumor cells (A431, SW480, HEp2) with efficiencies similar to those of Ad5, whereas its replication in normal p53-positive cells was substantially limited. Thus, Adel2 proved to be capable of selective infection and lysis of p53-deficient human tumor cells in vitro. On intratumor injection, Adel2 dramatically suppressed the growth of human epidermoid carcinoma (A431) in nude mice. Adel2 is thus a promising model for designing therapeutic agents against p53-deficient human tumors.     

The interaction between the fiber knob domain and the cellular attachment receptor determines the intracellular trafficking route of adenoviruses

Most of the presently used adenovirus (Ad) vectors are based on serotype 5. However, the application of these vectors is limited by the native tropism of Ad5. To address this problem, a series of fiber chimeric vectors were produced to take advantage of the different cellular receptors used by Ad of different subgroups. In this study we utilize an Ad5-based chimeric vector containing sequences encoding the Ad35 fiber knob domain instead of the Ad5 knob (Ad5/35L) to analyze factors responsible for selection of intracellular trafficking routes by Ads. By competition analysis with recombinant Ad5 and Ad35 knobs we showed that the Ad5/35L vector infected cells through a receptor different from the Ad5 receptor. Intracellular trafficking of Ad5 and Ad5/35L viruses was analyzed in HeLa cells by tracking fluorophore-conjugated Ad particles, by immunostaining for capsid hexon protein, by electron microscopy, and by Southern blotting for viral DNA. These studies showed that the interaction with the Ad35 receptor(s) predestines Ad5/35L vector to intracellular trafficking pathways different from those of Ad5. Ad5 efficiently escaped from the endosomes early after infection. In contrast, Ad5/35L remained longer in late endosomal/lysosomal compartments and used them to achieve localization to the nucleus. However, a significant portion of Ad5/35L particles appeared to be recycled back to the cell surface. This phenomenon resulted in significantly less efficient Ad5/35L-mediated gene transfer compared to that of Ad5. We also demonstrated that the selection of intracellular trafficking routes was determined by the fiber knob domain and did not depend on the length of the fiber shaft. This study contributes to a better understanding of the mechanisms that govern the infection of retargeted, capsid-modified vectors which have potential application for hematopoietic stem cell and tumor gene therapy.     

Immunochemical Properties of Recombinant Polypeptides Mimicking Domains I and II of West Nile Virus Glycoprotein E

Complementary DNA fragments (nucleotides 935–1475, 1091–1310, and 935–1193) encoding the N-terminal portion of glycoprotein E of West Nile virus (WNV), strain LEIV-Vlg99-27889-human, were cloned. Recombinant polypeptides of glycoprotein E (E_1–180, E_53–126, and E_1–86) of the WNV having amino acid sequences corresponding to the cloned cDNA fragments and mimicking the main functional regions of domains I and II of surface glycoprotein E were purified by affinity chromatography. According to ELISA and Western blotting, 12 types of monoclonal antibodies (MAbs) raised in our laboratory against recombinant polypeptide E_1–180 recognized the WNV glycoprotein E. This is indicative of similarity between the antigenic structures of the short recombinant polypeptides and corresponding regions of the glycoprotein. Analysis of interactions of the MAbs with short recombinant polypeptides and protein E of tick-borne encephalitis virus revealed at least six epitopes within domains I and II of the WNV protein E. We found at least seven MAb types against the region between amino acid residues (aa) 86 and 126 of domain II, which contains the peptide responsible for fusion of the virus and cell membranes (residues 98–110). The epitope for antireceptor MAbs 10H10 was mapped within the 53–86 aa region of domain II of WNV protein E, which is evidence for the spatial proximity of the fusion peptide and the coreceptor of protein E (residues 53–86) for cellular laminin-binding protein (LBP). The X-ray pattern of protein E suggests that the bc loop (residues 73–89) of domain II interacts with LBP and, together with the cd loop (fusion peptide), determines the initial stages of flavivirus penetration into the cell.     

Characterization of glycoprotein E C-End of West Nile virus and evaluation of its interaction force with αVβ3 integrin as putative cellular receptor

Recombinant polypeptide containing the 260–466 amino acid sequence of West Nile virus (WNV) strain LEIV-Vlg99-27889-human glycoprotein E (gpE, E_260–466) was constructed. Immunochemical similarity between the E_260–466 and gpE of WNV was proven by enzyme immunoassay (EIA), immunoblot, competitive EIA, hemagglutination inhibition, and neutralization tests using polyclonal and monoclonal antibodies against the viral gpE and recombinant E_260–466. Polypeptide E_260–466 induced formation of virus neutralizing and cross-reactive antibodies that were interactive with various epitopes of this recombinant protein. It is shown by evaluation of the interaction of E_260–466 with one of the proposed cell receptors of WNV that average E_260–466-αVβ3 integrin-specific interaction force measured using atomic force spectroscopy was 80 and 140 pN for single and double interactions, correspondingly. Taken together with previously described interaction between laminin-binding protein (LBP) and WNV gpE domain II, it is proposed that WNV gpE can interact specifically with two cellular proteins (LBP and αVβ3 integrin) during virus entry.     

Genome size and structure determine efficiency of postinternalization steps and gene transfer of capsid-modified adenovirus vectors in a cell-type-specific manner

Adenovirus serotype 5 (Ad5) vectors containing Ad B-group fibers have become increasingly popular as gene transfer vectors because they efficiently transduce human cell types that are relatively refractory to Ad5 infection. So far, most B-group fiber-containing vectors have been first-generation vectors, deleted of E1 and/or E3 genes. Transduction with these vectors, however, results in viral gene expression and is associated with cytotoxicity and immune responses against transduced cells. To circumvent these problems, we developed fiber-chimeric Ad vectors devoid of all viral genes that were produced either by the homologous recombination of first-generation vectors or by using the Cre/lox-based helper virus system. In this study we compared early steps of infection between first-generation (35-kb genome) and Ad vectors devoid of all viral genes with genome sizes of 28 kb and 12.6 kb. All vectors possessed an Ad35-derived fiber knob domain, which uses CD46 as a primary attachment receptor. Using immortalized human hematopoietic cell lines and primary human CD34-positive hematopoietic cells, we found that the Ad genome size did not affect the efficiency of virus attachment to and internalization into cells. Furthermore, independently of the genome length and structure, all vectors migrated to the nucleus through late endosomal and lysosomal cellular compartments. However, the vector containing the short 12.6-kb genome was unable to efficiently escape from endosomes and deliver its DNA into the nucleus. Moreover, compared to other vectors, these Ad particles were less stable and had an abnormal capsid protein composition, including a lack of capsid-stabilizing protein IX. Our data indicate that the size and structure of the packaged viral genomes can affect the integrity of Ad particles, which in turn results in lower infectivity of Ad vectors.     

Immunochemical properties of the West Nile virus prM protein and the C-terminal fragment of the M protein

The cDNA fragments 466–966 and 878–1088 coding for the precursor M (prM) protein and polypeptide M_31–75-E_1–30 of the Russian strain LEIV-Vlg99-27889-human of the West Nile virus (WNV) were synthesized and cloned. The corresponding prM and M_31–75-E_1–30 recombinant polypeptides were purified by affinity chromatography. The prM polypeptide interacted with a polyclonal serum against WNV in ELISA and immunoblotting, demonstrating the immunochemical similarity of the recombinant polypeptide and the native WNV prM protein. Six species-specific monoclonal antibodies (mAbs) against the prM recombinant polypeptide recognized at least four epitopes on the recombinant polypeptides. In addition, mAb 7D11 displayed a virus-neutralizing activity. The patterns of mAb interactions with the prM, M_31–75-E_1–30, E_1–180, and E_260–466 recombinant polypeptides revealed cross-reacting epitopes in regions 260–466 of the E protein and 31–75 of the M_31–75-E_1–30 polypeptide and the WNV prM protein. A spatial model revealed structural similarity of the C-terminal regions of the E and M proteins of WNV, supporting the results of immunochemical experiments. Based on virus neutralization by mAb 7D11, which recognized an epitope mapping to region 31–75 of the WNV M protein, an important function in virus penetration into the cell was assumed for the C-terminal region of the M protein.