A fragile site in the human U2 small nuclear RNA gene cluster is revealed by adenovirus type 12 infection.

Using in situ hybridization, we found that the U2 small nuclear RNA gene cluster mapped very close to and was frequently disrupted by the gaps and breaks induced specifically in the human 17q21-q22 region by highly oncogenic adenovirus type 12 (Ad12). Restriction mapping revealed no structural alterations in the U2 gene locus as a result of Ad12 infection. Likewise, no Ad12-induced alterations in U2 RNA levels were detected. We estimate that the maximum size of the region specifically disrupted by this virus was less than 350 to 700 kilobases. A comparison of these data with similar data regarding biochemically induced fragile sites was made.     

Processing of vimentin occurs during the early stages of adenovirus infection.

Evidence is presented that a fraction of vimentin, a component of cytoskeleton recently found to be associated with intracytoplasmic, migrating adenovirus type 2 (Ad2), is processed into smaller polypeptides at early times after infection. The extent of vimentin cleavage appears to depend upon both the multiplicity of infection and the adenovirus serotype. Ad2, Ad5, Ad4, and Ad9 induced similar vimentin cleavage in infected cells, whereas Ad3, Ad7, and Ad12, for which most infecting particles are found sequestered within phagosomes, induced very little, if any, vimentin breakdown. This suggests that vimentin processing is in some way related to the number of virus particles migrating through the cytoplasm. Experiments performed in vitro and in vivo with adenovirus temperature-sensitive mutants H2 ts1 and H2 ts112 and UV-inactivated wild-type Ad2 indicated that vimentin processing is due to a nonvirion, cytoskeleton-associated, proteolytic enzyme activated by adenovirus and sharing characteristics with the protease described by Nelson and Traub (W.J. Nelson and P. Traub, J. Cell Sci. 57:25-49, 1982). The activity of this protease appears to be required for productive infection by adenovirus serotypes 2 and 5 (subgroup C), 4 (subgroup E), and 9 (subgroup D) but not by the oncogenic serotypes 3 and 7 (subgroup B) and 12 (subgroup A).     

Adenovirus cyt+ locus, which controls cell transformation and tumorigenicity, is an allele of lp+ locus, which codes for a 19-kilodalton tumor antigen.

The early region E1b of adenovirus type 2 (Ad2) codes for two major tumor antigens of 53 and 19 kilodaltons (kd). The adenovirus lp+ locus maps within the 19-kd tumor antigen-coding region (G. Chinnadurai, Cell 33:759-766, 1983). We have now constructed a large-plaque deletion mutant (dl250) of Ad2 that has a specific lesion in the 19-kd tumor antigen-coding region. In contrast to most other Ad2 lp mutants (G. Chinnadurai, Cell 33:759-766, 1983), mutant dl250 is cytocidal (cyt) on infected KB cells, causing extensive cellular destruction. Cells infected with Ad2 wt or most of these other Ad2 lp mutants are rounded and aggregated without cell lysis (cyt+). The cyt phenotype of dl250 resembles the cyt mutants of highly oncogenic Ad12, isolated by Takemori et al. (Virology 36:575-586, 1968). By intertypic complementation analysis, we showed that the Ad12 cyt mutants indeed map within the 19-kd tumor antigen-coding region. The transforming potential of dl250 was assayed on an established rat embryo fibroblast cell line, CREF, and on primary rat embryo fibroblasts and baby rat kidney cells. On all these cells, dl250 induced transformation at greatly reduced frequency compared with wt. The cells transformed by this mutant are defective in anchorage-independent growth on soft agar. Our results suggest that the 19-kd tumor antigen (in conjunction with E1a tumor antigens) may play an important role in the maintenance of cell transformation. Since we have mapped the low-oncogenic or nononcogenic Ad12 cyt mutants within the 19-kd tumor antigen-coding region, our results further indicate that the 19-kd tumor antigen also directly or indirectly plays an important role in tumorigenesis of Ad12. Our results show that the cyt+ locus is an allele of the lp+ locus and that the cyt phenotype may be the result of mutations in specific domains of the 19-kd tumor antigen.     

Modeling of the human intercellular adhesion molecule-1, the human rhinovirus major group receptor

A model has been built of the amino-terminal domain of the intercellular adhesion molecule-1 (ICAM-1), the receptor for most human rhinovirus serotypes. The model was based on sequence and presumed structural homology to immunoglobulin constant domains. It fits well into the putative receptor attachment site, the canyon, on the human rhinovirus-14 (HRV14) surface in a manner consistent with most of the mutational data for ICAM-1 (Staunton, D. E., Dustin, M. L., Erickson, H. P., Springer, T. A. Cell, in press, 1989) and HRV14 (Colonno, R. J., Condra, J. H., Mizutani, S., Callahan, P. L., Davies, M. E., Murcko, M. A. Proc. Natl. Acad. Sci. U.S.A. 85: 5449-5453, 1988).     

Identification of adenovirus 12-encoded E1A tumor antigens synthesized in infected and transformed mammalian cells and in Escherichia coli

A 16-amino acid peptide, H2N-Arg-Glu-Gln-Thr-Val-Pro-Val-Asp-Leu-Ser-Val-Lys-Arg-Pro-Arg-Cys-COOH (peptide 204), targeted to the common C-terminus of human adenovirus 12 (Ad12) tumor antigens encoded by the E1A 13S mRNA and 12S mRNA, has been synthesized. Antibody prepared in rabbits against peptide 204 immunoprecipitated two proteins of apparent Mr 47,000 and 45,000 from extracts of [35S]methionine-labeled Ad12-early infected KB cells and a 47,000 protein from extracts of the Ad12-transformed hamster cell line, HE C19. Immunoprecipitation analysis of infected and transformed cells labeled with 32Pi showed that both major Ad12 E1A T antigens are phosphoproteins. Immunofluorescence microscopy of Ad12-early infected KB cells with antipeptide antibody showed the site of E1A protein concentration to be predominantly nuclear. E1A proteins were detected by immunofluorescence at 4 to 6 h postinfection and continued to increase until at least 18 h postinfection. Antipeptide 204 antibody was used to analyze the proteins synthesized in Escherichia coli cells transformed by plasmids containing cDNA copies of the Ad12 E1A 13S mRNA or 12S mRNA under the control of the tac promoter (D. Kimelman, L. A. Lucher, M. Green, K. H. Brackmann, J. S. Symington, and M. Ptashne, Proc. Natl. Acad. Sci. U.S.A., in press). A major protein of ca. 47,000 was immunoprecipitated from extracts of each transformed E. coli cell clone. Two-dimensional gel electrophoretic analysis of immunoprecipitates revealed that the T antigens synthesized in infected KB cells, transformed hamster cells, and transformed E. coli cells possess very similar molecular weights and acidic isoelectric points of 5.2 to 5.4.     

Structure of Adenovirus Complexed with Its Internalization Receptor, αvβ5 Integrin

The three-dimensional structure of soluble recombinant integrin alphavbeta5 bound to human adenovirus types 2 and 12 (Ad2 and -12) has been determined at approximately 21-A resolution by cryoelectron microscopy (cryo-EM). The alphavbeta5 integrin is known to promote Ad cell entry. Cryo-EM has shown that the integrin-binding RGD (Arg-Gly-Asp) protrusion of the Ad2 penton base protein is highly mobile (P. L. Stewart, C. Y. Chiu, S. Huang, T. Muir, Y. Zhao, B. Chait, P. Mathias, and G. R. Nemerow, EMBO J. 16:1189-1198, 1997). Sequence analysis indicated that the Ad12 RGD surface loop is shorter than that of Ad2 and probably less flexible, hence more suitable for structural characterization of the Ad-integrin complex. The cryo-EM structures of the two virus-receptor complexes revealed a ring of integrin density above the penton base of each virus serotype. As expected, the integrin density in the Ad2 complex was diffuse while that in the Ad12 complex was better defined. The integrin consists of two discrete subdomains, a globular domain with an RGD-binding cleft approximately 20 A in diameter and a distal domain with extended, flexible tails. Kinetic analysis of Ad2 interactions with alphavbeta5 indicated approximately 4.2 integrin molecules bound per penton base at close to saturation. These results suggest that the precise spatial arrangement of five RGD protrusions on the penton base promotes integrin clustering and the signaling events required for virus internalization.     

Characterization of a second cleavage site and demonstration of activity in trans by the papain-like proteinase of the murine coronavirus mouse hepatitis virus strain A59.

The 21.7-kb replicase locus of mouse hepatitis virus strain A59 (MHV-A59) encodes several putative functional domains, including three proteinase domains. Encoded closest to the 5' terminus of this locus is the first papain-like proteinase (PLP-1) (S. C. Baker et al., J. Virol. 67:6056-6063, 1993; H.-J. Lee et al., Virology 180:567-582, 1991). This cysteine proteinase is responsible for the in vitro cleavage of p28, a polypeptide that is also present in MHV-A59-infected cells. Cleavage at a second site was recently reported for this proteinase (P. J. Bonilla et al., Virology 209:489-497, 1995). This new cleavage site maps to the same region as the predicted site of the C terminus of p65, a viral polypeptide detected in infected cells. In this study, microsequencing analysis of the radiolabeled downstream cleavage product and deletion mutagenesis analysis were used to identify the scissile bond of the second cleavage site to between Ala832 and Gly833. The effects of mutations between the P5 and P2' positions on the processing at the second cleavage site were analyzed. Most substitutions at the P4, P3, P2, and P2' positions were permissive for cleavage. With the exceptions of a conservative P1 mutation, Ala832Gly, and a conservative P5 mutation, Arg828Lys, substitutions at the P5, P1, and P1' positions severely diminished second-site proteolysis. Mutants in which the p28 cleavage site (Gly247 / Val248) was replaced by the Ala832 / Gly833 cleavage site and vice versa were found to retain processing activity. Contrary to previous reports, we determined that the PLP-1 has the ability to process in trans at either the p28 site or both cleavage sites, depending on the choice of substrate. The results from this study suggest a greater role by the PLP-1 in the processing of the replicase locus in vivo.     

Sequence of the DNA-binding protein gene of a human subgroup B adenovirus (type 7). Comparisons with subgroup C (type 5) and subgroup A (type 12)

The adenovirus type 7 (Ad7) single-stranded DNA-binding protein (DBP) structural gene has been sequenced and located between 66.7 and 62.3 map units. This region codes for a protein that contains 517 amino acid residues with a calculated molecular mass of 58,240 daltons. We compared the Ad7 amino acid sequence with those reported for the Ad5 (Kruijer, W., van Schaik, F.M.A., and Sussenbach, J.S. (1981) Nucleic Acids Res. 9, 4439-4457) and Ad12 (Kruijer, W., van Schaik, F.M.A., Speijer, J.G., and Sussenbach, J.S. (1983) Virology 128, 140-153) DNA-binding proteins. A greater amount of amino acid sequence homology was found in the carboxyl-terminal DNA-binding domain of the molecule. This homology is 61% between Ad7 and Ad5 and 49% when Ad12 was included in the comparison. The NH2-terminal domain of DBP retained a 49% homology between Ad7 and Ad5 and a 23% homology for all three serotypes. The greatest difference between the Ad7 and Ad5 DBPs is the absence, in the Ad7 protein, of 12 amino acids located between the two functional domains in the Ad5 protein (amino acids 151-162). In addition, three regions of high amino acid conservation between Ad5, Ad7, and Ad12 consisting of 9 (178-186), 9 (322-330), and 12 (464-475) consecutive amino acids (numbers refer to Ad5) in the DNA-binding portion of the molecule were revealed. These three regions contain a centrally located basic amino acid (183, 326, and 470) as well as an aromatic amino acid residue (181, 324, and 469). Since basic and aromatic amino acids have been implicated in other single-stranded DNA-binding protein/DNA interactions (Anderson, R.A., Nakashima, V., and Coleman, J.E. (1975) Biochemistry 14,907-917; Kowalczykowski, S.C., Lonberg, N., Newport, J.W., and von Hippel, P.H. (1981). J. Mol. Biol. 145, 75-104), these three conserved regions may represent DBP/DNA contact points.