Purified JC virus T and T' proteins differentially interact with the retinoblastoma family of tumor suppressor proteins.

The amino termini of polyomavirus T antigens contain LXCXE and J domains, which are necessary for binding and inactivating the retinoblastoma family of tumor suppressors. Both of these motifs are found in the JC virus (JCV) early proteins T'(135), T'(136), and T'(165), leading to the suggestion that these recently discovered proteins complement the cell-cycle-deregulating function of the JCV large T antigen (TAg). To investigate this hypothesis, the three JCV T' proteins were produced in a baculovirus expression system and purified by immunoaffinity chromatography. To facilitate purification, hybridomas that secrete antibodies recognizing amino-terminal epitopes of JCV early proteins were produced. Potential interactions between the early viral proteins and the cellular proteins pRB, p107, and p130 were investigated by incubating purified JCV TAg and T' proteins with extracts of MOLT-4 cells, a human T cell line. The four viral proteins preferentially bound hypophosphorylated species of the cellular proteins and exhibited the highest binding affinity to p107 and the lowest affinity to pRB. TAg and T'(165) bound more pRB and less p107 than did T'(135) and T'(136); T'(165) also bound less p130 than the other three early proteins. Results of these in vitro interactions were compared to those obtained in vivo using POJ cells, a transformed human glial cell line that expresses JCV early proteins, relatively high levels of pRB and p107, and low levels of p130. Most of the pRB in POJ cells is hyperphosphorylated, and only a fraction of the hypophosphorylated form(s) of pRB is bound by the viral proteins. In contrast, only hypophosphorylated p130 is detected in the transformed cells, and most of this protein was found in complex with the viral proteins. Finally, nearly all of the p107 in POJ cells is bound by the JCV proteins.

Purified JC virus T antigen derived from insect cells preferentially interacts with binding site II of the viral core origin under replication conditions.

The human polyomavirus JC virus (JCV) establishes persistent, asymptomatic infections in most individuals, but in severely immunocompromised hosts it may cause the fatal demyelinating brain disease progressive multifocal leukoencephalopathy. In cell culture JCV multiplies inefficiently and exhibits a narrow host range. This restricted behavior occurs, in part, at the level of DNA replication, which is regulated by JCV's multifunctional large tumor protein (TAg). To prepare purified JCV TAg (JCT) for biochemical analyses, the recombinant baculovirus B-JCT was generated by cotransfection of insect cells with wild-type baculovirus and the vector pVL-JCT(Int-) containing the JCT-coding sequence downstream of the efficient polyhedrin promoter. JCT expressed in infected cells was immunoaffinity purified using the anti-JCT monoclonal antibody PAb 2000. Characterization of the viral oncoprotein indicated that it exists in solution as a mixture of monomeric and oligomeric species. With the addition of ATP, the population of monomers decreased and that of hexamers and double hexamers increased. A DNA mobility shift assay indicated that origin binding occurred primarily with the double-hexamer form. A comparison of the specific DNA-binding activities of JCT and SV40 TAg (SVT) revealed that JCT generally exhibited greater affinity for binding site II relative to binding site I (B.S. I) of both viral origin regions, whereas SVT preferentially bound B.S. I. Furthermore, JCT bound nonviral DNA more efficiently than did SVT. These functional differences between the two TAgs may contribute to the reduced DNA replication potential of JCV in vitro, and to the virus' ability to establish persistent infections in vivo.

Cooperative action of cellular proteins YB-1 and Pur alpha with the tumor antigen of the human JC polyomavirus determines their interaction with the viral lytic control element.

Human JC polyomavirus (JCV) is the etiologic agent of the neurodegenerative disease progressive mulifocal leukoencephalopathy. By using JCV as a model, we investigated the role of the viral early protein tumor antigen (TAg) in the binding of two cellular proteins, Pura alpha and YB-1, to JCV regulatory sequences. Results from band-shift assays with purified YB-1, Pur alpha, and TAg indicated that efficient binding of Pur alpha, a strong activator of early gene transcription, to a single-stranded target sequence corresponding to the viral lytic control element, is diminished in the presence of the late gene activator YB-1, which recognizes the opposite strand of the Pur alpha binding site. Of particular interest was the ability of Pur alpha and TAg to enhance binding of YB-1 to DNA molecules without being associated with this complex. Binding studies using a mutant peptide encompassing the N terminus of YB-1 indicated that the C terminus of YB-1 is important for its DNA binding activity. The ability of Pur alpha and TAg to increase binding of YB-1 to DNA is independent of the YB-1 C terminus. Similarly, results from band-shift assays using Pur alpha variants indicated that two distinct regions of this protein contribute either to its ability to bind DNA or to its ability to enhance YB-1 DNA binding activity. Based on the interaction of Pur alpha, YB-1, and TAg, and their binding to DNA, a model is proposed for the role of these proteins in transcription of viral early and late genes during the lytic cycle.

PAb 2000 specifically recognizes the large T and small t proteins of JC virus.

A monoclonal antibody, PAb 2000, has been derived which recognizes the large T protein of JC virus (JCV), but not the corresponding proteins of the related polyomaviruses BK virus (BKV) and SV40. The epitope bound by PAb 2000 was localized to the amino-terminal 81 amino acids of this multifunctional protein. As observed previously with several monoclonal antibodies that bind a similar region of SV40 large T antigen, PAb 2000 was found to interact with the small t antigen and the denatured form of large T antigen. This monoclonal antibody recognized a subpopulation of T protein, the abundance of which varied in different species of cells transformed by JCV. The availability of PAb 2000, the first JCV T antigen-specific monoclonal antibody, will facilitate the purification and biochemical characterization of the JCV oncoproteins.

Hybrid genomes of the polyomaviruses JC virus, BK virus, and simian virus 40: identification of sequences important for efficient transformation.

Hybrid viral genomes were used to investigate the influence of specific polyomavirus sequences on the transforming behavior of JC virus (JCV). One set of chimeric DNAs was made by exchanging the regulatory regions between JCV and simian virus 40 (SV40) or JCV and BK virus (BKV). A second set of constructs was produced that expressed hybrid JCV-BKV T proteins under the control of either JCV or BKV regulatory signals. Transformation of Rat 2 cells with the parental and chimeric DNAs indicated that both the JCV regulatory signals and the sequence encoding the amino terminus of T protein contributed to the restricted transforming behavior of this virus. Analysis of the viral proteins in the transformed rat cells indicated that the large T antigens of JCV and BKV were less stable than their SV40 counterpart, that small t protein was produced in JCV transformants, and that the subpopulation of T antigen that forms a stable complex with cellular p53 protein was smaller in JCV-transformed cells than in SV40- or BKV-transformed cells.