Kaposi's sarcoma-associated herpesvirus LANA2 is a B-cell-specific latent viral protein that inhibits p53.

Kaposi's sarcoma-associated herpesvirus (KSHV), or human herpesvirus 8, is associated with three proliferative diseases ranging from viral cytokine-induced hyperplasia to monoclonal neoplasia: multicentric Castleman's disease (CD), Kaposi's sarcoma (KS), and primary effusion lymphoma (PEL). Here we report a new latency-associated 1,704-bp KSHV spliced gene belonging to a cluster of KSHV sequences having homology to the interferon regulatory factor (IRF) family of transcription factors. ORFK10.5 encodes a protein, latency-associated nuclear antigen 2 (LANA2), which is expressed in KSHV-infected hematopoietic tissues, including PEL and CD but not KS lesions. LANA2 is abundantly expressed in the nuclei of cultured KSHV-infected B cells. Transcription of K10.5 in PEL cell cultures is not inhibited by DNA polymerase inhibitors nor significantly induced by phorbol ester treatment. Unlike LANA1, LANA2 does not elicit a serologic response from patients with KS, PEL, or CD as measured by Western blot hybridization. Both KSHV vIRF1 (ORFK9) and LANA2 (ORFK10.5) appear to have arisen through gene duplication of a captured cellular IRF gene. LANA2 is a potent inhibitor of p53-induced transcription in reporter assays. LANA2 antagonizes apoptosis due to p53 overexpression in p53-null SAOS-2 cells and apoptosis due to doxorubicin treatment of wild-type p53 U2OS cells. While LANA2 specifically interacts with amino acids 290 to 393 of p53 in glutathione S-transferase pull-down assays, we were unable to demonstrate LANA2-p53 interaction in vivo by immunoprecipitation. These findings show that KSHV has tissue-specific latent gene expression programs and identify a new latent protein which may contribute to KSHV tumorigenesis in hematopoietic tissues via p53 inhibition.

Three unrelated viral transforming proteins (vIRF, EBNA2, and E1A) induce the MYC oncogene through the interferon-responsive PRF element by using different transcription coadaptors.

Kaposi sarcoma-associated herpesvirus vIRF is a viral transcription factor that inhibits interferon signaling and transforms NIH 3T3 cells, but does not bind interferon-stimulated response element (ISRE) DNA sequences. Here we show that induction of the MYC protooncogene is required for cell transformation by vIRF, and that vIRF increases MYC transcription up to 15-fold through specific promoter interactions at an ISRE sequence called the plasmacytoma repressor factor (PRF) element. These effects are resistant to cycloheximide but are inhibited by a dominant-negative ISRE-binding protein, indicating that vIRF acts together with a cellular cofactor at the PRF element to directly transactivate MYC. The coadaptor CREB-binding protein (CBP) binds vIRF and synergizes transactivation of MYC, but, unexpectedly, closely related histone acetyltransferases p300 and P/CAF potently suppress vIRF transactivation. On the basis of the prediction that other interferon-inhibiting viral transforming proteins behave similarly, we found that Epstein-Barr virus-induced nuclear antigen 2 (EBNA2) also binds p300/CBP, and that both EBNA2 and adenovirus E1A transactivate MYC through the PRF element. For E1A, P/CAF coactivates MYC, whereas both p300 and CBP suppress E1A transactivation. For EBNA2, both P/CAF and CBP coactivate the MYC promoter, whereas p300 suppresses EBNA2 transactivation. These findings demonstrate that viral transforming proteins can activate as well as inhibit transcription through coadaptor interactions. At some promoters CBP and p300 have previously unrecognized, competitive antagonism to each other. While all three viral proteins target the same promoter element, each has a different coadaptor use profile. These findings are consistent with cellular MYC repression playing a role in innate immunity as well as in control of cell proliferation.