Peter G. Medveczky

The latent human herpesvirus-6A genome specifically integrates in telomeres of human chromosomes in vivo and in vitro

Previous research has suggested that human herpesvirus-6 (HHV-6) may integrate into host cell chromosomes and be vertically transmitted in the germ line, but the evidence—primarily fluorescence in situ hybridization (FISH)—is indirect. We sought, first, to definitively test these two hypotheses. Peripheral blood mononuclear cells (PBMCs) were isolated from families in which several members, including at least one parent and child, had unusually high copy numbers of HHV-6 DNA per milliliter of blood. FISH confirmed that HHV-6 DNA colocalized with telomeric regions of one allele on chromosomes 17p13.3, 18q23, and 22q13.3, and that the integration site was identical among members of the same family. Integration of the HHV-6 genome into TTAGGG telomere repeats was confirmed by additional methods and sequencing of the integration site. Partial sequencing of the viral genome identified the same integrated HHV-6A strain within members of families, confirming vertical transmission of the viral genome. We next asked whether HHV-6A infection of naïve cell lines could lead to integration. Following infection of naïve Jjhan and HEK-293 cell lines by HHV-6, the virus integrated into telomeres. Reactivation of integrated HHV-6A virus from individuals’ PBMCs as well as cell lines was successfully accomplished by compounds known to induce latent herpesvirus replication. Finally, no circular episomal forms were detected even by PCR. Taken together, the data suggest that HHV-6 is unique among human herpesviruses: it specifically and efficiently integrates into telomeres of chromosomes during latency rather than forming episomes, and the integrated viral genome is capable of producing virions.

Chromosomally integrated human herpesvirus 6: questions and answers

Chromosomally integrated human herpesvirus 6 (ciHHV‐6) is a condition in which the complete HHV‐6 genome is integrated into the host germ line genome and is vertically transmitted in a Mendelian manner. The condition is found in less than 1% of controls in the USA and UK, but has been found at a somewhat higher prevalence in transplant recipients and other patient populations in several small studies. HHV‐6 levels in whole blood that exceed 5.5 log10 copies/ml are strongly suggestive of ciHHV‐6. Monitoring DNA load in plasma and serum is unreliable, both for identifying and for monitoring subjects with ciHHV‐6 due to cell lysis and release of cellular DNA. High HHV‐6 DNA loads associated with ciHHV‐6 can lead to erroneous diagnosis of active infection. Transplant recipients with ciHHV‐6 may be at increased risk for bacterial infection and graft rejection. ciHHV‐6 can be induced to a state of active viral replication in vitro. It is not known whether ciHHV‐6 individuals are put at clinical risk by the use of drugs that have been associated with HHV‐6 reactivation in vivo or in vitro. Nonetheless, we urge careful observation when use of such drugs is indicated in individuals known to have ciHHV‐6. Little is known about whether individuals with ciHHV‐6 develop immune tolerance for viral proteins. Further research is needed to determine the role of ciHHV‐6 in disease. Copyright

Activation of Stat3 in v-Src Transformed Fibroblasts Requires Cooperation of Jak1 Kinase Activity

Signal transducers and activators of transcription (STATs) are latent cytoplasmic transcription factors that transduce signals from the cell membrane to the nucleus upon activation by tyrosine phosphorylation. Several protein-tyrosine kinases can induce phosphorylation of STATs in cells, including Janus kinase (JAK) and Src family kinases. One STAT family member, Stat3, is constitutively activated in Src-transformed NIH3T3 cells and is required for cell transformation. However, it is not entirely clear whether Src kinase can phosphorylate Stat3 directly or through another pathway, such as JAK family kinases. To address this question, we investigated the phosphorylation of STATs in baculovirus-infected Sf-9 insect cells in the presence of Src. Our results show that Src can tyrosine-phosphorylate Stat1 and Stat3 but not Stat5 in this system. The phosphorylated Stat1 and Stat3 proteins are functionally activated, as measured by their abilities to specifically bind DNA oligonucleotide probes. In addition, the JAK family member Jak1 efficiently phosphorylates Stat1 but not Stat3 in Sf-9 cells. By contrast, we observe that AG490, a JAK family-selective inhibitor, and dominant negative Jak1 protein can significantly inhibit Stat3-induced DNA binding activity as well as Stat3-mediated gene activation in NIH3T3 cells. Furthermore, wild-type or kinase-inactive platelet-derived growth factor receptor enhances Stat3 activation by v-Src, consistent with the receptor serving a scaffolding function for recruitment and activation of Stat3. Our results demonstrate that Src kinase is capable of activating STATs in Sf-9 insect cells without expression of JAK family members; however, Jak1 and platelet-derived growth factor receptor are required for maximal Stat3 activation by Src kinase in mammalian cells. Based on these findings, we propose a model in which Jak1 serves to recruit Stat3 to a receptor complex with Src kinase, which in turn directly phosphorylates and activates Stat3 in Src-transformed fibroblasts.

In vitro antiviral drug sensitivity of the Kaposi's sarcoma-associated herpesvirus

Objective:Kaposis sarcoma-associated herpesvirus (KSHV), or human herpesvirus 8, has been implicated as the causative agent of Kaposis sarcoma. Retrospective studies show that the risk of development of Kaposis sarcoma is significantly lower in AIDS patients who received ganciclovir or phosphonoformic acid (PFA) therapy. Therefore, in vitro antiviral drug sensitivity of KSHV was studied. Methods:The KSHV genome is a latent episome in lymphoma cells such as the BCBL-1 cell line. Lytic KSHV DNA synthesis is induced by the phorbol ester 12-O-tetradecanoyl phorbol-13-acetate in BCBL-1 cells; this system was used to evaluate the effects of antiviral drugs on KSHV DNA synthesis. Results:Linear (lytic) KSHV DNA synthesis and virus secretion was inhibited in BCBL-1 cell cultures by cidofovir (median inhibitory concentration, 0.05 µM), ganciclovir (5.1 µM) and PFA (97 µM), and by aciclovir (75 µM). Prolonged incubation of BCBL-1 cells with antiviral drugs had no effect on episomal KSHV DNA synthesis. Conclusions:The antiviral drug assay developed shows that KSHV is very sensitive to cidofovir, moderately sensitive to ganciclovir and PFA, and weakly sensitive to aciclovir. Therefore, low doses of cidofovir, or high doses of PFA or ganciclovir could suppress clinical reactivation of KSHV. Antiviral drugs did not inhibit episomal virus DNA synthesis, suggesting that the latent form of viral DNA is replicated by host DNA polymerases. Consequently, no benefit can be expected from antiviral drugs in KSHV-positive B-cell lymphomas or during latency.

Classification of HHV-6A and HHV-6B as distinct viruses

Shortly after the discovery of human herpesvirus 6 (HHV-6), two distinct variants, HHV-6A and HHV-6B, were identified. In 2012, the International Committee on Taxonomy of Viruses (ICTV) classified HHV-6A and HHV-6B as separate viruses. This review outlines several of the documented epidemiological, biological, and immunological distinctions between HHV-6A and HHV-6B, which support the ICTV classification. The utilization of virus-specific clinical and laboratory assays for distinguishing HHV-6A and HHV-6B is now required for further classification. For clarity in biological and clinical distinctions between HHV-6A and HHV-6B, scientists and physicians are herein urged, where possible, to differentiate carefully between HHV-6A and HHV-6B in all future publications.

Epigenetic regulation of Kaposi's sarcoma-associated herpesvirus replication.

Kaposis sarcoma-associated herpesvirus (KSHV) is the causative agent of Kaposis sarcoma and B-lymphocyte disorders, primary effusion lymphoma (PEL) and Multicentric Castlemans Disease (MCD). KSHV usually exists in a latent form in which the viral genome is circularized into an extrachormosomal episome. However, induction of lytic replication by environmental stimuli or chemical agents is important for the spread of KSHV. The switch between latency and lytic replication is regulated by epigenetic factors. Hypomethylation of the promoter of replication and transcription activator (RTA), which is essential for the lytic switch, leads to KSHV reactivation. Histone acetylation induces KSHV replication by influencing protein-protein-associations and transcription factor binding. Histone modifications also determine chromatin structure and nucleosome positioning, which are important for KSHV DNA replication during latency. The association of KSHV proteins with chromatin remodeling complexes promotes the open chromatin structure needed for transcription factor binding and DNA replication. Additionally, post-translational modification of KSHV proteins is important for the regulation of RTA activity and KSHV replication. KSHV may also cause epigenetic modification of the host genome, contributing to promoter hypermethylation of tumor suppressor genes in KSHV-associated neoplasias.

The molecular biology of human herpesvirus-6 latency and telomere integration

The genomes of herpesviruses establish latency as a circular episome. However, Human herpesvirus-6 (HHV-6) has been shown to specifically integrate into the telomeres of chromosomes during latency and vertically transmit through the germ-line. This review will focus on the telomere integration of HHV-6, the potential viral and cellular genes that mediate integration, and the clinical impact on the host.

Review, part 1: Human herpesvirus-6-basic biology, diagnostic testing, and antiviral efficacy.

Louis Flamand, Anthony L. Komaroff, Jesse H. Arbuckle, Peter G. Medveczky, and Dharam V. Ablashi* Department of Microbiology, Infectious Diseases and Immunology, Faculty of Medicine, Laval University, Quebec, Canada Department of Medicine, Brigham & Women’s Hospital and Harvard Medical School, Boston, Massachusetts Department of Molecular Medicine, University of South Florida College of Medicine, Tampa, Florida HHV-6 Foundation, Santa Barbara, California

Activation of the Lck Tyrosine-protein Kinase by the Binding of the Tip Protein of Herpesvirus Saimiri in the Absence of Regulatory Tyrosine Phosphorylation

The Tip protein of herpesvirus saimiri 484 binds to the Lck tyrosine-protein kinase at two sites and activates it dramatically. Lck has been shown previously to be activated by either phosphorylation of Tyr394 or dephosphorylation of Tyr505. We examined here whether a change in the phosphorylation of either site was required for the activation of Lck by Tip. Remarkably, mutation of both regulatory sites of tyrosine phosphorylation did not prevent activation of Lck by Tip eitherin vivo or in a cell free in vitro system. Tip therefore appears to be able to activate Lck through an induced conformational change that does not necessarily involve altered phosphorylation of the kinase. Tip may represent the prototype of a novel type of regulator of tyrosine-protein kinases.

Genetic requirements for the episomal maintenance of oncogenic herpesvirus genomes.

Herpesviruses are large double-stranded DNA viruses that are characterized by lifelong latency. Epstein-Barr virus (EBV), the recently discovered Kaposis sarcoma associated herpesvirus (KSHV), also referred to as human herpesvirus-8 (HHV-8), and the simian Herpesvirus saimiri (HVS) are associated with malignant lymphoproliferative diseases. These viruses establish latent infection in lymphoid cells. During latency only a few viral genes are expressed and the viral genome persists as a multicopy circular episome. The episome contains repetitive sequences that serve as multiple cooperative binding sites for the viral DNA binding proteins Epstein-Barr virus nuclear antigen 1 (EBNA-1) of EBV and latency-associated nuclear antigen (LANA1) of KSHV and HVS, which are expressed during latency. The oligomerized proteins associate with the viral genome and tether it to host chromosomes, assuring continual lifelong persistence of the virus.