The Role of the JC Virus in Central Nervous System Tumorigenesis.

Cancer is the second leading cause of mortality worldwide. The study of DNA tumor-inducing viruses and their oncoproteins as a causative agent in cancer initiation and tumor progression has greatly enhanced our understanding of cancer cell biology. The initiation of oncogenesis is a complex process. Specific gene mutations cause functional changes in the cell that ultimately result in the inability to regulate cell differentiation and proliferation effectively. The human neurotropic Polyomavirus JC (JCV) belongs to the family Polyomaviridae and it is the causative agent of progressive multifocal leukoencephalopathy (PML), which is a fatal neurodegenerative disease in an immunosuppressed state. Sero-epidemiological studies have indicated JCV infection is prevalent in the population (85%) and that initial infection usually occurs during childhood. The JC virus has small circular, double-stranded DNA that includes coding sequences for viral early and late proteins. Persistence of the virus in the brain and other tissues, as well as its potential to transform cells, has made it a subject of study for its role in brain tumor development. Earlier observation of malignant astrocytes and oligodendrocytes in PML, as well as glioblastoma formation in non-human primates inoculated with JCV, led to the hypothesis that JCV plays a role in central nervous system (CNS) tumorigenesis. Some studies have reported the presence of both JC viral DNA and its proteins in several primary brain tumor specimens. The discovery of new Polyomaviruses such as the Merkel cell Polyomavirus, which is associated with Merkel cell carcinomas in humans, ignited our interest in the role of the JC virus in CNS tumors. The current evidence known about JCV and its effects, which are sufficient to produce tumors in animal models, suggest it can be a causative factor in central nervous system tumorigenesis. However, there is no clear association between JCV presence in CNS and its ability to initiate CNS cancer and tumor formation in humans. In this review, we will discuss the correlation between JCV and tumorigenesis of CNS in animal models, and we will give an overview of the current evidence for the JC virus's role in brain tumor formation.

Progressive Multifocal Leukoencephalopathy in Primary Immunodeficiencies.

PURPOSE: Progressive multifocal leukoencephalopathy (PML) is a rare but severe demyelinating disease caused by the polyomavirus JC (JCV) in immunocompromised patients. We report a series of patients with primary immune deficiencies (PIDs) who developed PML. METHODS: Retrospective observational study including PID patients with PML. Clinical, immunological, imaging features, and outcome are provided for each patient. RESULTS: Eleven unrelated patients with PIDs developed PML. PIDs were characterized by a wide range of syndromic or genetically defined defects, mostly with combined B and T cell impairment. Genetic diagnosis was made in 7 patients. Before the development of PML, 10 patients had recurrent infections, 7 had autoimmune and/or inflammatory manifestations, and 3 had a history of malignancies. Immunologic investigations showed CD4+ lymphopenia (median 265, range 50-344) in all cases. Six patients received immunosuppressive therapy in the year before PML onset, including prolonged steroid therapy in 3 cases, rituximab in 5 cases, anti-TNF-α therapy, and azathioprine in 1 case each. Despite various treatments, all but 1 patient died after a median of 8 months following PML diagnosis. CONCLUSION: PML is a rare but fatal complication of PIDs. Many cases are secondary to immunosuppressive therapy warranting careful evaluation before initiation subsequent immunosuppression during PIDs.

Prevalence of antibodies against BKPyV subtype I and IV in kidney transplant recipients and in the general Czech population.

Active infection with BK polyomavirus (BKPyV) may cause serious complications in transplantation settings. Recently, the level of BKPyV IgG seroreactivity in graft donors has been shown to predict viremia and BKPyV-associated nephropathy in kidney transplant (KTx) recipients. Pretransplantation testing of the donor and recipient BKPyV serostatus could, therefore, identify patients at high risk. For the development of serological immunoassays, antibody response to the predominant BKPyV subtypes (BKPyV-I and BKPyV-IV) was studied using virus-like particle (VLP)-based enzyme-linked immunosorbent assay (ELISA). VLPs made from the capsid protein, VP1, derived from BKPyV-I and BKPyV-IV subtypes were produced using a baculovirus expression system and used as antigens. The tests were used for IgG antibody determination in 50 KTx recipients and 111 healthy blood donors. While 87% of samples reacted with mixed BKPyV-I and BKPyV-IV antigens, only 49% of samples were reactive in both ELISA tests when using BKPyV-I or BKPyV-IV antigens separately. Twenty-seven percent of healthy blood donors and 26% of KTx recipients were reactive only with BKPyV-I, while 9% and 20% were reactive only with BKPyV-IV, respectively. To determine the specificities of the antigens, selected seropositive samples were retested after preadsorption with soluble BKPyV-I, BKPyV-IV, or JC polyomavirus antigens. The experiments confirmed that recombinant VP1 VLP-based ELISAs predominantly detected BKPyV type-specific antibodies. The results imply that anti-BKPyV antibody ELISA tests should contain a mixture of subtype-specific VLP-based antigens instead of antigen derived from the most prevalent BKPyV-I subtype. The tests can be used for serological surveys of BKPyV infection and improved KTx patient management.

The DNA damage response promotes polyomavirus JC infection by nucleus to cytoplasm NF- kappaB activation.

BACKGROUND: Infection of glial cells by human neurotropic polyomavirus JC (JCV), the causative agent of the CNS demyelinating disease progressive multifocal leukoencephalopathy (PML), rapidly inflicts damage to cellular DNA. This activates DNA damage response (DDR) signaling including induction of expression of DNA repair factor Rad51. We previously reported that Rad51 co-operates with the transcription factor NF-κB p65 to activate JCV early transcription. Thus Rad51 induction by JCV infection may provide positive feedback for viral activation early in JCV infection. DDR is also known to stimulate NF-κB activity, a phenomenon known as nucleus to cytoplasm or "inside-out" NF-κB signaling, which is initiated by Ataxia telangiectasia mutated (ATM) protein, a serine/threonine kinase recruited and activated by DNA double-strand breaks. Downstream of ATM, there occurs a series of post-translational modifications of NF-κB essential modulator (NEMO), the γ regulatory subunit of inhibitor of NF-κB (IκB) kinase (IKK), resulting in NF-κB activation. METHODS: We analyzed the effects of downstream pathways in the DDR by phosphospecific Western blots and analysis of the subcellular distribution of NEMO by cell fractionation and immunocytochemistry. The role of DDR in JCV infection was analyzed using a small molecule inhibitor of ATM (KU-55933). NEMO sumoylation was investigated by Western and association of ATM and NEMO by immunoprecipitation/Western blots. RESULTS: We show that JCV infection caused phosphorylation and activation of ATM while KU-55933 inhibited JCV replication. JCV infection caused a redistribution of NEMO from cytoplasm to nucleus. Co-expression of JCV large T-antigen and FLAG-tagged NEMO showed the occurrence of sumoylation of NEMO, while co-expression of ATM and FLAG-NEMO demonstrated physical association between ATM and NEMO. CONCLUSIONS: We propose a model where JCV infection induces both overexpression of Rad51 protein and activation of the nucleus to cytoplasm NF-κB signaling pathway, which then act together to enhance JCV gene expression.

Human polyomavirus JC replication and non-coding control region analysis in multiple sclerosis patients under natalizumab treatment.

In the last years, the treatment of multiple sclerosis (MS) patients with natalizumab has been associated with the occurrence of progressive multifocal leukoencephalopathy (PML) caused by human polyomavirus JC (JCV). Here, we have shown a significant correlation between patients with JC viruria and positive JC-specific antibody response and patients without JCV-specific antibodies after 1 year of natalizumab (p = 0.0006). Furthermore, JCV-specific quantitative PCR on urine and plasma samples, collected at the enrollment (t0) and every 4 months (t1, t2, t3) in the first year and at two time points (t4 and t5) in the second year of natalizumab treatment, indicated the prevalence of JC viremia rather than JC viruria only in the second year of treatment (p = 0.04). Moreover, the analysis of JCV non-coding control region (NCCR) sequences in peripheral blood mononuclear cells of patients with JC-specific antibodies after 12 natalizumab infusions (t3) revealed the presence of rearranged sequences, whereas the prevalence of genotypes 1A, 1B, and 4 was detected in these patients by VP1 sequence analysis. In summary, JC viruria evaluation seems to be useful to identify early those patients who do not already develop a humoral immune response against JCV. It may also be interesting to study the JCV NCCR rearrangements since they could give us new insights on the onset of neuro-invasive viral variants.

Increased prevalence of JC polyomavirus viruria was associated with arthritis/arthralgia in patients with systemic lupus erythematosus.

OBJECTIVE: The objective of this paper is to investigate the prevalence of reactivation of the human polyomavirus John Cunningham virus (JCV) in patients with systemic lupus erythematosus (SLE) and its associated clinical manifestations. METHODS: Sixty-one patients with SLE and 22 controls were enrolled. Urine JCV viral load was quantified by real-time polymerase chain reaction (PCR). Length variants of the VP1 gene were analyzed using capillary electrophoresis. RESULTS: The prevalence of JCV viruria (63.9% vs. 18.2%, p < 0.001) and urine JCV viral load (2.92 ± 2.76 vs. 0.81 ± 1.85 copies/ml by log10 scale, p < 0.001) were significantly higher in patients with SLE compared with controls. JCV viruria (+) SLE patients had a higher occurrence of arthritis/arthralgia compared with JCV viruria (-) SLE patients (64.1% vs. 22.7%, p = 0.003). In SLE patients, the urine JCV viral load was significantly associated with the occurrence of arthritis/arthralgia. SLE patients with urine JCV viral load >10,000 copies/ml exhibited a 12.75-fold (95% confidence interval 2.88-56.40) risk in clinical arthritis/arthralgia, 18.90-fold (95% confidence interval 2.10-170.39) risk in persistent arthritis, and significantly greater number of length variants in the VP1 gene of JCV compared with JCV viruria (-) SLE patients. CONCLUSION: Reactivation of JCV in the urinary tract of SLE patients was very common. Both JCV viruria and urine JCV viral load were associated with the occurrence of arthritis/arthralgia in patients with SLE. High urine JCV viral load also was associated with the genetic variant in the VP1 gene.

IFNα and ß Mediated JCPyV Suppression through C/EBPß-LIP Isoform.

Polyomavirus JC (JCPyV) causes the demyelinating disease progressive multifocal leukoencephalopathy (PML). JCPyV infection is very common in childhood and, under conditions of severe immunosuppression, JCPyV may reactivate to cause PML. JC viral proteins expression is regulated by the JCPyV non-coding control region (NCCR), which contains binding sites for cellular transcriptional factors which regulate JCPyV transcription. Our earlier studies suggest that JCPyV reactivation occurs within glial cells due to cytokines such as TNF-α which stimulate viral gene expression. In this study, we examined interferon-α (IFNα) or ß (IFNß) which have a negative effect on JCPyV transcriptional regulation. We also showed that these interferons induce the endogenous liver inhibitory protein (LIP), an isoform of CAAT/enhancer binding protein beta (C/EBPß). Treatment of glial cell line with interferons increases the endogenous level of C/EBPß-LIP. Furthermore, we showed that the negative regulatory role of the interferons in JCPyV early and late transcription and viral replication is more pronounced in the presence of C/EBPß-LIP. Knockdown of C/EBPß-LIP by shRNA reverse the inhibitory effect on JCPyV viral replication. Therefore, IFNα and IFNß negatively regulate JCPyV through induction of C/EBPß-LIP, which together with other cellular transcriptional factors may control the balance between JCPyV latency and activation.

[Neurological complications of JC virus infection: A review]. / Complications neurologiques de l'infection par le virus JC : revue générale.

Although human polyomavirus JC (JCV) seroprevalence in the general population is high, its neurological complications are rare and progressive multifocal leukoencephalopathy (PML), a lethal central nervous system (CNS) demyelinating disease, is the most well-known. After an usually asymptomatic primary infection during late childhood, a latent JCV form persists in different sites, notably the kidneys and lymphocytes. Rearrangement of that archetype into the prototypical neurotropic strain can reactivate JCV, thereby enabling its CNS penetration and infection of glial cells. In a context of defective immune defenses (HIV infection, cancer or immunosuppressant therapies) this infection leads to oligodendrocyte death that contributes, via demyelinization, to PML but also, as more recently described, to other CNS complications, e.g., JCV granule cell neuronopathy, meningitis or encephalitis. Clinical manifestations depend on the localization of the lesions. The increasingly widespread use of new immunomodulatory monoclonal antibodies to treat multiple sclerosis and other inflammatory systemic diseases has increased PML frequency in those previously rarely affected entities. Diagnosis relies on magnetic resonance imaging, JCV detection in cerebrospinal fluid and, when necessary, brain histology. PML is often lethal. No specific, evidence-based treatment with clinically relevant efficacy is available. The therapeutic objective is to restore host immune responses to JCV, while avoiding immune-reconstitution inflammatory syndrome.

Viral Genomic Characterization and Replication Pattern of Human Polyomaviruses in Kidney Transplant Recipients.

Human Polyomavirus (HPyV) infections are common, ranging from 60% to 100%. In kidney transplant (KTx) recipients, HPyVs have been associated with allograft nephropathy, progressive multifocal leukoencephalopathy, and skin cancer. Whether such complications are caused by viral reactivation or primary infection transmitted by the donor remains debated. This study aimed to investigate the replication pattern and genomic characterization of BK Polyomavirus (BKPyV), JC Polyomavirus (JCPyV), and Merkel Cell Polyomavirus (MCPyV) infections in KTx. Urine samples from 57 KTx donor/recipient pairs were collected immediately before organ retrieval/transplant and periodically up to post-operative day 540. Specimens were tested for the presence of BKPyV, JCPyV, and MCPyV genome by virus-specific Real-Time PCR and molecularly characterized. HPyVs genome was detected in 49.1% of donors and 77.2% of recipients. Sequences analysis revealed the archetypal strain for JCPyV, TU and Dunlop strains for BKPyV, and IIa-2 strain for MCPyV. VP1 genotyping showed a high frequency for JCPyV genotype 1 and BKPyV genotype I. Our experience demonstrates that after KTx, HPyVs genome remains stable over time with no emergence of quasi-species. HPyVs strains isolated in donor/recipient pairs are mostly identical, suggesting that viruses detected in the recipient may be transmitted by the allograft.

PURA, the gene encoding Pur-alpha, member of an ancient nucleic acid-binding protein family with mammalian neurological functions.

The PURA gene encodes Pur-alpha, a 322 amino acid protein with repeated nucleic acid binding domains that are highly conserved from bacteria through humans. PUR genes with a single copy of this domain have been detected so far in spirochetes and bacteroides. Lower eukaryotes possess one copy of the PUR gene, whereas chordates possess 1 to 4 PUR family members. Human PUR genes encode Pur-alpha (Pura), Pur-beta (Purb) and two forms of Pur-gamma (Purg). Pur-alpha is a protein that binds specific DNA and RNA sequence elements. Human PURA, located at chromosome band 5q31, is under complex control of three promoters. The entire protein coding sequence of PURA is contiguous within a single exon. Several studies have found that overexpression or microinjection of Pura inhibits anchorage-independent growth of oncogenically transformed cells and blocks proliferation at either G1-S or G2-M checkpoints. Effects on the cell cycle may be mediated by interaction of Pura with cellular proteins including Cyclin/Cdk complexes and the Rb tumor suppressor protein. PURA knockout mice die shortly after birth with effects on brain and hematopoietic development. In humans environmentally induced heterozygous deletions of PURA have been implicated in forms of myelodysplastic syndrome and progression to acute myelogenous leukemia. Pura plays a role in AIDS through association with the HIV-1 protein, Tat. In the brain Tat and Pura association in glial cells activates transcription and replication of JC polyomavirus, the agent causing the demyelination disease, progressive multifocal leukoencephalopathy. Tat and Pura also act to stimulate replication of the HIV-1 RNA genome. In neurons Pura accompanies mRNA transcripts to sites of translation in dendrites. Microdeletions in the PURA locus have been implicated in several neurological disorders. De novo PURA mutations have been related to a spectrum of phenotypes indicating a potential PURA syndrome. The nucleic acid, G-rich Pura binding element is amplified as expanded polynucleotide repeats in several brain diseases including fragile X syndrome and a familial form of amyotrophic lateral sclerosis/fronto-temporal dementia. Throughout evolution the Pura protein plays a critical role in survival, based on conservation of its nucleic acid binding properties. These Pura properties have been adapted in higher organisms to the as yet unfathomable development of the human brain.