Infection of human B lymphocytes with lymphocryptoviruses related to Epstein-Barr virus

Lymphocryptoviruses (LCVs) naturally infecting Old World nonhuman primates are closely related to the human LCV, Epstein-Barr virus (EBV), and share similar genome organization and sequences, biologic properties, epidemiology, and pathogenesis. LCVs can efficiently immortalize B lymphocytes from the autologous species, but the ability of a given LCV to immortalize B cells from other Old World primate species is variable. We found that LCV from rhesus monkeys did not immortalize human B cells, and EBV did not immortalize rhesus monkey B cells. In this study, baboon LCV could not immortalize human peripheral blood B cells but could readily immortalize rhesus monkey B cells. Thus, efficient LCV-induced B-cell immortalization across distant Old World primate species appears to be restricted by a species-specific block. To further characterize this species restriction, we first cloned the rhesus monkey LCV major membrane glycoprotein and discovered that the binding epitope for the EBV receptor, CD21, was highly conserved. Stable infections of human B cells with recombinant amplicons packaged in rhesus monkey or baboon LCV envelopes were also consistent with a species-restricted block occurring after virus binding and penetration. Transient infections of human B cells with simian LCV resulted in latent LCV EBNA-2 gene expression and activation of cell CD23 gene expression. EBV-immortalized human B cells could be coinfected with baboon LCV, and the simian virus persisted and replicated in human B cells. Thus, several lines of evidence indicate that the species restriction for efficient LCV-induced B-cell immortalization occurs beyond virus binding and penetration. This has important implications for the study of LCV infection in Old World primate models and for human xenotransplantation where simian LCVs may be inadvertently introduced into humans.     

Growth arrest of Epstein-Barr virus immortalized B lymphocytes by adenovirus-delivered ribozymes

Epstein-Barr virus (EBV) infection is associated with several human diseases that involve unrestricted proliferation of B lymphocytes. EBV nuclear antigen 1 (EBNA-1) is expressed in all EBV-infected cells and plays an essential role in persistence of the EBV genome. EBNA-1 has also been reported to have oncogenic potential. As an approach for treating EBV infections, we examined the capacity of EBNA-1 ribozymes delivered by recombinant adenoviruses to suppress EBNA-1 expression and to block virus-induced B cell proliferation. In contrast to primary B cells, EBV-transformed B lymphoblastoid cell lines expressed alphav integrins, the adenovirus internalization receptors, and were also susceptible to adenovirus-mediated gene delivery. Adenovirus delivery of a specific ribozyme (RZ1) to lymphoblastoid cell lines, suppressed EBNA-1 mRNA and protein expression, significantly reduced the number of EBV genomes, and nearly abolished cell proliferation in low serum. Adenovirus delivery of RZ1 also prevented EBV infection of an established EBV-negative B cell line. These studies demonstrate the potential use of adenovirus-encoded ribozymes to treat EBV-induced lymphoproliferative disorders.     

Epstein-Barr virus contributes to the malignant phenotype and to apoptosis resistance in Burkitt's lymphoma cell line Akata

In the present study, we established an in vitro system representing the Burkitt's lymphoma (BL)-type Epstein-Barr virus (EBV) infection which is characterized by expression of EBV-determined nuclear antigen 1 (EBNA-1) and absence of EBNA-2 and latent membrane protein 1 (LMP1) expression. EBV-negative cell clones isolated from the EBV-positive BL line Akata were infected with an EBV recombinant carrying a selectable marker, and the following selection culture easily yielded EBV-infected clones. EBV-reinfected clones showed BL-type EBV expression and restored the capacity for growth on soft agar and tumorigenicity in SCID mice that were originally retained in parental EBV-positive Akata cells and lost in EBV-negative subclones. Moreover, it was found that EBV-positive cells were more resistant to apoptosis than were EBV-negative cells. EBV-infected cells expressed the bcl-2 protein, through which cells might become resistant to apoptosis, at a higher level than did uninfected cells. This is the first report that BL-type EBV infection confers apoptosis resistance even in the absence of expression of LMP1 and BHRF1, both of which are known to have an antiapoptotic function. Surprisingly, transfection of the EBNA-1 gene into EBV-negative Akata clones could not restore malignant phenotypes and apoptosis resistance, thus suggesting that EBNA-1 alone was not sufficient for conferring them. Our results suggest that the persistence of EBV in BL cells is required for the cells to be more malignant and apoptosis resistant, which underlines the oncogenic role of EBV in BL genesis.     

Perspectives on the use of the baboon in embryology and teratology research

This paper summarizes the developmental stages of the baboon during the period of organ formation and provides comparative information for other primates, including the human. Special attention is directed to the early development of the nervous system, eye, ear and nose/palate. The similarity in development of these structures with humans indicates that the baboon is a suitable model for studies of normal and abnormal neurological development. Spontaneous prenatal loss rates in the baboon (2.4-11.2%) are slightly lower than those reported in rhesus and cynomologus monkeys. The baboon, in addition to the cynomologus monkey and macaque, has been used as a model in teratology research to assess the potential risk of thalidomide, sex steroids, Bendectin and rubella virus, as well as to study the pathogenesis of malformations associated with the corticosteroid triamcinolone acetonide. The rate of spontaneous malformations (<1%) in baboons, similar to that reported for other commonly used primates, supports their continued use as a teratological model. In this regard, a sample protocol is provided for the safety evaluation of biotechnology products using nonhuman primates, which are the most appropriate model for those compounds which are bioactive in species closely related to humans.     

Control of lipolysis in intra-abdominal fat cells of nonhuman primates: comparison with humans

The mechanisms that control lipolysis in intra-abdominal fat cells from various primate species, the marmoset (Callithrix jacchus), the baboon (Papio papio), and the macaque (Macaca fascicularis), were compared to those of human intraabdominal fat cells. Selective beta 1- or beta 2-adrenoceptor agonists induced lipolysis in all species. Selective beta 3-agonists (BRL 37344, CL 316243, and SR 58611) acted as partial agonists in marmoset but were inefficient in other primates, including humans. alpha 2-Adrenoceptor number ([3H]RX 8210002 binding) equalized (baboon) or exceeded (other primates) beta 1/beta 2-adrenoceptors ([3H]CGP 12177 binding). Baboon fat cell membranes expressed similar amounts of coupled beta- and alpha 2-adrenoceptors. In all species, norepinephrine- or epinephrine-induced lipolysis did not reach the lipolytic effect of isoproterenol but their effects were enhanced after alpha 2-adrenoceptor blockade. N6-phenylisopropyladenosine (PIA) induced a full antilipolytic effect in baboon, macaque, and human adipocytes through adenosine receptors ([3H]DPCPX binding). Peptide YY (PYY) weakly inhibited lipolysis in baboon. Adrenocorticotropic hormone (ACTH) was inactive whereas parathyroid hormone (PTH) partially stimulated lipolysis in primates. Histamine was partially lipolytic in marmoset only. This study emphasizes the similarities of the mechanisms controlling the lipolysis in nonhuman primate and in human adipocytes and suggests that the baboon and the macaque should provide unique models for the study of the regulation of lipolysis.     

Infection of baboons with a simian immunodeficiency virus/HIV-1 chimeric virus constructed with an HIV-1 Thai subtype E envelope

OBJECTIVE: To construct an infectious chimeric simian immunodeficiency virus/HIV-1 (SHIV) with the envelope of a Thai subtype E HIV-1 strain for use in a non-human primate model. METHODS: A novel SHIV genome was derived using the sequences of the ectodomain of the envelope gene from the Thai subtype E strain, HIV-1(9466). This SHIV (SHIV9466.33) was recovered by cocultivation from human peripheral blood mononuclear cells (PBMC) after transfection of human rhabdosarcoma cells. Rhesus macaque and baboon PBMC were screened in vitro for susceptibility to infection with SHIV9466.33. After successful infection of baboon PBMC, four animals were inoculated intravenously with SHIV9466.33 and monitored for plasma viral RNA, virus isolation from the PBMC, seroconversion, T-cell subsets, and signs of disease. RESULTS: SHIV9466.33 was able to infect PBMC from 12 out of 14 baboons. All four of the baboons selected for in vivo inoculation became infected. Peak plasma viral RNA levels of 8000 to 700,000 RNA copies/ml were measured at 2 weeks post-inoculation. Virus was isolated from the PBMC of all four baboons during acute infection, and all seroconverted. Although transient declines in CD4+ T-cells were observed during early infection, CD4+ levels remained within normal ranges thereafter. In contrast, in vitro cultures of PBMC of four rhesus macaques were not susceptible to infection with SHIV9466.33. CONCLUSION: SHIV9466.33 containing an HIV-1 subtype E envelope displayed tropism for baboon PBMC but not for rhesus macaque PBMC. This chimeric virus established infection and induced antiviral antibodies in baboons inoculated by the intravenous route with cell-free virus. Thus, infection of baboons with SHIV9466.33 will serve as an important animal model for future studies of HIV-1 vaccine efficacy.     

Epstein-Barr virus protein LMP2A regulates reactivation from latency by negatively regulating tyrosine kinases involved in sIg-mediated signal transduction

Like other herpesviruses, Epstein-Barr Virus (EBV) persists in its host through an ability to establish latent infection with episodic reactivations. In latent infection EBV expresses an integral membrane protein LMP2A that regulates reactivation from latency. LMP2A is constitutively tyrosine phosphorylated and is associated with lyn and syk tyrosine kinases. The activity of lyn is substantially reduced. In EBV-infected cells in which LMP2A is expressed, crosslinking of sIg fails to trigger the protein tyrosine kinase signal cascade, tyrosine phosphorylation of cell proteins does not change, second messengers are not generated, and lytic EBV infection is not induced. In contrast, crosslinking of sIg on cells infected with EBV recombinants with null mutations in LMP2A results in transient tyrosine phosphorylation of lyn, syk, phospholipase C gamma 2 and phosphatidylinositol-3' kinase, transiently increased intracellular free calcium, and reactivation of lytic EBV infection. These studies describe a novel molecular regulator of herpesvirus latency and focus attention on the importance of transmembrane signal transduction in herpes virus reactivation from latency. They support the working hypothesis that the identification of ligand-receptor interactions that can result in the induction of reactivation will provide an important inroad toward the delineation of the molecular mechanism, which govern herpesvirus reactivation from latency.     

Epstein-Barr virus activity in patients on chronic hemodialysis

Patients with uremia are susceptible to viral infections, especially to Epstein-Barr virus (EBV). Sixty-one patients with end-stage renal diseases on chronic hemodialysis (HD), 14 patients with impaired renal function (CRF), and 27 healthy controls were studied with regard to EBV infection. Uremic patients (HD and CRF) had a significantly higher incidence of EBV infection and higher titers of anti-EBV VCA-IgG antibody than healthy controls. The anti-EBNA-1 titer was significantly higher in patients whose dialysis period was more than 3 months than in whom the dialysis period was 3 months or less. Immunoblotting analysis also showed stronger EBNA-1 signals in hemodialysis patients than EBNA-2, which was strongly detected in the CRF group and in healthy controls. EBV DNA was detected by Southern blot hybridization after PCR amplification of peripheral leukocytes, and occurred at a greater incidence in hemodialysis patients than in the other groups. Taken together, these results demonstrated that hemodialysis patients had persistent EBV infection.     

Epstein-Barr virus transmission from a blood donor to an organ transplant recipient with recovery of the same virus strain from the recipient's blood and oropharynx

A previous study (Savoie et al, Blood 83:2715, 1994) identified eight transplant patients who acquired Epstein-Barr virus (EBV) infection during the peritransplant period. Three of these patients subsequently developed B-cell lymphoproliferative disease within 4 months of transplantation. Among these, there was a 16-year-old liver transplant patient who was negative for EBV at the time of transplant and who received an EBV-negative organ. After transplant, this patient was transfused with 9 U of packed red blood cells. Eight of the donors were EBV-positive and one was EBV-negative. We succeeded in obtaining spontaneous lymphoblastoid cell lines (LCLs) from the blood of three of these donors, one of whom also yielded a cord-blood line established with his throat-wash EBV. Blood from a fourth donor did not yield an LCL, but his throat washing did have transforming activity when inoculated onto cord-blood leukocytes. We initially could establish spontaneous LCLs only from the recipient's blood. However, a throat-wash sample taken 11 weeks later did show transforming activity. The recipient was shown to have acquired the EBV infection from one of eight EBV-seropositive blood donors. Analysis of fragment length polymorphisms after polymerase chain reaction amplification of the EBV BamHI-K fragment was used to establish strain identity. Western blot analysis for existence of size polymorphisms in three classes of Epstein-Barr nuclear antigens (EBNA-1, EBNA-2, and EBNA-3) confirmed the DNA results. It is noteworthy that the blood donor responsible for transmitting his EBV strain to the recipient had experienced clinical infectious mononucleosis 15 months before donating blood. Our results may, thus, indicate a requirement for leukodepletion of blood destined for immunosuppressed EBV-negative patients. Finally, blood donors with a recent history of infectious mononucleosis should probably be identified so that their blood is not given to EBV-negative transplant patients.