Serum interleukin-6 (IL-6), IL-10, tumor necrosis factor (TNF) alpha, soluble type II TNF receptor, and transforming growth factor beta levels in human immunodeficiency virus type 1-infected individuals with Mycobacterium avium complex disease.

To characterize changes in serum cytokine levels in human immunodeficiency virus type 1 (HIV-1)-infected persons with Mycobacterium avium complex (MAC) bacteremia, the levels of IL-1alpha (interleukin-1alpha), IL-6, IL-10, tumor necrosis factor alpha (TNF-alpha), soluble type II TNF receptor (sTNF-RII), and transforming growth factor beta (TGF-beta) in serum were measured in two cohorts of HIV-1-infected persons with MAC bacteremia. The first cohort was part of a MAC prophylaxis study. Patients with bacteremia were matched with controls without bacteremia. Elevated IL-6, IL-10, TNF-alpha, sTNF-RII, and TGF-beta levels were noted at baseline for all subjects, a result consistent with advanced HIV-1 disease. IL-1alpha was not detected. No differences in cytokine levels in serum were noted at baseline and at the time of bacteremia between patients with MAC and controls. In the second cohort, subjects had serum samples collected at the time of MAC bacteremia and thereafter while on macrolide therapy. Serum samples at time of bacteremia were collected from HIV-1-infected persons at a time when neither highly active antiretroviral therapy (HAART) nor MAC prophylaxis was used routinely. MAC treatment resulted in decreased levels of IL-6 and TNF-alpha in serum, which were evident for IL-6 by 4 to 6 weeks and for TNF-alpha by 8 to 16 weeks. Thus, antibiotic treatment for MAC results in decreased levels of IL-6 and TNF-alpha in serum in HIV-1-infected persons who are not on HAART.

Effect of potent antiretroviral therapy on immune responses to Mycobacterium avium in human immunodeficiency virus-infected subjects.

To characterize the influence of highly active antiretroviral therapy (HAART) on cell-mediated immunity (CMI) to Mycobacterium avium complex (MAC), we measured immune responses to M. avium in human immunodeficiency virus (HIV)-infected individuals before and during HAART, in subjects with a history of disseminated MAC (DMAC), and in HIV-uninfected control subjects. Forty-seven percent of untreated HIV-infected patients and 78% of control subjects exhibited in vitro proliferative responses to M. avium (P=.03). Proliferative responses to M. avium increased after HAART for 3 months and were present in 77% of subjects after 6 months. Mean interferon-gamma production increased from 199 to 1156 pg/mL after HAART (P=.06). Proliferative responses to M. avium occurred in 76% of DMAC subjects receiving HAART. CD4 and CD8 but not gammadelta T cells expanded in response to M. avium. CMI to M. avium reconstitutes rapidly after HAART and appears sustained even with partial viral suppression.

CMV retinitis recurs after stopping treatment in virological and immunological failures of potent antiretroviral therapy.

OBJECTIVES: To determine predictors of clinical relapse of cytomegalovirus (CMV) end-organ disease in a cohort of 17 HIV-infected patients with healed and treated CMV retinitis (CMVR) who responded to HAART with an increase in CD4 cell counts to above 70 cells/mm3 and discontinued CMV maintenance therapy (MT). DESIGN: Seventeen patients were monitored for reactivation of retinitis. The CD4 cell counts, HIV RNA and peripheral blood mononuclear cell (PBMC) lymphoproliferative assays to CMV at 3 month intervals were compared between patients with and without reactivation of CMVR. Positive lymphoproliferative responses were defined as a stimulation index of 3 or greater. RESULTS: Five out of 17 (29%) patients experienced a recurrence of CMVR a mean of 14.5 months after stopping CMV MT and between 8 days and 10 months after CD4 cell counts fell below 50 cells/mm3. Median CD4 cell counts and plasma HIV RNA at reactivation were 37 cells/mm3 and 5.3 log10 copies/ml. Three patients recurred at a previously active site of the retina, one had contralateral CMVR, and one a recurrence of retinitis and pancreatitis simultaneously. Mean lymphoproliferative responses to CMV were 2.4 in patients with reactivation versus 21.0 stimulation index (SI) in patients without reactivation (P= 0.01). A model incorporating four variables (CD4 cell counts and HIV RNA at maintenance discontinuation, highest CD4 cell count, nadir HIV RNA and median lymphoproliferative responses) identified correctly 88% of patients with and without reactivation. CONCLUSION: CMV disease recurs after virological and immunological failure of HAART if CD4 cell counts drop below 50. In this situation, anti-CMV agents should be resumed before clinical reactivation ensues, because of the risk of contralateral retinal involvement and systemic disease.

Pathogenic and protective correlates of T cell proliferation in AIDS. HNRC Group. HIV Neurobehavioral Research Center.

To investigate the association of antigen specific CD4 T cell activation with HIV disease progression and AIDS-related central nervous system damage, T cell proliferation responses to HIV, CMV, and HSV were evaluated in infected individuals. CD4 T cell loss and neurocognitive impairment were assessed at 6-mo intervals. Individuals with known times of seroconversion who responded to more HIV peptides were at greater risk of progressing to < 200 CD4 T cells (P = 0.04) and dying (P = 0.03) than those with responses to fewer peptides. A positive correlation (0.52) was seen between the breadth of the HIV proliferation response and HIV plasma RNA levels. Higher proliferation responses to CMV and HSV were also associated with more rapid CD4 loss (P = 0.05). HLA phenotyped individuals (n = 150) with two HLA-DR alleles associated with response to more HIV peptides and CMV (DR-2,5,w6,10) were less likely to develop neurocognitive (P = 0.002) and neurologic impairment (P = 0.04), but were not protected from CD4 loss and death. Thus, the ability to generate a greater T cell proliferation response to HIV and opportunistic herpes viruses may lead to resistance to central nervous system damage, but also risk of more rapid HIV disease progression.

Immune predispositions for cytomegalovirus retinitis in AIDS. The HNRC Group.

CMV retinitis develops in approximately 28-35% of all AIDS patients at later stages of disease, often leading to blindness. To determine whether the subset of AIDS patients who developed CMV retinitis (CMV-R) were immunologically predisposed, T cell proliferation responses to CMV were examined prospectively in an HIV infected, HLA typed, longitudinal study population. Individuals who developed CMV-R had significantly lower T cell proliferation responses to CMV, both early and late in disease, compared to CD4 matched controls who have not developed CMV-R. Since HLA proteins influence T-cell recognition, phenotypes of 21 CMV-R patients were examined to determine whether certain HLA alleles were associated with low immune response and predisposed AIDS patients to CMV-R. HLA DR7 and B44 were at increased (nearly twice the expected) frequency in those with CMV-R. The combined association of either B44, 51 or DR7 with CMV-R was highly significant (P = .008, relative risk of CMV-R = 15) with correction for multiple comparisons. Low immune responses were twice as frequent in those with (61%) compared to those without (30%) predisposing alleles. Thus, AIDS patients with immunogenetically related hyporesponsiveness to CMV antigens may be at increased risk of retinitis.

CMV-specific immune responses and HLA phenotypes of AIDS patients who develop CMV retinitis. HNRC Group. HIV Neurobehavioral Research Center.

HLA phenotype and immune responses to CMV were studied to determine whether the subset of AIDS patients who developed CMV retinitis were immunogenetically or immunologically predisposed. CMV retinitis develops in approximately 28-35% of AIDS patients and CMV encephalitis develops in 40% of those with retinitis, often leading to death. T-cell proliferation responses to CMV and HIV were assayed prospectively in individuals enrolled in a longitudinal study at the HIV Neurobehavioral Research Center (HNRC) in San Diego. Seventy-three participants, at various stages of disease, have been HLA typed and followed, clinically and immunologically, for up to 5 years. Six HIV infected individuals who eventually developed CMV retinitis, and were assayed prospectively, had a history of low T-cell proliferation to CMV antigens before they were profoundly immunosuppressed. All 10 individuals with CMV retinitis had at least one of three HLA alleles (or combinations): A2B44 (p = 0.02), B51(p = 0.02), or DR7 (p = 0.01) (collective p value = 0.007). Three of the 10 had two or more of these alleles. Of AIDS patients with CD4 counts below 100 and actively at risk for retinitis, 7/15 with A2B44,51, or DR7 have developed retinitis compared to 0/13 without these HLA alleles (relative risk = 23.8). All 4 patients with these alleles who have died, had retinitis. These results suggest that HIV infected individuals with HLA phenotypes A2B44, B51, and DR7 have low T-cell immune responses to CMV and are predisposed to CMV retinitis and encephalitis as immunodeficiency progresses.

Mechanisms of immune activation of human immunodeficiency virus in monocytes/macrophages.

Monocytes/macrophages (M/M) are the major host of human immunodeficiency virus (HIV) in solid tissues. However, blood monocytes are nonpermissive for HIV infection, indicating that M/M activation or differentiation is necessary for HIV replication. Since M/M are activated during immune responses, we investigated the effect of T-cell activation on HIV expression in M/M derived from peripheral blood of HIV-infected individuals. Previously, we reported that coculture of monocytes from HIV-infected donors with T cells and mitogens resulted in M/M differentiation and HIV expression. Production of HIV by M/M from infected donors required direct contact between monocytes and T cells (for the first 24 h), and the response to alloantigens, but not mitogens, was restricted to HLA-DR. In this study, we found that HIV was more readily recovered from M/M of asymptomatic HIV seropositive donors (69%) than from M/M of symptomatic donors (57%). Viral antigens (e.g., inactivated herpes simplex virus) could initiate the immune response and HIV expression. The ability of noninfected T cells to activate HIV expression in M/M and observations that treatments of M/M with antibodies to deplete T cells did not reduce HIV expression suggested that the monocytes were endogenously infected. To define the aspects of immune activation specifically involved in initiating HIV expression in M/M, interactions of M/M and T cells and participation of cytokines were investigated. The T cell which activated M/M was CD4+ CD8-. Fixed allogeneic cells are known to induce T-cell activation but were not able to serve as antigen for M/M differentiation, suggesting that M/M may need to function as antigen-presenting cells to receive the signal to differentiate and express HIV. Blocking of M/M-T-cell interaction with antibodies directed against LFA-1 or interleukin-1 prevented HIV expression. However, inhibition of later stages of T-cell activation, such as blocking of interleukin-2 receptors, did not diminish HIV expression in M/M. Consistent with the requirement for cell-cell contact between M/M and T cells, a variety of cytokines were unable to initiate HIV replication in M/M. The ability of T cells to induce cellular differentiation and HIV replication in M/M in vitro suggests that initiation of an immune response to an antigen, such as an opportunistic pathogen, could be a mechanism by which HIV disseminates to tissues in vivo.

Relationship of cerebrospinal fluid immune activation associated factors to HIV encephalitis.

OBJECTIVES AND DESIGN: Because macrophages are the predominant immune cell and the predominant infected cell in the brains of patients with HIV encephalitis, we studied macrophage and immune activation-associated factors in the cerebrospinal fluid (CSF) from 39 autopsied AIDS cases for whom complete neuropathologic evaluation of the brain was available. RESULTS: CSF HIV p24 antigen was present in less than one-third of cases (11 out of 39). Less than half of the autopsies with moderate to severe parenchymal infection by HIV had high levels of CSF p24, although all autopsies with elevated levels of HIV p24 had moderate to severe HIV encephalitis. Elevated levels of cytokines, beta 2-microglobulin, neopterin, and quinolinic acid were observed. CONCLUSIONS: Although many of the CSF findings showed a strong correlation with each other, none showed a strong correlation with the severity of HIV infection of the brain itself. The absence of a close association between CSF abnormalities and HIV encephalitis could reflect the abundance of complicating opportunistic infections in these terminally ill patients or the inadequacy of CSF as a marker of basal ganglia involvement in HIV encephalitis. These findings complicate interpretation of clinical studies of CSF in patients with AIDS where neuropathologic evaluation is unavailable.

Immunopathogenesis of HIV encephalitis.

HIV infection leads to severe immunosuppression and in a sub-population of patients, encephalitis. Whether systemic immunosuppression is required for CNS infection is still unclear. However, latent infection of monocytes/macrophages is an important mechanism by which HIV escapes immune surveillance and enters the CNS. Unlike other viral encephalitides, HIV predominantly infects macrophages/microglia and not neurons and glia. These cells produce retroviral proteins and cytokines which may be neurotoxic. Despite significant MHC expression within the CNS, there is a limited infiltration of immune cells, possibly due to a defect in systemic immunity. Anti-retroviral therapy by decreasing viral replication and reversing immunosuppression, may arrest nervous system damage.

Pathogenesis of HIV encephalitis.

A wide spectrum of infectious agents attack the central nervous system (CNS) of acquired immunodeficiency syndrome (AIDS) patients. Human immunodeficiency virus (HIV) itself, infects the CNS of a subgroup of these patients. The mechanism behind why HIV enters the CNS is unclear. We have observed an interesting association between HIV and opportunistic viral infections that may explain why HIV enters the brain. Infection of the CNS by opportunistic agents results in recruitment of latently HIV-infected monocytes. Upon differentiation into macrophages these cells produce abundant HIV. Latent HIV-infection of monocytes/macrophages provides a unique opportunity for cooperativity between opportunistic infections and HIV in mediating CNS damage.

T-cell-induced expression of human immunodeficiency virus in macrophages.

Macrophages are major reservoirs of human immunodeficiency virus (HIV) in the tissues of infected humans. As monocytes in the peripheral blood do not show high levels of infection, we have investigated the expression of HIV in T-cell-activated, differentiated macrophages. Peripheral blood mononuclear cells were isolated from HIV-seropositive individuals and stimulated with antigens or mitogens, and the nonadherent fraction was removed. Macrophages were cultured alone for 2 weeks, and HIV expression was assessed. Results from p24 antigen capture assays demonstrated that the presence of autologous T cells and concanavalin A or autologous T cells and allogeneic cells for the initial 24 h of culture induced HIV expression in 35 of 47 (74%) HIV-seropositive patients tested. The macrophage monolayers could be immunostained with anti-HIV antibodies to reveal discrete infectious centers, indicating that complete virus replication was occurring in the macrophages and that infection of adjacent cells was mediated by cell-cell contact. Time course studies of the interval of coculture of the adherent and nonadherent cells indicated that 24 h (but not 2 h) was sufficient for induction of HIV in the macrophages. Direct contact between the adherent cells and activated T cells was required as well. Since the presence of autologous T cells also appeared to be necessary, induction of HIV expression in macrophages may be genetically restricted. HIV-seronegative nonadherent cells were able to induce HIV expression in macrophages from HIV-seropositive donors, demonstrating that the virus originated in the monocytes and was reactivated in the context of a classic T-cell-mediated immune reaction. The high percentage of monocytes from HIV-seropositive donors which can be induced to replicate HIV by activated T cells suggests that infection of monocytes may be critical to the pathogenesis of this lentivirus infection.

T cell recognition of HIV synthetic peptides in a natural infection.

Because T cell responses are critical for defense against viral infections, a series of synthetic peptides derived from the predicted sequence for HIV-1 proteins gp41, pg120, gag, and viral polymerase were used to test the T cell proliferative response of HIV-1 seropositive individuals. Of HIV-1-infected donors from various clinical categories 90% (27/30) had sensitized cells that proliferated in response to at least one of 21 HIV peptides tested. Cells from HIV seronegative controls did not proliferate (0/9) in response to these HIV peptides. Individuals with fewer clinical manifestations of HIV-1 disease responded to a greater number of peptides (average for asymptomatic seropositives = 8.1 peptides; AIDS patients averaged 2.0). The number of peptides recognized also correlated with absolute number of CD4+ cells, but not with delayed cutaneous hypersensitivity to a (non-HIV) battery of Ag. However, clinical stage at no time correlated with the response to any particular peptide. Response patterns differed considerably among individuals, and some peptides stimulated proliferation in many (48%) HIV-infected donors (peptides gp41-2 and pol-3), whereas another peptide elicited no T cell response in any donor tested (peptide gp120-8). We have also begun to investigate the basis for individual heterogeneity of T lymphocyte proliferative responses of HIV-infected donors to the 21 HIV synthetic peptides. Peptide structure and HLA class II determinants both influenced patterns of lymphocyte responses. Reactivity correlated with peptide size, the presence of alpha and beta secondary structure and lack of reverse turn potential. Hydropathy and charge had no predictive value. Peptides derived from HIV sequences that vary highly among strains tended to be recognized less frequently. HIV-infected lymphocyte donors were HLA typed to examine the influence of the MHC on T lymphocyte proliferation. Analysis of the frequencies of individuals reacting to specific peptides, when compared to the allele frequencies in the population at large, indicated association of some responses to DR alleles. More DR association was observed with peptides that showed "moderate" reactivity than with those that were "highly" reactive. We suggest that highly reactive peptides are capable of forming a structure closer to an "ideal" T cell epitope that can associate with many DR alleles. In contrast, "moderately" reactive determinants have less favorable structures for interaction, are more limited in their ability to interact and therefore show more restriction to specific class II alleles.

B- and T-lymphocyte responses to an immunodominant epitope of human immunodeficiency virus.

Using synthetic peptides, we characterized the B-lymphocyte (antibody) and T-lymphocyte (proliferation) responses to an immunodominant epitope of human immunodeficiency virus type 1 (HIV-1) located near the amino-terminal end of the transmembrane glycoprotein (env amino acids 598 to 609). Both immunoglobulin M (IgM) and IgG antibodies against this epitope appeared early after primary infection with HIV-1. In an animal model, the IgG response to a synthetic peptide derived from this sequence was T-helper-cell dependent, whereas the IgM response was T-cell independent. In addition, antibody generated by immunization with this peptide had HIV-1-neutralizing activity. Greater than 99% (201 of 203) of patients infected with HIV-1 generated antibody to this peptide in vivo; however, only 24% (7 of 29) had T cells that proliferated in response to this peptide in vitro. These observations suggest that different HIV-1 gp41 epitopes elicit B-cell and T-cell immune responses.

Cellular localization of human immunodeficiency virus infection within the brains of acquired immune deficiency syndrome patients.

Dysfunction of the central nervous system (CNS) is a prominent feature of the acquired immune deficiency syndrome (AIDS). Many of these patients have a subacute encephalitis consistent with a viral infection of the CNS. We studied the brains of 12 AIDS patients using in situ hybridization to identify human immunodeficiency virus [HIV, referred to by others as human T-cell lymphotropic virus type III (HTLV-III), lymphadenopathy-associated virus (LAV), AIDS-associated retrovirus (ARV)] nucleic acid sequences and immunocytochemistry to identify viral and cellular proteins. Nine patients had significant HIV infection in the CNS. In all examined brains, the white matter was more severely involved than the grey matter. In most cases the infection was restricted to capillary endothelial cells, mononuclear inflammatory cells, and giant cells. In a single case with severe CNS involvement, a low-level infection was seen in some astrocytes and neurons. These results suggest that CNS dysfunction is due to indirect effects rather than neuronal or glial infection.

Recent clinical isolates of cytomegalovirus suppress human cytomegalovirus-specific human leukocyte antigen-restricted cytotoxic T-lymphocyte activity.

Peripheral blood mononuclear cells harvested from healthy adults seropositive for human cytomegalovirus (HCMV) and cultured with laboratory strain AD-169 demonstrated human leukocyte antigen-restricted and HCMV-specific killing on target cells infected with either HCMV laboratory strain AD-169 or recent low-passage HCMV isolates. These results indicated that the determinants recognized by cytotoxic T lymphocytes (CTLs) are shared among different strains of HCMV. However, when low-passage isolates, rather than high-passage AD-169 virions, were used to stimulate CTL activity, the lytic response was significantly lower against all targets. Mixing of AD-169 and low-passage HCMV isolates induced low CTL activity. Collectively, the findings suggest that low-passage HCMV isolates have dual effects--antigenic stimulation and immunosuppression--whereas laboratory strain AD-169 is primarily immunogenic. The study of several recent isolates indicated that they varied in their ratio of immunostimulation to suppression, that infectious virus was necessary to produce suppression, and that suppressive isolates did not have to be present at the initiation of culture to exert their suppressive effects.

Suppression of natural killer cell activity and T cell proliferation by fresh isolates of human cytomegalovirus.

Human cytomegalovirus (HCMV) infections are commonly associated with immunosuppression. A direct effect of this virus on lymphocyte functions in vitro, however, has not been shown. We have been investigating the effects of low-passage, fresh isolates of HCMV (cell-free and cell-associated) on natural killer cell (NK) activity and T cell proliferation. Cell-associated, low-passage isolates of HCMV markedly depressed NK activity. Suppression of NK activity was clearly manifested only after seven days of culture and could not be correlated with titer of virus or cell viability. Addition of interferon-alpha (IFN-alpha) but not interleukin-2 (IL-2) partially reconstituted the response, whereas depletion of infected monocytes prevented inhibition of NK-mediated lysis. The effects of cell-free and cell-associated isolates of HCMV on T cell proliferation differed in several respects from suppression of NK activity. Both cell-associated and cell-free isolates of HCMV completely abrogated antigen-specific and mitogen responses. This effect was apparent after only three days of culture with virus and was not reversed by either IFN or IL-2. Cell-associated strain AD169 also induced suppression but to a lesser extent. From observations reported here and other data, we suggest that HCMV can cause direct suppression of lymphocyte functions.

Localization of cytomegalovirus proteins and genome during fulminant central nervous system infection in an AIDS patient.

Approximately one-half of autopsied acquired immune deficiency syndrome (AIDS) patients demonstrate probable human cytomegalovirus (CMV) infection of the central nervous system (CNS). Because CMV in brain tissue or cerebrospinal fluid is difficult to culture, we used antisera, and radioactive probes to diagnose CMV infection in the brain of an autopsied AIDS patient, who died of a fulminant CNS and systemic infection with CMV, suggesting a complete seeding of the ependymal regions possibly followed by a uniform ventriculofugal spread of the virus deep into the parenchyma. Cytomegalic cells were observed in optic nerve, retina, ependymal and subependymal regions of the brain and in the motor (but not sensory) root-CNS junctions. Immunocytochemistry demonstrated viral antigen predominantly in cytomegalic cells, which also stained positively for glial fibrillary acidic protein, S-100, or neuron-specific enolase, but not a common leukocyte antigen. Virions were visible in these cells examined by electron microscopy. No viral replication was observed in pineocytes, pituicytes or the choroid plexus. Morphologically normal cells that were CMV antigen-negative proved to be infected after in situ hybridization with well-defined human CMV DNA fragments. Hence, morphologically normal glia and neurons show restricted replication of CMV, indicating that such cells may be latently infected.

Detection of human cytomegalovirus in peripheral blood lymphocytes in a natural infection.

In situ hybridization was used to detect human cytomegalovirus (HCMV) in the peripheral blood mononuclear cells of some naturally infected (seropositive) individuals. A subpopulation of cells hybridized specifically to a portion of the HCMV genome that is heavily transcribed during the immediate-early period of infection. The hybridization signal was markedly reduced by base hydrolysis and ribonuclease, and therefore the probe appears to be detecting viral RNA. A fluorescence-activated cell sorter was used to select lymphocytes bearing the OKT4 and OKT8 markers. Hybridization with the HCMV probe revealed a higher proportion of positive cells in the OKT4 than in the OKT8 subset. This observation specifically identifies lymphocytes as a cell population involved in natural HCMV infection and suggests that lymphocytes may be a reservoir for maintaining infection and may also serve as a vehicle for its spread by blood transfusion.

Delayed hypersensitivity and immune protection against herpes simplex virus: suppressor T cells that regulate the induction of delayed hypersensitivity effector T cells also regulate the induction of protective T cells.

We have been studying delayed hypersensitivity (DH) to herpes simplex virus (HSV) in order to examine the role of this response in host defense against acute and recurrent HSV infections. In previous reports the basic parameters of DH to HSV have been characterized by using a murine ear swelling model, and also the regulation of DH to HSV induced by i.v. injection of the virus. In this paper, we describe a murine protection system and our use of the ability to specifically regulate DH to HSV to examine the correlation between T cells that transfer DH (TDH) and cells that transfer protection from acute HSV infection. Both DH and protection can be transferred with lymph node cells from mice immunized subcutaneously 4 days previously. The effector cell appears to be a T cell, because serum from these donors confers no protection and treatment of immune cells with anti-Thy-1.2 plus complement reduced their ability to protect. Tolerance of DH to HSV was induced by i.v. injection 7 days before subcutaneous immunization. Tolerized mice were unable to generate protective cells. Furthermore, tolerized mice contained suppressor T cells that suppressed not only DH but also the development of protective cells. Regulation of protective cells was shown to be virus specific, because mice tolerized with vesicular stomatitis virus (VSV) were not impaired in their ability to generate T cells that protected from HSV infection. The correlation between the TDH cell and cells that transfer protection from acute HSV infection is discussed.

Cytomegalovirus infects human lymphocytes and monocytes: virus expression is restricted to immediate-early gene products.

In this investigation, we studied the ability of human cytomegalovirus to infect peripheral blood mononuclear cells. With monoclonal antibody technology, we demonstrated that cytomegalovirus could infect human lymphocytes of T- and B-cell lineage, natural killer cells, and monocytes. Furthermore, virus expression was limited to the synthesis of immediate-early cytomegalovirus polypeptides. These peripheral blood mononuclear cells did not produce infectious virus, nor were mature virions visualized by electron microscopy. This abortive infection of mononuclear cells was most convincingly shown with stocks of cytomegalovirus that had been recently isolated from infected patients and passaged minimally in fibroblasts. This argues for an increased lymphotropic effect of some isolates of cytomegalovirus, compared to strains of virus that are extensively adapted to growth in fibroblasts. Furthermore, immunocompetent cells that were shown to be abortively infected with cytomegalovirus lost selected differentiated functions.