Cytomegalovirus cell tropism.

The human cytomegalovirus (HCMV) can infect a remarkably broad cell range within its host, including parenchymal cells and connective tissue cells of virtually any organ and various hematopoietic cell types. Epithelial cells, endothelial cells, fibroblasts and smooth muscle cells are the predominant targets for virus replication. The pathogenesis of acute HCMV infections is greatly influenced by this broad target cell range. Infection of epithelial cells presumably contributes to inter-host transmission. Infection of endothelial cells and hematopoietic cells facilitates systemic spread within the host. Infection of ubiquitous cell types such as fibroblasts and smooth muscle cells provides the platform for efficient proliferation of the virus. The tropism for endothelial cells, macrophages and dendritic cells varies greatly among different HCMV strains, mostly dependent on alterations within the UL128-131 gene locus. In line with the classification of the respective proteins as structural components of the viral envelope, interstrain differences concerning the infectivity in endothelial cells and macrophages are regulated on the level of viral entry.

Evaluation of the COBAS Amplicor HCMV Monitor for early detection and monitoring of human cytomegalovirus infection after allogeneic stem cell transplantation.

Early diagnosis of human cytomegalovirus (HCMV) infection and the introduction of preemptive antiviral therapy have reduced HCMV-related mortality after allogeneic stem cell transplantation. A critical goal remains stratifying risk profiles and minimizing potential harm owing to antiviral overtreatment. We compared the commercially available standardized COBAS Amplicor CMV Monitor (CACM) to an in-house PCR assay, for the monitoring of HCMV infection. Seventy-two patients were surveyed by an in-house PCR of whole blood, quantitative viral load assessment by CACM and virus culture assays in a prospective and a retrospective study. A high concordance between CACM and PCR was documented. The viral load at onset correlated with the peak viral load (Spearman rank correlation R=0.634, P=0.0004). In patients developing HCMV disease, both viral loads were in trend higher (P=0.823, respectively P=0.053), and the viremic episodes longer (P=0.015), as compared to asymptomatically HCMV-infected patients. The serological pre-transplant status was the major risk factor for the development of HCMV disease, showing highest risk for seropositive patients receiving a seronegative graft, whereas donor type (related or unrelated) and graft type (bone marrow or peripheral blood mobilized stem cells) did not have an influence. HCMV infection proved to be a risk factor for the development of non-viral opportunistic infections (P=0.002).

Cytomegalovirus infection after orthotopic liver transplantation is restricted by a pre-existing antiviral immune response of the recipient.

Infection of the liver by the human cytomegalovirus (HCMV) frequently occurs after orthotopic liver transplantation (OLT). However, the role of viral replication and the inflammatory reaction in the development of HCMV-associated liver dysfunction is unclear. To address this question in vivo, 84 liver biopsy specimens from 74 patients who received an orthotopic liver transplant were investigated by immunohistochemical detection of viral antigens and cell type specific marker proteins. The extent of viral replication was correlated with the HCMV antibody status of donor and recipient. HCMV immediate early antigens were found in 25 of 84 liver tissue sections investigated, hepatocytes being the predominant target cells. Bile duct epithelial cells, endothelial cells, mesenchymal cells and sinusoidal lining cells were also found susceptible to HCMV infection. The detection of viral capsid antigens, nuclear inclusions in infected cells and foci of infected cells were suggestive of permissive infection in these cells. In 25 HCMV-positive liver biopsy specimens, the median extent of HCMV infection was 0.33 (0.02-5.67) infected cells/mm(2) liver tissue. Primary infection of liver transplant recipients (D+/R-) was associated with a significantly higher extent of organ involvement as compared to reinfection or reactivation (D+/R+). In contrast, the extent of inflammatory infiltrates in areas of infected liver cells was higher in tissues of patients with pre-existing immunoreactivity (R+) compared to patients without pre-existing immunoreactivity (R-). In conclusion, these results favour the assumption that the immune response to HCMV is effective in restricting viral spread in the liver.

Induction of CMV-specific T-cell lines using Ag-presenting cells pulsed with CMV protein or peptide.

BACKGROUND: CMV disease is still associated with a high morbidity and mortality in recipients of a solid organ or stem cell graft, especially in patients undergoing allogenic stem cell transplantation. Reconstitution of CMV-specific CD4(+) and CD8(+) cytotoxic T cell responses are essential to control CMV infection following allogenic stem cell transplantation. The transfer of unselected populations of lymphocytes from the peripheral blood of a CMV-scropositive donor to a transplant recipient can be used to control CMV infection. However, such transfer of unselected donor lymphocytes is limited by potentially fatal complications that arise from alloreactive T cells, also present in the unselected donor lymphocytes. Thus to make infusion of donor T cells safe and also more effective in controlling CMV infection in the recipient of the T cell infusion, T cells are manipulated in vitro to deplete alloreactive T cells and to enrich for CMV-specific T cells. METHODS: Using various antigen-presenting cells (monocytes/PBMNCs/dendritic cells) and different modes of antigen presentation (infected APCs, pulsing of protein or peptide antigen) different CMV-specific T cell populations can be generated and expanded. RESULTS: Using protein-/or peptide-pulsed DCs CMV-specific CD8(+) cytoxic T cell lines (can be generated and expanded) in addition CMV-specific CD4(+) T cell lines can be generated when CMV-protein-pulsed DCs are used as antigen-presenting cells. When peripheral blood mononuclear cells were stimulated with CMV lysates predominantly CMV-specific CD4(+) T cells are generated and expanded ex vivo. DISCUSSION: Depending on the APC used (monocytes versus DC) and the mode of antigen presentation (protein versus peptide pulsing) different CMV-specific T cell populations of varying purity can be generated which show preserved function when tested for specific proliferation, cytokine production and cytotoxicity.

Evaluation of the Murex CMV DNA Hybrid Capture assay (version 2.0) for early diagnosis of cytomegalovirus infection in recipients of an allogeneic stem cell transplant.

Early diagnosis of CMV infection based on sensitive diagnostic assays has helped to reduce CMV-related mortality after allogeneic stem cell transplantation (SCT). In this study, the commercialized Murex CMV DNA Hybrid Capture assay (version 2.0) (HCS) was prospectively compared to an in-house CMV-DNA PCR assay from whole blood in patients after allogeneic stem cell transplantation. Overall, a high concordance between HCS and PCR was documented (kappa = 0.686; n = 385). The HCS assay was found to be as sensitive as the PCR indicating active CMV infection at a median of 35 and 34 days after transplantation, respectively. None of the HCS-negative patients developed CMV-related symptoms (negative predictive value 100%). Declining CMV DNA load in the blood was found to be an indicator for effective antiviral therapy, whereas persistence of a high viral load was associated with fatal CMV disease. In conclusion, the Hybrid Capture CMV DNA assay (v 2.0) allows early diagnosis of CMV infection after allogeneic SCT and assessment of the efficacy of antiviral therapy.

Ex vivo generation of human cytomegalovirus-specific cytotoxic T cells by peptide-pulsed dendritic cells.

Adoptive transfer of donor-derived human cytomegalovirus (HCMV)-specific T-cell clones can restore protective immunity after stem cell transplantation. Ex vivo induction of HCMV-specific T cells using HCMV-infected fibroblasts as stimulator cells confines this approach to HCMV-seropositive donors and requires the presence of infectious virus during the stimulation procedure. In this study, we describe a potential alternative strategy to generate HCMV-specific T cells ex vivo for adoptive immunotherapy. Generation of HCMV-specific cytotoxic T lymphocytes (CTLs) ex vivo was investigated using peptide-pulsed dendritic cells as antigen-presenting cells. HCMV-specific T cells were generated and sufficiently expanded for adoptive immunotherapy in 6 out of 14 HCMV-seropositive and 2 out of 11 HCMV-seronegative donors. The CTLs recognized HCMV-infected autologous fibroblasts. No lysis was observed with either non-infected autologous or HLA-mismatched infected fibroblasts. Staining with tetrameric HLA/peptide complexes revealed significant enrichment for peptide-specific T cells of up to 28% and > 90% of CD8(+) T cells after three and five specific stimulations respectively. In addition, the expansion rates indicated that ex vivo generation of > 1 x 10(9) HCMV-specific T cells was possible after 6--7 weeks when cultures were initiated with 1--5 x 10(6) responder cells. Thus, the approach with peptide-pulsed DCs to generate HCMV-specific CTLs is feasible for clinical application after allogeneic stem cell transplantation.

Tropism of human cytomegalovirus for endothelial cells is determined by a post-entry step dependent on efficient translocation to the nucleus.

Marked interstrain differences in the endothelial cell (EC) tropism of human cytomegalovirus (HCMV) isolates have been described. This study aimed to define the step during the replicative cycle of HCMV that determines this phenotype. The infection efficiency of various HCMV strains in EC versus fibroblasts was quantified by immunodetection of immediate early (IE), early and late viral antigens. Adsorption and penetration were analysed by radiolabelled virus binding assays and competitive HCMV-DNA-PCR. The translocation of penetrated viral DNA to the nucleus of infected cells was quantified by competitive HCMV-DNA-PCR in pure nuclear fractions. The intracytoplasmic translocation of capsids that had penetrated was followed by immunostaining of virus particles on a single particle level; this was correlated with the initiation of viral gene expression by simultaneous immunostaining of viral IE antigens. The infectivity of nonendotheliotropic HCMV strains in EC was found to be 100-1000-fold lower when compared to endotheliotropic strains. The manifestation of this phenotype at the level of IE gene expression indicated the importance of initial replication events. Surprisingly, no interstrain differences were detected during virus entry. However, dramatic interstrain differences were found regarding the nuclear translocation of penetrated viral DNA. With nonendotheliotropic strains, the content of viral DNA in the cell nucleus was 100-1000-fold lower in EC when compared to endotheliotropic strains, thereby reflecting the strain differences in IE gene expression. Simultaneous staining of viral particles and viral IE antigen revealed that interstrain differences in the transport of penetrated capsids towards the nucleus of endothelial cells determine the EC tropism of HCMV.

Risk factors for treatment failures in patients receiving PCR-based preemptive therapy for CMV infection.

PCR-based preemptive therapy with ganciclovir has been shown to reduce the incidence of CMV disease after BMT. Failures of this treatment strategy are CMV disease and secondary non-viral infections. Eighty-six consecutive patients at high risk for CMV disease who received PCR-based preemptive therapy with ganciclovir were assessed for treatment failures and possible risk factors. Ganciclovir was initiated in 57 of 86 patients (66%). Only 28 of 86 (32%) patients received 4 or more weeks of ganciclovir. Recurrence of CMV infection after successful treatment was more frequent among recipients of a BMT from an unrelated compared to a sibling donor (P = 0.004). Three (3.5%) patients developed non-fatal early onset CMV disease and seven of 68 (10.3 %) late onset CMV disease (>100 days post transplant). Risk factors for late onset CMV disease were cGVHD (P = 0.0017) and duration of prior antiviral therapy >4 weeks (P = 0. 0073). The incidence of secondary non-viral infections was 28% with the duration of antiviral treatment being a significant risk factor for secondary bacterial (P = 0.0045) and invasive fungal infections (P = 0.006). Thus, PCR-based preemptive treatment with ganciclovir reduces early onset CMV disease, but the duration of antiviral therapy prior to day +100 is a significant risk factor for late onset CMV disease as well as secondary non-viral infections.

Hepatocytes are permissive for human cytomegalovirus infection in human liver cell culture and In vivo.

The cytopathic potential of human cytomegalovirus (HCMV) in human liver cells was analyzed in cell culture and in tissue sections from patients with HCMV hepatitis. Liver cell cultures, consisting of hepatocytes, bile duct epithelial cells, and stromal cells were infected by various HCMV strains. Cytopathic effects, viral gene expression, and virus production were detected. Infected cell types were identified by immunocytochemical double labeling. Hepatocytes were the predominant target cells of HCMV infection in liver tissues and in cell culture. Late-stage infected cultured hepatocytes produced infectious progeny virus, and infectious virus was propagated from liver tissue specimens. HCMV infection in cultured liver cells closely resembled in vivo infection of the liver with regard to the target cell spectrum and the permissive course of infection. It is concluded that HCMV can cause direct liver parenchyma damage by efficient cytolytic infection of hepatocytes.

Human cytomegalovirus infection of immature dendritic cells and macrophages.

A central aspect of human cytomegalovirus (HCMV) pathogenesis is the interaction of the virus with different antigen-presenting cell (APC) types of the host. In principle, a number of various cell types have the potential of antigen presentation when MHC II expression is induced by appropriate stimuli. The most potent antigen presenters are monocytes/macrophages and dendritic cells (DCs), therefore called professional APCs. Interestingly, these cells seem to be targets of productive HCMV infection. The susceptibility of the monocyte/macrophage system has been analyzed intensively during the past decade. Investigation of the role of DCs during HCMV infection, however, has begun only recently.

Evaluation of Murex CMV DNA hybrid capture assay for detection and quantitation of cytomegalovirus infection in patients following allogeneic stem cell transplantation.

Murex hybrid capture DNA assay (HCS) is a solution hybridization antibody capture assay for detection and quantitation of cytomegalovirus (CMV) DNA in leukocytes. To determine whether CMV HCS is sensitive enough to initiate and monitor antiviral therapy after allogeneic stem cell transplantation (SCT), 51 consecutive SCT recipients were prospectively screened for the appearance of CMV infection by HCS, PCR, and culture assays from blood samples. Preemptive antiviral therapy was initiated after the second positive PCR result in all patients, as previously reported, and HCS was not considered for clinical decision making. A total of 417 samples were analyzed. Of these, 21 samples were found to be positive by PCR and HCS, 88 samples were PCR positive but HCS negative, and 308 were negative by both assays. Concordance of results between PCR and HCS and between HCS and blood culture was observed in 78.9 and 95.9% of the samples assayed, respectively. PCR was found to be more sensitive than HCS, and HCS was more sensitive than the blood culture assay (P < 0.0001). Four patients with symptomatic CMV infection were PCR positive prior to the onset of CMV-related symptoms, whereas HCS detected CMV DNA in three patients prior to and one at onset of CMV disease. The numbers of genomes per milliliter of blood were higher in patients with symptomatic CMV infection than in those with asymptomatic CMV infection (P = 0.06). None of the HCS-negative patients developed CMV disease. Thus, all patients with CMV disease were correctly identified by HCS; however, the lower sensitivity limit of the HCS assay may still be insufficient to allow diagnosis of CMV infection early enough to prevent CMV disease in patients following allogeneic SCT.

Quantification of replication of clinical cytomegalovirus isolates in cultured endothelial cells and fibroblasts by a focus expansion assay.

A method for quantitative analysis of the growth properties of human cytomegalovirus (HCMV) in various cell culture systems was developed. Recent HCMV isolates are, in most cases cell associated, causing only limited cytopathic effect. This renders comparative analysis of the biological properties of such isolates difficult. The focus expansion assay described in this study is based on cocultivation of infected fibroblasts with a cell type of choice, relying on cell mediated infectivity. The extent of replication of a given isolate in cell culture is quantified by determining the size of resulting infectious foci. Analysis of various clinical isolates and laboratory strains indicated that this assay is a reliable and valid method to define growth properties of HCMV in cell culture. Remarkable differences in the cytopathogenicity of these isolates in fibroblasts as well as in endothelial cells were found. The assay will be useful in studies regarding cell tropism and virulence of recent HCMV isolates and for the quick and easy phenotypic characterization of HCMV deletion mutants.

Tissue macrophages are infected by human cytomegalovirus in vivo.

On the basis of in vitro experiments, it has been suggested that cells of hematopoietic origin play a major role in the pathogenesis and latency of human cytomegalovirus (HCMV). To elucidate the in vivo importance of hematopoietic cells in acute HCMV infection, tissue sections from various infected organs were investigated by immunohistochemical double-labeling analyses. Monoclonal antibodies directed against distinct viral and cellular antigens were used to identify infected macrophages, polymorphonuclear cells, and lymphocytes. Macrophages and polymorphonuclear cells were targets for HCMV infection in different tissues. Viral proteins representing all stages of permissive HCMV infection were detected in macrophages, suggesting that these cells support the complete viral replication cycle. In polymorphonuclear cells, viral gene expression was restricted to the immediate early phase, indicating that these cells are abortively infected. These findings suggest that macrophages play an important role in the hematogenous spread of HCMV into solid organs.

Fibroblasts, epithelial cells, endothelial cells and smooth muscle cells are major targets of human cytomegalovirus infection in lung and gastrointestinal tissues.

High titre replication of human cytomegalovirus (HCMV) in cell culture is restricted to primary human fibroblasts. During acute infection in vivo, HCMV nucleic acids and antigens have been found in various organs. Using only morphological criteria, inconsistent data have been reported about the cell types that can be infected by HCMV. In particular, the role of fibroblasts in organ infections has remained unclear. To define accurately the target cells of HCMV in vivo, tissue sections from lung and gastrointestinal tract of patients suffering from acute HCMV infection were investigated using immunohistochemical double-labelling analyses. Monoclonal antibodies with defined specificity against immediate early (IE), early (E) and late (L) viral antigens and antibodies directed against cell marker proteins were employed to identify infected cells. The results demonstrated that a broad spectrum of cells was infected by HCMV in vivo. Consistent with their susceptibility in culture, fibroblasts formed a major population of HCMV-infected cells. In contrast, haemopoietic cells were only infrequently stained with virus-specific antibodies. Fibroblasts, epithelial cells, endothelial cells, smooth muscle cells and macrophages appeared to be permissive for HCMV replication. Contrary to this, polymorphonuclear cells showed only IE gene expression, indicating that these cells were abortively infected. The analysis of the distribution of infected cells in tissue supported the hypothesis that endothelial cells and monocytes/macrophages may play a crucial role in the haematogenous spread of HCMV; in contrast, fibroblasts, smooth muscle cells and epithelial cells may form the cell populations important for the multiplication and spread of the virus in infected tissues.

Reduced levels of IE2 gene expression and shutdown of early and late viral genes during latent infection of the glioblastoma cell line U138-MG with selectable recombinants of human cytomegalovirus.

To establish stable culture conditions which support persistence of the human cytomegalovirus (HCMV) genome in a latent state, the expression of the bacterial neomycin phosphotransferase (neo) from HCMV recombinants was used for selection. Different cell lines were infected with HCMV recombinants. The human glioblastoma line U138-MG was rendered resistant to G418 and retained the viral genome. More than 90% of the cells expressed the viral IE1 protein of 72 kDa for a culture period of 18 months. Many fewer cells expressed IE2-encoded proteins. No late gene expression or infectious virus was detectable. IE2 gene expression in latently infected cells appeared to be restricted at the level of RNA accumulation. Treatment with TPA or retinoic acid led to enhanced expression of the IE2 gene and the early genes encoding pp65 (UL83) and p52 (UL44). Superinfection with wild-type HCMV led to replication of neo-recombinant virus, indicating that replication-competent virus had been retained in latently infected U138-MG and that the cells had kept their permissive phenotype. Latent HCMV infection in U138-MG cells provides a useful model system for studying the role of particular viral and cellular genes in latent and permissive infections.

Immunohistochemical detection of viral antigens in smooth muscle, stromal, and epithelial cells from acute human cytomegalovirus gastritis.

To analyze the expression of different human cytomegalovirus (HCMV) antigens in gastric biopsy samples from a renal transplant recipient suffering from HCMV gastritis, monoclonal antibodies (MAbs) were used in immunohistochemical analyses. In samples obtained before the start of specific therapy with ganciclovir, MAbs against immediate-early (E13), early (CCH2), and late antigen (XP1) reacted with cells in the smooth muscle, stromal, and epithelial layers. MAb E13 stained morphologically altered and unaltered cells; MAbs CCH2 and XP1 predominantly stained cytomegalic cells. After therapy with ganciclovir was begun, the three viral antigens were almost exclusively found in the epithelial cell layer, whereas viral antigen appeared to be cleared from smooth muscle and stromal cells. All cells stained by MAb E13 in these samples showed characteristic morphologic alterations, in contrast to cells in earlier samples. The changes in the pattern of viral antigen expression may reflect the effects of antiviral therapy.

Cell types infected in human cytomegalovirus placentitis identified by immunohistochemical double staining.

Chronic villitis is almost always present in intrauterine infection with human cytomegalovirus (HCMV). The inflammatory response to this virus has been described in detail. However, little is known about the types of placental cells that may be infected by HCMV and six cases of HCMV placentitis were thus investigated to identify the vulnerable cell types. Immunohistochemical double staining analyses were performed using antibodies to HCMV immediate early antigens and to specific cellular marker proteins. Fixed connective tissue cells could be demonstrated to be the predominantly infected cell type in each placental tissue. Endothelial cells and macrophages were also found to be infected in all six cases, whereas evidence of trophoblast infection was obtained in four cases. It is concluded that release of infectious virus by connective tissue cells, macrophages and endothelial cells may play a critical role in transplacental transmission of HCMV. The findings further suggest that the cytopathic effect of HCMV infection on these cells might be involved in the pathogenesis of intrauterine HCMV disease.