Lymphoma cell apoptosis in the liver induced by distant murine cytomegalovirus infection

Cytomegalovirus (CMV) poses a threat to the therapy of hematopoietic malignancies by hematopoietic stem cell transplantation, but efficient reconstitution of antiviral immunity prevents CMV organ disease. Tumor relapse originating from a minimal residual leukemia poses another threat. Although a combination of risk factors was supposed to enhance the incidence and severity of transplantation-associated disease, a murine model of a liver-adapted B-cell lymphoma has previously shown a survival benefit and tumor growth inhibition by nonlethal subcutaneous infection with murine CMV. Here we have investigated the underlying antitumoral mechanism. Virus replication proved to be required, since inactivated virions or the highly attenuated enhancerless mutant mCMV-DeltaMIEenh did not impact the lymphoma in the liver. Surprisingly, the dissemination-deficient mutant mCMV-DeltaM36 inhibited tumor growth, even though this virus fails to infect the liver. On the other hand, various strains of herpes simplex viruses consistently failed to control the lymphoma, even though they infect the liver. A quantitative analysis of the tumor growth kinetics identified a transient tumor remission by apoptosis as the antitumoral effector mechanism. Tumor cell colonies with cells surviving the CMV-induced "apoptotic crisis" lead to tumor relapse even in the presence of full-blown tissue infection. Serial transfer of surviving tumor cells did not indicate a selection of apoptosis-resistant genetic variants. NK cell activity of CD49b-expressing cells failed to control the lymphoma upon adoptive transfer. We propose the existence of an innate antitumoral mechanism that is triggered by CMV infection and involves an apoptotic signal effective at a distant site of tumor growth.     

Human cytomegalovirus infection of bone marrow myofibroblasts enhances myeloid progenitor adhesion and elicits viral transmission

Human cytomegalovirus (CMV) infection of bone marrow transplant recipients can cause pancytopenia, as well as life-threatening interstitial pneumonia. CMV replicates actively in bone marrow stromal cells, whereas it remains latent in hematopoietic progenitors. Our aim was to study the influence of CMV infection on adherence of CD34(+) cells to the myofibroblastic component of human bone marrow and examine transmission of virus from myofibroblasts to CD34(+) cells. We show that smooth actin, but not fibronectin, organization is markedly modified by CMV infection of bone marrow stromal myofibroblasts. Nonetheless, CMV infection led to increased adherence of the CD34(+) progenitor cell line, KG1a, relative to adherence to uninfected myofibroblasts from the same donors. Adherence of CD34(+) cells to infected bone marrow myofibroblasts resulted in transfer of virions and viral proteins through close cell-to-cell contacts. This phenomenon may play a role in the pathophysiology of CMV bone marrow infection and in eventual virus dissemination.     

Bone marrow failure by cytomegalovirus is associated with an in vivo deficiency in the expression of essential stromal hemopoietin genes.

Bone marrow (BM) failure associated with cytomegalovirus (CMV) infection is a feared complication after clinical BM transplantation. Experiments in long-term BM cultures have indicated that BM stromal cells (BMSC) are targets of productive CMV infection, but an in situ infection of BM stroma remained to be documented, and the pathomechanism is open to question. Here we describe a murine in vivo model of lethal CMV aplastic anemia (CMV-AA). The reconstitution of hematopoietic progenitor cells expressing stem cell factor (SCF) receptor was found to be defective in CMV-AA. While murine CMV replication in permissive parenchymal tissues is cytolytic, the hematopoietic cord was found to be a site of very limited virus production with foci of reticular BMSC expressing the intranuclear viral IE1 protein, but with only a few BMSC positive for viral genome in the in situ hybridization. XX-XY BM chimeras were established in order to quantitate Y-chromosome-tagged BMSC by a PCR specific for the male-sex-determining gene Tdy. This approach revealed that murine CMV infection is not associated with a significant loss of BMSC. Despite the physical integrity of the stromal network, the functional integrity of the stroma was impaired. While housekeeping genes were expressed normally in BMSC of infected mice, the expression of genes encoding the essential hemopoietins SCF, granulocyte colony-stimulating factor, and interleukin-6 was markedly reduced. In conclusion, the mechanism of BM failure is not a stromal lesion but an insufficient stromal function. These findings explain CMV-AA as a manifestation of multiple hemopoietin deficiency.     

Cellular Localization of Latent Murine Cytomegalovirus

Herpesviruses typically establish latent infection in their hosts. The cell(s) responsible for harboring latent virus, in most cases, is not known. Using immunofluorescence and PCR-in situ hybridization (PISH), a technique which combines the sensitivity of PCR with the localization and specificity of in situ hybridization, we provide the first direct evidence that endothelial cells are a major site of murine cytomegalovirus (MCMV) DNA in latently infected animals. These findings are consistent with existing knowledge of the biological behavior of CMV, in particular the transmission of latent CMV by solid organ and bone marrow transplantation, in both human and animal models. In addition, we have localized MCMV DNA in the lung alveolar macrophage and in bone marrow cells. Our findings confirm that bone marrow-derived hematopoietic cells are a site of CMV latency and further suggest that bone marrow may be a reservoir of infected progeny capable of migrating into the circulation and establishing latency in various tissues. These findings provide clearly needed insight into the site of latent infection which is central to an understanding of the mechanisms of reactivation.     

Murine model of interstitial cytomegalovirus pneumonia in syngeneic bone marrow transplantation: persistence of protective pulmonary CD8-T-cell infiltrates after clearance of acute infection

Interstitial pneumonia (IP) is a severe organ manifestation of cytomegalovirus (CMV) disease in the immunocompromised host, in particular in recipients of bone marrow transplantation (BMT). Diagnostic criteria for the definition of CMV-IP include clinical evidence of pneumonia together with CMV detected in bronchoalveolar lavage or lung biopsy. We have used the model of syngeneic BMT and simultaneous infection of BALB/c mice with murine CMV for studying the pathogenesis of CMV-IP by controlled longitudinal analysis. A disseminated cytopathic infection of the lungs with fatal outcome was observed only when reconstituting CD8 T cells were depleted. Neither CD8 nor CD4 T cells mediated an immunopathogenesis of acute CMV-IP. By contrast, after efficient hematolymphopoietic reconstitution, viral replication in the lungs was moderate and focal. The histopathological picture was dominated by preferential infiltration of CD8 T cells confining viral replication to inflammatory foci. Notably, after clearance of acute infection, CD62L(lo) and CD62L(hi) subsets of CD44(+) memory CD8 T cells were found to persist in lung tissue. One can thus operationally distinguish an early CMV-positive IP (phase 1) and a late CMV-negative IP (phase 2). According to the definition, phase 2 histopathology would not be diagnosed as a CMV-IP and could instead be misinterpreted as a CMV-induced immunopathology. We document here that phase 1 as well as phase 2 pulmonary CD8 T cells are capable of exerting effector functions and are effectual in protecting against productive infection. We propose that antiviral "stand-by" memory-effector T cells persist in the lungs to prevent virus recurrence from latency.     

Spirogermanium: effects on hematopoietic stem cells and survival of normal and tumor-bearing mice

The effect of spirogermanium (SG) on hematopoietic stem cells, tumor burden, and survival times was investigated in C3H mice with transplanted mammary carcinoma. Compared to normal mice, the number of hematopoietic stem cells, or colony-forming units per spleen (CFU-S), was lower in the marrow of tumor-bearing mice. Spirogermanium at 15 and 30 mg/kg was not toxic to the normal hematopoietic cells in the marrow of either normal or tumor-bearing mice. In contrast to animals treated with cyclophosphamide, SG did not decrease the tumor growth rate or prolong the survival times of tumor-bearing C3H mice. Doses of 35-40 mg/kg SG did not prolong the survival times or decrease the tumor burden of AKR/J mice with a long-passaged lymphoma. These studies demonstrate that SG has minimal inhibitory effects to the marrow of normal mice and may promote the maintenance of normal marrow cells in tumor-bearing animals. However, in two different transplanted tumor cell lines, SG did not inhibit tumor growth or prolong host survival time.     

Control of Cytomegalovirus in Bone Marrow Transplantation Chimeras Lacking the Prevailing Antigen-Presenting Molecule in Recipient Tissues Rests Primarily on Recipient-Derived CD8 T Cells

Cytomegalovirus (CMV) infection during the transient immunodeficiency after bone marrow transplantation (BMT) develops into disease unless antiviral CD8 T cells are restored in due course. Histoincompatibility between donor and recipient is associated with increased risk. Complications may include a rejection response against the foreign major histocompatibility complex (MHC) antigens and a lack of antiviral control resulting from a misfit between donor-derived T cells and the antigenic viral peptides presented in recipient tissues. Here we have established a murine model of CMV disease after experimental BMT performed across a single MHC class I disparity. Specifically, BALB/c bone marrow cells expressing the prevailing antigen-presenting molecule L^d were transplanted into the L^d gene deletion mutant BALB/c-H-2^dm2, an experimental setting that entails a selective risk of host-versus-graft but not graft-versus-host response. The reconstituted T-cell population proved to be chimeric in that it consisted of L^d-positive donor-derived and L^d-negative recipient-derived cells. Pulmonary infiltrates did not include cytolytic T cells directed against L^d. This finding implies that the infection did not trigger a host-versus-graft response. Notably, upon adoptive transfer, donor-derived CD8 T cells preferentially protected tissues of donor genotype, whereas recipient-derived CD8 T cells protected tissues of either genotype. We infer from these data that the focus on immunodominant antigens presented by L^d within the donor cell population distracted the donor T cells from protecting recipient tissues and that protection in the chimeras was therefore primarily based on recipient T cells. As a consequence, T-cell chimerism after BMT should give a positive prognosis with respect to control of CMV.Cytomegaloviruses (CMV) are kept under tight immune control (for reviews, see references 22 and 23). As a consequence, acute CMV infection is resolved rapidly and does not result in disease unless the host is immunologically immature or immunocompromised. Bone marrow (BM) transplantation (BMT) as a therapy of hematological malignancies is associated with a transient immunodeficiency. Accordingly, during the period of immunocompromise, transmission of donor-type CMV with the transplant as well as recurrence of CMV from latency established within the organs of the transplantation recipient both entail a risk for destructive virus replication in tissues resulting in multiple-organ CMV disease (16). In BMT recipients, CMV-induced interstitial pneumonia is a frequent and endangering manifestation of CMV disease (11, 27). However, CMV infection does not inevitably result in fatal disease. It appears that CD8 T-cell reconstitution is the decisive parameter in the control of CMV after BMT. Clinical data have shown that both efficient reconstitution of CD8 T cells (41) and supplementation of antiviral CD8 T cells by preemptive cytoimmunotherapy with T-cell lines (42, 50) correlate with a reduced risk of human CMV disease, whereas combined in vivo-ex vivo T-cell depletion, intended as a prophylaxis against graft-versus-host (GvH) disease, accidentally resulted in an increased incidence of CMV infections in BMT patients (14). Aspects of these clinical problems can be approached experimentally in a murine model of BMT and concurrent infection with murine CMV (for an overview, see reference 35). Specifically, depletion of CD8 T cells, but not of CD4 T cells, performed in vivo during the phase of reconstitution after BMT abolished the development of protective antiviral immunity, with an inevitably lethal outcome (34, 47) resulting from multiple-organ pathology (34), including BM aplasia (29, 30). Likewise, an insufficient endogenous reconstitution was successfully supplemented by experimental adoptive cytoimmunotherapy with antiviral CD8 T cells. Again, CD4 T cells were not effective (36, 37, 39, 47). Altogether, clinical data on human CMV infection and experimental data from the murine model have so far been concordant and have identified CD8 T cells as the principal effectors controlling CMV infections after BMT.These findings imply that all conditions which lower the efficacy of CD8 T-cell reconstitution will increase the risk for progression of asymptomatic CMV infection to fatal CMV disease. Histoincompatibility between graft and recipient is a factor likely to negatively influence the restoration of antiviral immunity. Accordingly, even though cases of severe human CMV disease have been reported also after autologous BMT (27, 40), the incidence of CMV-related complications is generally higher after histoincompatible BMT (51). In clinical BMT, donor and recipient are usually matched in major histocompatibility complex (MHC) class II molecules, whereas differences in minor histocompatibility loci and in MHC class I loci are tolerated if unavoidable. Complications caused in the CMV-infected recipient by histoincompatibility may include (i) an impaired engraftment of transplanted cells in the recipient BM stroma, (ii) an immunological GvH response as well as a host-versus-graft (HvG) response directed against the foreign minor or major histocompatibility molecules, and (iii) a lack of antiviral T-cell control resulting from an inappropriate repertoire of viral antigenic peptides presented by infected tissue cells of the transplantation recipient.In a first attempt to dissect these possibilities, we have established a murine model of experimental BMT performed across a single MHC class I disparity, namely, the presence and absence of the L^d molecule in BALB/c mice (MHC class I molecules K^d, D^d, and L^d) and the L^d gene deletion mutant BALB/c-H-2^dm2 (44), respectively. Depending on the choice of donor and recipient for the BMT, immunogenetical GvH and HvG conditions can be studied separately (35). Work presented herein focuses on the HvG setting with BALB/c as the donor strain and the mutant as the recipient. Hence, after incomplete depletion of hematopoietic cells of the recipients, this model entails a risk for graft rejection caused by a recipient response directed against the donor MHC class I molecule L^d. In addition, presentation of viral peptides by L^d, including the immunodominant IE1 nonapeptide of murine CMV (18, 38), is confined to donor-derived hematopoietic cells and their progeny, whereas the parenchymal and stromal sites of cytocidal infection (34) lack L^d as the prevailing peptide presenter. The aim of the study was to investigate the influence of this particular MHC class I disparity on the control of murine CMV after BMT.     

Control of Murine Cytomegalovirus in the Lungs: Relative but Not Absolute Immunodominance of the Immediate-Early 1 Nonapeptide during the Antiviral Cytolytic T-Lymphocyte Response in Pulmonary Infiltrates

The lungs are a major organ site of cytomegalovirus (CMV) infection, pathogenesis, and latency. Interstitial CMV pneumonia represents a critical manifestation of CMV disease, in particular in recipients of bone marrow transplantation (BMT). We have employed a murine model for studying the immune response to CMV in the lungs in the specific scenario of immune reconstitution after syngeneic BMT. Control of pulmonary infection was associated with a vigorous infiltration of the lungs, which was characterized by a preferential recruitment and massive expansion of the CD8 subset of α/β T cells. The infiltrate provided a microenvironment in which the CD8 T cells differentiated into mature effector cells, that is, into functionally active cytolytic T lymphocytes (CTL). This gave us the opportunity for an ex vivo testing of the antigen specificities of CTL present at a relevant organ site of viral pathogenesis. The contribution of the previously identified immediate-early 1 (IE1) nonapeptide of murine CMV was evaluated by comparison with the CD3-redirected cytolytic activity used as a measure of the overall CTL response in the lungs. The IE1 peptide was detected by pulmonary CTL, but it accounted for a minor part of the response. Interestingly, no additional viral or virus-induced antigenic peptides were detectable among naturally processed peptides derived from infected lungs, even though infected fibroblasts were recognized in a major histocompatibility complex-restricted manner. We conclude that the antiviral pulmonary immune response is a collaborative function that involves many antigenic peptides, among which the IE1 peptide is immunodominant in a relative sense.     

Simian immunodeficiency virus inhibits bone marrow hematopoietic progenitor cell growth.

The pathogenic mechanisms underlying the depressed hematopoietic functions seen in human immunodeficiency virus-infected individuals were explored in rhesus monkeys infected with the simian immunodeficiency virus of macaques (SIVmac). Bone marrow hematopoietic progenitor cell colony formation, both granulocyte/macrophage (CFU-GM) and erythrocyte (BFU-E), was shown to be decreased in number in SIVmac-infected rhesus monkeys. SIVmac was readily isolated from bone marrow cells of infected monkeys and was shown to be harbored in macrophages rather than T lymphocytes. The in vitro infection of normal bone marrow cells by SIVmac inhibited colony formation. A striking in vivo correlation between increased SIVmac load in bone marrow cells and decreased hematopoietic progenitor cell colony growth was also shown. Finally, inhibition of SIVmac replication in bone marrow macrophages resulted in increased progenitor cell colony growth from bone marrow cells. These results suggest that the infection of bone marrow macrophages by the acquired immunodeficiency syndrome (AIDS) virus may contribute to depressed bone marrow hematopoietic progenitor cell growth. Moreover, inhibition of AIDS virus replication in these macrophages might induce significant improvement in hematopoietic function.     

Absent or rare human immunodeficiency virus infection of bone marrow stem/progenitor cells in vivo.

An important question in human immunodeficiency virus (HIV) pathogenesis is whether HIV-infected bone marrow CD34+ stem/progenitor cells serve as a significant reservoir of virus in HIV-infected individuals. Our data indicate that infection of bone marrow stem/progenitor cells with HIV occurs rarely, if ever, in vivo. In the present study, CD34+ cells were immunomagnetically purified from the bone marrow of HIV-seropositive individuals, and purified cells or colony-forming cells of the granulocyte/macrophage lineage were analyzed for HIV proviral DNA by the polymerase chain reaction. No HIV DNA was detected in colony-forming cells of the granulocyte/macrophage lineage from HIV-positive patients. Furthermore, no virus was found in CD34(+)-enriched cells from six of seven samples from asymptomatic HIV-infected individuals and four of four samples from patients with AIDS-related complex or AIDS. Thus, infected stem cells are not a major source of persistent HIV and do not account for hematopoietic suppression. These findings have positive implications for the concept of marrow reconstitution with autologous stem cells, genetically engineered for HIV resistance, following marrow-ablative antiviral therapy.     

Myeloproliferative sarcoma virus (MPSV), a new tool for the study of hematopoiesis

MPSV induces a myeloproliferative syndrome in susceptible mice associated with an invasion of hematopoietic and nonhematopoietic organs with tumor nodules. The effect of the virus on the various hematopoietic precursors (CFU-S, CFU-C, CFU-E, BFU-E) was studied in vivo in the spleen, blood, and bone marrow, and in vitro, using colony assays in semisolid medium. After in vivo and in vitro infection MPSV induces the appearance of CFU-C, independent of added colony-stimulating activity and of pure and mixed BFU-E, independent of burst-promoting activity. MPSV also induces in vivo an amplification of the size and concentration of the hematopoietic system, including hematopoietic stem cells. MPSV infection may also alter the hemapoietic microenvironment. Modification of the disease by total body irradiation followed by bone marrow stem cell reconstitution or by splenectomy is compatible with mediation of the virus effect at the level of hematopoietic microenvironment. MPSV may constitute a new tool to study the regulation of murine hematopoiesis and viral genetic information, which can specifically induce characteristic disturbances of this system.     

Preemptive CD8 T-Cell Immunotherapy of Acute Cytomegalovirus Infection Prevents Lethal Disease,Limits the Burden of Latent Viral Genomes,and Reduces the Risk of Virus Recurrence

In the immunocompetent host, primary cytomegalovirus (CMV) infection is resolved by the immune response without causing overt disease. The viral genome, however, is not cleared but is maintained in a latent state that entails a risk of virus recurrence and consequent organ disease. By using murine CMV as a model, we have shown previously that multiple organs harbor latent CMV and that reactivation occurs with an incidence that is determined by the viral DNA load in the respective organ (M. J. Reddehase, M. Balthesen, M. Rapp, S. Jonjic, I. Pavic, and U. H. Koszinowski. J. Exp. Med. 179:185–193, 1994). This predicts that a therapeutic intervention capable of limiting the load of latent viral genome should also reduce the risk of virus recurrence. Here we demonstrate the benefits and the limits of a preemptive CD8 T-cell immunotherapy of CMV infection in the immunocompromised bone marrow transplantation recipient. Antiviral CD8 T cells prevented CMV disease and accelerated the resolution of productive infection. The therapy also resulted in a lower load of latent CMV DNA in organs and consequently reduced the incidence of recurrence. The data thus provide a further supporting argument for clinical trials of preemptive cytoimmunotherapy of human CMV disease with CD8 T cells. However, CD8 T cells failed to clear the viral DNA. The therapy-susceptible portion of the DNA load differed between organs and was highest in the lungs. The existence of an invariant, therapy-resistant load suggests a role for immune system evasion mechanisms in the establishment of CMV latency.Recurrence of productive infection by reactivation of latent viral genome in the immunocompromised host is a feature common to the members of the herpesvirus family (39; reviewed in reference 38). Specifically, in the case of human cytomegalovirus (CMV), the human herpesvirus type 5, primary as well as recurrent infection during the temporal immunodeficiency early after bone marrow (BM) transplantation (BMT) entails a risk of graft failure and severe organ manifestations of CMV disease (8, 44). Early findings by Quinnan et al. (24) have suggested a correlation between efficient reconstitution of the cellular immune response and the control of post-BMT CMV infection, and more recent clinical data have attributed this control to the reconstituted CD8 T cells (35). Accordingly, restoration of antiviral immunity in the critical phase before the reconstitution by BMT becomes effective should diminish the risk of CMV disease. Experimental research with the model of murine CMV infection has positively demonstrated the antiviral and protective efficacy of adoptively transferred acutely sensitized (31, 34) or memory (28) CD8 T cells recovered from immune donors as well as of short-term CD8 T-cell lines propagated in culture (32). These studies have been pivotal for clinical trials of a preemptive CD8 T-cell immunotherapy of post-BMT human CMV infection in patients (37, 43).Infection of the BMT recipient can accidentally result from the transmission of infectious virus, however, productive infection is more commonly initiated by reactivation of latent CMV in either the transplant or the recipient’s own organs or, occasionally, both (11). For the murine model system, we have previously demonstrated the existence of multiple organ sites of CMV latency at which the latent viral DNA is retained after the resolution of productive primary infection and after clearance of the viral genome from hematopoietic leukocytic cells in BM and blood (27). In accordance with the wide distribution of the latent viral DNA, recurrence was found to occur focally in any of the organs, which led us to propose the concept of multifocal CMV latency and recurrence (27). Most importantly, the incidence of recurrence was found to correlate with the load of latent viral DNA in the respective tissue. Specifically, low virus dissemination and rapid control of infection in immunocompetent adult mice resulted in a low load and was associated with a low risk of recurrence, whereas the delayed control of infection in neonatal mice resulted in a high load and was associated with a high risk. Furthermore, there were also organ-specific differences. In accordance with the high incidence of interstitial CMV pneumonia after BMT, the lungs were identified as having a high load of latent CMV (2, 17).It is apparent that antiviral CD8 T cells generated during primary infection as well as memory cells present during latency do not eradicate latently infected cells under physiological conditions, since latency would not exist if they did. However, it has been open to question whether adoptive transfer of antiviral CD8 effector cells could prevent the escape of virus into latency. We will show here that modulation of primary infection by experimental CD8 T-cell immunotherapy has indeed had an effect on the load of latent viral DNA in tissues. The effect of the therapy is of relevance, since the load of latent viral DNA can be kept below the threshold required for effective recurrence. Our data thus provide a further supporting argument for clinical trials of cytoimmunotherapy. Interestingly, however, the data also predict that no dosage of CD8 T cells will prevent the establishment of latency.     

Combined infection by Moloney murine leukemia virus and a mink cell focus-forming virus recombinant induces cytopathic effects in fibroblasts or in long-term bone marrow cultures from preleukemic mice.

We described previously a preleukemic state in mice inoculated with Moloney murine leukemia virus (M-MuLV) characterized by generalized hematopoietic hyperplasia in the spleen. To investigate this further, long-term bone marrow cultures (LTBMC) from preleukemic mice were established. Surprisingly, LTBMC from M-MuLV-inoculated preleukemic mice showed less hematopoiesis than LTBMC from control mice. This resulted from a quantitative defect in establishment of bone marrow stromal cells in the LTBMC. This phenomenon could also be observed in LTBMC from normal mice infected in vitro with a stock of M-MuLV containing a mink cell focus-forming virus (MCF) derivative (M-MCF), but not in LTBMC infected with M-MuLV alone. This implicated MCF derivatives in the reduction in bone marrow stromal cells. The phenomenon could also be detected in infected NIH 3T3 cells. Combined infection of M-MuLV plus M-MCF resulted in fewer cells, in comparison to uninfected cells or cells infected with either virus alone. Further studies indicated that this was predominantly due to an inhibition in cell growth rather than to cell lysis. The cytopathic effect did not appear to result from overreplication of viral DNA, as measured by Southern blots. Thus, combined infection with M-MuLV and an MCF derivative had cytostatic effects on cell growth. This phenomenon might also contribute to the leukemogenic process in vivo.     

CMV infections in bone marrow transplanted patients--evaluation of prophylaxis with Cytotect (CMV hyperimmuneglobulin)

Cytomegalovirus (CMV) infection is a frequent and clinically important infection following bone marrow transplantation. Candidates for this study were patients admitted for transplantation: 22 patients received bone marrow from a HLA-identical, MCR-nonreactive sibling, in 9 patients an autologous BMT was performed. The anti-CMV IgG (Cytotect) was administered at a dosage of 1 ml/kg on days -7, 13, 33, 53, 73 and 93 after BMT. 5 patients in the very beginning of our BMT program did not receive Cytotect. Patients were given random blood products from the bloodbank not tested for CMV positivity. Active CMV infection or seroconversion in our patients was defined as a rise in IgG titer against the late antigen of fourfold or more or an IgM increase. In the allogeneic BMT group the pretransplant serological status was in 6 cases negative in recipients and donor, in 7 patients positive in recipients and negative in donors, and in 4 patients positive in recipients and donors. Of the 6 patients seronegative in recipients and donors, 3 developed active infection and of the 7 patients pretransplant positive with seronegative donors 3 developed active infection and 4 latent infections during the period from 2 to 100 days following grafting. 1 patient out of the group transplanted in third partial remission of AML developed interstitial pneumonia and died on day +30.4 of the 4 cases with seropositivity of recipients and donors developed active CMV infection. Of 9 patients with autologous transplantation 6 patients were pretransplant seropositive. 3 of these 6 developed active infection and 2 latent infection 30 to 180 days after grafting.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cytomegalovirus Inhibits the Engraftment of Donor Bone Marrow Cells by Downregulation of Hemopoietin Gene Expression in Recipient Stroma

Cytomegalovirus (CMV) disease after bone marrow (BM) transplantation is often associated with BM graft failure. There are two possible reasons for such a correlation. First, a poor hematopoietic reconstitution of unrelated etiology could promote the progression of CMV infection by the lack of immune control. Alternatively, CMV infection could interfere with the engraftment of donor BM cells in recipient BM stroma. Evidence for a causative role of CMV in BM aplasia came from studies in long-term BM cultures and from the murine in vivo model of CMV-induced aplastic anemia. A deficiency in the expression of essential stromal hemopoietins, such as stem cell factor (SCF), has indicated a functional insufficiency of the stromal microenvironment. It remained open to question whether CMV mediates a negative regulation of hemopoietin gene expression (the downregulation model) or whether it causes the default of a positive regulator (the lack-of-induction model). Further, even though implicitly assumed, it has never been formally documented that CMV directly interferes with the engraftment of a BM cell transplant. We addressed these problems in a murine model of CMV infection after experimental male-into-female BM transplantation. The data indicate that the downregulation model applies. Quantitation of the male-sex-determining gene tdy demonstrated an impaired engraftment of donor BM cells in the BM stroma of the female recipients. This graft failure was reflected by a diminished population of SCF-receptor-expressing hematopoietic progenitor cells and correlated with a reduced level of stromal SCF gene expression. Interestingly, high doses of BM cells protected against stromal insufficiency by a mechanism unrelated to control of infection.     

Subdominant CD8 T-cell epitopes account for protection against cytomegalovirus independent of immunodomination

Cytomegalovirus (CMV) infection continues to be a complication in recipients of hematopoietic stem cell transplantation (HSCT). Preexisting donor immunity is recognized as a favorable prognostic factor for the reconstitution of protective antiviral immunity mediated primarily by CD8 T cells. Furthermore, adoptive transfer of CMV-specific memory CD8 T (CD8-T(M)) cells is a therapeutic option for preventing CMV disease in HSCT recipients. Given the different CMV infection histories of donor and recipient, a problem may arise from an antigenic mismatch between the CMV variant that has primed donor immunity and the CMV variant acquired by the recipient. Here, we have used the BALB/c mouse model of CMV infection in the immunocompromised host to evaluate the importance of donor-recipient CMV matching in immundominant epitopes (IDEs). For this, we generated the murine CMV (mCMV) recombinant virus mCMV-DeltaIDE, in which the two memory repertoire IDEs, the IE1-derived peptide 168-YPHFMPTNL-176 presented by the major histocompatibility complex class I (MHC-I) molecule L(d) and the m164-derived peptide 257-AGPPRYSRI-265 presented by the MHC-I molecule D(d), are both functionally deleted. Upon adoptive transfer, polyclonal donor CD8-T(M) cells primed by mCMV-DeltaIDE and the corresponding revertant virus mCMV-revDeltaIDE controlled infection of immunocompromised recipients with comparable efficacy and regardless of whether or not IDEs were presented in the recipients. Importantly, CD8-T(M) cells primed under conditions of immunodomination by IDEs protected recipients in which IDEs were absent. This shows that protection does not depend on compensatory expansion of non-IDE-specific CD8-T(M) cells liberated from immunodomination by the deletion of IDEs. We conclude that protection is, rather, based on the collective antiviral potential of non-IDEs independent of the presence or absence of IDE-mediated immunodomination.     

Rescue of myeloid lineage-committed preprogenitor cells from cytomegalovirus-infected bone marrow stroma.

The effect of murine cytomegalovirus on myelopoiesis was studied in long-term bone marrow culture to find an in vitro correlate for the lethal virus interference with bone marrow reconstitution (W. Mutter, M. J. Reddehase, F. W. Busch, H.-J. Bühring, and U. H. Koszinowski, J. Exp. Med. 167:1645-1658, 1988). The in vitro generation of granulocyte-monocyte progenitors (CFU-GM) discontinued after infection of the stromal cell layer, whereas the proliferation and differentiation of CFU-GM to granulocyte-monocyte colonies remained unaffected. A protocol was established to probe the functional integrity of earlier hematopoietic cells. Pre-CFU-GM (the progenitors of the CFU-GM) could be recovered from an infected bone marrow donor culture by transfer onto an inductive recipient stromal cell layer. Thus, at least in vitro, infection of bone marrow stroma appears to be the only cause of the defect in myelopoiesis.     

Early bone marrow hematopoietic defect in simian/human immunodeficiency virus C2/1-infected macaques and relevance to advance of disease

To clarify hematological abnormalities following infection with human immunodeficiency virus (HIV), we examined the hematopoietic capability of bone marrow by using cynomolgus monkeys infected with pathogenic simian/human immunodeficiency virus (SHIV) strain C2/1, an animal model of HIV infection. The relationship between the progress of the infection and the CD4/CD8 ratio of T lymphocytes or the amount of SHIV C2/1 viral load in the peripheral blood was also investigated. A colony assay was performed to assess the hematopoietic capability of bone marrow stem cells during the early and advanced phases of the infection. Colonies of granulocytes-macrophages (GM) were examined by PCR for the presence of the SIVmac239 gag region to reveal direct viral infection. There was a remarkable decrease in the CFU-GM growth on days 1 and 3 postinoculation, followed by recovery on day 56. During the more advanced stage, the CFU-GM growth decreased again. There was minimal evidence of direct viral infection of pooled cultured CFU-GM despite the continuously low CD4/CD8 ratios. These results indicate that the decrease in colony formation by bone marrow stem cells is reversible and fluctuates with the advance of the disease. This decrease was not due to direct viral infection of CFU-GM. Our data may support the concept that, in the early phase, production of inhibitory factors or deficiency of a stimulatory cytokine is responsible for some of the bone marrow defects described in the SHIV C2/1 model.