Hepatitis C virus infection involves CD34(+) hematopoietic progenitor cells in hepatitis C virus chronic carriers.

Although hepatitis C virus (HCV) mainly affects hepatocytes, infection is widespread and involves immunologically privileged sites. Whether lymphoid cells represent further targets of early HCV infection, or whether other cells in the hematopoietic microenvironment may serve as a potential virus reservoir, is still unclear. We studied whether pluripotent hematopoietic CD34(+) cells support productive HCV infection and can be used to establish an in vitro infection system for HCV. Six patients were selected as part of a cohort of HCV chronic carriers who developed a neoplastic disease. Reverse transcriptase-polymerase chain reaction (RT-PCR) and branched DNA signal amplification assays were used to detect and quantitate HCV RNA in extracted nucleic acids from purified bone marrow and peripheral blood CD34(+) cells. Direct in situ RT-PCR, flow cytometry analysis, and immunocytochemistry were applied to demonstrate specific viral genomic sequences and structural and nonstructural virus-related proteins in intact cells. Results indicated that both positive and negative HCV RNA strands and viral proteins were present in CD34(+) cells from all HCV-positive patients and in none of the controls. Additional experiments showed that a complete viral cycle took place in CD34(+) cells in vitro. Spontaneous increases in viral titers indicated that virions were produced by infected hematopoietic progenitor cells. To further define the cellular tropism, we attempted to infect CD34(+) cells in vitro. We were unable to demonstrate viral uptake by cells. These findings suggest that HCV replication can occur in the early differentiation stages of hematopoietic progenitor cells, and that they may be an important source of virus production.

Clonal analysis of intrahepatic B cells from HCV-infected patients with and without mixed cryoglobulinemia.

Clonal rearrangements of Ig heavy chain (IgH) genes and hepatitis C virus (HCV) genomic sequences were assayed on intrahepatic B lymphocytes isolated from HCV chronically infected patients with and without type II mixed cryoglobulinemia (MC). Liver tissue samples from eight patients with and nine without MC were subjected to routine histologic studies, immunophenotyping, and genotypic analysis including IgH V-D-J region gene rearrangements by PCR. RT-PCR, signal amplification by branched DNA assay, and in situ hybridization technique were used to detect and quantitate HCV RNA genomic sequences in selected B cells purified from each tissue sample. Although HCV infection of intrahepatic B cells was shown in all patients both with and without MC, frank B cell monoclonal and oligoclonal patterns were found in only three and four patients with MC, respectively. No monoclonal profile was seen in the noncryoglobulinemic patients, whereas an oligoclonal profile was demonstrated in four of them. No clonalities were shown in HCV-unrelated patients matched for age and severity of liver disease. No obvious difference in HCV genotype distribution was found in relation to the clonal expansion profile. Noncryoglobulinemic patients showing clonal expansion in liver tissue had higher titers of serum rheumatoid factor (RF). Spontaneous production of RF was shown in cell cultures of intrahepatic B cells, suggesting their persistent stimulation in vivo. These data indicate that HCV infection of B cells and B cell clonal expansions occur in the liver microenvironment and preferentially involve RF-producing cells.

In situ simultaneous detection of hepatitis C virus RNA and hepatitis C virus-related antigens in hepatocellular carcinoma.

BACKGROUND: The overwhelming evidence that chronic infection with the hepatitis C virus (HCV) is an important cause of hepatocellular carcinoma (HCC) is based on epidemiologic, case-control, and cohort studies as well as laboratory investigations. To address better the pathogenesis of HCV infection at the single-cell level, the authors developed a specific reproducible method for the simultaneous detection of HCV specific sequences and antigens in liver tissue, using a combination of nonradioactive in situ hybridization and immunohistochemistry. METHODS: After immunohistochemical staining of the liver sections for E2/NS-1, C22-3, C33c, C100-3, and NS-5 antigens with immunogold-silver technique, in situ hybridization was performed on the same sections using digoxigenin-labeled HCV 5' NonCoding specific probes. The hybridization signal was detected by an antidigoxigenin, Fab fragment-alkaline phosphatase conjugate. This simultaneous detection permitted the subcellular localization of HCV RNA and antigens with excellent preservation of tissue morphology and absence of background staining. In addition, the types and percentages of cells harboring HCV in tissue could be determined. RESULTS: The in situ detection of HCV showed positive signals in both cancerous and noncancerous areas of liver tissue in six of six HCV-infected patients with HCC and in none of four controls, including three HCV negative HCC patients and one patient with epithelioid hemangioendothelioma. Two classes of infected cells were distinguished throughout the liver: (1) cells containing large amounts of negative-stranded HCV RNA, which were probably undergoing active viral replication; and (2) cells displaying positive-stranded HCV RNA only, with unpredictable levels of viral replication. Both types expressed core, envelope, and NS-3, -4, and -5 proteins. HCV RNA and antigens were exclusively cytoplasmic. Detection of viral proteins was highly predictive of the presence of large amounts of HCV RNA in the same cell. Fewer HCV positive cells were consistently demonstrated in the cancerous area. CONCLUSIONS: These findings support the contention that HCV infects hepatocytes and replicates in them, even after their malignant transformation.

Detection and distribution of hepatitis C virus-related proteins in lymph nodes of patients with type II mixed cryoglobulinemia and neoplastic or non-neoplastic lymphoproliferation.

The role of hepatitis C virus (HCV) in the pathogenesis of type II mixed cryoglobulinemia (MC) has been strongly emphasized in the last few years. Although MC is a benign lymphoproliferative disorder, the risk of overt B-cell malignancy greatly increases during its course. The occurrence of HCV infection in 10% to 30% of patients with non-Hodgkin's lymphoma (NHL) suggests that this virus may have a role in the development of MC-associated B-cell malignancies. We identified 2 patients with hyperplastic reactive lymphadenopathy (HRL) and 12 with NHL in two series of MC patients chronically infected with HCV collected over a 5-year period. Structural and nonstructural HCV-related proteins were investigated in lymph node sections by immunohistochemistry and their location and distribution were correlated with clinical and histologic findings, viremic state, and HCV genotypes. In HRL, HCV proteins were found in the cytoplasm of lymphoid cells, mainly in interfollicular areas. However, occasional positive cells were found in the mantle zone and in the germinal centers of follicles. In addition, strong reactivity was found in the circulating mononuclear cells of capsular blood vessels. HCV immunodeposits were found in 3 of 12 (25%) NHL cases. Positive cells were frequently restricted to the cortex; if not, they were randomly diffused in the neoplastic tissue. Positivity was related to the low-grade type of NHL; in the 2 composite cases, HCV immunodetection was found in the small cells, whereas large anaplastic cells were regularly negative. Other viruses previously involved in lymphoproliferation, ie, human herpes virus-6 and Epstein-Barr virus, were absent in all tissues. These data emphasize that lymphoid organs may be a site of HCV infection. The demonstration of HCV-related proteins in a nonmalignant condition, namely HRL, indicates that HCV infection precedes the neoplastic transformation and possibly plays a major role in lymphomagenesis in MC.

Immunochemical and biomolecular studies of circulating immune complexes isolated from patients with acute and chronic hepatitis C virus infection.

Circulating immune complexes (ICs) were isolated by affinity chromatography and sucrose density gradient fractionation during acute and chronic hepatitis C virus (HCV) infection. Immunochemical and biomolecular studies showed that they basically consist of the virus component, IgG with specific anti-HCV activity and IgM bearing 17.109 epitope (IgM 17.109), an antigenic determinant common to rheumatoid factors (RFs) with WA cross-idiotype (XId). An antigen-specific IC assay was used to demonstrate IgG anti-HCV/IgM 17.109 ICs (IgG-IgM ICs) in five out of the five patients with acute and in 8 out of the 10 patients with chronic hepatitis C who mounted an IgG anti-HCV immune response. They were not detected in patients with no IgG anti-HCV response. IgG-IgM ICs appeared in step with IgG anti-HCV seroconversion and remained detectable for a long period irrespective of clinical outcome, in that they were demonstrated over a 4-year follow-up of patients with chronic hepatitis C. Their presence was unrelated to the severity and progression of liver histology. Despite similar serum levels of IgM 17.109 XId, antigen-specific IgG-IgM ICs were not found in acute and chronic hepatitis B or in acute hepatitis A. Thus, these ICs appear to be uniquely associated with HCV infection, supporting the view that IgM 17.109 XId derive from an antigen-driven response strictly related to the involved antigen. Even although they have no apparent effects on the progression of HCV-related liver disease, their presence may help to explain the immunological abnormalities and extrahepatic disorders observed in HCV infection.

Detection of hepatitis C virus (HCV) proteins by immunofluorescence and HCV RNA genomic sequences by non-isotopic in situ hybridization in bone marrow and peripheral blood mononuclear cells of chronically HCV-infected patients.

Immunofluorescence (IF) to detect HCV antigens and non-isotopic in situ hybridization (NISH) to detect HCV RNA genome were carried out on bone marrow (BM) and peripheral blood (PB) mononuclear cells (MC) of 11 chronically HCV-infected patients. In four patients (36.4%) HCV antigens were detected in monocytes/macrophages as well as in B lymphocytes in both BMMC and PBMC. Positive T lymphocytes in BMMC were found in three of them, but only one patient showed positive T cells in PBMC. NISH invariably demonstrated minus and plus HCV RNA genomic strands either in monocytes/macrophages or B and T lymphocytes in BMMC and PBMC in the four HCV antigen-positive patients and in two further patients not expressing viral proteins in blood MC. IF signals appeared diffusely distributed within the cytoplasm, or as brilliant granules in distinct submembrane areas or else in cytoplasm membrane. Nuclei never stained. Similarly, NISH displayed HCV RNA accumulation restricted to MC cytoplasm only, nuclei being persistently negative. NISH, however, was unable to detect cell membrane signal. Infection of blood MC is a common event in naturally acquired HCV infection, since none of these patients was conditioned by immunomodulating or immunosuppressive therapies. No difference was found in terms of age, length of disease, anti-HCV immune response, type and severity of chronic liver damage between patients with HCV-infected MC and patients without cell infection. These results demonstrate that HCV can infect BMMC and PBMC that represent important extrahepatic sites of virus replication, and may help to explain the immunological abnormalities observed in chronic HCV carriers.

Hepatitis C virus infection and clonal B-cell expansion.

The striking association between hepatitis C virus (HCV) infection and the so-called "essential" mixed cryoglobulinemia (MC) has led to the hypothesis that HCV plays a major role in the production of cryoglobulins. Analysis of soluble and cryoprecipitable immune complexes shows that the hepatitis C virion is bound to IgM bearing the WA cross-idiotype (XId). The production of WA XId IgM seems to be the result of chronic stimulation by HCV of a population of WA XId + CD5 + B cells. It is possible that the reactivity of WA XId IgM does not initially include rheumatoid factor (RF) activity, which may be acquired secondarily from mutational events accompanying a probably T-cell independent B cell proliferation. Type II MC is a benign proliferation that progresses to malignancy in a minority of patients. This is consistent with the concept that malignancy progression involves the accumulation of multiple mutations of proto-oncogenes and tumor suppressor genes that are facilitated by chronic antigenic stimulation. The recent demonstration of HCV in hyperplastic reactive lymphoadenopathy and in the neoplastic lymph nodes of patients with MC strengthens the putative role played by HCV in lymphomagenesis. A fuller understanding of the virus-related mechanisms of lymphoproliferation in MC patients would contribute significantly to the development of therapeutic strategies.

Immunohistochemical detection of hepatitis C virus-related proteins in liver tissue.

OBJECTIVE: Hepatitis C virus (HCV)-associated antigens (Ags) are hard to detect and poorly defined in liver tissue, and are of uncertain interpretation. The failure of immunohistochemistry in HCV infection may be due to the affinity of specific antisera, the levels of Ags in infected tissues, the labile and unstable expression of antigenic determinants, and the use of fixatives that may alter or destroy viral epitopes. Strategies to optimize all stages of tissue specimen processing have therefore been devised in the liver biopsies of patients with acute and chronic hepatitis, and those with hepatocellular carcinoma (HCC). METHODS: HCV-Ags were detected with a two-stage indirect immunostaining procedure on unfixed cryostat liver sections from 7 acute and 23 chronic HCV-infected patients, and from 4 patients with HCV-associated HCC. A mixture of monoclonal antibodies directed to structural and non-structural HCV-related proteins were used as the primary reagents. RESULTS: HCV-Ags in 50-70% of the hepatocytes were found in all seven acute hepatitis patients compared with < or = 20% hepatocytes (P < 0.05) in 10 out of 23 patients (43.5%) with chronic hepatitis. Immunoreactive signals appeared as diffuse or coarse granular deposits in the cytoplasm only. The nuclei were unstainable. No clear membranous pattern was found, although fine granular, submembranous accumulation in distinct areas of the cytoplasm was observed. In acute hepatitis, HCV-Ag positive hepatocytes were distributed in the lobules in direct relation to the areas of necrosis and inflammatory cell accumulation, whereas in chronic hepatitis the immunoreactive cells were not clearly related to the necrotic foci. HCV-Ag immunodeposits were demonstrated in all patients with HCC. The immunoreactive signal in neoplastic cells was primarily located in the cytoplasm and rarely in the nuclei. As compared with the non-neoplastic zones, neoplasia demonstrated a significantly higher specific signal. CONCLUSIONS: Immunohistology is a powerful tool for the identification of HCV-related proteins in liver tissue. Sensitivity was significantly enhanced by the use of fresh-frozen tissues, which presumably preserve their HCV antigen structure, and by a mixture of monoclonal antibodies directed against HCV-related proteins, possibly on account of the separate access of each probe to different target proteins. The demonstration of HCV infection in hepatocyte cytoplasm indicates that this is the primary site of HCV replication, while its presence in malignant cells suggests that the virus could be substantially involved in the pathogenesis of HCC.

Hepatitis C virus within a malignant lymphoma lesion in the course of type II mixed cryoglobulinemia.

Hepatitis C virus (HCV) has been implicated as the major etiologic factor sustaining B-cell clonal expansion in type II mixed cryoglobulinemia (MC). A putative pathogenetic role of HCV in the development of MC-associated B-cell malignancies has also been speculated. We report for the first time the localization of HCV within a parotid non-Hodgkin's lymphoma (NHL) lesion in the course of HCV-related type II essential MC, an important step to implicate any infectious agent in the lymphomagenesis. Plus and minus strand HCV RNA was first demonstrated by polymerase chain reaction on the whole RNA from the lesion. Further immunohistochemical studies localized HCV c22 proteins in the residual ductal or acinar parotid structures, which also abnormally expressed HLA-DR antigens. Weak c22 signals were inconstantly detected in cells strictly confined around the residual epithelium, while all the remaining infiltrating cells in the parotid lesion stained c-22-negative. Staining for c33 and c100 HCV antigens was negative. In situ hybridization (ISH) studies again identified the residual parotid epithelial cells as the site of HCV infection and replication in the NHL lesion. Sialotropic viruses previously involved in lymphoproliferation, ie, Epstein-Barr virus and human herpesvirus-6, were absent in the same tissue lesion. According to the current models of B-cell lymphomagenesis, a role of HCV as an exogenous antigenic stimulus should be considered for NHL development in the present case, whereas malignant B cells do not appear permissive of active HCV replication. Further efforts would be worthwhile to clarify a role of HCV infection in the development of some B-cell malignancies.

Localization of hepatitis C virus antigens in liver and skin tissues of chronic hepatitis C virus-infected patients with mixed cryoglobulinemia.

Skin and/or liver biopsy specimens were obtained from the following patients: 15 anti-hepatitis C virus (HCV), HCV RNA-positive patients and 3 anti-HCV, HCV RNA-negative patients with type II mixed cryoglobulinemia (MC); 7 anti-HCV, HCV RNA-positive patients with chronic active liver disease (CALD); 5 anti-HCV, HCV RNA-negative patients with noncryoglobulinemic vasculitis; and 7 anti-HCV, HCV RNA-negative patients with lichen ruber planus. A pool of murine monoclonal antibodies (MAbs) developed against c22-3, c33c, and c100-3 proteins was used to detect HCV-related antigens (Ags) by indirect immunohistochemistry. Acid electroelution (AEE) of tissue sections was performed to enhance the sensitivity of the immunohistochemical method. In anti-HCV-positive MC patients, specific HCV-related Ags were detected in the small vessels of the skin and in the cytoplasm of hepatocytes. Prior AEE of biopsy sections allowed detection of HCV Ags in 6 of 15 (40%) skin biopsy and in 9 of 14 (64.3%) liver biopsy specimens. HCV immunoreactive deposits in the skin displayed two immunohistochemical patterns: (1) coarse intraluminal material associated with dermal inflammatory infiltrates and intravascular deposition of eosinophilic hyaline material; and (2) reactivity confined to the vessel wall in the context of an apparently normal tissue. Immunoglobulin (Ig) G and IgM deposition in the skin showed immunohistochemical features comparable with those found for HCV Ag deposits.(ABSTRACT TRUNCATED AT 250 WORDS)

Demonstration and distribution of HCV RNA sequences by in situ hybridization and HCV-related proteins by immunohistochemistry in the liver tissue of patients with chronic HCV infection.

Nonisotopic in situ cytohybridization of HCV RNA was attempted in liver specimens from 12 chronically hepatitis C virus (HCV) infected patients. Oligonucleotides deduced from 5'-noncoding and core regions of the HCV genome were labeled with digoxigenin and used on paraformaldehyde-fixed frozen liver sections. The hybrids were visualized immunohistochemically with alkaline phosphatase-conjugated anti-digoxigenin and alkaline phosphatase substrate. These findings were correlated with the results of tissue immunohistochemistry for HCV antigens identified with specific mouse monoclonal antibodies developed against c22-3 antigen (Ag), a core-encoded protein, and c100-3 Ag, a NS4-encoded protein, and histologic assessment of each liver. HCV RNA detected in the above assay was predominantly cytoplasmic; it was detected in all 12 patients and in none of the controls. Tissue HCV RNA was associated with the presence of cytoplasmic (c100-3 Ag) and membrane (c22-3 Ag) expression of viral proteins in all 9 patients with histological evidence of chronic progressive liver disease as judged by the presence of piecemeal necrosis, and lobular and portal tract inflammation. Despite the presence of abundant HCV RNA, none of 3 patients without histological evidence of chronic liver disease showed intrahepatocyte expression of viral proteins. These findings support the view that tissue HCV antigens are markers of progressive damage and demonstrate that active liver disease does not occur without such markers. It is proposed that synthesis of viral proteins and membrane accumulation of c22-3 Ag may be involved in the pathogenesis of hepatocyte injury in chronic hepatitis C infection.

Natural interferon-alpha versus its combination with 6-methyl-prednisolone in the therapy of type II mixed cryoglobulinemia: a long-term, randomized, controlled study.

Type II mixed cryoglobulinemia (MC) is an often progressive vasculitis characterized by circulating cold-precipitable proteins that usually consists of polyclonal IgG and monoclonal IgM kappa with rheumatoid factor (RF) activity. Its etiology is unknown, although recent evidence strongly suggests that hepatitis C virus (HCV) plays a major role. Plasmapheresis, corticosteroids, and cytotoxic drugs have been used in the therapy of MC patients. Recently, favorable results with recombinant interferon-alpha (rIFN alpha) have been reported. To further assess its effectiveness, we studied the effects of natural human interferon-alpha (nIFN alpha), alone and in combination with 6-methyl-prednisolone (PDN), in a prospective, randomized, controlled trial in patients with symptomatic MC. Sixty-five patients were enrolled onto the trial, 52 (80%) of whom presented serum anti-HCV antibodies and specific genomic RNA sequences. Fifteen patients received nIFN alpha (3 MU) intramuscularly (IM) three times weekly, whereas 17 patients also received 16 mg/d of PDN orally on non-IFN days. Moreover, 18 patients received 16 mg/d of PDN only, and 15 were untreated. Treatment was discontinued after 1 year and patients were monitored for 8 to 17 months (mean, 13). A complete response was achieved in eight of 15 patients (53.3%) treated with nIFN alpha and nine of 17 (52.9%) treated with nIFN alpha plus PDN, as compared with three of 18 patients (16.7%) who received PDN only (P < .05) and one of 15 (6.7%) untreated controls (P < .01). Partial response occurred in two of 15 (13.3%) patients treated with nIFN alpha, three of 17 (17.6%) who received nIFN alpha plus PDN, one of 18 (5.5%) who received PDN only, and one of 15 (6.7%) controls. A complete response in six patients (66.7%) was achieved within 3 months in the group that received nIFN alpha plus PDN, as compared with two patients (25%) of those who received nIFN alpha alone (P < .02). In anti-HCV-positive patients, the clinical response occurred in step with reduced or undetectable levels of HCV RNA and transaminase normalization. Quantification of circulating HCV RNA represented a good predictive response marker. The probability of relapse within 3 months after treatment was 100% (three of three patients) and 75% (six of eight patients), respectively, in patients who received PDN alone or nIFN alpha alone as compared with none of those who received nIFN alpha plus PDN (P < .001).(ABSTRACT TRUNCATED AT 250 WORDS)

Hepatitis C virus infection and mixed cryoglobulinemia: a striking association.

The high frequency of liver involvement in cryoglobulinemia is well established. Although both etiology and pathogenesis have remained so far undefined, recent studies suggest an association of mixed cryoglobulinemia with hepatitis C virus infection. To explore this hypothesis further, we assessed the prevalence of hepatitis C virus antibodies and RNA in a large group of patients, including: (1) 35 patients with cryoglobulinemia without clinical evidence of liver involvement (group 1), (2) 15 patients with symptomatic cryoglobulinemia associated with chronic liver disease (group 2) and (3) 12 patients with asymptomatic cryoglobulinemia associated with chronic liver disease (group 3). Anti-hepatitis C virus antibodies were detected by a second-generation enzyme-linked immunosorbent assay and third-generation immunoblot (SIA Prototype RIBA), whereas the polymerase chain reaction was used for the detection of viral RNA. Anti-hepatitis C virus antibodies, as detected by enzyme-linked immunosorbent assay, were demonstrated in 21 (60%) patients from group 1, 11 (73.3%) from group 2 and 10 (83.3%) from group 3. The immunoblot identified as positive 3 further patients in group 1 (giving a prevalence of 68.6%) and all patients in groups 2 and 3. Hepatitis C virus RNA was demonstrated in cryoprecipitates from 21 of 24 immunoblot-positives and from 6 of 11 immunoblot-negatives, indicating an actual active viral replication in 77.1% of group 1. This was also found in 13 (86.7%) and 10 (83.3%) cryoprecipitates of groups 2 and 3, respectively. Type II cryoglobulinemia was the prevalent form in group 1 (88.6%) and group 2 (73.3%), whereas type III was found in group 3 (58.3%) and in 26.7% of group 2.(ABSTRACT TRUNCATED AT 250 WORDS)

Circulating levels and liver tissue distribution of intercellular adhesion molecule-1 during beta-interferon therapy of hepatitis C virus-associated chronic active liver disease.

Intercellular adhesion molecule-1, an immunoglobulin supergene family member, is known to account for important steps in cell activation and the immune response. By a non-isotopic slot-dot immunoblotting assay, we measured circulating levels of intercellular adhesion molecule-1 in 26 patients with hepatitis C virus-associated chronic active liver disease before and after beta-interferon therapy, in 6 patients with non-A, non-B acute self-limiting hepatitis and in 13 healthy subjects. Circulating intercellular adhesion molecule-1 was found in 10 of 13 (77%) normal controls at low concentrations which were not statistically different from those measured in patients with hepatitis C virus-associated chronic active liver disease responsive to beta-interferon, whereas significantly higher levels were found in unresponsive patients. Higher serum intercellular adhesion molecule-1 levels were found in 4 of 10 (40%) beta-interferon-responsive patients compared with 13 of 16 (18%) unresponsive patients. Intercellular adhesion molecule-1 levels persisted after discontinuation of beta-interferon treatment and did not correlate with hepatocytolysis (as indicated by alanine aminotransferase serum activity) either in chronic active liver disease or acute hepatitis. However, a good correlation was found between intercellular adhesion molecule-1 and its expression on liver cells, thus emphasizing that induced circulating levels may reflect the state of activation at the sites of the inflammatory process. These data strongly support the view that intercellular adhesion molecule-1 plays an important role in liver cell damage in hepatitis C virus-associated acute and chronic liver disease, and that its circulating levels may be a good prognostic parameter of responsiveness to beta-interferon therapy.