Gender and strain-specific differences in the development of steatosis in rats.

Non-alcoholic fatty liver disease (NAFLD) is a common problem with a wide variety of phenotypes. While its pathogenesis is still not fully understood, several risk factors for disease progression have been identified. Therefore, defining adequate animal models may serve to unreveal the pathogenesis in NAFLD. We studied Lewis and Sprague-Dawley rats of both genders (n = 6) fed standard (Std) or high-fat (HF) diet for three weeks. Disease stage was assessed by haematoxylin-eosin, Azan Heidenheim and Oil-Red staining, apoptosis by single-stranded DNA (ssDNA) detection and liver regeneration by Ki-67 staining. Serum markers of liver injury and lipid metabolism including adipocytokines were analysed. Livers of both strains and genders fed with HF diet demonstrated evidence of steatosis. Lewis rats developed microvesicular steatosis whereas Sprague-Dawley rats presented macrovesicular steatosis accompanied by pronounced fibrosis. Female gender of both strains was associated with lower steatosis grade and higher proliferation rate (P < 0.05). Gender-specific differences were most prominent in Lewis rats on a HF diet, where females showed lower alkaline phosphatase, cholesterol, triglyceride and leptin levels and a more favourable low-density lipoprotein/high-density lipoprotein ratio than males (P < 0.05). Reverse transcriptase-polymerase chain reaction analysis was performed to demonstrate changes in expression of various genes important for liver regeneration, fibrosis and steatosis. HF diet induced downregulation of proangiogenic genes such as vascular endothelial growth factor receptor 1 and 2 (P < 0.05) in males was not present in females. In conclusion, strain and gender served major roles in disease progression. These differences should be considered when designing studies and may offer new ways to advance therapeutic strategies.

Laser secondary neutral mass spectrometry for copper detection in micro-scale biopsies.

Disease progression and clinical diagnostics of a number of hereditable metabolic diseases are determined by organ involvement in disturbed deposition of certain molecules. Current clinical imaging is unable to visualize this maldistribution with sufficient specificity and sensitivity, such as in Wilson's disease. The quest for understanding cellular Cu distribution in these patients requires element- and molecule-specific images with nanometer-scale spatial resolution. We have used a new cryo-mass spectrometric instrument with an integrated cryosectioning chamber for preparation and analysis of frozen hydrated samples of Wilson's disease tissue. With laser post-ionization secondary neutral mass spectrometry (laser-SNMS), we were able to image Cu and other intrinsic elements and molecules in less than 1 mg of frozen hydrated liver tissue from a murine model of Wilson's disease. A 40-50 times higher Cu concentration was measured in the disease tissue as compared to the control mouse. Furthermore, major histomorphological changes were observed using this advanced nano-science tool. The results showed that the combination of in-vacuum cryosectioning and cryo-laser-SNMS technologies is particularly well suited for identifying specific cell structures and imaging trace element concentrations with subcellular resolution and upper-parts-per-billion sensitivity in biological samples. This technology can provide a novel diagnostic tool for clinical applications in various diseases involving trace elements.

Herpes simplex virus type-1 amplicon vectors for vaccine generation in acute lymphoblastic leukemia.

For leukemia vaccine generation, high-efficiency gene transfer is required to express immunomodulatory molecules that stimulate potent antileukemic immune responses. In this context, herpes simplex virus type-1 (HSV-1)-derived vectors have proven to be a promising tool for genetic modification of lymphoblastic leukemia cells. Yet, vector-associated viral protein expression might inadvertently modulate vaccine efficacy facilitating both immune evasion and immune stimulation. To explore the issue of immune-stimulation versus immune-suppression in immature lymphoblastic leukemia cells, two types of HSV-1 amplicon vectors, helper virus-dependent and helper virus-free that express the immunomodulatory molecules CD70 and IL-2, were compared with regard to their vector-associated immunomodulatory potential. We first established that lymphoblastic cell lines and primary acute lymphoblastic leukemia (ALL) cells express HSV receptor genes. Lymphoblastic cell lines were transduced with high efficiency, and in primary ALL cells high gene transfer rates of 47+/-15 and 42+/-14% were obtained with helper virus-dependent and -free HSV-1 amplicon vectors, respectively. The efficacy of the two amplicon vectors to induce antineoplastic responses was assessed in a vaccine setting in mice with pre-existing highly malignant lymphoblastic disease. Treatment of mice with vaccine cells transgenically expressing CD70+IL2 significantly suppressed lymphoblastic cell proliferation and improved survival. Of note, when helper virus-dependent HSV-1 amplicon vectors were used for vaccine preparation, the high immunogenic potential of the vector itself, in the absence of transgenic CD70+IL2 expression, seemed to be sufficient to mediate protection comparable to the antineoplastic response achieved by expression of immunomodulatory molecules. Thus for vaccine generation in B lymphoblastic leukemia, the immunogenic potential of HSV-1 helper virus-dependent amplicon vectors does provide additional benefit to the high transduction efficiency of HSV-1-derived vectors.

Tumor vaccines--application to childhood cancer.

Currently, several clinical studies explore the therapeutic potential of tumor vaccines which are genetically modified to produce immunostimulatory molecules as a complementary approach for conventional cancer therapy. In this review the immunological basis and the preclinical design of such vaccine strategies are described with particular emphasis to acute leukemia and neuroblastoma. The role of cytokines, chemokines and costimulatory surface molecules for generation of tumor vaccines is summarized, and the advantages and disadvantages of autologous, allogenic and dendritic cell vaccines are discussed. Finally, combination-immunogens are introduced as a potent means of enhancing the anti-tumor response.

Immunodominant B-cell domains of hepatitis C virus envelope proteins E1 and E2 identified during early and late time points of infection.

BACKGROUND/AIMS: We characterized immunoreactive B-cell domains of hepatitis C virus (HCV) envelope proteins E1 and E2 by a peptide ELISA using sera of patients who were infected by the same isolate of HCV (HCV-AD78). METHODS: Fifty-four overlapping peptides which corresponded to the sequence of E1 and E2 of isolate HCV-AD78 were used to detect specific antibodies. Three groups of HCV-AD78 related sera were analyzed. Two groups were from sera obtained at early time points of infection (months 4-15) from patients who later resolved infection (group A), or who later developed chronic disease (group B). Group C sera were from later time points of chronic disease. As a control, sera of chronic HCV patients who did not have HCV-AD78 infection were also analyzed (group D). RESULTS: In group A, 25 of the 54 peptides produced OD405 above the cut-off, whereas 17 peptides produced such values in group B. Only 10 and 3 peptides yielded such values in groups C and D, respectively. The overall prevalence of antibodies against peptides was high in the early phase of infection (means of 28.7+/-14.8% and 25.9+/-14.5% in groups A and B, respectively). At later time points of chronic infection (group C), the overall prevalence was lower (mean 18.6+/-15.4%). Group D sera produced the lowest overall prevalence (mean 13.2+/-14.1%). Three peptides, covering aa271-290, aa481-500 and aa551-570, were recognized significantly more frequently (p<0.05) by group A sera than group B sera. CONCLUSIONS: We conclude that more linear epitopes of the HCV envelope are recognized with a high prevalence of antibodies, as was suggested previously. However, most B-cell domains of the HCV envelope induce a similarly high antibody response in patients who resolve infection or develop chronic disease.

The "interferon sensitivity determining region" of hepatitis C virus is a stable sequence element.

BACKGROUND/AIMS: A sequence of 40 amino acids within the nonstructural protein 5A of hepatitis C virus (HCV) has been suggested to be an interferon sensitivity determining region (ISDR). The variations in the ISDR after 12-14 years of chronic infection and the correlation between ISDR and interferon response were studied in patients who were infected by the same HCV isolate. METHODS: We determined the HCV-ISDRs of 13 chronically infected patients by direct sequencing of polymerase chain reaction products. All patients were infected by isolate HCV-AD78, but differed with respect to their sensitivity to interferon. Four patients were complete responders, two patients were non-responders, and seven showed a partial response. RESULTS: The ISDR of HCV-AD78 differed from a prototypical HCV-1b sequence in one amino acid and was therefore classified as an intermediate type. Direct sequencing of the HCV-ISDRs of the patients 12-14 years after infection, but before interferon therapy, revealed a rate of 2.2x10(-3) nucleotide substitutions per site per year, resulting in only single intermediate type amino acid exchanges. All sequences ranked with the intermediate type. Moreover, during interferon treatment no selection to a wild type ISDR was observed in five partial responders. CONCLUSIONS: Within the homogeneous patient group examined here, no correlation was found between the ISDR and the interferon response. Recent studies found only a small number of mutant type ISDRs in Europe. Additionally, our results indicate that the ISDR is a stable sequence element. This provides an explanation for the divergent data relating to the importance of the ISDR in different geographical regions.

Antibodies directed to envelope proteins of hepatitis C virus outside of hypervariable region 1.

The relatively high variability of the hepatitis C virus (HCV) envelope proteins E1 and E2 suggests that parts of these proteins other than the hypervariable region 1 (HVR1) might be involved in the induction of virus neutralizing antibodies. To test this hypothesis, two HCV proteins, pE1 and pE2 delta, were generated by in vitro translation. They represent amino acids 174-337 of E1 and 411-688 of E2, respectively, of isolate HCV-AD78; the protein pE2 delta contained no HVR1. As a control, protein pG.HVR1, which represents amino acids 384-410 of HVR1 of isolate HCV-AD78, was expressed separately. These three proteins were used in an immunoprecipitation assay to detect the presence of antiviral antibodies in sera of patients infected with the same isolate of HCV (HCV-AD78). Sera were obtained 4-8 months postinfection from patients who later resolved an acute infection or developed chronic liver disease. A high prevalence of antibodies (up to 85.7%) against pE1 and pE2 delta could be detected in both groups of patients, suggesting that these forms of the HCV envelope proteins contain B-cell epitopes. The antibody responses against proteins pE1 and pE2 delta did not differ significantly between patients with resolving or chronic infection, whereas antibodies against protein pG.HVR1 were associated with resolution of infection. Rabbit antisera raised against pE1 and pE2 delta were tested for their ability to neutralize the binding of HCV to susceptible cells in tissue cultures. The results suggested that although a few B-cell epitopes outside of HVR1 can induce virus neutralizing antibodies, these antibodies are probably not associated with the resolution of infection.

Cloning and characterization of a complete open reading frame of the hepatitis C virus genome in only two cDNA fragments.

The synthesis of long cDNA molecules encoding the complete genome of RNA viruses has recently been demonstrated; this major improvement has numerous practical applications such as construction of infectious cDNA clones or study of sequence variability at the level of a single RNA molecule. Using hepatitis C virus (HCV) as a model, we established an RT-PCR technique for amplification of cDNA fragments with a length of about 5 kb. The RT reaction was carried out with a Moloney murine leukaemia virus reverse transcriptase lacking detectable RNase H activity. For PCR reactions an enzyme mix containing Taq and Pwo DNA polymerases was used. Hot start and addition of 5% DMSO were also important to efficiently achieve long PCR products. About 10(6) HCV genome equivalents/ml in serum were needed in order to amplify the HCV genome in only two cDNA fragments covering about 98% of the complete genome. Analysis of the HCV quasi-species is also possible by this method as shown by sequencing of the hypervariable region 1 (HVR1) after cloning of cDNAs. The integrity of the long cDNA clones was proven by (1) restriction analyses, (2) partial sequencing and (3) expression of respective gene products. In vitro transcribed cDNAs were translated in rabbit reticulocyte lysate. Structural and nonstructural HCV proteins were identified by immunoprecipitation using patient serum. These results suggest that the two cDNA clones encode a complete and functional open reading frame of HCV.

Epitope mapping of antibodies directed against hypervariable region 1 in acute self-limiting and chronic infections due to hepatitis C virus.

Epitopes of hypervariable region 1 (HVR1) were mapped by enzyme-linked immunosorbent assay using follow-up sera of patients, all of whom were infected with the same isolate of hepatitis C virus (HCV). Our results suggest that (i) an early appearance (up to month 13 postinfection) of antibodies directed to the N terminus of HVR1 is associated with acute self-limiting infections of HCV and (ii) isolate-independent antibodies which are mainly directed to the C terminus of HVR1 seem to persist in chronically infected patients. The relevance of HVR1-specific antibodies for neutralization was evaluated by characterization of a rabbit serum.

Early antibody response against hypervariable region 1 is associated with acute self-limiting infections of hepatitis C virus.

Antibodies directed to hypervariable region 1 (HVR1) of hepatitis C virus (HCV) have recently been shown to neutralize the corresponding HCV isolate in vitro. We analyzed the appearance of antibodies directed to HVR1 during the course of infection in a large group of patients who have been infected by the same isolate of a HCV contaminated anti-D immunoglobulin (HCV-AD78). An enzyme-linked immunosorbent assay (ELISA) was established using a synthetic peptide to detect antibodies against the main HVR1 variant of HCV-AD78. 207 sera obtained at different time points post infection (p.i.) of 51 patients having either acute self-limiting (n = 28) or chronic infection (n = 23) were studied. Antibodies directed to HVR1 were found at least at one time point during the infection course in 15 of 28 patients (53%) having acute self-limiting infections and in 17 of 23 patients (74%) with chronic disease. The time of appearance of anti-HVR1 was significantly different between these two patient groups (P < .025) although appearance and titers of other HCV-specific antibodies were found to be similar at early time points p.i. In acute self-limiting infections 9 of 21 sera (43%) of respective patients with sera available within the first 6 months p.i. were anti-HVR1 positive. The highest prevalence of anti-HVR1 in this group of patients was within month 6 to 12 p.i. (64%). None of the sera available after 24 months p.i. had such antibodies. In contrast, only 2 of 15 sera (13%) of chronically infected patients with respective time points of sera were anti-HVR1 positive within the first 6 months p.i. and only 5 of 18 sera (28%) were positive within month 7 to 12 p.i. Seven patients with chronic HCV infections showed at least two consecutive anti-HVR1 negative early time points up to month 18 p.i. Prevalence of anti-HVR1 after 24 months p.i. was high (84%) in this group of patients and most of the patients maintained high levels of anti-HVR1 for up to 17 years p.i. Our findings suggest clearance of virus by respective neutralizing antibodies resulting in a self-limiting infection and may have implications for prognosis of the disease and also for any future vaccine development.

Characterization of antibody response to hepatitis C virus protein E2 and significance of hypervariable region 1-specific antibodies in viral neutralization.

Antibodies directed against hypervariable region 1 (HVR1) within the viral glycoprotein E2 of hepatitis C virus (HCV) are postulated to neutralize virus. An in vitro infection/binding assay of human fibroblast cells was established in order to study neutralization of HCV. Occurrence of mutations in the nucleotide sequence of HVR1 as compared to the inoculum after infection of human fibroblasts suggested replication of HCV in these cells. The significance of HVR1-specific antibodies in sera of patients who were infected in a single-source outbreak by an HCV contaminated anti-D immunoglobulin (IgG) preparation was studied. Using immunoprecipitation and ELISA, HVR1-specific antibodies could be detected in most of the sera obtained early (< or = 1 year p.i.) and late (up to 14 years p.i.) in single patients. Further characterization of the HVR1-specific antibodies in patient sera by attachment studies of HCV to the human fibroblasts suggested that HVR1-specific antibodies in sera obtained early p.i. can neutralize virus of the anti-D IgG preparation.

Antibodies in human sera specific to hypervariable region 1 of hepatitis C virus can block viral attachment.

It has been postulated that antibodies specific to the hypervariable region 1 (HVR1) within the putative envelop protein E2 of hepatitis C virus (HCV) can neutralize virus. We studied such antibodies in sera of patients who were infected in a single-source outbreak by a contaminated anti-D immunoglobulin preparation (HCV-AD78). The nucleotide sequences of cDNAs encoding HVR1 of HCV-AD78 were determined. The four major variants (HVR1.A, B, C, and D) were expressed as fusion proteins in Escherichia coli. Sixty-seven percent of sera contained antibodies to HVR1.A. Sera unrelated to infection of the outbreak also recognized HVR1.A but to a lesser extent (15%), suggesting that not all HVR1-specific antibodies are absolutely isolate-specific. Antibodies directed against individual variants of HVR1 were found in sera obtained early postinfection (p.i.) (< or = 1 year) but also in sera obtained several years later. An in vitro binding assay of HCV to tissue culture cells was employed to further characterize these sera. Five of seven sera that were obtained early p.i. prevented binding of HCV to cells. Preincubation of such sera with HVR1-specific fusion proteins restored binding of HCV to cells in four of five sera. These findings suggest that the majority of neutralizing antibodies are directed against HVR1.

The poliovirus receptor: identification of domains and amino acid residues critical for virus binding.

The N-terminal domain 1 of the human poliovirus receptor (hPVR), a three-domain, immunoglobulin-like molecule, was previously shown to be necessary and sufficient to confer poliovirus (PV) susceptibility to mouse cells. However, studies with truncated versions of hPVR suggested that the C-terminal hPVR domains may contribute to receptor function. We describe sets of hybrid receptors, constructed between hPVR and hICAM-1 (human intercellular adhesion molecule-1) that were tested in mouse cells for hPVR functionally. Whereas the context in which hPVR is expressed is of minor importance, all three domains of hPVR are required to reach wild-type function. Single and multiple amino acid exchanges were introduced into the first hPVR domain in order to localize regions that were involved in virus-receptor interactions. The mutations were analyzed for their ability to bind PV1 (Mahoney) or monoclonal antibodies as well as their ability to support viral replication in either the hPVR alpha or hybrid hPVR-hICAM-1 receptor context. When placed into a model of the V domain of hPVR, the effect of the mutations indicated that the C'C"D as well as the DE region harbored amino acids that contacted the PV1(M) surface in the process of receptor-virus complex formation. The binding of the virus to the receptor and subsequent uptake into the cells were linked; no hPVR mutants were observed that bound the virus but blocked infection. N-glycosylation of the four sites in domains 1 and 2 is not required for hPVR function, but glycosylation in domain 1 has a greater effect on receptor function than that of domain 2.

Typing of hepatitis C virus isolates by DNA enzyme immunoassay.

Recently, at least six types of hepatitis C viruses (HCV) have been identified. Different types of HCV appear to possess different pathogenic properties and a different sensitivity to interferon treatment. Typing of HCV isolates may therefore be an important diagnostic procedure. We report on a new method for identification of HCV types 1a, 1b, 2a, 2b and 3a which are most prevalent in Europe, North America and Japan. The assay is based on a combination of two well established techniques, the polymerase chain reaction (PCR) and DNA enzyme immunoassay (DEIA). In the first step of the method a cDNA of about 250 bp corresponding to the HCV core-region is amplified by nested PCR. The target cDNA is then hybridized to type-specific oligonucleotides fixed to a solid phase through an avidin-biotin bridge. The formed hybrids are detected by a standard ELISA using monoclonal antibodies reacting with double-stranded DNA. Typically, signal-to-noise (S/N) ratios between 18.2 and 48.6 could be observed when different HCV types/subtypes were analyzed by this method. The test was evaluated using cloned HCV cDNAs of known types and by sequence determination of some of the typed cDNAs. Typing of 115 isolates from Germany, Russia and Turkey revealed that subtype 1b (59-100%) and 1a (24-32%) are most prevalent in these countries.

N glycosylation of the virus binding domain is not essential for function of the human poliovirus receptor.

The human poliovirus receptor (hPVR) is a glycoprotein with three immunoglobulin-like extracellular domains, of which the N-terminal domain (V-type domain) is necessary and sufficient for virus binding and uptake. The effect of N glycosylation of the V domain of hPVR on binding and entry of poliovirus was studied. Stable mouse L-cell lines were generated that express PVR-specific cDNA. One of the cell lines expressed a mutant of hPVR, in which both asparagine residues of the two N-glycosylation sites of the V domain were changed to aspartate (N105D) and serine (N120S), respectively. In the second mutant cell line, the portion of the cDNA encoding the V domain of hPVR was substituted by the homologous sequence of the recently isolated PVR cDNA from monkey cells. This V domain naturally lacks both N glycosylation sites and encodes D105 and S120 at the respective positions of the open reading frame. Absence of N glycosylation at these sites was demonstrated by in vitro translation of the two mutant coding sequences in the presence of microsomal membranes. Both PVR mutant cell lines were capable of poliovirus binding and replication. However, binding of anti-PVR monoclonal antibody D171 and protection from viral replication by this antibody were observed only with the glycosylation mutant carrying the human V domain. In contrast, infection of the cell line expressing the monkey-human hybrid receptor was not blocked even though monkey cells are fully protected by monoclonal antibody D171. The data suggest that N glycosylation of the V domain of hPVR is not essential for viral replication in human tissues and that differential glycosylation of hPVR at these sites is likely not a determinant of viral tissue tropism. Furthermore, the virus binding site and the epitope recognized by monoclonal antibody D171 do not appear to overlap.

The soluble form of two N-terminal domains of the poliovirus receptor is sufficient for blocking viral infection.

By means of deleting a C-terminal portion of the open reading frame of the poliovirus receptor cDNA, and by vaccinia virus-mediated overexpression we have produced a protein corresponding to the first two N-terminal Ig-like domains of the poliovirus receptor. This protein that lacked the third Ig-like domain, the transmembrane region and most of the intracellular C-terminal tail was detected in the medium of vaccinia virus infected cells. The properties of the truncated PVR cDNA were further characterized by in vitro translation and modification. The molecular weight of the unmodified protein was found to be 27 kDa; translation in the presence of dog pancreas microsomes led to an increase in molecular weights which we attribute to N-glycosylation. Upon incubation with poliovirus at 37 degrees C, the vaccinia-virus generated protein specifically reduced infectivity of poliovirus. Sucrose gradients of poliovirus particles derived after incubation with the protein showed the induction of a slower sedimenting particle (135S). Our experiments suggest that the two N-terminal domains of the poliovirus receptor in soluble form are sufficient for the conversion of poliovirus into a non-infectious particle.

A chimeric poliovirus/CD4 receptor confers susceptibility to poliovirus on mouse cells.

The human poliovirus receptor consists of three extracellular immunoglobulinlike domains, a transmembrane domain, and an intracytoplasmic domain. The amino-terminal variable-type domain (V domain) of the human poliovirus receptor is necessary and sufficient for its function as a viral receptor (H.-C. Selinka, A. Zibert, and E. Wimmer, Proc. Natl. Acad. Sci. USA 88:3598-3602, 1991). In this paper, data are presented showing that transfer of the putative poliovirus receptor-binding domain to a truncated receptor for the human immunodeficiency virus results in a functional receptor for poliovirus. After expression in mouse cells, this chimeric protein confers susceptibility to poliovirus. Thus, unlike human immunodeficiency virus, poliovirus can enter mouse cells by way of a truncated CD4 receptor if the specific binding domain for poliovirus is provided.

Vaccinia virus-mediated expression and identification of the human poliovirus receptor.

We have used cDNA encoding the cellular receptor for poliovirus (PVR) to prepare polyclonal antisera against beta-galactosidase PVR fusion proteins. One of these antisera allowed identification of a glycoprotein doublet band of about 67 kDa in membrane preparations of HeLa cells and in a PVR cosmid-bearing mouse cell line. In vitro translation of PVR-specific transcripts gave rise to a protein of 46 kDa; the product had a molecular weight of 67 kDa when microsomal membranes were added to the cell-free extract. Overexpression of PVR cDNA in mouse L-cells by means of a recombinant vaccinia virus led to the synthesis of a glycoprotein having a molecular weight identical to that of the glycosylated in vitro product. The vaccinia virus-mediated protein was also recognized by a monoclonal antibody that blocks poliovirus infection. Its biological activity was demonstrated by poliovirus binding and infectivity assays. The data show that PVR is a glycoprotein of 67 kDa and that this protein is sufficient to confer poliovirus susceptibility to mouse cells.