Evaluation of hepatitis C virus envelope proteins expressed in E. coli and insect cells for use as tools for antibody screening.

BACKGROUND/METHODS: The two envelope proteins of hepatitis C virus, E1 and E2, were expressed in E. coli and, as secretory proteins, in Sf9 insect cells using recombinant baculoviruses. Co-infection of insect cells with E1 and E2-recombinant baculoviruses was performed, which has been shown to result in formation of E1-E2 dimers. All envelope proteins were purified by Ni2+-NTA chromatography and used for screening of serum samples in a HCV EIA assay. Serum samples of normal blood donors, chronically HCV-infected patients, a mixed titer panel and several seroconversion panels were screened and compared to test results with Cobas Core Anti-HCV EIA. RESULTS: Screening of the sera of chronically HCV-infected patients (100% positive in Cobas Core Anti-HCV EIA) revealed 10-40% anti-E1 positive sera using different Sf9-expressed, glycosylated proteins and 93% using E. coli-expressed, non-glycosylated E1 protein. When the same sera were tested with different E2 proteins expressed in Sf9 cells and in E. coli, about 70-73% showed anti-E2 reactivity. When the proteins from Sf9 cells co-infected with E1- and E2-recombinant baculoviruses were tested, 70-80% of the same sera showed anti-envelope reactivity. CONCLUSIONS: Testing of these patient antisera, and those from the well-characterized mixed titer panel BBI-PHV203, showed that recombinant E1 expressed in E. coli and co-expressed E1 and E2 proteins from Sf9 cells could be used as additional tools for anti-HCV antibody screening.

Purification and in vitro-phospholabeling of secretory envelope proteins E1 and E2 of hepatitis C virus expressed in insect cells.

The putative envelope glycoproteins of hepatitis C virus (HCV), E1 and E2, were expressed as recombinant, secretory proteins in Sf9 insect cells through infection with recombinant baculoviruses. The influenza virus hemagglutinin signal sequence (HASS) was inserted upstream of the HCV-cDNAs in order to effect secretion. Furthermore, a hexa-histidine tag for purification on a Ni(2+)-nitrilotriacetic acid (Ni(2+)-NTA) column and a protein kinase A (PKA) recognition sequence for in vitro-phospholabeling were fused upstream of the HCV-cDNA. E1- and E2 proteins lacking their carboxy-terminal, hydrophobic sequence were produced by baculovirus-infected insect cells in bioreactors of 23 1. The medium was concentrated and proteins were purified under native conditions on Ni(2+)-NTA columns. Purified proteins could be phospholabeled in vitro using the catalytic subunit of protein kinase. A isolated from bovine heart and gamma-[32P]ATP. Labeled E1 and E2 proteins expressed in insect cells could be immunoprecipitated with sera from HCV-infected patients. Co-expression of these E1 and E2 proteins led to the formation of E1-E2 complexes within the insect cell and to secretion of these complexes into the medium.

Hepatitis C virus core protein: carboxy-terminal boundaries of two processed species suggest cleavage by a signal peptide peptidase.

The expression and processing of hepatitis C virus core protein was analyzed. Two protein bands, 21 kDa (P21), corresponding to the full-length core, and 19 kDa (P19), were detected as major products when core protein was expressed in the standard rabbit reticulocyte lysate system or in Sf9 insect cells. Core proteins with amino-terminal hexa-histidine tags were expressed which allowed the purification of the hexa-histidine P19 core with NI(2+)-NTA columns. With the help of mass spectrometry, the molecular weight of hexa-histidine-P19 was analyzed and its carboxy-terminus could be calculated. Fusion proteins of truncated core/core-E1 species fused to mouse dihydrofolate reductase (mDHFR) showed cleavage in the expected region. Cleavage sites could be determined by amino-terminal protein sequencing of the DHFR-fusion partner. Our data show that there are not one but two core products with an apparent molecular weight of about 19 kDa, ending either at amino acid leucine 179 or leucine 182, respectively. These cleavages in the hydrophobic, carboxy-terminal region of HCV core suggest processing by (a) recently proposed eucaryotic signal peptide peptidase(s) (F. Lyko et al. (1995) J. Biol. Chem. 270, 19873-19878). Furthermore, our results demonstrate that cleavage at these sites and the formation of the P19 species does not require previous processing at the signalase site (position 191/192) of the HCV-polyprotein.

Effect of 4-quinolones and novobiocin on calf thymus DNA polymerase alpha primase complex, topoisomerases I and II, and growth of mammalian lymphoblasts.

The influence of ciprofloxacin, nalidixic acid, norfloxacin, novobiocin, and ofloxacin on elements of eucaryotic DNA replication was investigated in vitro. Each of the 4-quinolones, when present in amounts of more than 100 micrograms/ml, reversibly inhibited the DNA synthesis performed by the 95 DNA polymerase alpha primase complex from calf thymus. Novobiocin at 500 micrograms/ml or at higher concentrations irreversibly inactivated DNA polymerase alpha primase complex. The accuracy of in vitro DNA synthesis in the absence of repair mechanisms was determined from amber-revertant assays with phi X174am16(+) DNA as template. The antimicrobial agents did not significantly increase the frequencies of base pairing mismatches during the course of replication, indicating that the basal mutation rate is not affected by novobiocin and the 4-quinolones. The Ki values of 50% inhibition of DNA topoisomerases from calf thymus by ciprofloxacin, norfloxacin, novobiocin, nalidixic acid, and ofloxacin were 300, 400, 1,000 or more, 1,000 or more, and 1,500 or more micrograms/ml, respectively, in the case of topoisomerase I, and the Ki values were 150, 300, 500, 1,000, and 1,300 micrograms/ml, respectively, in the case of topoisomerase II. The procaryotic topoisomerase II is approximately 100-fold more sensitive to inhibition by ciprofloxacin, norfloxacin, and ofloxacin than is its eucaryotic counterpart. Growth curves of lymphoblasts were recorded in the presence of ofloxacin and ciprofloxacin. Neither 1 nor 10 micrograms of ciprofloxacin or of ofloxacin per ml affected cell proliferation. Ofloxacin and ciprofloxacin at 100 micrograms/ml inhibited cell growth; 1,000 micrograms/ml led to cell death. No correlation exists between the antimicrobial and cytotoxic activities of the 4-quinolones.