Auxotrophy-Based Detection of Hyperornithinemia in Mouse Blood and Urine

Abstract Gyrate atrophy of the choroid and retina (GACR) is a hereditary form of progressive blindness caused by homozygosity for loss-of-function mutations in the ornithine aminotransferase gene (Oat). The high levels of circulating ornithine that lead to ophthalmic symptoms in young adults are also displayed by 2 ornithine aminotransferase (OAT)-deficient mouse models of GACR. Here, we have developed an inexpensive and quantitative bacteria-based test for detecting hyperornithinemia in blood or urine samples from these mutant mice, a test that we suggest could be used to facilitate the identification and treatment of OAT-deficient humans before the onset of visual impairment.

A novel immunocompetent rat model of HCV infection and hepatitis.

BACKGROUND & AIMS: Hepatitis C virus (HCV) infects millions of people worldwide. Therapy is limited, and treatment does not produce a sustained response in the majority of patients. Development of new agents has been hampered by the lack of a convenient animal model. The aim of this study was to determine whether an immunocompetent rat, tolerized and transplanted with a human hepatoma cell line (Huh 7 cells), could be used to sustain an HCV infection. METHODS: Fetal rats were tolerized in utero with 10(5) Huh 7 cells. One day after birth, rats were transplanted with 5 x 10(6) Huh 7 cells and, a week later, inoculated with HCV, genotype 1. RESULTS: In tolerized, transplanted, and HCV-infected rats, Huh 7 cells were found in the liver, and HCV viral replication was detected by the presence of negative strand HCV RNA. HCV levels in serum were measured at 11,000 copies/mL at week 4, peaked at 22,500 copies/mL by week 12. In tolerized, transplanted, inoculated rats, but not controls, serum alanine aminotransferase (ALT) values increased to 60 IU/L by week 4 and reached a peak of approximately 120 IU/L by week 13. Histology showed foci of mononuclear infiltrates in portal and central regions. CONCLUSIONS: HCV-inoculated immunocompetent rats tolerized and transplanted with Huh 7 cells support HCV gene expression, viral replication, and develop biochemical and histologic evidence of hepatitis.

Conjugation of an antisense oligodeoxynucleotide to ribonuclease h results in sequence-specific cleavage and intracellular inhibition of HCV gene expression.

A recombinant E. coli ribonuclease H (RNase H) was chemically coupled to an antisense oligodeoxynucleotide (ODN) against the 5'-noncoding region (5'-NCR) of the hepatitis C virus. Purity of the conjugates was confirmed by sodium deodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) as a band corresponding to approximately 23 kDa. Conjugate function was tested by the cleavage of a HCV RNA transcript including the 5'-NCR and core region and showed HCV sequence-specific cleavage by the appearance of an expected approximately 1000 nt fragment of RNA. Cleavage was not seen by RNase H alone, or ODN alone. Delivery studies using (32)P- and (125)I-labeling showed that while RNAse H failed to enter cells, the conjugate was efficiently taken into the cells. To assess intracellular effects, a cell line, Huh-7/CMV-NCRCDeltaluc, which expresses HCV mRNA (nt 1-585) fused to a marker gene, was transfected with the conjugate. Reporter gene expression was suppressed by 51.2% with the conjugate compared to only 39.7% by ODN alone, 35.8% by a mixture of RNase H plus ODN, and not at all by RNase H alone. In conclusion, the RNase H-ODN conjugate effectively cleaved an HCV transcript in vitro and inhibited expression of an HCV-marker fusion construct in a liver-derived cell line.

Secondary structure and hybridization accessibility of hepatitis C virus 3'-terminal sequences.

The 3'-terminal sequences of hepatitis C virus (HCV) positive- and negative-strand RNAs contribute cis-acting functions essential for viral replication. The secondary structure and protein-binding properties of these highly conserved regions are of interest not only for the further elucidation of HCV molecular biology, but also for the design of antisense therapeutic constructs. The RNA structure of the positive-strand 3' untranslated region has been shown previously to influence binding by various host and viral proteins and is thus thought to promote HCV RNA synthesis and genome stability. Recent studies have attributed analogous functions to the negative-strand 3' terminus. We evaluated the HCV negative-strand secondary structure by enzymatic probing with single-strand-specific RNases and thermodynamic modeling of RNA folding. The accessibility of both 3'-terminal sequences to hybridization by antisense constructs was evaluated by RNase H cleavage mapping in the presence of combinatorial oligodeoxynucleotide libraries. The mapping results facilitated identification of antisense oligodeoxynucleotides and a 10-23 deoxyribozyme active against the positive-strand 3'-X region RNA in vitro.

A DNA delivery system containing listeriolysin O results in enhanced hepatocyte-directed gene expression.

AIM:To determine whether incorporation of the pH dependent bacterial toxin listeriolysin O (LLO) into the DNA carrier system could increase the endosomal escape of internalized DNA and result gene expression.METHODS:A multi component delivery system was prepared consisting of asialoglycoprotein (ASG), poly L-lysine(PL), and LLO.Two marker genes, luciferase and beta galactosidase in plasmids were complexed and administered in vitro to Huh7(ASG receptor (+) and SK Hep1(ASG receptor (-) cells. Purity, hemolytic activity, gene expression, specificity, and toxicity were evaluated.RESULTS:An LLO containing conjugate retained cell target-ing specificity and membranolytic activity. In ASG receptor (+) cells,luciferase gene expression was enhanced by more than 7 fold over that of conjugates without the incorporation of listeriolysin O. No significant expression occurred in ASG receptor (-) cells. Enhancement of betagalactosidase gene expression was less, but still significantly increased over controls. There was no detectable toxicity at concentrations shown to be effective in transfection studies.CONCLUSIONS:ASOR-PL can be coupled to LLO using disulfide bonds, and successfully target and increase the gene expression of foreign DNA.