Your search keyword '"Lahser FC"' showing total 4 results

1. Conserved C-terminal threonine of hepatitis C virus NS3 regulates autoproteolysis and prevents product inhibition.

Author

Wang W, Lahser FC, Yi M, Wright-Minogue J, Xia E, Weber PC, Lemon SM, and Malcolm BA

Subjects

Hepacivirus genetics, Humans, Mutation, Polyproteins metabolism, Protein Biosynthesis, Replicon, Threonine chemistry, Transcription, Genetic, Transfection, Tumor Cells, Cultured, Virus Replication, Gene Expression Regulation, Viral, Hepacivirus metabolism, Viral Nonstructural Proteins chemistry, Viral Nonstructural Proteins metabolism

Abstract

Inspection of over 250 hepatitis C virus (HCV) genome sequences shows that a threonine is strictly conserved at the P1 position in the NS3-NS4A (NS3-4A) autoproteolysis junction, while a cysteine is maintained as the P1 residue in all of the putative trans cleavage sites (NS4A-4B, NS4B-5A, and NS5A-5B). To understand why T631 is conserved at the NS3-4A junction of HCV, a series of in vitro transcription-translation studies were carried out using wild-type and mutant (T631C) NS3-4A constructs bearing native, truncated, and mutant NS4A segments. The autocleavage of the wild-type junction was found to be dependent on the presence of the central cofactor domain of NS4A (residues 21 to 34). In contrast, all NS3-4A T631C mutant proteins underwent self-cleavage even in the absence of the cofactor. Subgenomic replicons derived from the Con1 strain of HCV and bearing the T631C mutation showed reduced levels of colony formation in transfection studies. Similarly, replicons derived from a second genotype 1b virus, HCV-N, demonstrated a comparable reduction in replication efficiency in transient-transfection assays. These data suggest that the threonine is conserved at position 631 because it serves two functions: (i) to slow processing at the NS3-4A cleavage site, ensuring proper intercalation of the NS4A cofactor with NS3 prior to polyprotein scission, and (ii) to prevent subsequent product inhibition by the NS3 C terminus.

Published

2004

2. Genetic analysis of a poliovirus/hepatitis C virus (HCV) chimera: interaction between the poliovirus cloverleaf and a sequence in the HCV 5' nontranslated region results in a replication phenotype.

Author

Zhao WD, Lahser FC, and Wimmer E

Subjects

HeLa Cells, Hepacivirus physiology, Humans, Nucleic Acid Conformation, Phenotype, Recombination, Genetic, 5' Untranslated Regions, Hepacivirus genetics, Poliovirus genetics, Virus Replication

Abstract

Internal ribosomal entry sites (IRESs) can function in foreign viral genomes or in artificial dicistronic mRNAs. We describe an interaction between the wild-type hepatitis C virus (HCV)-specific sequence and the poliovirus (PV) 5'-terminal cloverleaf in a PV/HCV chimeric virus (containing the HCV IRES), resulting in a replication phenotype. Either a point mutation at nucleotide (nt) 29 or a deletion up to nt 40 in the HCV 5' nontranslated region relieved the replication block, yielding PV/HCV variants replicating to high titers. Fortuitous yet crippling interactions between an IRES and surrounding heterologous RNA must be considered when IRES-based dicistronic expression vectors are being constructed.

Published

2000

3. Poliovirus/Hepatitis C virus (internal ribosomal entry site-core) chimeric viruses: improved growth properties through modification of a proteolytic cleavage site and requirement for core RNA sequences but not for core-related polypeptides.

Author

Zhao WD, Wimmer E, and Lahser FC

Subjects

3C Viral Proteases, Binding Sites, Blotting, Western, Cysteine Endopeptidases genetics, Frameshift Mutation, HeLa Cells, Hepacivirus enzymology, Hepacivirus genetics, Hepacivirus growth & development, Humans, Peptides genetics, Peptides metabolism, Poliovirus enzymology, Poliovirus genetics, Poliovirus growth & development, Protein Biosynthesis, Protein Sorting Signals, Viral Core Proteins biosynthesis, Viral Core Proteins genetics, Virus Replication, Cysteine Endopeptidases metabolism, Hepacivirus physiology, Poliovirus physiology, RNA, Viral, Viral Core Proteins metabolism, Viral Proteins

Abstract

H.-H. Lu and E. Wimmer (Proc. Natl. Acad. Sci. USA 93:1412-1417, 1996) have demonstrated that the internal ribosomal entry site (IRES) of poliovirus (PV) can be functionally replaced by the related genetic element from hepatitis C virus (HCV). One important finding of this study was that open reading frame sequences 3' of the initiating AUG, corresponding to the open reading frame of the HCV core polypeptide, are required to create a viable chimeric virus. This made necessary the inclusion of a PV 3C protease (3Cpro) cleavage site for proper polyprotein processing to create the authentic N terminus of the PV capsid precursor. Chimeric PV/HCV (P/H) viruses, however, grew poorly relative to PV. The goal of this study was to determine the molecular basis of impaired replication and enhance the growth properties of this chimeric virus. Genetic modifications leading to a different proteinase (PV 2Apro) cleavage site between the HCV core sequence and the PV polyprotein (P/H701-2A) proved far superior with respect to viral protein expression, core-PV fusion polyprotein processing, plaque phenotype, and viral titer than the original prototype PV/HCV chimera containing the PV 3Cpro-specific cleavage site (P/H701). We have used this new virus model to answer two questions concerning the role of the HCV core protein in P/H chimeric viral proliferation. First, a derivative of P/H701-2A with frameshifts in the core-encoding sequence was used to demonstrate that production of the core protein was not necessary for the translation and replication of the P/H chimera. Second, a viral construct with a C-terminal truncation of 23 amino acids of the core gene was used to show that a signal sequence for signal peptidase processing, when present in the viral construct, is detrimental to P/H virus growth. The novel P/H chimera described here are suitable models for analyzing the function(s) of the HCV elements by genetic analyses in vivo and for antiviral drug discovery.

Published

1999

4. Contributions of the brome mosaic virus RNA-3 3'-nontranslated region to replication and translation.

Author

Lahser FC, Marsh LE, and Hall TC

Subjects

Base Sequence, Capsid biosynthesis, Hordeum microbiology, Molecular Sequence Data, Mutagenesis, Nucleic Acid Conformation, Protoplasts microbiology, RNA, RNA, Messenger metabolism, Sequence Deletion, Transcription, Genetic, Transfection, Virus Replication, Mosaic Viruses genetics, Mosaic Viruses growth & development, Protein Biosynthesis, RNA, Viral genetics, Regulatory Sequences, Nucleic Acid genetics

Abstract

Sequences upstream of the 3'-terminal tRNA-like structure of brome mosaic virus RNAs have been predicted to fold into several stem-loop and pseudoknot structures. To elucidate the functional role of this upstream region, a series of deletions was made in cDNA clones of RNA-3, a genomic component not required for replication. These deletion mutants were transcribed in vitro and cotransfected with RNA-1 and RNA-2 into barley protoplasts. Deletion of single stem-loop structures gave progeny retaining near-wild-type accumulation levels. Constructions representing deletion of two or three stem-loops substantially lowered the accumulation of progeny RNA-3 relative to wild-type levels. RNA-3 mutants bearing deletions of longer sequences or of the entire region (delta PsKs RNA-3) replicated poorly, yielding no detectable RNA-3 or RNA-4 progeny. Levels of RNA-1 and RNA-2, in the presence of a mutant RNA-3, were found to increase relative to the accumulation observed in a complete wild-type transfection. The stability of delta PsKs RNA-3 in protoplasts was somewhat lower than that of wild-type RNA during the first 3 h postinoculation. Little difference in translatability in vitro of wild-type and RNA-3 constructs bearing deletions within the stem-loop region was observed, and Western immunoblot analysis of viral coat protein produced in transfected protoplasts showed that protein accumulation paralleled the amount of RNA-4 message produced from the various sequences evaluated. These results indicate that the RNA-3 pseudoknot region plays a minor role in translational control but contributes substantially to the overall replication of the brome mosaic virus genome.

Published

1993