Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.2.1.23 (beta-galactosidase)
 14,648 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Monoclonal antibodies were prepared against the avian myeloblastosis virus reverse transcriptase. These monoclonal antibodies specifically immunoprecipitated the alpha and beta subunits of the reverse transcriptase molecule, as well as the Pr180gag-pol precursor protein present in virus-infected cells. In addition, these monoclonal antibodies inhibited the DNA polymerase activity associated with the reverse transcriptase molecule but not the RNase H activity. The monoclonal antibody preparations were specific for the amino-terminal portion of the protein, as determined by the immunoprecipitation of a reverse transcriptase-beta-galactosidase fusion protein produced in Escherichia coli by molecular cloning procedures.
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PMID:Production and characterization of monoclonal antibodies against avian retrovirus reverse transcriptase. 618 37

A 1.6-kilobase-pair DNA fragment derived from the Escherichia coli chromosome was analyzed by Tn3 transposon insertion and deletion mapping to locate a mutator gene, dnaQ (mutD), and the rnh gene that codes for RNase H. When a strong promoter, PL of lambda phage, was placed at the right- and left-side of the cloned DNA fragment, the dnaQ protein and RNase H, respectively were overproduced. These results suggested that the two genes are transcribed in opposite directions and that their promoters are located in a narrow region between the genes. Nucleotide sequence analysis confirmed this and further revealed that transcriptional and translational initiation signals for the two genes overlap. From the sequence data it was deduced that the dnaQ protein and RNase H consist of 243 and 155 triplets and have molecular weights of 27,500 and 17,500, respectively. dnaQ81 amber mutant showed two codon alterations, CAG(glutamine-195) leads to TAG(amber) and ACA(threonine-193) leads to ATA(isoleucine). The dnaQ-lacZ and the rnh-lacZ fused genes were constructed and hybrid proteins with beta-galactosidase activity were produced. From beta-galactosidase levels it was estimated that the promoter for dnaQ is 5 times more active than that for rnh.
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PMID:Structure and expression of the dnaQ mutator and the RNase H genes of Escherichia coli: overlap of the promoter regions. 631 47

Molecular genetic studies have revealed that the human hepatitis B viral (HBV) Pol protein, a polypeptide of about 94 kDa, contains four domains. These are the 5'-terminal protein, spacer, RNA reverse transcriptase/DNA polymerase, and RNase H, respectively, from the amino (N) to carboxy (C) terminus. No evidence indicates as yet the involvement of a specific protease in cleaving the Pol protein or the presence of protease-cutting sites in the Pol protein. An in vitro-translated Pol protein was shown to be cleaved by purified thrombin but not in the presence of its inhibitor, hirudin. Two thrombin-cutting sites, spanning 194 amino acids, were then deduced by thrombin digestion of Pol protein with various lengths of C-terminal deletion. These two putative cutting sites, one located in the spacer region and the other in the beginning of the polymerase region, were found to be conserved at similar positions in the Pol protein of all hepadnaviruses. By using a novel method called the LacZ localization assay (LLA), it was demonstrated that a tripartite fusion protein containing the nucleus localization sequence (NLS) of SV40 large T Ag, the putative thrombin cutting sequence (Ile-Arg-Ile-Pro-Arg320-Thr) of HBV Pol protein and the full length beta-galactosidase of E. coli, exhibited a lower percentage (approximately 53%) of targeting into the nucleus of transfected hepatoma cells when compared with a similar tripartite protein containing a single mutation (Arg320 residue into Trp320) of HBV Pol protein (approximately 78%) or with a bipartite protein of SV40 NLS-beta-galactosidase (approximately 90%). These results indicate that the putative thrombin-cutting site in the spacer region of HBV Pol protein could be cleaved by a cellular protease resulting in the separation of NLS sequence from the beta-galactosidase and rendering a lower frequency of X-gal staining in the nucleus.
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PMID:Demonstration of the presence of protease-cutting site in the spacer of hepatitis B viral Pol protein. 773 Apr 38

Error-prone DNA synthesis by retroviral reverse transcriptases (RTs) is a major contributor to variation in retroviral populations. Structural features of retroviral RTs that are important for accuracy of DNA synthesis in vivo are not known. To identify structural elements of murine leukemia virus (MLV) RT important for fidelity in vivo, we developed a D17-based encapsidating cell line (ANGIE P) which is designed to express the amphotropic MLV envelope. ANGIE P also contains an MLV-based retroviral vector (GA-1) which encodes a wild-type bacterial beta-galactosidase gene (lacZ) and a neomycin phosphotransferase gene. Transfection of ANGIE P cells with wild-type or mutated MLV gag-pol expression constructs generated GA-1 virus that was able to undergo only one cycle of viral replication upon infection of D17 cells. The infected D17 cell clones were characterized by staining with 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-Gal), and the frequencies of inactivating mutations in lacZ were quantified. Three mutations in the YVDD motif (V223M, V223S, and V223A) and two mutations in the RNase H domain (S526A and R657S) exhibited frequencies of lacZ inactivation 1.2- to 2.3-fold higher than that for the wild-type MLV RT (P < 0.005). Two mutations (V223I and Y598V) did not affect the frequency of lacZ inactivation. These results establish a sensitive in vivo assay for identification of structural determinants important for accuracy of DNA synthesis and indicate that several structural determinants may have an effect on the in vivo fidelity of MLV RT.
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PMID:Development of an in vivo assay to identify structural determinants in murine leukemia virus reverse transcriptase important for fidelity. 1059 Jan 19

Using in vivo fidelity assays in which bacterial beta-galactosidase or green fluorescent protein genes served as reporters of mutations, we have identified a murine leukemia virus (MLV) RNase H mutant (Y586F) that exhibited an increase in the retroviral mutation rate approximately 5-fold in a single replication cycle. DNA-sequencing analysis indicated that the Y586F mutation increased the frequency of substitution mutations 17-fold within 18 nt of adenine-thymine tracts (AAAA, TTTT, or AATT), which are known to induce DNA bending. Sequence alignments indicate that MLV Y586 is equivalent to HIV-1 Y501, a component of the recently described RNase H primer grip domain, which contacts and positions the DNA primer strand near the RNase H active site. The results suggest that wild-type reverse transcriptase (RT) facilitates a specific conformation of the template-primer duplex at the polymerase active site that is important for accuracy of DNA synthesis; when an adenine-thymine tract is within 18 nt of the polymerase active site, the Y586F mutant RT cannot facilitate this specific template-primer conformation, leading to an increase in the frequency of substitution mutations. These findings indicate that the RNase H primer grip can affect the template-primer conformation at the polymerase active site and that the MLV Y586 residue and template-primer conformation are important determinants of RT fidelity.
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PMID:Y586F mutation in murine leukemia virus reverse transcriptase decreases fidelity of DNA synthesis in regions associated with adenine-thymine tracts. 1211 2

The effect of reverse transcriptase (RT) catalyzed mutations on continued extension of the nascent DNA chain was investigated. A system using the alpha-lac gene of beta-galactosidase as template and two sets of conditions was used. In one, RT was allowed to reassociate with the primer-template after falling off, while in a second RT was sequestered after dissociating. In the first condition, subsequent extension of errors that may have initially caused enzyme dissociation can occur. In the second, such errors would not be extended. Fully extended products were assayed by alpha-complementation to assess mutation frequency. A lower frequency in the latter scenario implies that some errors caused the polymerase to dissociate. Allowing only a single binding event lowered the mutation frequency of the products by about 1/2 suggesting that approximately 1 in 2 errors terminated synthesis. In other experiments, when added to a primer-template with a terminal mismatch at the 3' end, RT dissociated from the template about 50-90% of the time (depending on mismatch type) rather than extending. Running start reactions indicated that extension was more likely if an actively synthesizing RT made the mutation. RT RNase H cleavage analysis showed that 3' mismatches weakened the association of RT with the primer-terminus. Taken together, these results suggest that an actively synthesizing RT enzyme that has just made a mistake is likely bound in a configuration that generally enhances extension of the mistake. This is in contrast to RTs that must bind to then extend mismatches. The importance of these findings with respect to the mechanism of mutagenesis is discussed.
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PMID:Analysis of mutations made during active synthesis or extension of mismatched substrates further define the mechanism of HIV-RT mutagenesis. 1274 51

The RNase H primer grip of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) contacts the DNA primer strand and positions the template strand near the RNase H active site, influencing RNase H cleavage efficiency and specificity. Sequence alignments show that 6 of the 11 residues that constitute the RNase H primer grip have functional equivalents in murine leukemia virus (MLV) RT. We previously showed that a Y586F substitution in the MLV RNase H primer grip resulted in a 17-fold increase in substitutions within 18 nucleotides of adenine-thymine tracts, which are associated with a bent DNA conformation. To further determine the effects of the MLV RNase H primer grip on replication fidelity and viral replication, we performed additional mutational analysis. Using either beta-galactosidase (lacZ) or green fluorescent protein (GFP) reporter genes, we found that S557A, A558V, and Q559L substitutions resulted in statistically significant increases in viral mutation rates, ranging from 2.1- to 3.8-fold. DNA sequencing analysis of nonfluorescent GFP clones indicated that the mutations in RNase H primer grip significantly increased the frequency of deletions between the primer-binding site (PBS) and sequences downstream of the PBS. In addition, quantitative real-time PCR analysis of reverse transcription products revealed that the mutant RTs were substantially inefficient in plus-strand DNA transfer relative to the wild-type control. These results indicate that the MLV RNase H primer grip is an important determinant of in vivo fidelity of DNA synthesis and suggest that the mutant RT was unable to copy through the DNA-RNA junction of the minus-strand DNA and the tRNA because of its bent conformation resulting in error-prone plus-strand DNA transfer.
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PMID:Mutations in the RNase H primer grip domain of murine leukemia virus reverse transcriptase decrease efficiency and accuracy of plus-strand DNA transfer. 1559 35

DNA sensing at a single nucleotide resolution is achieved using a hairpin-shaped, unmodified (unlabeled) RNA probe or the precursor double-stranded DNA (dsDNA) in a prokaryotic cell-free translation medium. The molecular-beacon-like probe consists of a loop region that is complementary to the target sequence and a stem composed of a ribosome-binding site (RBS) and its docking domain; the RBS is followed by the gene for a reporter protein such as luciferase or beta-galactosidase. Target binding at the loop opens the hairpin to make RBS accessible by the ribosome to start translation of the reporter protein. This sensing system is signal amplifying by virtue of catalytic DNA-to-RNA transcription when using a dsDNA probe, catalytic RNA-to-protein translation, catalytic signal transduction by the enzymatic reaction of the translated reporter protein and, in the presence of RNase H, catalytic or even irreversible translation-activation of the target-probe heteroduplex. Preparation of a probe takes 1-3 d and gene sensing using the probe takes 1-3 h.
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PMID:Cis-regulatory hairpin-shaped mRNA encoding a reporter protein: catalytic sensing of nucleic acid sequence at single nucleotide resolution. 1754 1