Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.7.6 (RNA polymerase)
 34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

SR proteins constitute a family of pre-mRNA splicing factors now thought to play several roles in mRNA metabolism in metazoan cells. Here we provide evidence that a prototypical SR protein, ASF/SF2, is unexpectedly required for maintenance of genomic stability. We first show that in vivo depletion of ASF/SF2 results in a hypermutation phenotype likely due to DNA rearrangements, reflected in the rapid appearance of DNA double-strand breaks and high-molecular-weight DNA fragments. Analysis of DNA from ASF/SF2-depleted cells revealed that the nontemplate strand of a transcribed gene was single stranded due to formation of an RNA:DNA hybrid, R loop structure. Stable overexpression of RNase H suppressed the DNA-fragmentation and hypermutation phenotypes. Indicative of a direct role, ASF/SF2 prevented R loop formation in a reconstituted in vitro transcription reaction. Our results support a model by which recruitment of ASF/SF2 to nascent transcripts by RNA polymerase II prevents formation of mutagenic R loop structures.
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PMID:Inactivation of the SR protein splicing factor ASF/SF2 results in genomic instability. 1609 57

Allele-specific inhibition (ASI) is a new strategy to treat cancer through a vulnerability created by the loss of large segments of chromosomal material by loss of heterozygosity (LOH). Using antisense approaches, it is possible to target single nucleotide polymorphisms (SNP) in the remaining allele of an essential gene in the tumor, thus killing the tumor while the heterozygous patient survives at the expense of the other nontargeted allele lost by the tumor. In this study, the feasibility of using locked nucleic acid (LNA)-modified DNAzymes (LNAzymes) of the 10-23 motif as allele-specific drugs was investigated. We demonstrate that incorporation of LNA into 10-23 motif DNAzymes increases their efficacy in mRNA degradation and that, in a cell-free system, the 10-23 motif LNAzyme can adequately discriminate and recognize an SNP in the large subunit of RNA polymerase II (POLR2A), an essential gene frequently involved in LOH in cancer cells. However, the LNAzymes, optimized under in vitro conditions, are not always efficient in cleaving their RNA target in cell culture, and the efficiency of RNA cleavage in cell culture is cell type dependent. The cleavage rate of the LNAzyme is also much slower than RNase H-recruiting DNA phosphorothioate antisense oligonucleotides. Moreover, compared with DNA phosphorothioates, the ability of the LNAzymes to differentially knock down two POLR2A alleles in cultured cancer cells is limited.
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PMID:Evaluation of LNA-modified DNAzymes targeting a single nucleotide polymorphism in the large subunit of RNA polymerase II. 1639 19

This paper summarizes our recent work on the coupling of surface enzyme chemistry and bioaffinity interactions on biopolymer microarrays for the creation of multiplexed biosensors with enhanced selectivity and sensitivity. The surface sensitive techniques of surface plasmon resonance imaging (SPRI) and surface plasmon fluorescence spectroscopy (SPFS) are used to detect the surface enzymatic transformations in real time. Three specific examples of novel coupled surface bioaffinity/surface enzymatic processes are demonstrated: (i) a surface enzymatic amplification method utilizing the enzyme ribonuclease H (RNase H) in conjunction with RNA microarrays that permits the ultrasensitive direct detection of genomic DNA at a concentration of 1 fM without labeling or PCR amplification, (ii) the use of RNA-DNA ligation chemistry to create renewable RNA microarrays from single stranded DNA microarrays, and (iii) the application of T7 RNA polymerase for the on-chip replication of RNA from double stranded DNA microarray elements. In addition, a simple yet powerful theoretical framework that includes the contributions of both enzyme adsorption and surface enzyme kinetics is used to quantitate surface enzyme reactivity. This model is successfully applied to SPRI and SPFS measurements of surface hydrolysis reactions of RNase H and Exonuclease III (Exo III) on oligonucleotide microarrays.
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PMID:Creating advanced multifunctional biosensors with surface enzymatic transformations. 1673 47

Reverse transcriptase (RT) plays an essential role in the HIV-1 replication process, which converts a single-strand RNA into a double-strand DNA via polymerase and RNase H activities. Therefore, inhibition of RT has been one of the primary therapeutic strategies for suppressing the replication of HIV-1. To facilitate the process of discovering the next generation of antiretroviral agents, this study presents a highly sensitive and nonradioactive RT polymerase assay that is based on electrochemiluminescence (ECL) technology, where a ruthenylated dUTP (Ru-dUTP) is employed as one of the dNTPs. The concentration of the RT enzymes required for the assay can be as low as 1 pM, enabling us to evaluate inhibitors with low picomolar potency. More importantly, the assay is capable of detecting endogenous RT activity in cell-free viruses. Therefore, the assay was applied to monitor the development of resistance mutation(s) by viruses under the treatment with a non-nucleoside reverse transcriptase inhibitor (NNRTI) in cell culture. The magnitude of resistance of the resulting mutant viruses was assessed directly by the assay, eliminating the need for cloning, expressing, and purifying the RT mutants.
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PMID:Monitoring the development of non-nucleoside reverse transcriptase inhibitor-associated resistant HIV-1 using an electrochemiluminescence-based reverse transcriptase polymerase assay. 1796 75

Reverse transcriptase of the human immunodeficiency virus possesses DNA polymerase and ribonuclease (RNase) H activities. Although the nucleic acid binding cleft separating these domains can accommodate structurally diverse duplexes, it is currently unknown whether regular DNA/RNA hybrids can simultaneously contact both active sites. In this study, we demonstrate that ligands capable of trapping the 3'-end of the primer at the polymerase active site affect the specificity of RNase H cleavage without altering the efficiency of the reaction. Experiments under single-turnover conditions reveal that complexes with a bound nucleotide substrate show specific RNase H cleavage at template position -18, while complexes with the pyrophosphate analogue foscarnet show a specific cut at position -19. This pattern is indicative of post-translocated and pre-translocated conformations. The data are inconsistent with models postulating that the substrate toggles between both active sites, such that the primer 3'-terminus is disengaged from the polymerase active site when the template is in contact with the RNase H active site. In contrast, our findings provide strong evidence to suggest that the nucleic acid substrate can engage both active sites at the same time. As a consequence, the bound and intact DNA/RNA hybrid can restrict access of RNase H active site inhibitors. We have mapped the binding site of the recently discovered inhibitor beta-thujaplicinol between the RNase H active site and Y501 of the RNase H primer grip, and have shown that the inhibitor is unable to bind to a preformed reverse transcriptase-DNA/RNA complex. In conclusion, the bound nucleic acid substrate and in turn, active DNA synthesis can represent an obstacle to RNase H inhibition with compounds that bind to the RNase H active site.
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PMID:HIV-1 reverse transcriptase can simultaneously engage its DNA/RNA substrate at both DNA polymerase and RNase H active sites: implications for RNase H inhibition. 1928 31

How living cells deal with head-on collisions of the replication and transcription complexes has been debated for a long time. Even in the widely studied model bacteria Escherichia coli, the enzymes that take care of such collisions are still unknown. We report here that in vivo, the DinG, Rep and UvrD helicases are essential for efficient replication across highly transcribed regions. We show that when rRNA operons (rrn) are inverted to face replication, the viability of the dinG mutant is affected and over-expression of RNase H rescues the growth defect, showing that DinG acts in vivo to remove R-loops. In addition, DinG, Rep and UvrD exert a common function, which requires the presence of two of these three helicases. After replication blockage by an inverted rrn, Rep in conjunction with DinG or UvrD removes RNA polymerase, a task that is fulfilled in its absence by the SOS-induced DinG and UvrD helicases. Finally, Rep and UvrD also act at inverted sequences other than rrn, and promote replication through highly transcribed regions in wild-type E. coli.
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PMID:The helicases DinG, Rep and UvrD cooperate to promote replication across transcription units in vivo. 1985 Dec 82

A hallmark of metazoan RNA polymerase II transcripts is the presence of numerous small exons surrounded by large introns. Abundant evidence indicates that splicing to excise introns occurs co-transcriptionally, prior to release of the nascent transcript from RNAP II. Here, we established an efficient model system for co-transcriptional splicing in vitro. In this system, CMV-DNA constructs immobilized on beads generate RNAP II transcripts containing two exons and an intron. Consistent with previous work, our data indicate that elongating nascent transcripts are tethered to RNAP II on the immobilized DNA template. We show that nascent transcripts that reach full length, but are still attached to RNAP II, are efficiently spliced. When the nascent transcript is cleaved within the intron using RNase H, both the 5' and 3' cleavage fragments are detected in the bound fraction, where they undergo splicing. Together, our work establishes a system for co-transcriptional splicing in vitro, in which the spliceosome containing the 5' and 3' exons are tethered to RNAP II for splicing.
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PMID:A model in vitro system for co-transcriptional splicing. 2063 Oct 7

During translation of the genetic information of DNA into proteins, mRNA is synthesized by RNA polymerase and after the transcription process degraded by RNase H. The endoribonuclease RNase H is a member of the nucleotidyl-transferase (NT) superfamily and is known to hydrolyze the phosphodiester bonds of RNA which is hybridized to DNA. Retroviral RNase H is part of the viral reverse transcriptase enzyme that is indispensable for the proliferation of retroviruses, such as HIV. Inhibitors of this enzyme could therefore provide new drugs against diseases like AIDS. In our study we investigated the molecular mechanism of RNA cleavage by human RNase H using a comprehensive high level DFT/B3LYP QM/MM theoretical method for the calculation of the stationary points and nudged elastic band (NEB) and free energy calculations to identify the transition state structures, the rate limiting step and the reaction barrier. Our calculations reveal that the catalytic mechanism proceeds in two steps and that the nature of the nucleophile is a water molecule. In the first step, the water attack on the scissile phosphorous is followed by a proton transfer from the water to the O2P oxygen and a trigonal bipyramidal pentacoordinated phosphorane is formed. Subsequently, in the second step the proton is shuttled to the O3' oxygen to generate the product state. During the reaction mechanism two Mg(2+) ions support the formation of a stable associated in-line S(N)2-type phosphorane intermediate. Our calculated energy barrier of 19.3 kcal mol(-1) is in excellent agreement with experimental findings (20.5 kcal mol(-1)). These results may contribute to the clarification and understanding of the RNase H reaction mechanism and of further enzymes from the RNase family.
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PMID:Atomistic details of the associative phosphodiester cleavage in human ribonuclease H. 2067 57

Reverse transcriptase (RT) catalyzes the formation of dsDNA from single-stranded retroviral RNA genome. This enzyme is unique among DNA polymerases in its ability to use either RNA or DNA as a template. Moloney Murine Leukemia virus reverse transcriptase lacking RNase H activity (M-MLVH- RT) especially holds particular interest because of its ability to eliminate the deleterious effect of RNase H, which results in more efficient synthesis of full-length cDNA from mRNA. Therefore, the development of a simple purification method attracts the attention of retroviral drug and enzyme researchers and manufacturers. The present work is the first purification example of a non-tagged (native) RT by affinity chromatography using synthetic affinity ligands. In this study, the ligand was selected from a structure-biased combinatorial library of dNTP-mimetic ligands, and it was evaluated for its ability to bind and purify M-MLVH- RT from inclusion bodies of recombinant E. coli. The selected ligand (AEAd), bearing 9-aminoethyladenine and 1,6-diamine-hexane both linked on the same triazine scaffold, displayed the highest enzyme purifying ability after applying mild desorption conditions (6 mM MnCl(2) in 20 mM Tris-HCl buffer, pH 7.5). The binding capacity of immobilized AEAd with M-MLVH- RT was determined to be equal to approximately 1 mg enzyme/g moist weight gel. Adsorption studies with immobilized AEAd and soluble M-MLVH- RT demonstrated that the formation of the respective complex was perturbed by ATP. Quality control tests of the purified M-MLVH- RT essentially showed a single band (sodium dodecyl sulfate polyacrylamide gel electrophoresis) and absence of nucleic acids and contaminating nuclease activities.
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PMID:Purification of M-MLVH- RT on a 9-aminoethyladenine-(1,6-diamine-hexane)-triazine selected from a combinatorial library of dNTP-mimetic ligands. 2082 67

Microarrays of RNA aptamers are fabricated in a one-step, multiplexed enzymatic synthesis on gold thin films in a microfluidic format and then employed in the detection of protein biomarkers with surface plasmon resonance imaging (SPRI) measurements. Single-stranded RNA (ssRNA) oligonucleotides are transcribed on-chip from double-stranded DNA (dsDNA) templates attached to microarray elements (denoted as generator elements) by the surface transcription reaction of T7 RNA polymerase. As they are synthesized, the ssRNA oligonucleotides diffuse in the microfluidic channel and are quickly captured by hybridization adsorption onto adjacent single-stranded DNA (ssDNA) microarray elements (denoted as detector elements) that contain a sequence complementary to 5'-end of the ssRNA. The RNA aptamers attached to these detector elements are subsequently used in SPRI measurements for the bioaffinity detection of protein biomarkers. The microfluidic generator-detector element format permits the simultaneous fabrication of multiple ssRNA oligonucleotides with different capture sequences that can hybridize simultaneously to distinct detector elements and thus create a multiplexed aptamer microarray. In an initial set of demonstration experiments, SPRI measurements are used to monitor the bioaffinity adsorption of human thrombin (hTh) and vascular endothelial growth factor (VEGF) proteins onto RNA aptamer microarrays fabricated in situ with this on-chip RNA polymerase synthesis methodology. Additional SPRI measurements of the hydrolysis and desorption of the surface-bound ssRNA aptamers with a surface RNase H are used to verify the capture of ssRNA with RNA-DNA surface hybridization onto the detector elements. The on-chip RNA synthesis described here is an elegant, one-step multiplexed methodology for the rapid and contamination-free fabrication of RNA aptamer microarrays for protein biosensing with SPRI.
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PMID:On-chip synthesis of RNA aptamer microarrays for multiplexed protein biosensing with SPR imaging measurements. 2245 58


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