EC:3.1.26.4 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.26.4 (RNase H)
2,751 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Kinases are a ubiquitous group of enzymes that catalyze the phosphoryl transfer reaction from a phosphate donor (usually ATP) to a receptor substrate. Although all kinases catalyze essentially the same phosphoryl transfer reaction, they display remarkable diversity in their substrate specificity, structure, and the pathways in which they participate. In order to learn the relationship between structural fold and functional specificities in kinases, we have done a comprehensive survey of all available kinase sequences (>17,000) and classified them into 30 distinct families based on sequence similarities. Of these families, 19, covering nearly 98% of all sequences, fall into seven general structural folds for which three-dimensional structures are known. These fold groups include some of the most widespread protein folds, such as Rossmann fold, ferredoxin fold, ribonuclease H fold, and TIM beta/alpha-barrel. On the basis of this classification system, we examined the shared substrate binding and catalytic mechanisms as well as variations of these mechanisms in the same fold groups. Cases of convergent evolution of identical kinase activities occurring in different folds are discussed.
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PMID:Sequence and structure classification of kinases. 1209 61

Resistance to zidovudine (3'-azido-3'-deoxythymidine, AZT) by the human immunodeficiency virus, type 1, requires multiple amino acid substitutions such as D67N/K70R/T215F/K219Q in the viral reverse transcriptase (RT). In this background of AZT resistance, additional "suppressive" substitutions such as Y181C restore sensitivity to AZT. In order to characterize the mechanism of this AZT resistance suppression, the Y181C substitution was introduced into both wild-type and AZT-resistant reverse transcriptase. The introduction of the Y181C substitution suppresses the increased repair (or unblocking) of the AZTMP-terminated primer provided by the AZT resistance substitutions in RT using either DNA or RNA templates, independently from the RT RNase H activity. Contrary to wild-type RT, the low level of unblocking activity is not due to inhibition by the next correct nucleotide binding to the RT/AZTMP-terminated primer complex. When Y181C is added to the AZT resistance substitutions, ATP binds with less affinity to the AZTMP-terminated primer-RT binary complex. These results provide an insight into one possible molecular mechanism of re-sensitization of AZT-resistant viruses by suppressive substitutions.
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PMID:The Y181C substitution in 3'-azido-3'-deoxythymidine-resistant human immunodeficiency virus, type 1, reverse transcriptase suppresses the ATP-mediated repair of the 3'-azido-3'-deoxythymidine 5'-monophosphate-terminated primer. 1290 45

The P-boranophosphates are efficient and near perfect mimics of natural nucleic acids in permitting reading and writing of genetic information with high yield and accuracy. Substitution of a borane (-BH3) group for oxygen in the phosphate ester bond creates an isoelectronic and isosteric mimic of natural nucleotide phosphate esters found in mononucleotides, i.e., AMP and ATP, and in RNA and DNA polynucleotides. Compared to natural nucleic acids, the boranophosphate RNA and DNA analogs demonstrate increased lipophilicity and resistance to endo- and exonucleases, yet they retain negative charge and similar spatial geometry. Borane groups can readily be introduced into the NTP and dNTP nucleic acid monomer precursors to produce alpha-P-borano nucleoside triphosphate analogs (e.g., NTPalphaB and dNTPalphaB). The NTPalphaB and dNTPalphaB are, in fact, good to excellent substrates for RNA and DNA polymerases, respectively, and allow ready enzymatic synthesis of RNA and DNA with P-boranophosphate linkages. Further, boranophosphate polymer products are good templates for replication, transcription, and gene expression; boronated RNA products are also suitable for reverse transcription to cDNA. Fully substituted boranophosphate DNA can activate the RNase H cleavage of RNA in RNA:DNA hybrids. Moreover, certain dideoxy-NTPalphaB analogs appear to be better substrates for viral reverse transcriptases than the regular ddNTPs, and may offer promising prodrug alternatives in antiviral therapy. These properties make boranophosphates promising candidates for diagnostics; aptamer selection; gene therapy; and antiviral, antisense, and RNAi therapeutics. The boranophosphates constitute a versatile family of phosphate mimics for processing genetic information and modulating gene function.
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PMID:Reading, writing, and modulating genetic information with boranophosphate mimics of nucleotides, DNA, and RNA. 1475 19

Metal ions are essential for DNA polymerase and RNase H activities of HIV-1 reverse transcriptase (RT). RT studies are routinely performed at 6-8 mM Mg2+, despite the fact that the in vivo concentration might be as low as 0.2 mM. We studied the influence of MgCl2 and ATP, which likely binds a significant fraction of the magnesium pool in vivo, on the DNA polymerase and RNase H activities of HIV-1 RT, its inhibition by nucleoside RT inhibitors (NRTIs) and primer unblocking by AZT-resistant RT. At low Mg2+ concentration, reverse transcription of a natural template strongly increased despite a dramatically reduced intrinsic polymerase activity under such conditions. Low Mg2+ concentrations affected the RNA stability and indirectly decreased its degradation by the RNase H activity. The reduced RNA degradation prevented premature dissociation of the template and primer strands that otherwise generated dead-end DNA products. In addition, low Mg2+ dramatically decreased the incorporation of NRTIs into DNA and increased nucleotide excision by AZT-resistant RT. The latter effect is also most likely owing to the diminished cleavage of the RNA template. Thus, differences in the free Mg2+ concentration between different cell types or during the cell cycle might strongly affect HIV-1 replication and its inhibition.
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PMID:Mg2+ dependency of HIV-1 reverse transcription, inhibition by nucleoside analogues and resistance. 1639 22

Inhibitors of the excision reaction catalysed by HIV-1 RT (reverse transcriptase) represent a promising approach in the fight against HIV, because these molecules would interfere with the main mechanism of resistance of this enzyme towards chain-terminating nucleotides. Only a limited number of compounds have been demonstrated to inhibit this reaction to date, including NNRTIs (non-nucleoside RT inhibitors) and certain pyrophosphate analogues. We have found previously that 2GP (2-O-galloylpunicalin), an antiviral compound extracted from the leaves of Terminalia triflora, was able to inhibit both the RT and the RNase H activities of HIV-1 RT without affecting cell proliferation or viability. In the present study, we show that 2GP also inhibited the ATP- and PP(i)-dependent phosphorolysis catalysed by wild-type and AZT (3'-azido-3'-deoxythymidine)-resistant enzymes at sub-micromolar concentrations. Kinetic and direct-binding analysis showed that 2GP was a non-competitive inhibitor against the nucleotide substrate, whereas it competed with the binding of RT to the template-primer (K(d)=85 nM). As expected from its mechanism of action, 2GP was active against mutations conferring resistance to NNRTIs and AZT. The combination of AZT with 2GP was highly synergistic when tested in the presence of pyrophosphate, indicating that the inhibition of RT-catalysed phosphorolysis was responsible for the synergy found. Although other RT inhibitors that compete with the template-primer have been described, this is the first demonstration that these compounds can be used to block the excision of chain terminating nucleotides, providing a rationale for their combination with nucleoside analogues.
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PMID:A new strategy to inhibit the excision reaction catalysed by HIV-1 reverse transcriptase: compounds that compete with the template-primer. 1735 25

Recent studies have identified a role for mutations in the connection and RNase H domains of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) resistance to nucleoside analog RT inhibitors (NRTI). To provide insight into the biochemical mechanism(s) involved, we investigated the effect of the G333D mutation in the connection domain of RT on resistance to zidovudine (AZT) and lamivudine (3TC) in enzymes that contain both M184V and thymidine analog mutations (TAMs; M41L, L210W, and T215Y). Our results from steady-state kinetic, pre-steady-state kinetic, and thermodynamic analyses indicate that G333D facilitates dual resistance to AZT and 3TC in two ways. First, in combination with M184V, G333D increased the ability of HIV-1 RT to effectively discriminate between the normal substrate dCTP and 3TC-triphosphate. Second, G333D enhanced the ability of RT containing TAMs and M184V to bind template/primer terminated by AZT-monophosphate (AZT-MP), thereby restoring ATP-mediated excision of AZT-MP under steady-state assay conditions. This study is the first to elucidate a molecular mechanism whereby a mutation in the connection domain of RT can affect NRTI susceptibility at the enzyme level.
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PMID:Mechanisms by which the G333D mutation in human immunodeficiency virus type 1 Reverse transcriptase facilitates dual resistance to zidovudine and lamivudine. 1796 7

Previous biochemical studies have demonstrated that synergy between non-nucleoside reverse transcriptase (RT) inhibitors (NNRTI) and nucleoside RT inhibitors (NRTIs) is due to inhibition by the NNRTI of the rate at which HIV-1 RT facilitates ATP-mediated excision of NRTIs from chain-terminated template/primers (T/P). However, these studies did not take into account the possible effects of NNRTI on the ribonuclease H (RNase H) activity of RT, despite recent evidence that suggests an important role for this activity in the NRTI excision phenotype. Accordingly, in this study, we compared the ability of efavirenz to inhibit the incorporation and excision of zidovudine (AZT) by HIV-1 RT using DNA/DNA and RNA/DNA T/Ps that were identical in sequence. Whereas IC(50) values for the inhibition of AZT-triphosphate incorporation by efavirenz were essentially similar for both DNA/DNA and RNA/DNA T/P, a 19-fold difference in IC(50) was observed between the AZT-monophosphate excision reactions, the RNA/DNA T/P substrate being significantly more sensitive to inhibition. Analysis of the RNase H cleavage events generated during ATP-mediated excision reactions demonstrated that efavirenz dramatically increased the rate of appearance of a secondary cleavage product that decreased the T/P duplex length to only 10 nucleotides. Studies designed to delineate the relationship between T/P duplex length and efficiency of AZT excision demonstrated that RT could not efficiently unblock chain-terminated T/P if the RNA/DNA duplex length was less than 12 nucleotides. Taken together, these results highlight an important role for RNase H activity in the NRTI excision phenotype and in the mechanism of synergy between NNRTI and NRTI.
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PMID:Efavirenz accelerates HIV-1 reverse transcriptase ribonuclease H cleavage, leading to diminished zidovudine excision. 1802 10

Human immunodeficiency virus (HIV) reverse transcriptase (RT) inhibitors can be classified into nucleoside and nonnucleoside RT inhibitors. Nucleoside RT inhibitors are converted to active triphosphate analogues and incorporated into the DNA in RT-catalyzed reactions. They act as chain terminators blocking DNA synthesis, since they lack the 3'-OH group required for the phosphodiester bond formation. Unfortunately, available therapies do not completely suppress viral replication, and the emergence of drug-resistant HIV variants is facilitated by the high adaptation capacity of the virus. Mutations in the RT-coding region selected during treatment with nucleoside analogues confer resistance through different mechanisms: (i) altering discrimination between nucleoside RT inhibitors and natural substrates (dNTPs) (e.g. Q151M, M184V, etc.), or (ii) increasing the RT's phosphorolytic activity (e.g. M41L, T215Y and other thymidine analogue resistance mutations), which in the presence of a pyrophosphate donor (usually ATP) allow the removal of chain-terminating inhibitors from the 3' end of the primer. Both mechanisms are implicated in multi-drug resistance. The excision reaction can be modulated by mutations conferring resistance to nucleoside or nonnucleoside RT inhibitors, and by amino acid substitutions that interfere with the proper binding of the template-primer, including mutations that affect RNase H activity. New developments in the field should contribute towards improving the efficacy of current therapies.
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PMID:Mechanisms of resistance to nucleoside analogue inhibitors of HIV-1 reverse transcriptase. 1827 47

Thymidine analogue-associated mutations (TAMs) in reverse transcriptase (RT) of the human immunodeficiency virus type 1 (HIV-1) cause resistance to 3'-azido-3'-deoxythymidine (AZT) through excision of the incorporated monophosphate. Mutations in the connection domain of HIV-1 RT can augment AZT resistance. It has been suggested that these mutations compromise RNase H cleavage, providing more time for AZT excision to occur. However, the underlying mechanism remains elusive. Here, we focused on connection mutations N348I and A360V that are frequently observed in clinical samples of treatment-experienced patients. We show that both N348I and A360V, in combination with TAMs, decrease the efficiency of RNase H cleavage and increase excision of AZT in the presence of the pyrophosphate donor ATP. The TAMs/N348I/A360V mutant accumulates transiently formed, shorter hybrids that can rebind to RT before the template is irreversibly degraded. These hybrids dissociate selectively from the RNase H-competent complex, whereas binding in the polymerase-competent mode is either not affected with N348I or modestly improved with A360V. Both connection domain mutations can compensate for TAM-mediated deficits in processive DNA synthesis, and experiments with RNase H negative mutant enzymes confirm an RNase H-independent contribution to increased levels of resistance to AZT. Moreover, the combination of diminished RNase H cleavage and increased processivity renders the use of both PP(i) and ATP advantageous, whereas classic TAMs solely enhance the ATP-dependent reaction. Taken together, our findings demonstrate that distinct, complementary mechanisms can contribute to higher levels of excision of AZT, which in turn can amplify resistance to this drug.
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PMID:Connection domain mutations N348I and A360V in HIV-1 reverse transcriptase enhance resistance to 3'-azido-3'-deoxythymidine through both RNase H-dependent and -independent mechanisms. 1854 11

We previously proposed that mutations in the connection subdomain (cn) of HIV-1 reverse transcriptase increase AZT resistance by altering the balance between nucleotide excision and template RNA degradation. To test the predictions of this model, we analyzed the effects of previously identified cn mutations in combination with thymidine analog mutations (D67N, K70R, T215Y, and K219Q) on in vitro RNase H activity and AZT monophosphate (AZTMP) excision. We found that cn mutations G335C/D, N348I, A360I/V, V365I, and A376S decreased primary and secondary RNase H cleavages. The patient-derived cns increased ATP- and PPi-mediated AZTMP excision on an RNA template compared with a DNA template. One of 5 cns caused an increase in ATP-mediated AZTMP excision on a DNA template, whereas three cns showed a higher ratio of ATP- to PPi-mediated excision, indicating that some cn mutations also affect excision on a DNA substrate. Overall, the results strongly support the model that cn mutations increase AZT resistance by reducing template RNA degradation, thereby providing additional time for RT to excise AZTMP.
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PMID:HIV-1 reverse transcriptase connection subdomain mutations reduce template RNA degradation and enhance AZT excision. 1866 7

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