Your search keyword '"DNA polymerization"' showing total 29 results

1. Homochirality: A Prerequisite or Consequence of Life?

Author

Brandenburg, Axel, Brack, André, Series Editor, Horneck, Gerda, Series Editor, Neubeck, Anna, editor, and McMahon, Sean, editor

Published

2021

2. Context-dependent DNA polymerization effects can masquerade as DNA modification signals

Author

Yusuke Takahashi, Massa Shoura, Andrew Fire, and Shinichi Morishita

Subjects

DNA polymerization, DNA modification, Non-B DNA, Whole genome amplification, Single-molecule real-time (SMRT) sequencing, DNA N6-methyladenine, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Single molecule measurements of DNA polymerization kinetics provide a sensitive means to detect both secondary structures in DNA and deviations from primary chemical structure as a result of modified bases. In one approach to such analysis, deviations can be inferred by monitoring the behavior of DNA polymerase using single-molecule, real-time sequencing with zero-mode waveguide. This approach uses a Single Molecule Real Time (SMRT)-sequencing measurement of time between fluorescence pulse signals from consecutive nucleosides incorporated during DNA replication, called the interpulse duration (IPD). Results In this paper we present an analysis of loci with high IPDs in two genomes, a bacterial genome (E. coli) and a eukaryotic genome (C. elegans). To distinguish the potential effects of DNA modification on DNA polymerization speed, we paired an analysis of native genomic DNA with whole-genome amplified (WGA) material in which DNA modifications were effectively removed. Adenine modification sites for E. coli are known and we observed the expected IPD shifts at these sites in the native but not WGA samples. For C. elegans, such differences were not observed. Instead, we found a number of novel sequence contexts where IPDs were raised relative to the average IPDs for each of the four nucleotides, but for which the raised IPD was present in both native and WGA samples. Conclusion The latter results argue strongly against DNA modification as the underlying driver for high IPD segments for C. elegans, and provide a framework for separating effects of DNA modification from context-dependent DNA polymerase kinetic patterns inherent in underlying DNA sequence for a complex eukaryotic genome.

Published

2022

3. Nucleobase-modified nucleosides and nucleotides: Applications in biochemistry, synthetic biology, and drug discovery

Author

Anthony Berdis

Subjects

DNA polymerization, nucleoside analogs, hydrogen bonding, synthetic biology, chemotherapy, Chemistry, QD1-999

Abstract

Abstract. DNA is often referred to as the “molecule of life” since it contains the genetic blueprint for all forms of life on this planet. The core building blocks composing DNA are deoxynucleotides. While the deoxyribose sugar and phosphate group are ubiquitous, it is the composition and spatial arrangement of the four natural nucleobases, adenine (A), cytosine (C), guanine (G), and thymine (T), that provide diversity in the coding information present in DNA. The ability of DNA to function as the genetic blueprint has historically been attributed to the formation of proper hydrogen bonding interactions made between complementary nucleobases. However, recent chemical and biochemical studies using nucleobase-modified nucleotides that contain “non-hydrogen bonding” functional groups have challenged many of the dogmatic views for the necessity of hydrogen-bonding interactions for DNA stability and function. Based on years of exciting research, this area has expanded tremendously and is thus too expansive to provide a comprehensive review on the topic. As such, this review article provides an opinion highlighting how nucleobase-modified nucleotides are being applied in diverse biomedical fields, focusing on three exciting areas of research. The first section addresses how these analogs are used as mechanistic probes for DNA polymerase activity and fidelity during replication. This section outlines the synthetic logic and medicinal chemistry approaches used to replace hydrogen-bonding functional groups to examine the contributions of shape/size, nucleobase hydrophobicity, and pi-electron interactions. The second section extends these mechanistic studies to provide insight into how nucleobase-modified nucleosides are used in synthetic biology. One example is through expansion of the genetic code in which changing the composition of DNA makes it possible to site-specifically incorporate unnatural amino acids bearing unique functional groups into enzymes and receptors. The final section describes results of pre-clinical studies using nucleobase-modified nucleosides as potential therapeutic agents against diseases such as cancer.

Published

2022

4. Context-dependent DNA polymerization effects can masquerade as DNA modification signals.

Author

Takahashi, Yusuke, Shoura, Massa, Fire, Andrew, and Morishita, Shinichi

Subjects

DNA, DNA structure, SINGLE molecules, ESCHERICHIA coli, NUCLEOTIDE sequence, DNA polymerases, ADENINE

Abstract

Background: Single molecule measurements of DNA polymerization kinetics provide a sensitive means to detect both secondary structures in DNA and deviations from primary chemical structure as a result of modified bases. In one approach to such analysis, deviations can be inferred by monitoring the behavior of DNA polymerase using single-molecule, real-time sequencing with zero-mode waveguide. This approach uses a Single Molecule Real Time (SMRT)-sequencing measurement of time between fluorescence pulse signals from consecutive nucleosides incorporated during DNA replication, called the interpulse duration (IPD). Results: In this paper we present an analysis of loci with high IPDs in two genomes, a bacterial genome (E. coli) and a eukaryotic genome (C. elegans). To distinguish the potential effects of DNA modification on DNA polymerization speed, we paired an analysis of native genomic DNA with whole-genome amplified (WGA) material in which DNA modifications were effectively removed. Adenine modification sites for E. coli are known and we observed the expected IPD shifts at these sites in the native but not WGA samples. For C. elegans, such differences were not observed. Instead, we found a number of novel sequence contexts where IPDs were raised relative to the average IPDs for each of the four nucleotides, but for which the raised IPD was present in both native and WGA samples. Conclusion: The latter results argue strongly against DNA modification as the underlying driver for high IPD segments for C. elegans, and provide a framework for separating effects of DNA modification from context-dependent DNA polymerase kinetic patterns inherent in underlying DNA sequence for a complex eukaryotic genome. [ABSTRACT FROM AUTHOR]

Published

2022

5. Effect of Microwaves on DNA and Proteins

Author

Yoshimura, Takeo, Sugiyama, Jun-ichi, Mineki, Shigeru, Ohuchi, Shokichi, and Geddes, Chris D., editor

Published

2017

6. An artificial nucleoside that simultaneously detects and combats drug resistance to doxorubicin.

Author

Choi, Jung‐Suk and Berdis, Anthony

Subjects

*DRUG resistance, *PHARMACOLOGY, *DNA replication, *DNA polymerases, *DNA damage

Abstract

Objectives: Doxorubicin is a DNA‐damaging agent used to treat hematological cancers. Unfortunately, drug resistance can occur by defective DNA repair activity coupled with the ability of DNA polymerases to misreplicate unrepaired DNA lesions. This study demonstrates that the efficacy of doxorubicin can be improved by using an artificial nucleoside to efficiently and selectively inhibit this activity. Methods: In vitro studies using acute lymphoblastic leukemia cell lines define the mechanism of cell death caused by combining an artificial nucleoside with doxorubicin. Results: Flow cytometry experiments demonstrate that combining an artificial nucleoside with doxorubicin potentiates the cell killing effects of the drug by increasing apoptosis. The potentiation effect correlates with expression of TdT, a specialized DNA polymerase overexpressed in acute lymphoblastic leukemia. Cell cycle experiments demonstrate that this combination blocks cells at S‐phase prior to inducing apoptosis. Finally, the unique chemical composition of the nucleoside analog was used to visualize the replication of damaged DNA in TdT‐positive cells. This represents a potential diagnostic tool to easily identify doxorubicin‐resistant cancer cells. Conclusion: Studies demonstrate that a novel artificial nucleoside improves the therapeutic efficacy of doxorubicin, thereby reducing the risk of potential side effects caused by the DNA‐damaging agent. [ABSTRACT FROM AUTHOR]

Published

2020

7. The Limited Roles of Autocatalysis and Enantiomeric Cross-Inhibition in Achieving Homochirality in Dilute Systems.

Author

Brandenburg, Axel

Abstract

To understand the effects of fluctuations on achieving homochirality, we employ a Monte-Carlo method where autocatalysis and enantiomeric cross-inhibition, as well as racemization and deracemization reactions are included. The results of earlier work either without autocatalysis or without cross-inhibition are reproduced. Bifurcation diagrams and the dependencies of the number of reaction steps on parameters are studied. In systems with 30,000 molecules, for example, up to a billion reaction steps may be needed to achieve homochirality without autocatalysis. [ABSTRACT FROM AUTHOR]

Published

2019

8. The structure of FIV reverse transcriptase and its implications for non-nucleoside inhibitor resistance.

Author

Galilee, Meytal and Alian, Akram

Subjects

*FELINE immunodeficiency virus, *REVERSE transcriptase, *ANTI-HIV agents, *DRUG resistance, *GENETIC mutation

Abstract

Reverse transcriptase (RT) is the target for the majority of anti-HIV-1 drugs. As with all anti-AIDS treatments, continued success of RT inhibitors is persistently disrupted by the occurrence of resistance mutations. To explore latent resistance mechanisms potentially accessible to therapeutically challenged HIV-1 viruses, we examined RT from the related feline immunodeficiency virus (FIV). FIV closely parallels HIV-1 in its replication and pathogenicity, however, is resistant to all non-nucleoside inhibitors (NNRTI). The intrinsic resistance of FIV RT is particularly interesting since FIV harbors the Y181 and Y188 sensitivity residues absent in both HIV-2 and SIV. Unlike RT from HIV-2 or SIV, previous efforts have failed to make FIV RT susceptible to NNRTIs concluding that the structure or flexibility of the feline enzyme must be profoundly different. We report the first crystal structure of FIV RT and, being the first structure of an RT from a non-primate lentivirus, enrich the structural and species repertoires available for RT. The structure demonstrates that while the NNRTI binding pocket is conserved, minor subtleties at the entryway can render the FIV RT pocket more restricted and unfavorable for effective NNRTI binding. Measuring NNRTI binding affinity to FIV RT shows that the “closed” pocket configuration inhibits NNRTI binding. Mutating the loop residues rimming the entryway of FIV RT pocket allows for NNRTI binding, however, it does not confer sensitivity to these inhibitors. This reveals a further layer of resistance caused by inherent FIV RT variances that could have enhanced the dissociation of bound inhibitors, or, perhaps, modulated protein plasticity to overcome inhibitory effects of bound NNRTIs. The more “closed” conformation of FIV RT pocket can provide a template for the development of innovative drugs that could unlock the constrained pocket, and the resilient mutant version of the enzyme can offer a fresh model for the study of NNRTI-resistance mechanisms overlooked in HIV-1. [ABSTRACT FROM AUTHOR]

Published

2018

9. Sensitive detection of DNA methyltransferase activity based on supercharged fluorescent protein and template-free DNA polymerization.

Author

Li, Daiqi, Lu, Guoyan, Lei, Chunyang, Wang, Zhen, Li, Lijun, Nie, Zhou, Huang, Yan, and Yao, Shouzhuo

Abstract

DNA methylation, catalyzed by DNA methyltransferases (MTases), is a key component of genetic regulation, and DNA MTases have been regarded as potential targets in anticancer therapy. Herein, based on our previously developed DNA-mediated supercharged green fluorescent protein (ScGFP)/graphene oxide (GO) interaction, coupled with methylation-initiated template- free DNA polymerization, we propose a novel fluorescence assay strategy for sensitive detection of DNA MTase activity. A hairpin DNA with a methylation-sensitive site and an amino-modified 3'-terminal (DNA-1) was designed and worked as a starting molecule. In the presence of DNA MTase, methylation-sensitive restriction endonuclease, and terminal deoxynucleotidyl transferase (TdT), DNA-1 can be sequentially methylated, cleaved, and further elongated. The resulting long DNA fragments quickly bind with ScGFP and form the ScGFP/DNA nanocomplex. Such nanocomplex can effectively protect ScGFP from being adsorbed and quenched by GO. Without the methylation-initiated DNA polymerization, the fluorescence of ScGFP will be quenched by GO. Thus, the DNA MTase activity, which is proportional to the amount of DNA polymerization products, can be measured by reading the fluorescence of ScGFP/GO. The method was successfully used to detect the activity of DNA adenine methylation (Dam) MTase with a wide linear range (0.1-100 U/mL) and a low detection limit of 0.1 U/mL. In addition, the method showed high selectivity and the potential to be applied in a complex sample. Furthermore, this study was successfully extended to evaluate the inhibition effect of 5-fluorouracil on Dam MTase activity and detect TdT activity. [ABSTRACT FROM AUTHOR]

Published

2016

10. Conformation and recognition of DNA damaged by antitumor cis-dichlorido platinum(II) complex of CDK inhibitor bohemine.

Author

Novakova, Olga, Liskova, Barbora, Vystrcilova, Jana, Suchankova, Tereza, Vrana, Oldrich, Starha, Pavel, Travnicek, Zdenek, and Brabec, Viktor

Subjects

*CONFORMATIONAL analysis, *DNA damage, *ANTINEOPLASTIC agents, *PLATINUM compounds, *METAL complexes, *CYCLIN-dependent kinase inhibitors, *PURINES

Abstract

Abstract: A substitution of the ammine ligands of cisplatin, cis-[Pt(NH3)2Cl2], for cyclin dependent kinase (CDK) inhibitor bohemine (boh), [2-(3-hydroxypropylamino)-6-benzylamino-9-isopropylpurine], results in a compound, cis-[Pt(boh)2Cl2] (C1), with the unique anticancer profile which may be associated with some features of the damaged DNA and/or its cellular processing (Travnicek Z et al. (2003) J Inorg Biochem 94, 307–316; Liskova B (2012) Chem Res Toxicol 25, 500–509). A combination of biochemical and molecular biology techniques was used to establish mechanistic differences between cisplatin and C1 with respect to the DNA damage they produce and their interactions with critical DNA-binding proteins, DNA-processing enzymes and glutathione. The results show that replacement of the NH3 groups in cisplatin by bohemine modulates some aspects of the mechanism of action of C1. More specifically, the results of the present work are consistent with the thesis that, in comparison with cisplatin, effects of other factors, such as: (i) slower rate of initial binding of C1 to DNA; (ii) the lower efficiency of C1 to form bifunctional adducts; (iii) the reduced bend of longitudinal DNA axis induced by the major 1,2-GG intrastrand cross-link of C1; (iv) the reduced affinity of HMG domain proteins to the major adduct of C1; (v) the enhanced efficiency of the DNA adducts of C1 to block DNA polymerization and to inhibit transcription activity of human RNA pol II and RNA transcription; (vi) slower rate of the reaction of C1 with glutathione, may partially contribute to the unique activity of C1. [Copyright &y& Elsevier]

Published

2014

11. Design of a biomolecular device that executes process algebra.

Author

Majumder, Urmi and Reif, John H.

Subjects

*SEMANTICS, *PI-calculus, *NUCLEIC acid hybridization, *DNA restriction enzymes, *BIOMOLECULES, *COMPUTATIONAL biology

Abstract

Process algebras are widely used for defining the formal semantics of concurrent communicating processes. This paper considers stochastic π- calculus which is a particularly expressive kind of process algebra providing a specification of probabilities of process behavior such as stochastic delays, communication and branching, as well as rates of execution. In this paper, we implement stochastic π-calculus at the molecular scale, providing a design for a DNA-based biomolecular device that executes the stochastic π-calculus. Designing this device is challenging due to the requirement that a specific pair of processes must be able to communicate repeatedly; this appears to rule out the use of many of the usual classes of DNA computation (e.g., tiling self-assembly or hybridization chain reactions) that allow computational rule molecules to float freely in solution within a test tube. Our design of the molecular stochastic π-calculus system makes use of a modified form of Whiplash-PCR (WPCR) machines. In our machine which we call π- WPCR machine, we connect (via a tethering DNA nanostructure) a number of DNA strands, each of which corresponds to a π-WPCR machines. This collection of π-WPCR machines is used to execute distinct concurrent processes, each with its own distinct program. To implement process communication protocols, our modifications to the original design of WPCR machines include the incorporation of additional secondary structure in the single strand ( stem-loop) as well as multiple-temperature thermal cycling. The enforced locality of the collection of π-WPCR machines insures that the same pair (or any subset of the entire collection) of processes be able to repeatedly communicate with each other. Additionally, our design of the devices include implementation of sequential execution of multiple process and limited process branching through use of restriction enzymes. [ABSTRACT FROM AUTHOR]

Published

2011

12. Terminal deoxynucleotidyl transferase: The story of a misguided DNA polymerase

Author

Motea, Edward A. and Berdis, Anthony J.

Subjects

*DNA polymerases, *TRANSFERASES, *DNA synthesis, *GENETIC recombination, *PROTEIN kinases, *IMMUNOGLOBULINS, *NUCLEOTIDES, *PYROPHOSPHATES

Abstract

Abstract: Nearly every DNA polymerase characterized to date exclusively catalyzes the incorporation of mononucleotides into a growing primer using a DNA or RNA template as a guide to direct each incorporation event. There is, however, one unique DNA polymerase designated terminal deoxynucleotidyl transferase that performs DNA synthesis using only single-stranded DNA as the nucleic acid substrate. In this chapter, we review the biological role of this enigmatic DNA polymerase and the biochemical mechanism for its ability to perform DNA synthesis in the absence of a templating strand. We compare and contrast the molecular events for template-independent DNA synthesis catalyzed by terminal deoxynucleotidyl transferase with other well-characterized DNA polymerases that perform template-dependent synthesis. This includes a quantitative inspection of how terminal deoxynucleotidyl transferase binds DNA and dNTP substrates, the possible involvement of a conformational change that precedes phosphoryl transfer, and kinetic steps that are associated with the release of products. These enzymatic steps are discussed within the context of the available structures of terminal deoxynucleotidyl transferase in the presence of DNA or nucleotide substrate. In addition, we discuss the ability of proteins involved in replication and recombination to regulate the activity of the terminal deoxynucleotidyl transferase. Finally, the biomedical role of this specialized DNA polymerase is discussed focusing on its involvement in cancer development and its use in biomedical applications such as labeling DNA for detecting apoptosis. [Copyright &y& Elsevier]

Published

2010

13. Non-natural nucleotides as probes for the mechanism and fidelity of DNA polymerases

Author

Lee, Irene and Berdis, Anthony J.

Subjects

*DNA polymerases, *NUCLEOTIDES, *HYDROGEN bonding, *ADENINE, *THYMINE, *MUTAGENESIS, *DNA replication, *POLYMERIZATION

Abstract

Abstract: DNA is a remarkable macromolecule that functions primarily as the carrier of the genetic information of organisms ranging from viruses to bacteria to eukaryotes. The ability of DNA polymerases to efficiently and accurately replicate genetic material represents one of the most fundamental yet complex biological processes found in nature. The central dogma of DNA polymerization is that the efficiency and fidelity of this biological process is dependent upon proper hydrogen-bonding interactions between an incoming nucleotide and its templating partner. However, the foundation of this dogma has been recently challenged by the demonstration that DNA polymerases can effectively and, in some cases, selectively incorporate non-natural nucleotides lacking classic hydrogen-bonding capabilities into DNA. In this review, we describe the results of several laboratories that have employed a variety of non-natural nucleotide analogs to decipher the molecular mechanism of DNA polymerization. The use of various non-natural nucleotides has lead to the development of several different models that can explain how efficient DNA synthesis can occur in the absence of hydrogen-bonding interactions. These models include the influence of steric fit and shape complementarity, hydrophobicity and solvation energies, base-stacking capabilities, and negative selection as alternatives to rules invoking simple recognition of hydrogen-bonding patterns. Discussions are also provided regarding how the kinetics of primer extension and exonuclease proofreading activities associated with high-fidelity DNA polymerases are influenced by the absence of hydrogen-bonding functional groups exhibited by non-natural nucleotides. [Copyright &y& Elsevier]

Published

2010

14. Isothermal reactivating Whiplash PCR for locally programmable molecular computation.

Author

Reif, John H. and Majumder, Urmi

Subjects

*MOLECULAR computers, *ROBOTS, *DNA polymerases, *POLYMERIZATION, *POLYMERASE chain reaction

Abstract

Whiplash PCR (WPCR; Hagiya et al., in Rubin H, Woods DH (eds) DNA based computers, vol III, pp 55–72. American Mathematical Society, Providence, RI, ) is a novel technique for autonomous molecular computation where a state machine is implemented with a single stranded DNA molecule and state transition is driven by polymerase and thermal cycles. The primary difference between WPCR computation and other forms of molecular computing is that the former is based on local, rather than global rules. This allows many (potentially distinct) WPCR machines to run in parallel. However, since each state transition requires a thermal cycle, multi-step WPCR machines are laborious and time-consuming, effectively limiting program execution to only a few steps. To date, no WPCR protocol has been developed which is both autocatalytic (self-executing) and isothermal (with no change in temperature). In this paper, we describe some isothermal and autocatalytic protocols that use a combination of strand displacement and DNA polymerization events. Our designs include (1) a protocol where transition rules cannot be reused in subsequent computing (2) a protocol where rules can be reused using an auxiliary strand displacement event but does not prevent back-hybridization (an event responsible for limiting the program execution to only a few state transitions before the machine stalls), (3) a reusable rule protocol that prevents back-hybridization. Furthermore, we show that the third machine which gets rid of thermal cycles and still prevents back-hybridization, is computationally equivalent to the original WPCR machine. We also compute the state transition likelihood and the corresponding rate in this protocol. Finally we present a DNA sequence design of a 3-state isothermal and reactivating WPCR machine along with an experimental verification plan. [ABSTRACT FROM AUTHOR]

Published

2010

15. HIV-1 Reverse Transcriptase Mutants Resistant to Nonnucleoside Reverse Transcriptase Inhibitors Do Not Adversely Affect DNA Synthesis: Pre-Steady-State and Steady-State Kinetic Studies.

Author

Domaoal, Robert A., Bambara, Robert A., and Demeter, Lisa M.

Subjects

*AIDS, *DNA synthesis, *ENZYMES, *NUCLEOTIDES, *HIV infections

Abstract

The article discusses a study which examines the effects of HIV type 1 reverse transcriptase mutants resistant to nonnucleoside reverse transcriptase inhibitor (NNRTI). The objective of the study was to evaluate the polymerase functions of the NNRTI-resistant reverse transcriptase including K103N, P236L and V106A. The study showed that, the enzyme interactions with nucleotides created no significant effects on the NNRTI-resistance mutations.

Published

2006

16. Inhibiting translesion DNA synthesis as an approach to combat drug resistance to DNA damaging agents

Author

Seol Kim, Jung Suk Choi, Edward A. Motea, and Anthony J. Berdis

Subjects

DNA Replication, 0301 basic medicine, DNA polymerase, DNA damage, Antineoplastic Agents, DNA-Directed DNA Polymerase, Precursor T-Cell Lymphoblastic Leukemia-Lymphoma, chemotherapy, 03 medical and health sciences, chemistry.chemical_compound, Cell Line, Tumor, medicine, Humans, Nucleotide, nucleoside analogs, Genetics, chemistry.chemical_classification, DNA polymerization, biology, Nucleoside analogue, DNA synthesis, business.industry, leukemia, DNA, Neoplasm, humanities, genomic DNA, 030104 developmental biology, Oncology, chemistry, Drug Resistance, Neoplasm, biology.protein, Cancer research, business, Nucleoside, DNA, Research Paper, medicine.drug

Abstract

// Jung-Suk Choi 1 , Seol Kim 2 , Edward Motea 3 and Anthony Berdis 1, 2, 4, 5 1 Department of Chemistry, Cleveland State University, Cleveland, OH 44115, USA 2 Department of Biological, Geological, and Environmental Sciences, Cleveland State University, Cleveland, OH 44115, USA 3 Departments of Radiation Oncology and Pharmacology, Harold C. Simmons Comprehensive Cancer Center, UT Southwestern Medical Center, Dallas, TX 75390, USA 4 Center for Gene Regulation in Health and Disease, Cleveland State University, Cleveland, OH 44115, USA 5 Case Comprehensive Cancer Center, Cleveland, OH 44106, USA Correspondence to: Anthony Berdis, email: a.berdis@csuohio.edu Keywords: DNA damage, DNA polymerization, chemotherapy, nucleoside analogs, leukemia Received: February 24, 2017 Accepted: April 11, 2017 Published: April 19, 2017 ABSTRACT Anti-cancer agents exert therapeutic effects by damaging DNA. Unfortunately, DNA polymerases can effectively replicate the formed DNA lesions to cause drug resistance and create more aggressive cancers. To understand this process at the cellular level, we developed an artificial nucleoside that visualizes the replication of damaged DNA to identify cells that acquire drug resistance through this mechanism. Visualization is achieved using "click" chemistry to covalently attach azide-containing fluorophores to the ethynyl group present on the nucleoside analog after its incorporation opposite damaged DNA. Flow cytometry and microscopy techniques demonstrate that the extent of nucleotide incorporation into genomic DNA is enhanced by treatment with DNA damaging agents. In addition, this nucleoside analog inhibits translesion DNA synthesis and synergizes the therapeutic activity of certain anti-cancer agents such as temozolomide. The combined diagnostic and therapeutic activities of this synthetic nucleoside analog represent a new paradigm in personalized medicine.

Published

2017

17. Dissociation in a Polymerization Model of Homochirality.

Author

Brandenburg, A., Andersen, A., and Nilsson, M.

Abstract

A fully self-contained model of homochirality is presented that contains the effects of both polymerization and dissociation. The dissociation fragments are assumed to replenish the substrate from which new monomers can grow and undergo new polymerization. The mean length of isotactic polymers is found to grow slowly with the normalized total number of corresponding building blocks. Alternatively, if one assumes that the dissociation fragments themselves can polymerize further, then this corresponds to a strong source of short polymers, and an unrealistically short average length of only 3. By contrast, without dissociation, isotactic polymers becomes infinitely long. [ABSTRACT FROM AUTHOR]

Published

2005

18. Stereo-selectivity of HIV-1 reverse transcriptase toward isomers of thymidine-5′-O-1-thiotriphosphate.

Author

Radzio, Jessica and Sluis-Cremer, Nicolas

Abstract

The first pre-steady-state kinetic analysis of the stereo-selective incorporation of Rp- and Sp-isomers of thymidine-5′-O-1-thiotriphosphate (TTPαS) by HIV-1 reverse transcriptase (RT) is reported. Rates of polymerization (kpol), apparent dissociation constants (Kd), and substrate specificities (kpol/Kd) were measured for TTP, Rp-TTPαS, and Sp-TTPαS in the presence of Mg2+, Mn2+, and Co2+. HIV-1 RT exhibits a strong preference to incorporate Sp-TTPαS over Rp-TTPαS in the presence of Mg2+; however, this stereo-selective preference was decreased when Mg2+ was replaced with Mn2+ and Co2+. Furthermore, HIV-1 RT exhibited no phosphorothioate elemental effects for the incorporation of Sp-TTPαS, but large elemental effects were calculated for Rp-TTPαS for each of the metals tested. These results are discussed in relation to our current understanding of the RT active-site structure and the mechanism of DNA synthesis. [ABSTRACT FROM AUTHOR]

Published

2005

19. Homochiral Growth Through Enantiomeric Cross-Inhibition.

Author

Brandenburg, A., Andersen, A., Höfner, S., and Nilsson, M.

Abstract

The stability and conservation properties of a recently proposed polymerization model are studied. The achiral (racemic) solution is linearly unstable once the relevant control parameter (here the fidelity of the catalyst) exceeds a critical value. The growth rate is calculated for different fidelity parameters and cross-inhibition rates. A chirality parameter is defined and shown to be conserved by the nonlinear terms of the model. Finally, a truncated version of the model is used to derive a set of two ordinary differential equations and it is argued that these equations are more realistic than those used in earlier models of that form. [ABSTRACT FROM AUTHOR]

Published

2005

20. MECHANISTIC STUDY OF HIV-1 REVERSE TRANSCRIPTASE AT THE ACTIVE SITE BASED ON QM/MM METHOD.

Author

Rungrotmongkol, Thanyada, Hannongbua, Supa, and Adrian Mulholland

Subjects

*VIRAL genetics, *MICROBIAL genetics, *RNA, *AIDS, *THERAPEUTICS, *SIMULATION methods & models, *POLYMERS

Abstract

HIV-1 RT catalyses the reverse transcription of viral genetic material (RNA) into double-stranded DNA, and is an important target of antiviral therapy in the treatment of AIDS. Better understanding of the structure, mechanism and functional role of residues involved in the resistance of HIV-1 RT against nucleoside-analog drugs may assist in the development of improved inhibitors, and also in understanding the effects of genetic variation on RT specificity and activity. In this study, firstly, molecular dynamics simulations (with CHARMM27) have been used to investigate binding interactions at the active site and the conformational behavior of the enzyme, then, mechanisms of deprotonation and DNA polymerization reactions have been modelled by the QM/MM method. A combined quantum mechanical and molecular mechanical (QM/MM) method (AM1/CHARMM) has been used to study the triphosphate substrate and the active site of HIV-1 reverse transcriptase complex structure, a virally-encoded enzyme. Free energy profiles for the reaction are also calculated. The obtained results provide important insight into the mechanistic activity of HIV-1 RT. [ABSTRACT FROM AUTHOR]

Published

2004

21. A Toy Model for the Generation of Homochirality during Polymerization.

Author

Sandars, P.

Abstract

This article examines a toy model of polymerization which though artificial and unphysical has some interesting chiral features. Two key elements, enantiomeric cross inhibition and chiral feedback, are shown to lead to bifurcation, so that the end product can become homo-chiral. We find that the bifurcation is driven by the cross-inhibition but is not strongly dependant on its strength, which for perfect feedback fidelity mainly determines the time scale. We also find that bifurcation with a high degree of chiral polarization remains even when the fidelity of the chiral feedback is substantially less than unity. For small values of the feedback fidelity the polarization drops below unity and at a critical value falls sharply to zero in a `phase transition'. The value at which this happens depends on the cross-inhibition in a complex way. By comparing the behaviour of polymers differing only in their final length, N, we find that the bifurcation process is enhanced as N increases. The symmetry breaking which we find is clearly a particular manifestation of general bifurcation theory. In addition it has the specific interest that, at least in our model, long homochiral polymers are possible even in the presence of substantial enantiomeric cross-inhibition. [ABSTRACT FROM AUTHOR]

Published

2003

22. Molecular mechanisms of HIV-1 resistance to nucleoside reverse transcriptase inhibitors (NRTIs).

Author

Sluis-Cremer, N., Arion, D., and Parniak, M. A.

Subjects

HIV, AIDS, NUCLEOSIDES, NUCLEOTIDES, DNA, POLYMERIZATION

Abstract

Nucleoside reverse transcriptase inhibitors (NRTIs), such as 3′-azido-3′-deoxythymidine, 2′,3′-dideoxyinosine and 2′,3′-dideoxy-3′-thiacytidine, are effective inhibitors of human immunodeficiency type 1 (HIV-1) replication. NRTIs are deoxynucleoside triphosphate analogs, but lack a free 3′-hydroxyl group. Once NRTIs are incorporated into the nascent viral DNA, in reactions catalyzed by HIV-1 reverse transcriptase (RT), further viral DNA synthesis is effectively terminated. NRTIs should therefore represent the ideal antiviral agent. Unfortunately, HIV-1 inevitably develops resistance to these inhibitors, and this resistance correlates with mutations in RT. To date, three phenotypic mechanisms have been identified or proposed to account for HIV-1 RT resistance to NRTIs. These mechanisms include alterations of RT discrimination between NRTIs and the analogous dNTP (direct effects on NRTI binding and/or incorporation), alterations in RT-template/primer interactions, which may influence subsequent NRTI incorporation, and enhanced removal of the chain-terminating residue from the 3′ end of the primer. These different resistance phenotypes seem to correlate with different sets of mutations in RT. This review discusses the relationship between HIV-1 drug resistance genotype and phenotype, in relation to our current knowledge of HIV-1 RT structure. [ABSTRACT FROM AUTHOR]

Published

2000

23. Determining 3'-Termini and Sequences of Nascent Single-Stranded Viral DNA Molecules during HIV-1 Reverse Transcription in Infected Cells

Author

Michael H. Malim, Andrew Sobala, and Darja Pollpeter

Subjects

General Immunology and Microbiology, DNA polymerization, General Chemical Engineering, General Neuroscience, Oligonucleotides, HIV Infections, Reverse Transcription, Virus Replication, General Biochemistry, Genetics and Molecular Biology, Article, Issue 143, deep sequencing, HEK293 Cells, 3'-terminus mapping, DNA, Viral, viral replication intermediates, HIV-1, Genetics, Humans, adaptor ligation, HIV-1 reverse transcripts, unbiased ssDNA ligation

Abstract

Monitoring of nucleic acid intermediates during virus replication provides insights into the effects and mechanisms of action of antiviral compounds and host cell proteins on viral DNA synthesis. Here we address the lack of a cell-based, high-coverage, and high-resolution assay that is capable of defining retroviral reverse transcription intermediates within the physiological context of virus infection. The described method captures the 3'-termini of nascent complementary DNA (cDNA) molecules within HIV-1 infected cells at single nucleotide resolution. The protocol involves harvesting of whole cell DNA, targeted enrichment of viral DNA via hybrid capture, adaptor ligation, size fractionation by gel purification, PCR amplification, deep sequencing, and data analysis. A key step is the efficient and unbiased ligation of adaptor molecules to open 3'-DNA termini. Application of the described method determines the abundance of reverse transcripts of each particular length in a given sample. It also provides information about the (internal) sequence variation in reverse transcripts and thereby any potential mutations. In general, the assay is suitable for any questions relating to DNA 3'-extension, provided that the template sequence is known.

Published

2019

24. Magnesium reduces nickel inhibition of DNA polymerization.

Author

Lynn, Shugene, Yew, F., and Jan, K.

Abstract

The activities of DNA polymerization and DNA ligation in extract of Chinese hamster ovary cells were both stimulated by MgCl2. DNA polymerization was stimulated by MgCl2 above 0.25 mM, whereas, MgCl2 above 2 mM was required to stimulate DNA ligation. The activity of DNA polymerization maintained a plateau at MgCl2 1–12 mM, whereas DNA ligation reached a maximal activity at MgCl2 6 mM and decreased thereafter. NiCl2 0.1-0.2 mM also had a stimulatory effect on DNA polymerization, but was much less potent than MgCl2. However, nickel ion (Ni2+) had no detectable stimulating effect on the activity of DNA ligation. In the presence of MgCl2, the activities of DNA polymerization and DNA ligation decreased with increasing concentration of NiCl2. Ni2+ inhibition of DNA polymerization was reduced by increasing the concentration of MgCl2, but increasing the concentration of MgCl2 did not reduce Ni2+ inhibition of DNA ligation. Preincubating cell extract with MgCl2 decreased the Ni2+ inhibition of DNA polymerization but not DNA ligation. These results suggest that Ni2+ may compete with magnesium ion (Mg2+) to reduce DNA polymerization, but this mechanism seems not applicable to Ni2+ inhibition of DNA ligation. [ABSTRACT FROM AUTHOR]

Published

1997

25. The structure of FIV reverse transcriptase and its implications for non-nucleoside inhibitor resistance

Author

Meytal Galilee and Akram Alian

Subjects

0301 basic medicine, RNA viruses, Models, Molecular, Feline immunodeficiency virus, Molecular biology, animal diseases, viruses, Mutant, medicine.disease_cause, Pathology and Laboratory Medicine, Crystallography, X-Ray, Biochemistry, Protein Structure, Secondary, Protein structure, Immunodeficiency Viruses, Medicine and Health Sciences, Enzyme Inhibitors, lcsh:QH301-705.5, Peptide sequence, Crystallography, biology, Chemistry, Physics, virus diseases, RNA-Directed DNA Polymerase, Condensed Matter Physics, 3. Good health, SIV, Medical Microbiology, Viral Pathogens, Lentivirus, Viruses, Physical Sciences, Crystal Structure, Reverse Transcriptase Inhibitors, Pathogens, Research Article, lcsh:Immunologic diseases. Allergy, Viral protein, Immunology, DNA construction, Immunodeficiency Virus, Feline, Microbiology, 03 medical and health sciences, Virology, Feline Acquired Immunodeficiency Syndrome, Retroviruses, Drug Resistance, Viral, Genetics, medicine, Solid State Physics, Animals, Amino Acid Sequence, Microbial Pathogens, 030102 biochemistry & molecular biology, DNA polymerization, DNA manipulations, Organisms, Biology and Life Sciences, HIV, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Reverse transcriptase, Fiv, Viral Replication, Protein Structure, Tertiary, Research and analysis methods, 030104 developmental biology, Molecular biology techniques, lcsh:Biology (General), Viral replication, HIV-2, HIV-1, Enzymology, Cats, Lentivirus Infections, Parasitology, lcsh:RC581-607

Abstract

Reverse transcriptase (RT) is the target for the majority of anti-HIV-1 drugs. As with all anti-AIDS treatments, continued success of RT inhibitors is persistently disrupted by the occurrence of resistance mutations. To explore latent resistance mechanisms potentially accessible to therapeutically challenged HIV-1 viruses, we examined RT from the related feline immunodeficiency virus (FIV). FIV closely parallels HIV-1 in its replication and pathogenicity, however, is resistant to all non-nucleoside inhibitors (NNRTI). The intrinsic resistance of FIV RT is particularly interesting since FIV harbors the Y181 and Y188 sensitivity residues absent in both HIV-2 and SIV. Unlike RT from HIV-2 or SIV, previous efforts have failed to make FIV RT susceptible to NNRTIs concluding that the structure or flexibility of the feline enzyme must be profoundly different. We report the first crystal structure of FIV RT and, being the first structure of an RT from a non-primate lentivirus, enrich the structural and species repertoires available for RT. The structure demonstrates that while the NNRTI binding pocket is conserved, minor subtleties at the entryway can render the FIV RT pocket more restricted and unfavorable for effective NNRTI binding. Measuring NNRTI binding affinity to FIV RT shows that the “closed” pocket configuration inhibits NNRTI binding. Mutating the loop residues rimming the entryway of FIV RT pocket allows for NNRTI binding, however, it does not confer sensitivity to these inhibitors. This reveals a further layer of resistance caused by inherent FIV RT variances that could have enhanced the dissociation of bound inhibitors, or, perhaps, modulated protein plasticity to overcome inhibitory effects of bound NNRTIs. The more “closed” conformation of FIV RT pocket can provide a template for the development of innovative drugs that could unlock the constrained pocket, and the resilient mutant version of the enzyme can offer a fresh model for the study of NNRTI-resistance mechanisms overlooked in HIV-1., Author summary The majority of anti-AIDS drugs target the reverse transcriptase (RT) enzyme of the HIV-1 virus. RT catalyzes the central step in the virus replication cycle converting the viral RNA genome into DNA for subsequent integration into the host genome. As with all anti-AIDS treatments, continued success of RT inhibitors is persistently disrupted by the occurrence of resistance mutations. To explore latent resistance mechanisms potentially accessible to therapeutically challenged HIV-1 viruses, we examined RT from the related feline immunodeficiency virus (FIV). FIV closely parallels HIV-1 in its replication and pathogenicity however is resistant to all non-nucleoside inhibitors of HIV-1 RT. We resolved the crystal structure of FIV RT, and using mutational and biochemical analyses, we show that specific differences in the FIV RT structure inhibit the binding of non-nucleoside inhibitors. We further show that mutating the protein to facilitate binding of the inhibitors does not confer sensitivity to these inhibitors, suggesting that other variances inherent in FIV RT modulate a second layer of resistance. These insights can help in the development of novel drugs against evolving HIV-1 RT resistance.

Published

2018

26. Artificial Nucleosides as Diagnostic Probes to Measure Translesion DNA Synthesis.

Author

Choi JS and Berdis A

Subjects

Catalysis, Click Chemistry, DNA chemistry, DNA Damage, DNA Repair, DNA Replication, Indoles chemistry, Nucleosides chemistry, Nucleotides chemistry

Abstract

The misreplication of damaged DNA, a biological process termed translesion DNA synthesis (TLS), produces a large number of adverse effects on human health. This chapter describes the application of an artificial nucleoside/nucleotide system that functions as a biochemical probe to quantify TLS activity under in vitro and in vivo conditions. For in vitro studies, the artificial nucleotide, 3-ethynyl-5-nitroindolyl-2'-deoxyriboside triphosphate (3-Eth-5-NITP), is used as it is efficiently inserted opposite an abasic site, a highly pro-mutagenic DNA lesion produced by several types of DNA-damaging agents. The placement of the ethynyl moiety allows the incorporated nucleoside triphosphate to be selectively tagged with azide-containing fluorophores via "click" chemistry. This reaction provides a facile way to quantify the extent of nucleotide incorporation opposite this and other noninstructional DNA lesions. The corresponding nucleoside, 3-Eth-5-NIdR, can be used to monitor TLS activity in hematological and adherent cancer cells treated with compounds that produce noninstructional DNA lesions. As described above, visualizing the replication of these lesions is achieved using copper-catalyzed "click" chemistry to tag the ethynyl moiety present on the nucleotide with fluorogenic probes. This technique represents a new diagnostic approach to quantify TLS activity inside cells. In addition, the application of this "clickable" nucleoside provides a chemical probe to identify cells that become drug resistant by the facile replication of noninstructional DNA lesions produced by DNA-damaging agents.

Published

2019

27. Graphene-Assisted Label-Free Homogeneous Electrochemical Biosensing Strategy based on Aptamer-Switched Bidirectional DNA Polymerization.

Author

Wang W, Ge L, Sun X, Hou T, and Li F

Subjects

Aptamers, Nucleotide genetics, Biosensing Techniques instrumentation, DNA genetics, Electrochemical Techniques instrumentation, Polymerization, Aptamers, Nucleotide chemistry, Biosensing Techniques methods, DNA chemistry, Electrochemical Techniques methods, Graphite chemistry

Abstract

In this contribution, taking the discrimination ability of graphene over single-stranded (ss) DNA/double-stranded (ds) DNA in combination with the electrochemical impedance transducer, we developed a novel label-free homogeneous electrochemical biosensor using graphene-modified glassy carbon electrode (GCE) as the sensing platform. To convert the specific aptamer-target recognition into ultrasensitive electrochemical signal output, a novel aptamer-switched bidirectional DNA polymerization (BDP) strategy, capable of both target recycling and exponential signal amplification, was compatibly developed in this study. In this strategy, all the designed DNA structures could be adsorbed on the graphene/GCE and, thus, serve as the electrochemical impedance signal reporter, while the target acts as a trigger of this BDP reaction, in which these designed DNA structures are bound together and, then, converted to long dsDNA duplex. The distinct difference in electrochemical impedance spectroscopy between the designed structures and generated long dsDNA duplex on the graphene/GCE allows label-free and homogeneous detection of target down to femto-gram level. The target can be displaced from aptamer through the polymerization to initiate the next recognition-polymerization cycle. Herein, the design and signaling principle of aptamer-switched BDP amplification system were elucidated, and the working conditions were optimized. This method not only provides a universal platform for electrochemical biosensing but also shows great potential in biological process researches and clinic diagnostics.

Published

2015

28. The Tryptophan Mutant in the Human Immunodeficiency Virus Type 1 Reverse Transcriptase Active Site

Author

Chery, Jessica, Operario, Darwin Joseph, Kim, Baek, Chery, Jessica, Operario, Darwin Joseph, and Kim, Baek

Abstract

Human Immunodeficiency Virus (HIV) is a lentivirus whose infection in humans eventually leads to Acquired Immunodeficiency Syndrome, better known as AIDS. AIDS is characterized by a dysfunctional immune system, more specifically during the !are stages of the HIV infection. When an individual contracts HIV, the virus attacks rhe body's immune system, which is responsible for fighting diseases and viruses. HIV is known to infect two types of cells in the body: CD4+ T cells and macrophages. When CD4+ T cells are attacked and killed, the immune system loses irs ability to coordinate immune responses against pathogens. This affects both cell-mediated responses (with CDS+ T cells) and responses with antibody-producing cells (B cells/plasma cells) . In other words, this causes an individual infected with HIV to become more susceptible to ill nesses and diseases than an uninfecred individual because his/her immune system is no longer able to mount a proper immune response to the pathogen. With a decrease in immune response, HIV continues to grow by producing "billions of new HIV viruses in the body" increasing an infected individual's susceptibility to all sorts of diseases, such as the common cold, flu, or other equally frequent virus infections. .

29. Role of Mitotic Replication Genes in Chromosome Duplication during Meiosis

Author

Zamb, T. J. and Roth, R.

Published

1977