Base pair fluctuations in helical models for nucleic acids

1. Mechanisms of nucleic acid (NA) unwinding by helicases 4322. Helicases may take advantage of ‘breathing’ fluctuations in dsNAs 4342.1 Stability and dynamics of dsNAs 4342.2 dsNAs ‘breathe’ in isolation 4352.3 Thermodynamics of terminal base pairs of dsNA 4382.4 Thermal fluctuations may be responsible for sequential base-pair opening at replication forks 4392.5 Helicases may capture single base-pair opening events sequentially 4403. Biochemical properties of helicases 4433.1 Binding of NAs 4433.2 Binding and hydrolysis of NTP 4453.3 Coordination between NA binding and NTP binding and hydrolysis activities 4464. Helicase structures and mechanistic consequences 4474.1 Amino-acid sequence analysis reveals conserved motifs that constitute the NTP-binding pocket and a portion of the NA-binding site 4474.2 Organization of hepatitis virus C NS3 RNA helicase 4494.2.1 Biochemical properties of HCV NS3 4494.2.2 Crystal structures of HCV NS3 helicase 4504.2.2.1 The apoprotein 4504.2.2.2 The protein–dU8 complex 4504.2.3 A possible unwinding mechanism 4524.2.4 What is the functional oligomeric state of HCV NS3? 4524.3 Organization of the PcrA helicase 4534.3.1 The apoenzyme and ADP–PcrA complex 4544.3.2 The protein–DNA–sulfate complex 4564.3.3 The PcrA–DNA–ADPNP complex 4564.3.4 A closer look at the NTP-binding site in the crystal structure of PcrA–ADPNP–DNA 4574.3.5 Communication between domains A and B 4574.3.6 How might ssDNA stimulate the ATPase activity of PcrA? 4574.3.7 A possible helicase translocation mechanism 4584.3.8 A possible unwinding mechanism 4584.4 Organization of the Rep helicase 4594.4.1 Biochemical properties 4594.4.2 Crystal structure of Rep bound to ssDNA 4624.5 Organization of the RecG helicase 4624.6 Hexameric helicases 4664.6.1 Insights from crystal structures of hexameric helicases 4674.6.2 Possible translocation and unwinding mechanisms 4685. Conclusions 4696. Acknowledgments 4727. References 472Helicases are proteins that harness the chemical free energy of ATP hydrolysis to catalyze the unwinding of double-stranded nucleic acids. These enzymes have been much studied in isolation, and here we review what is known about the mechanisms of the unwinding process. We begin by considering the thermally driven ‘breathing’ of double-stranded nucleic acids by themselves, in order to ask whether helicases might take advantage of some of these breathing modes. We next provide a brief summary of helicase mechanisms that have been elucidated by biochemical, thermodynamic, and kinetic studies, and then review in detail recent structural studies of helicases in isolation, in order to correlate structural findings with biophysical and biochemical results. We conclude that there are certainly common mechanistic themes for helicase function, but that different helicases have devised solutions to the nucleic acid unwinding problem that differ in structural detail. In Part II of this review (to be published in the next issue of this journal) we consider how these mechanisms are further modified to reflect the functional coupling of these proteins into macromolecular machines, and discuss the role of helicases in several central biological processes to illustrate how this coupling actually works in the various processes of gene expression.

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Pyrazolo[3,4-d]pyrimidine Nucleic Acids: Adjustment of the dA-dT to the dG-dC Base Pair Stability

ChemInform ◽

10.1002/chin.200402210 ◽

2004 ◽

Vol 35 (2) ◽

Author(s):

J. He ◽

G. Becher ◽

S. Budow ◽

F. Seela

Keyword(s):

Nucleic Acids ◽

Base Pair

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Enzymatic incorporation of an unnatural base pair between 4-propynyl-pyrrole-2-carbaldehyde and 9-methyl-imidazo[(4,5)-b]pyridine into nucleic acids

Nucleic Acids Symposium Series ◽

10.1093/nass/2.1.219 ◽

2002 ◽

Vol 2 (1) ◽

pp. 219-220 ◽

Cited By ~ 3

Author(s):

T. Mitsui ◽

M. Kimoto ◽

Y. Harada ◽

A. Sato ◽

A. Kitamura ◽

...

Keyword(s):

Nucleic Acids ◽

Base Pair

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Pyrazolo[3,4-d]pyrimidine Nucleic Acids: Adjustment of the dA-dT to the dG-dC Base Pair Stability

Nucleosides Nucleotides & Nucleic Acids ◽

10.1081/ncn-120021957 ◽

2003 ◽

Vol 22 (5-8) ◽

pp. 573-576 ◽

Cited By ~ 3

Author(s):

J. He ◽

G. Becher ◽

S. Budow ◽

F. Seela

Keyword(s):

Nucleic Acids ◽

Base Pair

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SNP Discrimination by Tolane-Modified Peptide Nucleic Acids: Application for the Detection of Drug Resistance in Pathogens

Molecules ◽

10.3390/molecules25040769 ◽

2020 ◽

Vol 25 (4) ◽

pp. 769 ◽

Cited By ~ 1

Author(s):

Kenji Takagi ◽

Tenko Hayashi ◽

Shinjiro Sawada ◽

Miku Okazaki ◽

Sakiko Hori ◽

...

Keyword(s):

Drug Resistance ◽

Nucleic Acids ◽

Base Pair ◽

Bacterial Infections ◽

Peptide Nucleic Acids ◽

Conformational Search ◽

Target Sequence ◽

Single Base ◽

Influenza A H1n1 ◽

Mismatched Base Pair

During the treatment of viral or bacterial infections, it is important to evaluate any resistance to the therapeutic agents used. An amino acid substitution arising from a single base mutation in a particular gene often causes drug resistance in pathogens. Therefore, molecular tools that discriminate a single base mismatch in the target sequence are required for achieving therapeutic success. Here, we synthesized peptide nucleic acids (PNAs) derivatized with tolane via an amide linkage at the N-terminus and succeeded in improving the sequence specificity, even with a mismatched base pair located near the terminal region of the duplex. We assessed the sequence specificities of the tolane-PNAs for single-strand DNA and RNA by UV-melting temperature analysis, thermodynamic analysis, an in silico conformational search, and a gel mobility shift assay. As a result, all of the PNA-tolane derivatives stabilized duplex formation to the matched target sequence without inducing mismatch target binding. Among the different PNA-tolane derivatives, PNA that was modified with a naphthyl-type tolane could efficiently discriminate a mismatched base pair and be utilized for the detection of resistance to neuraminidase inhibitors of the influenza A/H1N1 virus. Therefore, our molecular tool can be used to discriminate single nucleotide polymorphisms that are related to drug resistance in pathogens.

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