The crystal structure of d(GGm5CCGGCC): The effect of methylation on A‐DNA structure and stability

Christin A. Frederick; Daniel Saal; Gijs A. Van Der Marel; Jacques H. Van Boom; Andrew H.‐J Wang; Alexander Rich

doi:10.1002/bip.360260014

The crystal structure of d(GGm⁵CCGGCC): The effect of methylation on A‐DNA structure and stability

Christin A. Frederick, Daniel Saal, Gijs A. Van Der Marel, Jacques H. Van Boom, Andrew H.‐J Wang, Alexander Rich

Research output: Contribution to journal › Article › peer-review

11 Citations (Scopus)

Abstract

We describe the crystal structure of an octameric DNA sequence, d(GGm⁵CCGGCC), at 2.25 Å resolution. The sequence contains one C5‐methylated cytosine per DNA strand. This methylation corresponds to that utilized in vivo by the HaeIII restriction modification system. The present structure is compared to that of the unmethylated octamer solved previously as well as to other A‐DNA crystal structures. It retains the characteristics seen in these other DNA molecules, i.e., reduced base‐pair tilt angles and increased major groove width, indicating that the presence of the methyl groups does not drastically affect the A‐DNA backbone conformation. The position of the methyl groups appears to block the major grove, thus preventing potential sequence‐specific protein interactions. In addition, the presence of these hydrophobic substituents may enhance the overall stability of the A‐DNA conformation.

Original language	English
Pages (from-to)	S145-S160
Journal	Biopolymers
Volume	26
Issue number	S0
DOIs	https://doi.org/10.1002/bip.360260014
Publication status	Published - 1987
Externally published	Yes

ASJC Scopus subject areas

Biophysics
Biochemistry
Biomaterials
Organic Chemistry

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title = "The crystal structure of d(GGm5CCGGCC): The effect of methylation on A‐DNA structure and stability",

abstract = "We describe the crystal structure of an octameric DNA sequence, d(GGm5CCGGCC), at 2.25 {\AA} resolution. The sequence contains one C5‐methylated cytosine per DNA strand. This methylation corresponds to that utilized in vivo by the HaeIII restriction modification system. The present structure is compared to that of the unmethylated octamer solved previously as well as to other A‐DNA crystal structures. It retains the characteristics seen in these other DNA molecules, i.e., reduced base‐pair tilt angles and increased major groove width, indicating that the presence of the methyl groups does not drastically affect the A‐DNA backbone conformation. The position of the methyl groups appears to block the major grove, thus preventing potential sequence‐specific protein interactions. In addition, the presence of these hydrophobic substituents may enhance the overall stability of the A‐DNA conformation.",

author = "Frederick, {Christin A.} and Daniel Saal and {Van Der Marel}, {Gijs A.} and {Van Boom}, {Jacques H.} and Wang, {Andrew H.‐J} and Alexander Rich",

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doi = "10.1002/bip.360260014",

language = "English",

volume = "26",

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journal = "Biopolymers",

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TY - JOUR

T1 - The crystal structure of d(GGm5CCGGCC)

T2 - The effect of methylation on A‐DNA structure and stability

AU - Frederick, Christin A.

AU - Saal, Daniel

AU - Van Der Marel, Gijs A.

AU - Van Boom, Jacques H.

AU - Wang, Andrew H.‐J

AU - Rich, Alexander

PY - 1987

Y1 - 1987

N2 - We describe the crystal structure of an octameric DNA sequence, d(GGm5CCGGCC), at 2.25 Å resolution. The sequence contains one C5‐methylated cytosine per DNA strand. This methylation corresponds to that utilized in vivo by the HaeIII restriction modification system. The present structure is compared to that of the unmethylated octamer solved previously as well as to other A‐DNA crystal structures. It retains the characteristics seen in these other DNA molecules, i.e., reduced base‐pair tilt angles and increased major groove width, indicating that the presence of the methyl groups does not drastically affect the A‐DNA backbone conformation. The position of the methyl groups appears to block the major grove, thus preventing potential sequence‐specific protein interactions. In addition, the presence of these hydrophobic substituents may enhance the overall stability of the A‐DNA conformation.

AB - We describe the crystal structure of an octameric DNA sequence, d(GGm5CCGGCC), at 2.25 Å resolution. The sequence contains one C5‐methylated cytosine per DNA strand. This methylation corresponds to that utilized in vivo by the HaeIII restriction modification system. The present structure is compared to that of the unmethylated octamer solved previously as well as to other A‐DNA crystal structures. It retains the characteristics seen in these other DNA molecules, i.e., reduced base‐pair tilt angles and increased major groove width, indicating that the presence of the methyl groups does not drastically affect the A‐DNA backbone conformation. The position of the methyl groups appears to block the major grove, thus preventing potential sequence‐specific protein interactions. In addition, the presence of these hydrophobic substituents may enhance the overall stability of the A‐DNA conformation.

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The crystal structure of d(GGm⁵CCGGCC): The effect of methylation on A‐DNA structure and stability

Abstract

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