Chemistry Reference
In-Depth Information
80.
Hazra , T.K. ; Kow , Y.W. ; Hatahet , Z. ; Imhoff , B. ; Boldogh , I. ; Mokkapati , S.K. ; Mitra , S . ;
Izumi , T. ; Identifi cation and characterization of a novel human DNA glycosylase for
repair of cytosine derived lesions;
J. Biol. Chem.
, 2002 ,
277
, 30417 - 30420 .
Dou , H. ; Mitra , S. ; Hazra , T.K. ; Repair of oxidized bases in DNA bubble structures by
human DNA glycosylases NEIL1 and NEIL2;
J. Biol. Chem.
, 2003 ,
278
, 49679 - 49684 .
Hailer , M.K ; Slade , P.G. ; Martin , B.D. ; Rosenquist , T.A. ; Sugden , K.D. ; Recognition of
the oxidized lesions spiroiminodihydantoin and guanidinohydantoin in DNA by the
mammalian base excision repair glycosylases NEIL1 and NEIL2;
DNA Repair
, 2005 ,
4
,
41 - 50 .
Bruner , S.D. ; Norman , D.P. ; Verdine , G.L. ; Structural basis for recognition and repair of
the endogenous mutagen 8- oxoguanine in DNA ;
Nature
, 2000 ,
403
, 859 - 866 .
Mokkapati , S.K. ; Wiederhold , L. ; Hazra , T.K. ; Mitra , S. ; Stimulation of DNA glycosylase
activity of OGG1 by NEIL1: functional collaboration between two human DNA glyco-
sylases ;
Biochem.
, 2004 ,
43
, 11596 - 11604 .
Hazra , T.K. ; Izumi , T. ; Boldogh , I. ; Imhoff , B. ; Kow , Y.W. ; Jaruga , P. ; Dizdaroglu , M. ; Mitra ,
S. ; Identifi cation and characterization of a human DNA glycosylase for repair of modi-
fi ed bases in oxidatively damaged DNA;
Proc. Natl. Acad. Sci. USA
,
81.
82.
83.
84.
85.
2002 ,
99
,
3523 - 3528 .
Dou , H. ; Theriot , C.A. ; Das , A. ; Hedge , M.L. ; Matsumoto , Y. ; Boldogh , I. ; Hazra , T.K. ;
Bhakat , K.K. ; Mitra, S.; Interaction of the human DNA glycosylase NEIL1 with prolif-
erating cell nuclear antigen: The potential for replication- associated - repair of oxidized
bases in mammalian genomes;
J. Biol. Chem.
, 2008 ,
283
, 3130 - 3140 .
Jia , L. ; Shafi rovich , V. ; Geacintov , N.E. ; Broyde , S. ; Lesion specifi city in the base excision
repair enzyme hNeil1: Modeling and dynamoics studies;
Biochem.
,
86.
87.
2007 ,
46
,
5305 - 5314 .
Sugden , K.D. ; Wetterhahn , K.E. ; Direct and hydrogen peroxide- induced chromium(V)
oxidation of deoxyribose in single- stranded and double -stranded calf thymus DNA;
Chem. Res. Toxicol.
, 1997 ,
10
, 1397 - 1406 .
Pogoselski , W.K. ; Tullius , T.D. ; Oxidative strand scission of nucleic acids: routes initiated
by hydrogen abstraction from the sugar moiety;
Chem. Rev.
, 1998 ,
98
, 1089 - 1107 .
Breen , P.A. ; Murphy , J.A. ; Reactions of oxyl radicals with DNA;
Free Rad. Biol. Med.
,
1995 ,
18
, 1033 - 1077 .
Sugden , K.D. ; Formation of modifi ed cleavage termini from the reaction of chromium(V)
with DNA;
J. Inorg. Biochem.
, 1999 ,
77
, 177 - 183 .
Sugden , K.D. ; Wetterhahn , K.E. ; EPR evidence for chromium(V) binding to phosphate
and pyrophosphate: implications for chromium(V)- DNA interactions ;
Inorg. Chem.
,
1996 ,
35
, 3727 - 3728 .
Caldecott ,
88.
89.
90.
91.
92.
93.
K.W. ;
XRCC1
and
DNA
strand
break
repair ;
DNA Repair
,
2003 ,
2
,
955 - 969 .
W i s e , S r . J . P . ; W i s e , S.S. ; Little , J.E. ; The cytotoxicity and genotoxicity of particulate and
soluble hexavalent chromium in human lung cells;
Mutat. Res.
, 2002 ,
517
, 221 - 229 .
Damia , G. , D ' Incalci , M. ; Targeting DNA repair as a promising approach in cancer
therapy ;
Eur. J. Cancer
, 2007 ,
43
, 1791 - 1801 .
Caldecott , K.W. ; DNA single - strand breaks and neurodegeneration ;
DNA Repair
, 2004 ,
3
, 875 - 882 .
Blankert , S.A. ; Coryell , V.H. ; Picard , B.T. ; Wolf , K.K. ; Lomas , R.E. ; Stearns , D.M. ; Char-
acterization of nonmutagenic Cr(III)- DNA Interactions ;
Chem. Res. Toxicol.
, 2003 ,
16
,
847 - 854 .
Gelasco , A.; Lippard, S.J.; NMR solution structure of a DNA dodecamer duplex contain-
ing a
cis
-diammineplatinum(II) d(GpG) intrastrand crosslink, the major adduct of the
anticancer drug Cisplatin;
Biochem.
, 1998 ,
37
, 9230 - 9239 .
Lippard , S.J. ; New chemistry of an old molecule:
cis
- [Pt(NH
3
)
2
Cl
2
];
Science
, 1982 ,
218
,
1075 - 1082 .
Zhitkovich , A. ; Song , Y. ; Quievryn , G. ; Voitkun , V. ; Non - oxidative mechanisms are
responsible for the induction of mutagenesis by reduction of Cr(VI) with cysteine: role
94.
95.
96.
97.
98.
99.
100.