Jason G. Warren scite author profile

Mismatch repair (MMR) ensures the fidelity of DNA replication, initiates the cellular response to certain classes of DNA damage, and has been implicated in the generation of immune diversity. Each of these functions depends on MutSalpha (MSH2*MSH6 heterodimer). Inactivation of this protein complex is responsible for tumor development in about half of known hereditary nonpolyposis colorectal cancer kindreds and also occurs in sporadic tumors in a variety of tissues. Here, we describe a series of crystal structures of human MutSalpha bound to different DNA substrates, each known to elicit one of the diverse biological responses of the MMR pathway. All lesions are recognized in a similar manner, indicating that diversity of MutSalpha-dependent responses to DNA lesions is generated in events downstream of this lesion recognition step. This study also allows rigorous mapping of cancer-causing mutations and furthermore suggests structural pathways for allosteric communication between different regions within the heterodimer.

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Structures of GRP94-Nucleotide Complexes Reveal Mechanistic Differences between the hsp90 Chaperones

Dollins

et al. 2007

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GRP94, an essential endoplasmic reticulum chaperone, is required for the conformational maturation of proteins destined for cell-surface display or export. The extent to which GRP94 and its cytosolic paralog, Hsp90, share a common mechanism remains controversial. GRP94 has not been shown conclusively to hydrolyze ATP or bind cochaperones, and both activities, by contrast, result in conformational changes and N-terminal dimerization in Hsp90 that are critical for its function. Here, we report the 2.4 A crystal structure of mammalian GRP94 in complex with AMPPNP and ADP. The chaperone is conformationally insensitive to the identity of the bound nucleotide, adopting a "twisted V" conformation that precludes N-terminal domain dimerization. We also present conclusive evidence that GRP94 possesses ATPase activity. Our observations provide a structural explanation for GRP94's observed rate of ATP hydrolysis and suggest a model for the role of ATP binding and hydrolysis in the GRP94 chaperone cycle.

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The structural basis for the mutagenicity of O ⁶ -methyl-guanine lesions

Warren

Forsberg

Beese

2006

Proc. Natl. Acad. Sci. U.S.A.

139

178

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Methylating agents are widespread environmental carcinogens that generate a broad spectrum of DNA damage. Methylation at the guanine O 6 position confers the greatest mutagenic and carcinogenic potential. DNA polymerases insert cytosine and thymine with similar efficiency opposite O 6 -methyl-guanine (O6MeG). We combined pre-steady-state kinetic analysis and a series of nine x-ray crystal structures to contrast the reaction pathways of accurate and mutagenic replication of O6MeG in a high-fidelity DNA polymerase from Bacillus stearothermophilus. Polymerases achieve substrate specificity by selecting for nucleotides with shape and hydrogen-bonding patterns that complement a canonical DNA template. Our structures reveal that both thymine and cytosine O6MeG base pairs evade proofreading by mimicking the essential molecular features of canonical substrates. The steric mimicry depends on stabilization of a rare cytosine tautomer in C⅐O6MeG-polymerase complexes. An unusual electrostatic interaction between O-methyl protons and a thymine carbonyl oxygen helps stabilize T⅐O6MeG pairs bound to DNA polymerase. Because DNA methylators constitute an important class of chemotherapeutic agents, the molecular mechanisms of replication of these DNA lesions are important for our understanding of both the genesis and treatment of cancer.crystal structure ͉ DNA damage ͉ DNA polymerase ͉ protein-DNA complex A lkylating agents are potent environmental carcinogens that are produced by burning tobacco or in grilling foods (1, 2) and also may be formed enzymatically in vivo (3, 4), for instance, by enzymatic metabolite nitrosation (5). Such agents cause a broad spectrum of DNA lesions. Although modifications at the O6 position of guanine constitute a minority of the total lesions, they are the most carcinogenic (6-8). The cytotoxic effects of DNA-methylating agents have been exploited in their use as potent anticancer agents. O 6 -methyl-guanine (O6MeG) is mutagenic because polymerases frequently misinsert T opposite O6MeG instead of C, both in vivo (9, 10) and in vitro (11)(12)(13). In this study, we present the crystal structures of complexes of a high-fidelity DNA polymerase with substrates representing several steps of nucleotide insertion opposite O6MeG. Additionally, we have engineered a substrate in which the O6MeG⅐C/T pair lies in DNA outside the binding site of the polymerase, allowing us to compare the conformation of these base pairs in duplex DNA to the conformation of the base pairs constrained in the polymerase active site.The relative preference for incorporation of T and C opposite an O6MeG lesion varies somewhat with polymerase and sequence context (13). High-fidelity polymerases such as exonuclease-deficient E. coli polymerase I (Klenow fragment) (13) or bacteriophage T7 DNA polymerase (11) show an Ϸ7-fold preference for misinsertion of T. By comparison, these polymerases usually show a several thousand-fold preference for insertion of a correct base-pairing partner when copying a normal, undamaged DNA. O6MeG lesions ...

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Jason G. Warren

Structure of the Human MutSα DNA Lesion Recognition Complex

Structures of GRP94-Nucleotide Complexes Reveal Mechanistic Differences between the hsp90 Chaperones

The structural basis for the mutagenicity of O ⁶ -methyl-guanine lesions

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Jason G. Warren

Structure of the Human MutSα DNA Lesion Recognition Complex

Structures of GRP94-Nucleotide Complexes Reveal Mechanistic Differences between the hsp90 Chaperones

The structural basis for the mutagenicity of O 6 -methyl-guanine lesions

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The structural basis for the mutagenicity of O ⁶ -methyl-guanine lesions