Structural genomics of the
            <i>Thermotoga maritima</i>
            proteome implemented in a high-throughput structure determination pipeline

Lesley, Scott A.; Kühn, Peter; Godzik, Adam; Deacon, Ashley M.; Mathews, I.I.; Kreusch, Andreas; Spraggon, Glen; Klock, Heath E.; McMullan, Daniel; Shin, Tanya; Vincent, Juli; Robb, Alyssa; Brinen, Linda S.; Miller, Mitchell D.; McPhillips, Timothy M.; Miller, Mark A.; Scheibe, Daniel; Cánaves, Jaume M.; Guda, Chittibabu; Jaroszewski, Lukasz; Selby, Thomas L.; Elsliger, Marc‐André; Wooley, John; Taylor, Susan S.; Hodgson, Keith O.; Wilson, Ian A.; Schultz, Peter G.; Stevens, Raymond C.

doi:10.1073/pnas.142413399

Cited by 379 publications

(367 citation statements)

References 27 publications

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“…Proteome-scale crystallography is being pursued by several groups, including the Joint Center for Structural Genomics (JCSG) (1)(2)(3). These efforts have benefited greatly from recent technology enhancements in protein expression and crystallization.…”

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confidence: 99%

Rapid refinement of crystallographic protein construct definition employing enhanced hydrogen/deuterium exchange MS

Pantazatos

Kim

Klock

et al. 2004

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

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142

109

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Crystallographic efforts often fail to produce suitably diffracting protein crystals. Unstructured regions of proteins play an important role in this problem and considerable advantage can be gained in removing them. We have developed a number of enhancements to amide hydrogen͞high-throughput and high-resolution deuterium exchange MS (DXMS) technology that allow rapid identification of unstructured regions in proteins. To demonstrate the utility of this approach for improving crystallization success, DXMS analysis was attempted on 24 Thermotoga maritima proteins with varying crystallization and diffraction characteristics. Data acquisition and analysis for 21 of these proteins was completed in 2 weeks and resulted in the localization and prediction of several unstructured regions within the proteins. When compared with those targets of known structure, the DXMS method correctly localized even small regions of disorder. DXMS analysis was then correlated with the propensity of such targets to crystallize and was further used to define truncations that improved crystallization. Truncations that were defined solely on DXMS analysis demonstrated greatly improved crystallization and have been used for structure determination. This approach represents a rapid and generalized method that can be applied to structural genomics or other targets in a high-throughput manner.

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mentioning

confidence: 99%

Rapid refinement of crystallographic protein construct definition employing enhanced hydrogen/deuterium exchange MS

Pantazatos

Kim

Klock

et al. 2004

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

Self Cite

142

109

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“…The protein was crystallized using the nanodroplet vapor diffusion method 13 with standard JCSG crystallization protocols. 5 The crystallization reagent contained 20% polyethylene glycol (PEG)-3350 and 0.2 M potassium fluoride at pH 7.2. 15% ethylene glycol (final concentration) was included as a cryoprotectant.…”

Section: Materials and Methods Protein Production And Crystallizationmentioning

confidence: 99%

“…Here, we report the crystal structure of DcpS from Mouse determined using the semiautomated, high-throughput pipeline of the Joint Center for Structural Genomics (JCSG). 5 The crystal structure of Mouse DcpS [ Fig. 1(A)] was determined to 1.83-Å resolution by the molecular replacement (MR) method using a search model constructed from human DcpS [Protein Data Bank (PDB) code: 1st0], with a sequence identity of 89%.…”

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confidence: 99%

Crystal structure of an Apo mRNA decapping enzyme (DcpS) from Mouse at 1.83 Å resolution

et al. 2005

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“…The first phase of funding established a number of competing vertically integrated, multidisciplinary centers that had as their main objectives accelerating the rate of structure determination and greatly reducing the cost of determining crystal structures, largely by realizing the economy of scale and industrialization [9]. Phase I PSI centers focused largely on developing structural genomics pipelines (figure 2).…”

Section: Introductionmentioning

confidence: 99%

Practical applications of structural genomics technologies for mutagen research

Zemła

Segelke

2011

Mutation Research/Genetic Toxicology and Environmental Mutagene

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Here we present a perspective on a range of practical uses of structural genomics for mutagen research. Structural genomics is an overloaded term and requires some definition to bound the discussion; we give a brief description of public and private structural genomics endeavors, along with some of their objectives, their activities, their capabilities, and their limitations. We discuss how structural genomics might impact mutagen research in three different scenarios: at a structural genomics center, at a lab with modest resources that also conducts structural biology research, and at a lab that conducting mutagen research absent experimental structural biology. Applications span functional annotation of single genes, to constructing gene networks and pathways, to an integrated systems biology approach. Structural genomics centers can take advantage of systems biology models to target high value targets for structure determination and in turn extend systems models to better understand systems biology diseases or phenomenon. Individual investigator run structural biology laboratories can collaborate with structural genomics centers, but can also take advantage of technical advances and tools developed by structural genomics centers and can employ a structural genomics approach to advancing biological understanding. Individual investigator run non-structural biology laboratories can also collaborate with structural genomics center, possibly influencing targeting decisions, but can also use structure based annotation tools enabled by the growing coverage of protein fold space provided by structural genomics. Better functional annotation can inform pathway and systems biology models.

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Structural genomics of the Thermotoga maritima proteome implemented in a high-throughput structure determination pipeline

Cited by 379 publications

References 27 publications

Rapid refinement of crystallographic protein construct definition employing enhanced hydrogen/deuterium exchange MS

Rapid refinement of crystallographic protein construct definition employing enhanced hydrogen/deuterium exchange MS

Crystal structure of an Apo mRNA decapping enzyme (DcpS) from Mouse at 1.83 Å resolution

Practical applications of structural genomics technologies for mutagen research

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