Kinetic Analyses of Mutations in the Glycine-Rich Loop of cAMP-Dependent Protein Kinase

Grant, Bruce D.; Hemmer, Wolfram; Tsigelny, Igor F.; Adams, Joseph A.; Taylor, Susan S.

doi:10.1021/bi972987w

Cited by 83 publications

(86 citation statements)

References 35 publications

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“…4) which contains three highly conserved glycines that greatly control catalytic activity. [21,22] We also observed that activation of Csk through phosphopeptide binding to the SH2 domain decreases strain energies in this glycine-rich loop. [11] Likewise, in this study, activation of Csk through disulfide bond removal decreases strain in this loop.…”

Section: Discussionmentioning

confidence: 61%

A Novel Disulfide Bond in the SH2 Domain of the C-terminal Src Kinase Controls Catalytic Activity

Mills

Whitford

Shaffer

et al. 2007

Journal of Molecular Biology

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SummaryThe SH2 domain of the C-terminal Src kinase [Csk] contains a unique disulfide bond not present in other known SH2 domains. To investigate whether this unusual disulfide bond could serve a novel function, the effects of disulfide bond formation on catalytic activity of the full-length protein and on the structure of the SH2 domain were investigated. The kinase activity of full-length Csk decreases by an order of magnitude upon formation of the disulfide bond in the distal SH2 domain. NMR spectra of the fully oxidized and fully reduced SH2 domains exhibit similar chemical shift patterns and are indicative of similar, well-defined tertiary structures. The solvent-accessible disulfide bond in the isolated SH2 domain is highly stable and far from the small lobe of the kinase domain. However, reduction of this bond results in chemical shift changes of resonances that map to a cluster of residues that extend from the disulfide bond across the molecule to a surface that is in direct contact with the small-lobe of the kinase domain in the intact molecule. Normal mode analyses and molecular dynamics calculations suggest that disulfide bond formation has large effects on residues within the kinase domain, most notably within the active-site cleft. Overall, the data indicate that reversible cross-linking of two cysteines in the SH2 domain greatly impacts catalytic function and domaindomain communication in Csk. KeywordsCsk; cysteine; disulfide; kinase; NMR; phosphorylation The Src family of tyrosine kinases [SFKs] 1 are modular enzymes responsible for controlling various aspects of cellular growth and differentiation.[1] SH3 and SH2 domains in the SFKs flank the kinase domain and repress catalytic activity through intrasteric constraints. Most notably, the SH2 domain interacts tightly with a phosphotyrosine in the C-terminus of the kinase domain, inducing a closed conformation that poorly phosphorylates protein substrates.

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Section: Discussionmentioning

confidence: 61%

A Novel Disulfide Bond in the SH2 Domain of the C-terminal Src Kinase Controls Catalytic Activity

Mills

Whitford

Shaffer

et al. 2007

Journal of Molecular Biology

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“…In the crystal structure of Src (28), the side chain of Cys-277 is readily accessible, which may explain its sensitivity to oxidation. Furthermore, kinase activity appears particularly sensitive to modification to the Gly (29,30), as demonstrated for Src and Csk. All of these observations provide a mechanistic basis for the redox regulation at this residue.…”

Section: Discussionmentioning

confidence: 97%

“…The 3 Gly residues are a universally-conserved signature motif among all protein kinases, even though the intervening residues are variable. Kinetic and structural studies of both protein Ser/Thr kinase, cAMPdependent protein kinases (29), and a PTK, FPS (30), indicate that this loop is directly involved in catalysis. An examination of the amino acid sequences of all human PTKs indicates that only a small number of PTKs contain a Cys residue at the position equivalent to Cys-277 in Src (Table S1).…”

Section: Fgfr1 Responds To Redox Regulation In a Similarmentioning

confidence: 99%

Direct and specific inactivation of protein tyrosine kinases in the Src and FGFR families by reversible cysteine oxidation

Kemble

Sun

2009

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

127

120

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Accumulating evidence suggests that protein tyrosine phosphorylation-based signaling pathways are under the regulation of reactive oxygen species. Although protein tyrosine phosphatases are directly regulated by reversible oxidation, it is not clear whether protein tyrosine kinases (PTKs) are also directly regulated by reduction/oxidation (redox). In this study we report a mechanism of direct oxidative inactivation specific for the PTKs in the Src and fibroblast growth factor receptor (FGFR) families, key enzymes in mammalian signal transduction. Src is fully active when reduced and retains 8 -25% of the full activity toward various substrates when oxidized. This inactivation is caused by oxidation of a specific cysteine residue (Cys-277), which results in homodimerization of Src linked by a disulfide bridge. Cys-277 is located in the Gly loop in the catalytic domain. This cysteine residue is conserved only in 8 of the >90 PTKs in the human kinome, including 3 of the 10 Src family kinases and all 4 kinases of the FGFR family. FGFR1 is also reversibly regulated by redox because of this cysteine residue, whereas Csk, a PTK that lacks a cysteine residue at the corresponding position, is not similarly regulated. These results demonstrate a mechanism of direct redox regulation conserved in certain specific PTKs. R eactive oxygen species (ROS), such as hydrogen peroxide and superoxide, can alter the function of proteins by oxidizing free sulfhydryl groups to sulfenic, sulfinic, or sulfonic acids (1, 2). Cellular responses to ROS are historically considered a damage-control mechanism to certain pathological situations that lead to oxidative stress. However, recent studies indicate that certain growth factors and cell adhesion also stimulate the production of ROS, which serve as secondary messengers to regulate downstream signaling pathways (3, 4). Numerous protein phosphorylation pathways respond to ROS (5-9), and identifying the proteins and the residues sensitive to oxidation will help elucidate the mechanism of cross-talk between redox and protein tyrosine phosphorylation.The level of protein tyrosine phosphorylation is the function of opposing actions of protein tyrosine kinases (PTKs) and protein tyrosine phosphatases (PTPs). All PTPs contain a catalytic Cys residue in the active site, and oxidation of this residue leads to the inactivation of the PTP activity (10). This response is recognized as a major mechanism by which ROS regulate the level of protein tyrosine phosphorylation. However, whether PTKs also directly respond to ROS is not established. PTK Src is a key regulator of cell survival, cytoskeleton reorganization, DNA synthesis, and cell division (11,12). A number of studies suggest that Src also plays an important role in cellular response to ROS, because Src specific inhibitors and dominantnegative Src mutants strongly attenuate cellular response to ROS (13-16). However, how ROS regulate Src activity has been controversial, likely reflecting the complexity of Src regulation. Src contains regulatory str...

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“…The G-loop is one of the most flexible elements of the catalytic core and plays a key role in phosphoryl transfer. Specifically, G50 and G52 within the G-loop participate in the phosphoryl transfer reaction (16), and G55 plays a role in regulation, because it contributes to the conformational flexibility of the G-loop (17). It is notable that disease SNPs are enriched at sites involved in regulation rather than catalysis.…”

Section: N-lobementioning

confidence: 99%

Congenital disease SNPs target lineage specific structural elements in protein kinases

Torkamani

Kannan²,

Taylor

et al. 2008

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

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The catalytic domain of protein kinases harbors a large number of disease-causing single nucleotide polymorphisms (SNPs) and common or neutral SNPs that are not known or hypothesized to be associated with any disease. Distinguishing these two types of polymorphisms is critical in accurately predicting the causative role of SNPs in both candidate gene and genome-wide association studies. In this study, we have analyzed the structural location of common and disease-associated SNPs in the catalytic domain of protein kinases and find that, although common SNPs are randomly distributed within the catalytic core, known disease SNPs consistently map to regulatory and substrate binding regions. In particular, a buried side-chain network that anchors the flexible activation loop to the catalytic core is frequently mutated in disease patients. This network was recently shown to be absent in distantly related eukaryotic-like kinases, which lack an exaggerated activation loop and, presumably, are not regulated by phosphorylation.allostery ͉ cancer ͉ conservation ͉ evolution ͉ mutation

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Kinetic Analyses of Mutations in the Glycine-Rich Loop of cAMP-Dependent Protein Kinase

Cited by 83 publications

References 35 publications

A Novel Disulfide Bond in the SH2 Domain of the C-terminal Src Kinase Controls Catalytic Activity

A Novel Disulfide Bond in the SH2 Domain of the C-terminal Src Kinase Controls Catalytic Activity

Direct and specific inactivation of protein tyrosine kinases in the Src and FGFR families by reversible cysteine oxidation

Congenital disease SNPs target lineage specific structural elements in protein kinases

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