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Investigating the dynamics of adhesion complex turnover by mass spectrometry based proteomicsNg, Daniel January 2013 (has links)
Adhesion complexes (ACs) are large macromolecular complexes of integrins and associated proteins that connect the actin cytoskeleton to the extracellular matrix. In migrating cells, ACs are highly dynamic -- forming and maturing at the cell front and disassembling at the cell rear. The turnover of ACs enables and localises the necessary traction forces required for cell migration. There is evidence for the spatiotemporal recruitment of specific proteins during AC maturation or disassembly; however, a holistic understanding of the compositional changes to ACs during these states is lacking. To this end, we sought to characterise the dynamic changes that occur at ACs during turnover using a mass spectrometry (MS)-based proteomics approach. A major challenge in studying AC turnover is the desynchronised nature of AC formation, maturation and disassembly within a population of cells. Therefore a nocodazole-washout assay was used to synchronise microtubule-induced AC maturation and disassembly. To study the dynamics of AC turnover by MS, an AC isolation method was optimised for use with the nocodazole-washout assay. Subsequently, the maturation of ACs by the loss of microtubules was studied by MS-based proteomics, and it was found that this resulted in the overall accumulation of adhesion proteins, and also the conversion of fibrillar adhesions to focal adhesions. Studying the dynamic process of AC disassembly requires a sensitive MS quantification method; as such, label-free quantitative methods were compared, and it was found that LC-MS peak ion intensity quantification performed better than spectral counting. Using optimised methodologies for isolation of ACs and MS quantification, the dynamics of AC disassembly was analysed over the course of the nocodazole-washout assay. It was found that in general, microtubules were enriched around ACs, whereas many structural AC proteins decreased over time. In summary, we have optimised methods for the study of ACs by MS-based proteomics, and applied these methods to the study of AC turnover.
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SLK-mediated Phosphorylation of Paxillin Is Required for Focal Adhesion Turnover and Cell MigrationJennifer Leigh, Quizi 13 December 2011 (has links)
The precise mechanism regulating focal adhesion disassembly has yet to be elucidated. Recently, we have implicated the Ste20-like kinase SLK in mediating efficient focal adhesion turnover and cell migration in a Rac-1 and FAK-dependent manner. Although an indirect association of this kinase with the microtubule network has been determined, the exact involvement of SLK in the disassembly of the adhesion complex remains unclear. With the identification of the focal adhesion protein paxillin as a substrate of SLK, we show that SLK regulates adhesion turnover through its phosphorylation at S250. Mutation of S250 to a threonine residue ablates SLK phosphorylation of paxillin in vitro and results in reduced adhesion turnover and migration in vivo. Additionally, our studies demonstrate that overexpression of the paxillin S250T mutation prevents the redistribution of paxillin to the membrane ruffle in migrating cells. The complete loss of polyubiquitylation in the S250T mutant, combined with no observed reduction in S250T protein expression, suggests that S250 phosphorylation is required for a ubiquitin-mediated modification that regulates paxillin redistribution within the cell. Moreover, we show that phosphorylation of S250 is required for paxillin to interact with FAK. An observed accumulation of phospho-FAKY397 in cells overexpressing the paxillin S250T mutant suggests that phosphorylation of S250 is involved in regulating FAK-dependent focal adhesion dynamics. Consequently, our data suggests that SLK regulates adhesion turnover through the phosphorylation of paxillin at S250.
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SLK-mediated Phosphorylation of Paxillin Is Required for Focal Adhesion Turnover and Cell MigrationJennifer Leigh, Quizi 13 December 2011 (has links)
The precise mechanism regulating focal adhesion disassembly has yet to be elucidated. Recently, we have implicated the Ste20-like kinase SLK in mediating efficient focal adhesion turnover and cell migration in a Rac-1 and FAK-dependent manner. Although an indirect association of this kinase with the microtubule network has been determined, the exact involvement of SLK in the disassembly of the adhesion complex remains unclear. With the identification of the focal adhesion protein paxillin as a substrate of SLK, we show that SLK regulates adhesion turnover through its phosphorylation at S250. Mutation of S250 to a threonine residue ablates SLK phosphorylation of paxillin in vitro and results in reduced adhesion turnover and migration in vivo. Additionally, our studies demonstrate that overexpression of the paxillin S250T mutation prevents the redistribution of paxillin to the membrane ruffle in migrating cells. The complete loss of polyubiquitylation in the S250T mutant, combined with no observed reduction in S250T protein expression, suggests that S250 phosphorylation is required for a ubiquitin-mediated modification that regulates paxillin redistribution within the cell. Moreover, we show that phosphorylation of S250 is required for paxillin to interact with FAK. An observed accumulation of phospho-FAKY397 in cells overexpressing the paxillin S250T mutant suggests that phosphorylation of S250 is involved in regulating FAK-dependent focal adhesion dynamics. Consequently, our data suggests that SLK regulates adhesion turnover through the phosphorylation of paxillin at S250.
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SLK-mediated Phosphorylation of Paxillin Is Required for Focal Adhesion Turnover and Cell MigrationJennifer Leigh, Quizi 13 December 2011 (has links)
The precise mechanism regulating focal adhesion disassembly has yet to be elucidated. Recently, we have implicated the Ste20-like kinase SLK in mediating efficient focal adhesion turnover and cell migration in a Rac-1 and FAK-dependent manner. Although an indirect association of this kinase with the microtubule network has been determined, the exact involvement of SLK in the disassembly of the adhesion complex remains unclear. With the identification of the focal adhesion protein paxillin as a substrate of SLK, we show that SLK regulates adhesion turnover through its phosphorylation at S250. Mutation of S250 to a threonine residue ablates SLK phosphorylation of paxillin in vitro and results in reduced adhesion turnover and migration in vivo. Additionally, our studies demonstrate that overexpression of the paxillin S250T mutation prevents the redistribution of paxillin to the membrane ruffle in migrating cells. The complete loss of polyubiquitylation in the S250T mutant, combined with no observed reduction in S250T protein expression, suggests that S250 phosphorylation is required for a ubiquitin-mediated modification that regulates paxillin redistribution within the cell. Moreover, we show that phosphorylation of S250 is required for paxillin to interact with FAK. An observed accumulation of phospho-FAKY397 in cells overexpressing the paxillin S250T mutant suggests that phosphorylation of S250 is involved in regulating FAK-dependent focal adhesion dynamics. Consequently, our data suggests that SLK regulates adhesion turnover through the phosphorylation of paxillin at S250.
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SLK-mediated Phosphorylation of Paxillin Is Required for Focal Adhesion Turnover and Cell MigrationJennifer Leigh, Quizi January 2012 (has links)
The precise mechanism regulating focal adhesion disassembly has yet to be elucidated. Recently, we have implicated the Ste20-like kinase SLK in mediating efficient focal adhesion turnover and cell migration in a Rac-1 and FAK-dependent manner. Although an indirect association of this kinase with the microtubule network has been determined, the exact involvement of SLK in the disassembly of the adhesion complex remains unclear. With the identification of the focal adhesion protein paxillin as a substrate of SLK, we show that SLK regulates adhesion turnover through its phosphorylation at S250. Mutation of S250 to a threonine residue ablates SLK phosphorylation of paxillin in vitro and results in reduced adhesion turnover and migration in vivo. Additionally, our studies demonstrate that overexpression of the paxillin S250T mutation prevents the redistribution of paxillin to the membrane ruffle in migrating cells. The complete loss of polyubiquitylation in the S250T mutant, combined with no observed reduction in S250T protein expression, suggests that S250 phosphorylation is required for a ubiquitin-mediated modification that regulates paxillin redistribution within the cell. Moreover, we show that phosphorylation of S250 is required for paxillin to interact with FAK. An observed accumulation of phospho-FAKY397 in cells overexpressing the paxillin S250T mutant suggests that phosphorylation of S250 is involved in regulating FAK-dependent focal adhesion dynamics. Consequently, our data suggests that SLK regulates adhesion turnover through the phosphorylation of paxillin at S250.
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