John D. Shannon

The phosphorylation of protein tyrosine kinases (PTKs) on tyrosine residues is a critical regulatory event that modulates catalytic activity and triggers the physical association of PTKs with Src homology 2 (SH2)-containing proteins. The integrin-linked focal adhesion kinase, pp125FAK, exhibits extracellular matrix-dependent phosphorylation on tyrosine and physically associates with two nonreceptor PTKs, pp60src and pp59fyn, via their SH2 domains. Herein, we identify Tyr-397 as the major site of tyrosine phosphorylation on pp125FAK both in vivo and in vitro. Tyrosine 397 is located at the juncture of the N-terminal and catalytic domains, a novel site for PTK autophosphorylation. Mutation of Tyr-397 to a nonphosphorylatable residue dramatically impairs the phosphorylation of pp125FAK on tyrosine in vivo and in vitro. The mutation of Tyr-397 to Phe also inhibits the formation of stable complexes with pp60src in cells expressing Src and FAK397F, suggesting that autophosphorylation of pp125FAK may regulate the association of pp125FAK with Src family kinases in vivo. The identification of Tyr-397 as a major site for FAK autophosphorylation provides one of the first examples of a cellular protein containing a high-affinity binding site for a Src family kinase SH2 domain. This finding has implications for models describing the mechanisms of action of pp125FAK, the regulation of the Src family of PTKs, and signal transduction through the integrins.

The phosphorylation of protein tyrosine kinases (PTKs) on tyrosine residues is a critical regulatory event that modulates catalytic activity and triggers the physical association of PTKs with Src homology 2 (SH2)-containing proteins. The integrin-linked focal adhesion kinase, pp125FAK, exhibits extracellular matrix-dependent phosphorylation on tyrosine and physically associates with two nonreceptor PTKs, pp60src and pp59fyn, via their SH2 domains. Herein, we identify Tyr-397 as the major site of tyrosine phosphorylation on pp125FAK both in vivo and in vitro. Tyrosine 397 is located at the juncture of the N-terminal and catalytic domains, a novel site for PTK autophosphorylation. Mutation of Tyr-397 to a nonphosphorylatable residue dramatically impairs the phosphorylation of pp125FAK on tyrosine in vivo and in vitro. The mutation of Tyr-397 to Phe also inhibits the formation of stable complexes with pp60src in cells expressing Src and FAK397F, suggesting that autophosphorylation of pp125FAK may regulate the association of pp125FAK with Src family kinases in vivo. The identification of Tyr-397 as a major site for FAK autophosphorylation provides one of the first examples of a cellular protein containing a high-affinity binding site for a Src family kinase SH2 domain. This finding has implications for models describing the mechanisms of action of pp125FAK, the regulation of the Src family of PTKs, and signal transduction through the integrins.

Chronic wounds associated with vascular disease, diabetes mellitus, or aging are leading causes of morbidity in western countries and represent an unresolved clinical problem. The development of innovative strategies to promote tissue repair is therefore an important task that requires a more thorough analysis of the underlying molecular pathophysiology. We propose that the understanding of the complex biological events that control tissue repair or its failure largely benefits from a broad analytical approach as provided by novel proteomic methodologies. Here we present the first comparative proteome analysis of wound exudates obtained from normal healing or nonhealing (venous leg ulcer) human skin wounds. A total of 149 proteins were identified with high confidence. A minority of proteins was exclusively present in exudate of the healing wound (23 proteins) or the nonhealing wound (26 proteins). Of particular interest was the differential distribution of specific proteins among the two different healing phenotypes. Whereas in the exudate obtained from the healing wound mediators characteristic for tissue formation were abundantly present, in the exudate obtained from the nonhealing wound numerous mediators characteristic for a persistent inflammatory and tissue destructive response were identified. Furthermore, the study also revealed interesting results regarding the identification of new proteins with yet unknown functions in skin repair. This analysis therefore represents an important basis for the search for potential biomarkers, which give rise to a better understanding and monitoring of disease progression in chronic wounds.

Current evidence indicates that, of the thirteen known lysosomal peptide hydrolases, only seven, cathepsins A, B, C, D, H, L, and lysosomal carboxypeptidase B are located inside skeletal muscle cells. Only one of the reported neutral and alkaline proteases is located inside skeletal muscle cells', this neutral protease is the Ca2+-dependent proteinase, CAF. With the possible exception of cathepsin N, which can degrade collagen, it seems probable that any protease that contributes to postmortem tenderization needs to be located inside muscle cells. Because very little degradation of myosin or actin occurs in postmortem muscle, most of the small amount of proteolytic degradation of the myofibrillar proteins that occurs during postmortem storage must be due to CAF, which is unique in being unable to degrade myosin and actin. It is not certain that postmortem proteolysis by CAF causes increased tenderness; some recently discovered actin-fragmenting proteins could be involved.