Tyrosine motif

Insulin Receptor. Figure 1 Structure and function of the insulin receptor. Binding of insulin to the a-subunits (yellow) leads to activation of the intracellular tyrosine kinase ((3-subunit) by autophosphorylation. The insulin receptor substrates (IRS) bind via a phospho-tyrosine binding domain to phosphorylated tyrosine residues in the juxtamembrane domain of the (3-subunit. The receptor tyrosine kinase then phosphorylates specific tyrosine motifs (YMxM) within the IRS. These tyrosine phosphorylated motifs serve as docking sites for some adaptor proteins with SRC homology 2 (SH2) domains like the regulatory subunit of PI 3-kinase. 

Law DA, DeGuzman FR, Heiser P et al. (1999) Integrin cytoplasmic tyrosine motif is required for outside-in cdlb 33 signalling and platelet function. Nature 401 808-811 Leon C, Hechler B, Freund M et al. (1999) Defective platelet aggregation and increased resistance to thrombosis in purinergic P2Yi receptor-null mice. J Clin Invest 104 1731-1737... 

The extracellular domain of Trk receptors is made up of three leucine-rich 24 residue motifs flanked on either side by a cysteine cluster (Cl is on the outer side and C2 is in the inner side), followed by two immunoglobulin (Ig)-like domains and a single transmembrane domain. The cytoplasmic domain of Trk receptors contains several tyrosine motifs (Huang and Reichardt, 2003). The major ligand binding site on Trk receptors is located in the region proximal to the Ig-... 

Human siglecs Number of Ig domains Number of cytoplasm ic tyrosine motifs Sialic-acid- binding specificity Expression... 

The active site of the receptor is thought to be an asparagine motif which interacts with the dipole of the carbonyl group in the ester side of the transmitter, while the interaction on the other quaternary ammonium side is thought to be either an ion-pair interaction with an aspartic acid residue or an interaction between the delocalised positive charge on the quaternary nitrogen-F three methyl groups and an electron-rich pocket formed by three tyrosine motifs in the receptor (cation-7c-donor interaction). 

Phosphorylation is a common method of regulation. As described above, SH2 domains bind to phosphorylated tyrosine residues. Conversely, phosphorylation of serines and threonines proximal to SH3 and PDZ domains uncouples them from their target motifs. Therefore modulation of protein kinase activity in cells regulates interactions between adaptor proteins and their target proteins. 

Immunreceptor based activation motif. The classical ITAM motif comprises the consensus sequence Yxxl/ Lx(6-12)YxxI/L (where Y stands for tyrosine, I stands for isoleucine, L stands for leucine, and x can be any amino acid). Kinases containing tandem SH2 domains, as for example ZAJP-70 or SYK, recognize the phosphorylated ITAMs, thereby initiating downstream signaling events. 

Noncatalytic phosphotyrosine binding (PTB) domains are 100-150 residue modules, which bind Asn-Pro-X-Tyr motifs. PTB-domain binding specificity is determined by residues at the amino-terminal side of the phosphotyrosine. In most cases, the tyrosine residue must be phosphorylated in order to mediate binding. PTB domain containing proteins are often found in signal transduction pathways. 

Besides cytoplasmic protein kinases, membrane receptors can exert protein kinase activity. These so-called receptor tyrosine kinases (RTK) contain a ligandbinding extracellular domain, a transmembrane motif, and an intracellular catalytic domain with specificity for tyrosine residues. Upon ligand binding and subsequent receptor oligomerization, the tyrosine residues of the intracellular domain become phosphory-lated by the intrinsic tyrosine kinase activity of the receptor [3, 4]. The phosphotyrosine residues ftmction as docking sites for other proteins that will transmit the signal received by the RTK. 

Protein-protein interaction domain that binds to polyproline motifs with the sequence PXXP. Particularly important in assembling protein complexes at activated receptors which contain intrinsic tyrosine kinases. 

HSFl phosphorylation must be sensitive to nonheat inducers of HSF-DNA binding activity because HSFl phosphorylation can be achieved at 37 °C by other inducers of the HS response. HSF 1 contains polypeptide sequences that could serve as substrates for well characterized protein kinases, but few of these are known to be heat inducible. One family of protein kinases, the S6 protein kinases, have already been shown to exhibit heat inducible activity however, their peak level of activity during HS occurs well after the maximal induction of HSF phosphorylation (Jurivich et al., 1991). Thus, other protein kinases are likely to be directly linked to the phosphorylation of HSF. Some of the putative protein phosphorylation sites on HSF include motifs for protein kinase C, casein kinase, and enterokinase. There are tyrosine sequences that match substrates for known tyrosine kinases, but whether these residues are accessible to phosphorylation is not established. 

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