Tyrosine phosphorylation of tub and its association with Src homology 2 domain-containing proteins implicate tub in intracellular signaling by insulin.

A mutation in the tub gene leads to maturity-onset obesity, insulin resistance, and progressive retinal and cochlear degeneration in mice. tub is a member of a growing family of genes that encode proteins of unknown function that are remarkably conserved across species. The absence of obvious transmembrane domain(s) or signal sequence peptide motif(s) suggests that Tub is an intracellular protein. Additional sequence analysis revealed the presence of putative tyrosine phosphorylation motifs and Src homology 2 (SH2)-binding sites. Here we demonstrate that in CHO-IR cells, transfected Tub is phosphorylated on tyrosine in response to insulin and insulin-like growth factor-1 and that in PC12 cells, insulin but not EGF induced tyrosine phosphorylation of endogenous Tub. In vitro, Tub is phosphorylated by purified insulin receptor kinase as well as by Abl and JAK 2 but not by epidermal growth factor receptor and Src kinases. Furthermore, upon tyrosine phosphorylation, Tub associated selectively with the SH2 domains of Abl, Lck, and the C-terminal SH2 domain of phospholipase Cgamma and insulin enhanced the association of Tub with endogenous phospholipase Cgamma in CHO-IR cells. These data suggest that Tub may function as an adaptor protein linking the insulin receptor, and possibly other protein-tyrosine kinases, to SH2-containing proteins.     

Interactions of polyomavirus middle T with the SH2 domains of the pp85 subunit of phosphatidylinositol-3-kinase.

The binding of phosphatidylinositol-3-kinase to the polyomavirus middle T antigen is facilitated by tyrosine phosphorylation of middle T on residue 315. The pp85 subunit of phosphatidylinositol-3-kinase contains two SH2 domains, one in the middle of the molecule and one at the C terminus. When assayed by blotting with phosphorylated middle T, the more N-terminal SH2 domain is responsible for binding to middle T. When assayed in solution with glutathione S transferase fusions, both SH2s are capable of binding phosphorylated middle T. While both SH2 fusions can compete with intact pp85 for binding to middle T, the C-terminal SH2 is the more efficient of the two. Interaction between pp85 or its SH2 domains and middle T can be blocked by a synthetic peptide comprising the tyrosine phosphorylation sequence around middle T residue 315. Despite the fact that middle T can interact with both SH2s, these domains are not equivalent. Only the C-terminal SH2-middle T interaction was blocked by anti-SH2 antibody; the two SH2 fusions also interact with different cellular proteins.     

Universal minicircle sequence-binding protein, a sequence-specific DNA-binding protein that recognizes the two replication origins of the kinetoplast DNA minicircle

Replication of the kinetoplast DNA minicircle lagging (heavy (H))-strand initiates at, or near, a unique hexameric sequence (5'-ACGCCC-3') that is conserved in the minicircles of trypanosomatid species. A protein from the trypanosomatid Crithidia fasciculata binds specifically a 14-mer sequence, consisting of the complementary strand hexamer and eight flanking nucleotides at the H-strand replication origin. This protein was identified as the previously described universal minicircle sequence (UMS)-binding protein (UMSBP) (Tzfati, Y., Abeliovich, H., Avrahami, D., and Shlomai, J. (1995) J. Biol. Chem. 270, 21339-21345). This CCHC-type zinc finger protein binds the single-stranded form of both the 12-mer (UMS) and 14-mer sequences, at the replication origins of the minicircle L-strand and H-strand, respectively. The attribution of the two different DNA binding activities to the same protein relies on their co-purification from C. fasciculata cell extracts and on the high affinity of recombinant UMSBP to the two origin-associated sequences. Both the conserved H-strand hexamer and its flanking nucleotides at the replication origin are required for binding. Neither the hexameric sequence per se nor this sequence flanked by different sequences could support the generation of specific nucleoprotein complexes. Stoichiometry analysis indicates that each UMSBP molecule binds either of the two origin-associated sequences in the nucleoprotein complex but not both simultaneously.