GAB2

GRB2-associated-binding protein 2 also known as GAB2 is a protein that in humans is encoded by the GAB2 gene. GAB2 is a docking protein with a conserved, folded PH domain attached to the membrane and a large disordered region, which hosts interactions with signaling molecules. It is a member of the GAB/DOS family localized on the internal membrane of the cell. It mediates the interaction between receptor tyrosine kinases (RTKs) and non-RTK receptors serving as the gateway into the cell for activation of SHP2, Phosphatidylinositol 3-kinase (PI3K), Grb2, ERK, and AKT and acting as one of the first steps in these signaling pathways. GAB2 has been shown to be important in physiological functions such as growth in bone marrow and cardiac function. GAB2 has also been associated with many diseases including leukemia and Alzheimer's disease. GAB proteins were one of the first docking proteins identified in the mammalian signal transduction pathway. GAB2 along with many other adaptor, scaffold, and docking proteins, was discovered in the mid-1990s during the isolation and cloning of protein tyrosine kinase substrates and association partners. GAB2 was initially discovered as a binding protein and substrate of protein tyrosine phosphatase Shp2/PTPN11. Two other groups later cloned GAB2 by searching DNA database for protein with sequence homology to GAB1. GAB2 is a large multi-site docking protein (LMD) of about 100kD that has a folded N-terminal domain attached to an extended, disordered C-terminal tail rich in short linear motifs. LMDs are docking proteins that function as platforms mediating interaction between different signaling pathways and assisting with signal integration. The N-terminal is characterized by a Pleckstrin Homology (PH) domain that is the most highly conserved region between all members of the GAB family of proteins. (GAB1, GAB2, GAB3 and GAB4) GAB2 is an Intrinsically disordered protein, meaning that beyond the folded N-terminal region, the C-terminal region extends out into the cytoplasm with little or no secondary structure. The disordered region of the protein however may not be as disordered as was initially expected, as sequencing has revealed significant similarity between the “disordered” regions of GAB orthologs in different species. The PH domain of GAB2 recognizes phosphatidylinositol 3,4,5-triphosphate(PIP3) in the membrane and is responsible for localizing the GAB protein on the intracellular surface of the membrane and in regions where the cell contacts another cell. Some evidence also suggests that the PH domain plays a role in some signal regulation as well. Adjacent to the PH domain is a central, proline-rich domain that contains many PXXP motifs for binding to the SH3 domains of signaling molecules such as Grb2 (from which the name “Grb2-associated binding” protein, GAB, comes). It is hypothesized that binding sites in this region may be used in indirect mechanisms pairing the GAB2 protein to receptor tyrosine kinases. It is on the C-terminal tail that the various conserved protein binding motifs and phosphorylation sites of GAB2 are found. GAB2 binds to the SH2 domains of such signaling molecules as SHP2 and PI3K. By binding to the p85 subunit of PI3K, and continuing this signaling pathway GAB provides positive feedback for the creation of PIP3, produced as a result of the PI3K pathway, which binds to GAB2 in the membrane and promotes activation of more PI3Ks. Discovery of multiple binding sites in GAB proteins has led to the N-terminal folding nucleation (NFN) hypothesis for the structure of the disordered region. This theory suggests that the disordered domain is looped back to connect to the N-terminal, structured region several times to make the protein more compact. This would assist in promoting interactions between molecules bound to GAB and resisting degradation. GAB2 mediates the interactions between receptor tyrosine kinases (RTK) or non-RTK receptors, such as G protein coupled receptors, cytokine receptors, multichain immune recognition receptors and integrins, and the molecules of the intracellular signaling pathways. By providing a platform to host a wide array of interactions from extracellular inputs to intracellular pathways, GAB proteins can act as a gatekeeper to the cell, modulating and integrating signals as they pass them along, to control the functional state within the cell. Mutagenesis and Binding assays have helped to identify which molecules and what pathways are downstream of GAB2. The two main pathways of GAB proteins are SHP2 and PI3K. GAB protein binding to SHP2 molecules acts as an activator whose main effect is the activation of the ERK/MAPK pathway. There are also, however, other pathways that are activated by this interaction such as the pathways c-Kit-induced Rac activation and β1-integrin. PI3K activation by GAB2 promotes cell growth. The effects of all the pathways activated by GAB proteins are not known, but it is easy to see that amplification of signal can progress quickly and these proteins can have large effects on the state of the cell. While not lethal, GAB2 deficient knockout mice do exhibit phenotypic side-effects. These include weak allergic reactions, reduced mast cell growth in bone marrow and osteopetrosis. Knockout mice have also been used to show the importance of GAB2 in maintenance of cardiac function. A paracrine factor, NRG1 β, utilizes GAB2 to activate the ERK and AKT pathways in the heart to produce angiopoietin 1.