Dock7

Dock7 ( D edicator o f c yto k inesis 7), also known as Zir2, is a large (~240 kDa) is_associated_with::protein involved in is_associated_with::intracellular signalling networks. It is a member of the DOCK-C subfamily of the DOCK family of is_associated_with::guanine nucleotide exchange factors (GEFs) which function as activators of small is_associated_with::G proteins. Dock7 activates isoforms of the small G protein Rac.

Discovery
Dock7 was identified as one of a number of proteins which share high sequence similarity with the previously described protein is_associated_with::Dock180, the archetypal member of the DOCK family. Dock7 expression has been reported in is_associated_with::neurons and in the is_associated_with::HEK 293 cell line.

Structure and function
Dock7 is part of a large class of proteins (GEFs) which contibrute to cellular signalling events by activating small G proteins. In their resting state G proteins are bound to is_associated_with::Guanosine diphosphate (GDP) and their activation requires the dissociation of GDP and binding of is_associated_with::guanosine triphosphate (GTP). GEFs activate G proteins by promoting this nucleotide exchange.

Dock7 and other DOCK family proteins differ from other GEFs in that they do not possess the canonical structure of tandem DH-PH domains known to elicit nucleotide exchange. Instead they possess a is_associated_with::DHR2 domain which mediates G protein activation by stabilising it in its nucleotide free state. They also contain a is_associated_with::DHR1 domain which, in many DOCK family members, interacts with is_associated_with::phospholipids. Dock7 shares the highest level of sequence similarity with is_associated_with::Dock6 and is_associated_with::Dock8, the other members of the DOCK-C subfamily. However, the specificity of the Dock7 DHR2 domain appears to resemble that of DOCK-A/B subfamily proteins in that it binds Rac but not is_associated_with::Cdc42. Many DOCK family proteins contain important structural features at their N- and C-termini, however, these regions in Dock7 are poorly characterised thus far and no such features have been identified.

Regulation of Dock7 Activity
Many members of the DOCK family are regulated by is_associated_with::protein-protein interactions mediated via domains at their N- and C-termini, however, the mechanisms by which Dock7 is regulated are largely unknown. There is evidence that the production of PtdIns(3,4,5)P3 by members of the is_associated_with::Phosphoinositide 3-kinase (PI3K) family is important for efficient recruitment of Dock7 since the PI3K inhibitor is_associated_with::LY294002 was shown to block Dock7-dependent functions in neurons. This observation is consistent with the role of the DHR1 domain in other DOCK family proteins. In neurons of the is_associated_with::hippocampus Dock7 undergoes striking changes in subcellular localisation during the progressive stages of neuronal development, resulting in an abundance of this protein in a single is_associated_with::neurite which goes on to form the is_associated_with::axon of the polarised neuron.

In is_associated_with::Schwann cells (which generate an insulating layer, known as the myelin sheath, around axons of the is_associated_with::peripheral nervous system) Dock7 appears to be activated downstream of the is_associated_with::neuregulin receptor is_associated_with::ErbB2, which receives signals from the axon that induce Schwann cell proliferation, migration and myelination. ErbB2 has been shown to is_associated_with::tyrosine phosphorylate Dock7 and thus promote Schwann cell migration.

Signalling downstream of Dock7
DOCK proteins are known activators of small G proteins of the is_associated_with::Rho family. A study of Dock7 in HEK 293 cells and hippocampal neurons has shown that it can bind and promote nucleotide exchange on the Rac subfamily isoforms is_associated_with::Rac1 and is_associated_with::Rac3. This work suggests that Dock7 is a key mediator of the process that specifies which of the many neurites will become the axon. Indeed, overexpression of Dock7 induced the formation of multiple axons and is_associated_with::RNA interference knock-down of Dock7 prevented axon formation. In Schwann cells Dock7 was shown to regulate the activation of Cdc42 as well as Rac1 however no direct interaction between Dock7 and Cdc42 has been demonstrated. Dock7 has also been reported to interact with the is_associated_with::TSC1-is_associated_with::TSC2 (also known as hamartin-tuberin) complex, the normal function of which is disrupted in sufferers of is_associated_with::Tuberous sclerosis. It was subsequently suggested that Dock7 may function as a GEF for is_associated_with::Rheb, a small G protein that functions downstream of the TSC1-TSC2 complex. Although DOCK family proteins are generally considered as GEFs specific for Rho family G proteins is_associated_with::Dock4 has been shown to bind and activate Rap1, which is not a member of the Rho family. This apparent promiscuity among DOCK proteins and their targets, coupled with the fact that Rheb is highly expressed in the brain means that Dock7 GEF activity towards Rheb, although not yet demonstrated, would not be surprising.