Impaired fear response in mice lacking GIT1.

G protein-coupled receptor kinase interacting protein 1 (GIT1) belongs to the family of Arf GAP proteins and has been implicated in the regulation of G protein-coupled receptor (GPCR) sequestration, cell migration, synapse formation and dendritic spine morphogenesis in neurons. To extend these cellular studies on GIT1 to an in vivo system, we generated mice with globally inactivated Git1 gene by breeding mice carrying a conditional Git1(flox) allele with mice expressing the CMV-Cre transgene. Although many GIT1 knockout (GIT1-KO) animals died shortly after birth, homozygous mutants that survived the early post-partum period developed normally into adulthood and were fertile. Behavioral analyses of adult GIT1-KO mice revealed normal exploratory, anxiety- and depressive-like behaviors. However, GIT1-KO mice show impaired responses to fear conditioning and fear-potentiated startle. Overall, these findings suggest that GIT1 is involved in the regulation of amygdala-mediated experience-based emotional behaviors.

Anxiety-like behaviors in mice lacking GIT2.

G protein-coupled receptor kinase-interactor 2 (GIT2) is a signaling scaffold protein that also functions as GTPase-activating protein (GAPs) for ADP-ribosylation factor (Arf) small GTP-binding proteins. GIT2 has been implicated in the regulation of G protein-coupled receptor trafficking and cell adhesion and migration. To evaluate possible neurobehavioral functions of GIT2 in vivo, we evaluated GIT2-knockout (KO) mice for abnormalities in emotionality and mood. Male and female GIT2-KO mice presented with anxiety-like behaviors in the zero-maze and light-dark emergence tests. Immobility times in tail suspension were reduced in GIT2-KO males, but were normal in GIT2-KO females. Hence, GIT2-KO mice display anxiety-like behavior in an absence of depressive-like responses.

Differential expression of the ARF GAP genes GIT1 and GIT2 in mouse tissues.

GIT1 and GIT2 belong to the family of ADP-ribosylation factor GTPase-activating proteins (ARF-GAP) and have been implicated in the regulation of G protein-coupled receptor sequestration, cell migration, T-cell activation, neuronal spine formation, and aggregate formation in Huntington's disease. Examination of endogenous GIT protein expression in tissues, however, has been hampered by the lack of GIT2-specific antibodies. To visualize GIT1 and GIT2 gene expression in mouse tissues, we created mice with beta-galactosidase (beta-Gal) reporters inserted into the two GIT genes. beta-Gal staining confirmed the broad tissue distribution of GIT1 and GIT2 in the mouse but also revealed striking differences. GIT2 is expressed in most cells of the body, whereas GIT1 is restricted to only a subset of cells. For example, GIT2 is uniformly expressed throughout lung and liver, whereas GIT1 is restricted to cells lining blood vessels, bronchi, and bile ducts. Expression of GIT1 and GIT2 is mutually exclusive in the testes, where a developmental expression shift occurs, with GIT2 present in spermatogonia but GIT1 in mature spermatids. In conclusion, analysis of endogenous GIT expression revealed a nearly ubiquitous distribution of GIT2, whereas GIT1 is restricted to specific cell types even in tissues with apparently high GIT1 expression and is entirely absent from some tissues.

GIT1 utilizes a focal adhesion targeting-homology domain to bind paxillin.

The GIT proteins, GIT1 and GIT2, are GTPase-activating proteins for the ADP-ribosylation factor family of small GTP-binding proteins, but also serve as adaptors to link signaling proteins to distinct cellular locations. One role for GIT proteins is to link the PIX family of Rho guanine nucleotide exchange factors and their binding partners, the p21-activated protein kinases, to remodeling focal adhesions by interacting with the focal adhesion adaptor protein paxillin. We here identified the C-terminal domain of GIT1 responsible for paxillin binding. Combining structural and mutational analyses, we show that this region folds into an anti-parallel four-helix domain highly reminiscent to the focal adhesion targeting (FAT) domain of focal adhesion kinase (FAK). Our results suggest that the GIT1 FAT-homology (FAH) domain and FAT bind the paxillin LD4 motif quite similarly. Since only a small fraction of GIT1 is bound to paxillin under normal conditions, regulation of paxillin binding was explored. Although paxillin binding to the FAT domain of FAK is regulated by tyrosine phosphorylation within this domain, we find that tyrosine phosphorylation of the FAH domain GIT1 is not involved in regulating binding to paxillin. Instead, we find that mutations within the FAH domain may alter binding to paxillin that has been phosphorylated within the LD4 motif. Thus, despite apparent structural similarity in their FAT domains, GIT1 and FAK binding to paxillin is differentially regulated.

The protein stannin binds 14-3-3zeta and modulates mitogen-activated protein kinase signaling.

The molecular mechanisms underlying the selective toxicity of trimethyltin (TMT) remain unclear. Stannin (Snn), a protein preferentially expressed in TMT-sensitive cells, provides a direct link to the molecular basis for TMT toxicity. Recent evidence demonstrated that Snn peptides bind and de-alkylate TMT to dimethyltin (DMT); Snn may mediate both TMT and DMT toxicity. In this study, we demonstrate that Snn co-immunoprecipitates with a scaffolding protein 14-3-3, specifically with 14-3-3zeta isotype. Consistent with this, a detailed amino acid sequence analysis shows that Snn contains a putative 14-3-3 protein-binding site located within its hydrophilic loop. In addition, we present the evidence that Snn overexpression results in reduced extracellular regulated kinase activation and increased p38 activation. In contrast, the activity of c-Jun N-terminal kinase did not change following Snn overexpression. This is the first evidence that demonstrates a direct interaction between Snn and MAPK signaling molecules. Together, these findings indicate a role of Snn in modulation of MAPK signaling pathways through its interactions with 14-3-3zeta.

Stannin, a protein that localizes to the mitochondria and sensitizes NIH-3T3 cells to trimethyltin and dimethyltin toxicity.

Stannin (Snn) is a highly conserved, 88-amino acid protein that may mediate the selective toxicity of organotins. Snn is localized in tissues with known sensitivity to trimethyltin (TMT), including the central nervous system, immune system, spleen, kidney and lung. Cells in culture that do not express Snn show considerable resistance to TMT toxicity. In vitro, Snn peptide can bind TMT in a 1:1 ratio and can de-alkylate TMT to dimethyltin (DMT). We now show that transfection with Snn sensitized TMT-resistant NIH-3T3 mouse fibroblasts to both TMT and DMT cytotoxicity. Triple label confocal microscopy of Snn-transfected cells and Percoll gradient purification of mitochondria showed Snn localized to the mitochondria and other membrane structures. The mitochondrial localization of Snn, coupled with its ability to bind and dealkylate organotin compounds, indicates a possible mechanism by which selective alkyltin toxicity might be mediated.