c-Cbl localizes to actin lamellae and regulates lamellipodia formation and cell morphology.

Adhesive and locomotive properties of cells have key roles in normal physiology and disease. Cell motility and adhesion require the assembly and organization of actin microfilaments into stress fibers, lamellipodia and filopodia, and the formation of these structures is mediated by signalling through Rho; GTPases. Here we identify c-Cbl (a multi-adaptor proto-oncogene product involved in protein tyrosine kinase signalling) as an important regulator of the actin cytoskeleton. By immunofluorescence microscopy we have determined that c-Cbl co-localizes with the adaptor protein Crk to submembranous actin lamellae in NIH 3T3 fibroblasts and that c-Cbl's actin localization requires specific SH3-binding sequences. Further, we have found that truncation of this SH3-binding domain in c-Cbl profoundly alters the morphology of NIH 3T3 fibroblasts by inhibiting the formation of actin lamellae, lamellipodia and membrane ruffles. The induction of lamellipodia and membrane ruffles are also inhibited during cell spreading and migration, conditions when these structures are normally most prominent. The inhibitory effect of truncated c-Cbl expression on lamellipodia formation can be reversed by mutational inactivation of its divergent SH2 domain, by the co-expression of constitutively active Rac or by the overexpression of c-Cbl. This study therefore identifies a cytoskeletal role for c-Cbl which may involve the regulation of Crk and Rac, and which is dependent on targeting of c-Cbl to actin lamellae and the ability to recruit signalling protein(s) associated with its divergent SH2 domain.

The Cbl proto-oncogene product negatively regulates the Src-family tyrosine kinase Fyn by enhancing its degradation.

Fyn is a prototype Src-family tyrosine kinase that plays specific roles in neural development, keratinocyte differentiation, and lymphocyte activation, as well as roles redundant with other Src-family kinases. Similar to other Src-family kinases, efficient regulation of Fyn is achieved through intramolecular binding of its SH3 and SH2 domains to conserved regulatory regions. We have investigated the possibility that the tyrosine kinase regulatory protein Cbl provides a complementary mechanism of Fyn regulation. We show that Cbl overexpression in 293T embryonic kidney and Jurkat T-lymphocyte cells led to a dramatic reduction in the active pool of Fyn; this was seen as a reduction in Fyn autophosphorylation, reduced phosphorylation of in vivo substrates, and inhibition of transcription from a Src-family kinase response element linked to a luciferase reporter. Importantly, a Fyn mutant (FynY528F) relieved of intramolecular repression was still negatively regulated by Cbl. The Cbl-dependent negative regulation of Fyn did not appear to be mediated by inhibition of Fyn kinase activity but was correlated with enhanced protein turnover. Consistent with such a mechanism, elevated levels of Fyn protein were observed in cell lines derived from Cbl(-/-) mice compared to those in wild-type controls. The effects of Cbl on Fyn were not observed when the 70ZCbl mutant protein was analyzed. Taken together, these observations implicate Cbl as a component in the negative regulation of Fyn and potentially other Src-family kinases, especially following kinase activation. These results also suggest that protein degradation may be a general mechanism for Cbl-mediated negative regulation of activated tyrosine kinases.

The role of the PH domain and SH3 binding domains in dynamin function.

Dynamin, a 100 kD GTPase, is necessary for the normal development and function of mammalian neural tissue. In neurons, it is necessary for the biogenesis of synaptic vesicles, and in other cell types dynamin has a general and important role in clathrin mediated receptor endocytosis. Different isoforms function as molecular scissors either during the formation of coated vesicles from plasma membrane coated pits, or during the release of intracellular vesicles from donor membranes. The mechanism entails the formation of a horseshoe-shaped dynamin polymer at the neck of the budding vesicle, followed by neck scission through a GTP hydrolysis dependent activity. The primary sequence of dynamin contains several C-terminal SH3 binding proline motifs, a central pleckstrin homology (PH) domain, and an N-terminal GTPase domain. Each of these domains appears to play a distinct role in dynamin function. Dynamin is activated by stimulus coupled PKC phosphorylation in brain, possibly mediated through PKC interactions with the PH domain. Further, SH3 domain interactions with the C-terminal sequences and phophatidylinositol/G beta gamma interactions with the PH domain also increase dynamin GTPase activity. Each of these various regulatory mechanisms is important in dynamin function during vesicle budding, although the means by which these mechanisms integrate in the overall function of dynamin remains to be elucidated.

ADPRibosylation of chicken red cell tubulin and inhibition of microtubule self-assembly in vitro by the NAD(+)-dependent avian ADPRibosyl transferase.

Chicken erythrocyte tubulin was found to undergo NAD(+)-dependent ADPribosylation in vitro in the presence of ADPRtransferase also isolated from avian red blood cells. Unlike the low level of ADPR incorporation catalyzed by Cholera and Pertussis toxins (i.e., less than 0.005 mol ADPR/mol tubulin), the avian system displayed a much higher stoichiometry of 0.8-1.2 mol ADPR/mol tubulin. Modification resulted in potent inhibition of microtubule self-assembly, even in the presence of bovine brain microtubule-associated proteins or with the addition of pre-assembled microtubules.

Microtubule protein ADP-ribosylation in vitro leads to assembly inhibition and rapid depolymerization.

Bovine brain microtubule protein, containing both tubulin and microtubule-associated proteins, undergoes ADP-ribosylation in the presence of [14C]NAD+ and a turkey erythrocyte mono-ADP-ribosyltransferase in vitro. The modification reaction could be demonstrated in crude brain tissue extracts where selective ADP-ribosylation of both the alpha and beta chains of tubulin and of the high molecular weight microtubule-associated protein MAP-2 occurred. In experiments with purified microtubule protein, tubulin dimer, the high molecular weight microtubule-associated protein MAP-2, and another high molecular weight mirotubule-associated protein which may be a MAP-1 species were heavily labeled. Tubulin and MAP-2 incorporated [14C]ADP-ribose to an average extent of approximately 2.4 and 30 mol of ADP-ribose/mol of protein, respectively. Assembly of microtubule protein into microtubules in vitro was inhibited by ADP-ribosylation, and incubation of assembled steady-state microtubules with ADP-ribosyltransferase and NAD+ resulted in rapid depolymerization of the microtubules. Thus, the eukaryotic enzyme can ADP-ribosylate tubulin and microtubule-associated proteins to much greater extents than previously observed with cholera and pertussis toxins, and the modification can significantly modulate microtubule assembly and disassembly.