Endocytic turnover of Rab8 controls cell polarization.

Adaptation of cell shape and polarization through the formation and retraction of cellular protrusions requires balancing of endocytosis and exocytosis combined with fine-tuning of the local activity of small GTPases like Rab8. Here, we show that endocytic turnover of the plasma membrane at protrusions is directly coupled to surface removal and inactivation of Rab8. Removal is induced by reduced membrane tension and mediated by the GTPase regulator associated with focal adhesion kinase-1 (GRAF1, also known as ARHGAP26), a regulator of clathrin-independent endocytosis. GRAF1-depleted cells were deficient in multi-directional spreading and displayed elevated levels of GTP-loaded Rab8, which was accumulated at the tips of static protrusions. Furthermore, GRAF1 depletion impaired lumen formation and spindle orientation in a 3D cell culture system, indicating that GRAF1 activity regulates polarity establishment. Our data suggest that GRAF1-mediated removal of Rab8 from the cell surface restricts its activity during protrusion formation, thereby facilitating dynamic adjustment of the polarity axis.

Endocytic membrane turnover at the leading edge is driven by a transient interaction between Cdc42 and GRAF1.

Changes in cell morphology require coordination of plasma membrane turnover and cytoskeleton dynamics, processes that are regulated by Rho GTPases. Here, we describe how a direct interaction between the Rho GTPase Cdc42 and the GTPase-activating protein (GAP) GRAF1 (also known as ARHGAP26), facilitates rapid cell surface turnover at the leading edge. Both Cdc42 and GRAF1 were required for fluid-phase uptake and regulated the generation of transient GRAF1-coated endocytic carriers, which were distinct from clathrin-coated vesicles. GRAF1 was found to transiently assemble at discrete Cdc42-enriched punctae at the plasma membrane, resulting in a corresponding decrease in the microdomain association of Cdc42. However, Cdc42 captured in its active state was, through a GAP-domain-mediated interaction, localised together with GRAF1 on accumulated internal structures derived from the cell surface. Correlative fluorescence and electron tomography microscopy revealed that these structures were clusters of small membrane carriers with defective endosomal processing. We conclude that a transient interaction between Cdc42 and GRAF1 drives endocytic turnover and controls the transition essential for endosomal maturation of plasma membrane internalised by this mechanism.

Rac1 and calmodulin interactions modulate dynamics of ARF6-dependent endocytosis.

The main cellular Ca(2+) sensor, calmodulin (CaM), interacts with and regulates several small GTPases, including Rac1. The present study revealed high binding affinity of Rac1 for CaM and uncovered two new essential binding domains in Rac1: the polybasic region, important for phosphatidylinositol-4-phosphate 5-kinase (PIP5K) interaction, and the adjacent prenyl group. CaM inhibition increased Rac1 binding to PIP5K and induced an extensive phosphatidylinositol 4,5-bisphosphate (PI4,5P(2) )-positive tubular membrane network. Immunofluorescence demonstrated that the tubules were plasma membrane invaginations resulting from an ADP-ribosylation factor 6 (ARF6)-dependent and clathrin-independent pathway. The role of Rac1 in this endocytic route was analyzed by expressing constitutively active and inactive mutants. While active Rac1 impaired tubulation, the inactive mutant enhanced it. Intriguingly, inactive mutant expression elicited tubulation by recruiting PIP5K and inhibiting Rac1 at the plasma membrane. Accordingly, CaM inhibition inactivated Rac1 and increased Rac1/PIP5K interaction. Therefore, our findings highlight an important new role for Rac1 and CaM in controlling clathrin-independent endocytosis.

Calmodulin modulates H-Ras mediated Raf-1 activation.

We have previously demonstrated that, in COS-1 cells, inhibition of calmodulin increases Ras-GTP levels although it decreases Raf-1 activity and consequently MAPK. The present study analyzes the role of calmodulin in the regulation of Raf-1. First we show, using FRET microscopy, that inhibition of Raf-1 was not a consequence of a decreased interaction between H-Ras and Raf-1. Besides, the analysis of the phosphorylation state of Raf-1 showed that calmodulin, through downstream PI3K, is essential to ensure the Ser338-Raf-1 phosphorylation, critical for Raf-1 activation. We also show that the expression of a dominant negative mutant of PI3K impairs the calmodulin-mediated Raf-1 activation; in addition, both calmodulin and PI3K inhibitors decrease phospho-Ser338 and Raf-1 activity from upstream active H-Ras (H-RasG12V) and this effect is dependent on endocytosis. Importantly, in H-Ras depleted COS-1 cells, calmodulin does not modulate MAPK activation. Altogether, the results suggest that calmodulin regulation of MAPK in COS-1 cells relies upon H-Ras control of Raf-1 activity and involves PI3K.

ROCK1 is a novel Rac1 effector to regulate tubular endocytic membrane formation during clathrin-independent endocytosis.

Clathrin-dependent and -independent pathways contribute for ß1-integrin endocytosis. This study defines a tubular membrane clathrin-independent endocytic network, induced with the calmodulin inhibitor W13, for ß1-integrin internalization. This pathway is dependent on increased phosphatidylinositol 4,5-bisphosphate (PI(4,5)P2) levels and dynamin activity at the plasma membrane. Exogenous addition of PI(4,5)P2 or phosphatidylinositol-4-phosphate 5-kinase (PIP5K) expression mimicked W13-generated-tubules which are inhibited by active Rac1. Therefore, the molecular mechanisms downstream of Rac1, that controls this plasma membrane tubulation, were analyzed biochemically and by the expression of different Rac1 mutants. The results indicate that phospholipase C and ROCK1 are the main Rac1 effectors that impair plasma membrane invagination and tubule formation, essentially by decreasing PI(4,5)P2 levels and promoting cortical actomyosin assembly respectively. Interestingly, among the plethora of proteins that participate in membrane remodeling, this study revealed that ROCK1, the well-known downstream RhoA effector, has an important role in Rac1 regulation of actomyosin at the cell cortex. This study provides new insights into Rac1 functioning on plasma membrane dynamics combining phosphatidylinositides and cytoskeleton regulation.

Clathrin-Independent Endocytosis Suppresses Cancer Cell Blebbing and Invasion.

Cellular blebbing, caused by local alterations in cell-surface tension, has been shown to increase the invasiveness of cancer cells. However, the regulatory mechanisms balancing cell-surface dynamics and bleb formation remain elusive. Here, we show that an acute reduction in cell volume activates clathrin-independent endocytosis. Hence, a decrease in surface tension is buffered by the internalization of the plasma membrane (PM) lipid bilayer. Membrane invagination and endocytosis are driven by the tension-mediated recruitment of the membrane sculpting and GTPase-activating protein GRAF1 (GTPase regulator associated with focal adhesion kinase-1) to the PM. Disruption of this regulation by depleting cells of GRAF1 or mutating key phosphatidylinositol-interacting amino acids in the protein results in increased cellular blebbing and promotes the 3D motility of cancer cells. Our data support a role for clathrin-independent endocytic machinery in balancing membrane tension, which clarifies the previously reported role of GRAF1 as a tumor suppressor.

Genes encoding cuticular proteins are components of the Nimrod gene cluster in Drosophila.

The Nimrod gene cluster, located on the second chromosome of Drosophila melanogaster, is the largest synthenic unit of the Drosophila genome. Nimrod genes show blood cell specific expression and code for phagocytosis receptors that play a major role in fruit fly innate immune functions. We previously identified three homologous genes (vajk-1, vajk-2 and vajk-3) located within the Nimrod cluster, which are unrelated to the Nimrod genes, but are homologous to a fourth gene (vajk-4) located outside the cluster. Here we show that, unlike the Nimrod candidates, the Vajk proteins are expressed in cuticular structures of the late embryo and the late pupa, indicating that they contribute to cuticular barrier functions.

Differential involvement of H- and K-Ras in Raf-1 activation determines the role of calmodulin in MAPK signaling.

We have previously demonstrated that inhibition of calmodulin (CaM) and the concomitant reduction of PI3K interfere with H-Ras-mediated activation of Raf-1 [1]. In the present study, we show that CaM has completely opposite effects on K-Ras-mediated Raf-1 activation. The differential contribution of CaM in the regulation of Raf-1 kinase activity via K- or H-Ras correlates with the stimulatory or inhibitory effect of CaM on MAPK phosphorylation depending on the cell type analyzed. FRET microscopy and biochemical analysis show that inhibition of CaM increases K-Ras-GTP levels and consequently its association with Raf-1. Though inhibition of CaM, using the CaM antagonist W-13, significantly increased Raf-1 activation by K-Ras-GTP, MAPK activation downstream K-Ras/Raf-1 was strongly reduced in COS-1 and several other cell lines. In contrast, in other cell lines such as NIH3T3-wt8, W-13-mediated inhibition of CaM increased Raf-1 activity, but resulted in an increase in MAPK phosphorylation. These findings suggest that modulation of K-Ras activity via CaM regulates MAPK signaling only in certain cell types. In support of this hypothesis, the comparison of H- and K-Ras expression, GTP loading and Raf-1 interaction in COS-1 and NIH3T3-wt8 suggests that the overall role of CaM in MAPK signal output is determined by the ratio of activated H- and K-Ras and the cell-specific contribution of each isoform in Raf-1 activation.