Dominique T. Brandt

Dia1 and IQGAP1 interact in cell migration and phagocytic cup formation.

The Diaphanous-related formin Dia1 nucleates actin polymerization, thereby regulating cell shape and motility. Mechanisms that control the cellular location of Dia1 to spatially define actin polymerization are largely unknown. In this study, we identify the cytoskeletal scaffold protein IQGAP1 as a Dia1-binding protein that is necessary for its subcellular location. IQGAP1 interacts with Dia1 through a region within the Diaphanous inhibitory domain after the RhoA-mediated release of Dia1 autoinhibition. Both proteins colocalize at the front of migrating cells but also at the actin-rich phagocytic cup in macrophages. We show that IQGAP1 interaction with Dia1 is required for phagocytosis and phagocytic cup formation. Thus, we identify IQGAP1 as a novel component involved in the regulation of phagocytosis by mediating the localization of the actin filament nucleator Dia1.

Get to grips: steering local actin dynamics with IQGAPs

IQGAPs are actin‐binding proteins that scaffold numerous interaction partners, transmitting extracellular signals that influence mitogenic, morphological and migratory cell behaviour. However, the precise mechanisms by which IQGAP proteins influence actin dynamics and actin filament structures have been elusive. Now that IQGAP1 has emerged as a potential key regulator of actin‐cytoskeletal dynamics by recruiting both the actin related protein (Arp)2/3 complex and/or formin‐dependent actin polymerizing machineries, we propose that IQGAP1 might coordinate the function of mechanistically different actin nucleators for cooperative localized actin filament production in various cellular processes.

Protein kinase C induces actin reorganization via a Src- and Rho-dependent pathway

We have investigated the mechanism of PKC-induced actin reorganization in A7r5 vascular smooth muscle cells. PKC activation by 12-O-tetradecanoylphorbol-13-acetate induces the disassembly of actin stress fibers concomitant with the appearance of membrane ruffles. PKC also induces rapid tyrosine phosphorylation in these cells. As we could show, utilizing the Src-specific inhibitor PP2 and a kinase-deficient c-Src mutant, actin reorganization is dependent on PKC-induced Src activation. Subsequently, the activity of the small G-protein RhoA is decreased, whereas Rac and Cdc42 activities remain unchanged. Disassembly of actin stress fibers could also be observed using the Rho kinase-specific inhibitor Y-27632, indicating that the decrease in RhoA activity on its own is responsible for actin reorganization. In addition, we show that tyrosine phosphorylation of p190RhoGAP is increased upon 12-O-tetradecanoylphorbol-13-acetate stimulation, directly linking Src activation to a decrease in RhoA activity. Our data provide substantial evidence for a model elucidating the molecular mechanisms of PKC-induced actin rearrangements.

Gα12/13 Is Essential for Directed Cell Migration and Localized Rho-Dia1 Function

Scratch-wound assays are frequently used to study directed cell migration, a process critical for embryogenesis, invasion, and tissue repair. The function and identity of trimeric G-proteins in cell behavior during wound healing is not known. Here we show that Gα12/13, but not Gαq/11 or Gαi, is indispensable for coordinated and directed cell migration. In mouse embryonic fibroblasts endogenous Rho activity is present at the rear of migrating cells but also at the leading edge, whereas it is undetectable at the cell front of Gα12/13-deficient mouse embryonic fibroblasts. Spatial activation of Rho at the wound edge can be stimulated by lysophosphatidic acid. Active Rho colocalizes with the diaphanous-related formin Dia1 at the cell front. Gα12/13-deficient cells lack Dia1 localization to the wound edge and are unable to form orientated, stable microtubules during wound healing. Knock down of Dia1 reveals its requirement for microtubule stabilization as well as polarized cell migration. Thus, we identified Gα12/13-proteins as essential components linking extracellular signals to localized Rho-Dia1 function during directed cell movement.

Protein kinase Cδ induces Src kinase activity via activation of the protein tyrosine phosphatase PTPα

Previously we have shown that protein kinase C (PKC)-mediated reorganization of the actin cytoskeleton in smooth muscle cells is transmitted by the non-receptor tyrosine kinase, Src. Several authors have described how 12-O-tetradecanoylphorbol-13-acetate (TPA) stimulation of cells results in an increase of Src activity, but the mechanism of the PKC-mediated Src activation is unknown. Using PKC isozymes purified from Spodoptera frugiperda insect cells, we show here that PKC is not able to activate Src directly. Our data reveal that the PKC-dependent Src activation occurs via the activation of the protein tyrosine phosphatase (PTP) PTPα. PTPα becomes activated in vivo after TPA stimulation. Further, we show that PKCδ phosphorylates and activates only PTPα in vitro but not any other of the TPA-responsive PKC isozymes that are expressed in A7r5 rat aortic smooth muscle cells. To further substantiate our data, we show that cells lacking PKCδ have a markedly reduced PTPα and Src activity after 12-O-tetradecanoylphorbol-13-acetate stimulation. These data support a model in which the main mechanism of 12-O-tetradecanoylphorbol-13-acetate-induced Src activation is the direct phosphorylation and activation of PTPα by PKCδ, which in turn dephosphorylates and activates Src.

SCAI acts as a suppressor of cancer cell invasion through the transcriptional control of β 1 -integrin

Gene expression reprogramming governs cellular processes such as proliferation, differentiation and cell migration through the complex and tightly regulated control of transcriptional cofactors that exist in multiprotein complexes. Here we describe SCAI (suppressor of cancer cell invasion), a novel and highly conserved protein that regulates invasive cell migration through three-dimensional matrices. SCAI acts on the RhoA–Dia1 signal transduction pathway and localizes in the nucleus, where it binds and inhibits the myocardin-related transcription factor MAL by forming a ternary complex with serum response factor (SRF). Genome-wide expression analysis surprisingly reveals that one of the strongest upregulated genes after suppression of SCAI is β1-integrin. Decreased levels of SCAI are tightly correlated with increased invasive cell migration, and SCAI is downregulated in several human tumours. Functional analysis of the β1-integrin gene strongly argues that SCAI is a novel transcriptional cofactor that controls gene expression downstream of Dia1 to dictate changes in cell invasive behaviour.

Regulation of myocardin-related transcriptional coactivators through cofactor interactions in differentiation and cancer

Transcriptional signaling networks are orchestrated and fine-tuned through multiple interactions of transcription factors with subsets of cofactors thereby assembling multiprotein complexes to negatively or positively balance transcriptional output. These mechanisms account for the large diversity but also for time and tissue specific gene regulations through single transcription factors such as SRF. One family of SRF coactivatos that have attracted much attention is represented by the myocardin-related transcription factors (MRTFs). MRTFs themselves are controlled through interactions with a growing number of cofactors and transcriptional regulators. We recently identified SCAI (suppressor of cancer cell invasion), which can associate with MAL (MRTF-A) to modulate invasive cancer cell migration through regulation of β1-integrin expression and function. However, SCAI is likely to have additional functions depending on the tissue environment and signaling program. Interestingly, SCAI not only inhibits MRTF-A but can also regulate the activities of other MRTFs such as myocardin, or the oncogenic OTT-MAL fusion protein. Thus, SCAI may act in very different conditions such as during cancer progression, development or cell differentiation.

Mutant p53 promotes tumor progression and metastasis by the endoplasmic reticulum UDPase ENTPD5

Significance p53 mutations are the most frequent genetic alteration in cancer and are often indicative of poor patient survival prognosis. The most prevalent missense mutations lead to a “gain of function” (GOF) that actively drives tumor progression, metastasis, and therapy resistance. Our study links the mutant p53 (mutp53) GOF to enhanced N-glycoprotein folding via ectonucleoside triphosphate diphosphohydrolase 5 (ENTPD5) in the calnexin/calreticulin cycle of the endoplasmic reticulum. Mutp53 thus increases expression of prometastatic cell surface proteins, such as receptors and integrins, not only quantitatively but also qualitatively, with respect to N-glycosylation state. Our study reveals N-glycoprotein quality control in the endoplasmic reticulum as an indispensable mechanism underlying the progression of tumors with GOF mutp53 that could provide new possibilities for treating prognostically challenging p53-mutated cancers. Mutations in the p53 tumor suppressor gene are the most frequent genetic alteration in cancer and are often associated with progression from benign to invasive stages with metastatic potential. Mutations inactivate tumor suppression by p53, and some endow the protein with novel gain of function (GOF) properties that actively promote tumor progression and metastasis. By comparative gene expression profiling of p53-mutated and p53-depleted cancer cells, we identified ectonucleoside triphosphate diphosphohydrolase 5 (ENTPD5) as a mutant p53 target gene, which functions as a uridine 5′-diphosphatase (UDPase) in the endoplasmic reticulum (ER) to promote the folding of N-glycosylated membrane proteins. A comprehensive pan-cancer analysis revealed a highly significant correlation between p53 GOF mutations and ENTPD5 expression. Mechanistically, mutp53 is recruited by Sp1 to the ENTPD5 core promoter to induce its expression. We show ENTPD5 to be a mediator of mutant p53 GOF activity in clonogenic growth, architectural tissue remodeling, migration, invasion, and lung colonization in an experimental metastasis mouse model. Our study reveals folding of N-glycosylated membrane proteins in the ER as a mechanism underlying the metastatic progression of tumors with mutp53 that could provide new possibilities for cancer treatment.

Identification of Neurochondrin as a new interaction partner of the FH3 domain of the Diaphanous-related formin Dia1.

Mammalian Diaphanous (Dia)-related formins initiate the assembly of filamentous actin downstream of Rho GTPases to regulate cellular processes such as cytokinesis, cell polarity, cell motility and adhesion. In this work, we show that Neurochondrin (NC) is a novel Dia1 interacting protein. NC specifically binds to the formin homology 3 (FH3), but not to the FH1 or FH2 domain of Dia1. Both proteins show a partial co-localization in dissociated primary rat hippocampal neurons. Ectopic expression of both proteins induced neurite outgrowth in Neuro2A cells. Using a series of deletion mutants of NC we could show that the first 100 amino acids were responsible for its effect on neurite outgrowth, whereas the C-terminal part of NC had no neurite outgrowth promoting activity. Moreover, co-expression of the C terminus of NC with Dia1DeltaDAD resulted in a dramatic reduction of Dia1-induced neurite outgrowth. On the basis of actin fractionation assays, SRF-activity assays as well as microtubule stabilization assays, we could demonstrate that the C terminus of NC does not influence the actin polymerizing activity of Dia1, indicating a more specific function of NC in the modulation of Dia1 activity.

Functional Interaction of SCAI with the SWI/SNF Complex for Transcription and Tumor Cell Invasion

We have recently characterized SCAI (Suppressor of Cancer Cell Invasion), a transcriptional modulator regulating cancer cell motility through suppression of MAL/SRF dependent gene transcription. We show here that SCAI is expressed in a wide range of normal human tissues and its expression is diminished in a large array of primary human breast cancer samples indicating that SCAI expression might be linked to the etiology of human cancer. To establish a functional link between SCAI and tumorigenesis we performed affinity columns to identify SCAI-interacting proteins. Our data show that SCAI interacts with the tumor suppressing SWI/SNF chromatin remodeling complex to promote changes in gene expression and the invasive capacities of human tumor cells. Moreover our data implicate a functional hierarchy between SCAI and BRM, since SCAI function is abrogated in the absence of BRM expression.