The Aarskog-Scott syndrome protein Fgd1 regulates podosome formation and extracellular matrix remodeling in transforming growth factor β-stimulated aortic endothelial cells

Podosomes are dynamic actin-rich adhesion plasma membrane microdomains endowed with extracellular matrix-degrading activities. In aortic endothelial cells, podosomes are induced by transforming growth factor β (TGF-β), but how this occurs is largely unknown. It is thought that, in endothelial cells, podosomes play a role in vessel remodeling and/or in breaching anatomical barriers. We demonstrate here that, in bovine aortic endothelial cells, that the Cdc42-specific guanine exchange factor (GEF) Fgd1 is expressed and regulated by TGF-β to induce Cdc42-dependent podosome assembly. Within 15 min of TGF-β stimulation, Fgd1, but none of the other tested Cdc42 GEFs, undergoes tyrosine phosphorylation, associates with Cdc42, and translocates to the subcortical cytoskeleton via a cortactin-dependent mechanism. Small interfering RNA-mediated Fgd1 knockdown inhibits TGF-β-induced Cdc42 activation. Fgd1 depletion also reduces podosome formation and associated matrix degradation and these defects are rescued by reexpression of Fgd1. Although overexpression of Fgd1 does not promote podosome formation per se, it enhances TGF-β-induced matrix degradation. Our results identify Fgd1 as a TGF-β-regulated GEF and, as such, the first GEF to be involved in the process of cytokine-induced podosome formation. Our findings reveal the involvement of Fgd1 in endothelial cell biology and open up new avenues to study its role in vascular pathophysiology.     

Sodium fluoride induces podosome formation in endothelial cells

Background information. Fluoride is a well‐known G‐protein activator. Exposure of cultured cells to its derivatives results in actin cytoskeleton remodelling. Podosomes are actin‐based structures endowed with adhesion and matrix‐degradation functions. This study investigates actin cytoskeleton reorganization induced by fluoride in endothelial cells. Results. Treatment of cultured endothelial cells with sodium fluoride (NaF) results in a rapid and potent stimulation of podosome formation. Furthermore, we show that Cdc42 (cell‐division cycle 42), Rac1 and RhoA activities are stimulated in NaF‐treated cells. However, podosome assembly is dependent on Cdc42 and Rac1, but not RhoA. Although the sole activation of Cdc42 is sufficient to induce individual podosomes, a balance between RhoGTPase activities regulates podosome formation in response to NaF, which in this case are often found in groups or rosettes. As in other models, podosome formation in endothelial cells exposed to NaF also involves Src. Finally, we demonstrate that NaF‐induced podosomes are fully competent for matrix protein degradation. Conclusions. Taken together, our findings establish NaF as a novel inducer of podosomes in endothelial cells in vitro.     

Regulatory signals for endothelial podosome formation

Podosomes are punctate actin-rich adhesion structures which spontaneously form in cells of the myelomonocytic lineage. Their formation is dependent on Src and RhoGTPases. Recently, podosomes have also been described in vascular cells. These podosomes differ from the former by the fact that they are inducible. In endothelial cells, such a signal can be provided by either constitutively active Cdc42, the PKC activator PMA or TGFbeta, depending on the model. Consequently, other regulatory pathways have been reported to contribute to podosome formation. To get more insight into the mechanisms by which podosomes form in endothelial cells, we have explored the respective contribution of signal transducers such as Cdc42-related GTPases, Smads and PKCs in three endothelial cell models. Results presented demonstrate that, in addition to Cdc42, TC10 and TCL GTPases can also promote podosome formation in endothelial cells. We also show that PKCalpha can be either necessary or entirely dispensable, depending on the cell model. In contrast, PKCdelta is essential for podosome formation in endothelial cells but not smooth muscle cells. Finally, although podosomes vary very little in their molecular composition, the signalling pathways involved in their assembly appear very diverse.     

The Novel Adaptor Protein Tks4 (SH3PXD2B) Is Required for Functional Podosome Formation

Metastatic cancer cells have the ability to both degrade and migrate through the extracellular matrix (ECM). Invasiveness can be correlated with the presence of dynamic actin-rich membrane structures called podosomes or invadopodia. We showed previously that the adaptor protein tyrosine kinase substrate with five Src homology 3 domains (Tks5)/Fish is required for podosome/invadopodia formation, degradation of ECM, and cancer cell invasion in vivo and in vitro. Here, we describe Tks4, a novel protein that is closely related to Tks5. This protein contains an amino-terminal Phox homology domain, four SH3 domains, and several proline-rich motifs. In Src-transformed fibroblasts, Tks4 is tyrosine phosphorylated and predominantly localized to rosettes of podosomes. We used both short hairpin RNA knockdown and mouse embryo fibroblasts lacking Tks4 to investigate its role in podosome formation. We found that lack of Tks4 resulted in incomplete podosome formation and inhibited ECM degradation. Both phenotypes were rescued by reintroduction of Tks4, whereas only podosome formation, but not ECM degradation, was rescued by overexpression of Tks5. The tyrosine phosphorylation sites of Tks4 were required for efficient rescue. Furthermore, in the absence of Tks4, membrane type-1 matrix metalloproteinase (MT1-MMP) was not recruited to the incomplete podosomes. These findings suggest that Tks4 and Tks5 have overlapping, but not identical, functions, and implicate Tks4 in MT1-MMP recruitment and ECM degradation.     

The non-redundant role of N-WASP in podosome-mediated matrix degradation in macrophages

Wiskott-Aldrich Syndrome Protein (WASP) is a hematopoietic cell-specific regulator of Arp2/3-dependent actin polymerization. Despite the presence of the highly homologous N-WASP (neural-WASP), macrophages from WAS patients are devoid of podosomes, adhesion structures in cells of the monocytic lineage capable of matrix degradation via matrix metalloproteases (MMPs), suggesting that WASP and N-WASP play unique roles in macrophages. To determine whether N-WASP also plays a unique role in macrophage function, N-WASP expression was reduced using silencing RNA in a sub-line of RAW 264.7 macrophages (RAW/LR5). Similar to reduction in WASP levels, cells with reduced N-WASP levels were rounder and less polarized. Interestingly, podosomes still formed when N-WASP was reduced but they were unable to perform matrix degradation. This defect was rescued by re-expression of N-WASP, but not by over-expression of WASP, indicating that these proteins play distinct roles in podosome function. Additionally, reducing N-WASP levels mistargets the metalloprotease MT1-MMP and it no longer localizes to podosomes. However, N-WASP was only found to co-localize with MT1-MMP positive vesicles at podosomes, suggesting that N-WASP may play a role on the targeting or fusion of MMP-containing vesicles to podosomes in macrophage-like cells.     

Cdc42-driven podosome formation in endothelial cells

Ectopic expression of a constitutive active mutant of the GTPase Cdc42 (V12Cdc42) in vascular endothelial cells triggers the dissolution of stress fibres and focal adhesion contacts and causes the repolymerisation of actin into dots. Each punctate structure consists of an F-actin core surrounded by a vinculin ring, consistent with the definition of podosomes. We now report further analysis of these complexes and show the presence of established podosomal markers such as cortactin, gelsolin, dynamin, N-WASP, and Arp2/3 which are absent in focal adhesions. Endothelial podosomes appear as randomly distributed conical structures, distributed on, but restricted to, the ventral membrane and confined to contact sites between cells and their substratum. The nature of the extracellular matrix does not influence podosome formation nor their spatial organisation. Induction of podosomes in response to V12Cdc42 is not associated with a migratory nor with a proliferative phenotype. These results add endothelial cells to the list of cell types endowed with the ability to form podosomes in vitro and raise the possibility that endothelial cells could form such structures under certain physiological or pathological conditions.     

Metalloproteinase MT1-MMP islets act as memory devices for podosome reemergence

Podosomes are dynamic cell adhesions that are also sites of extracellular matrix degradation, through recruitment of matrix-lytic enzymes, particularly of matrix metalloproteinases. Using total internal reflection fluorescence microscopy, we show that the membrane-bound metalloproteinase MT1-MMP is enriched not only at podosomes but also at distinct “islets” embedded in the plasma membrane of primary human macrophages. MT1-MMP islets become apparent upon podosome dissolution and persist beyond podosome lifetime. Importantly, the majority of MT1-MMP islets are reused as sites of podosome reemergence. siRNA-mediated knockdown and recomplementation analyses show that islet formation is based on the cytoplasmic tail of MT1-MMP and its ability to bind the subcortical actin cytoskeleton. Collectively, our data reveal a previously unrecognized phase in the podosome life cycle and identify a structural function of MT1-MMP that is independent of its proteolytic activity. MT1-MMP islets thus act as cellular memory devices that enable efficient and localized reformation of podosomes, ensuring coordinated matrix degradation and invasion.     

TLR ligand-induced podosome disassembly in dendritic cells is ADAM17 dependent

Toll-like receptor (TLR) signaling induces a rapid reorganization of the actin cytoskeleton in cultured mouse dendritic cells (DC), leading to enhanced antigen endocytosis and a concomitant loss of filamentous actin–rich podosomes. We show that as podosomes are lost, TLR signaling induces prominent focal contacts and a transient reduction in DC migratory capacity in vitro. We further show that podosomes in mouse DC are foci of pronounced gelatinase activity, dependent on the enzyme membrane type I matrix metalloprotease (MT1-MMP), and that DC transiently lose the ability to degrade the extracellular matrix after TLR signaling. Surprisingly, MMP inhibitors block TLR signaling–induced podosome disassembly, although stimulated endocytosis is unaffected, which demonstrates that the two phenomena are not obligatorily coupled. Podosome disassembly caused by TLR signaling occurs normally in DC lacking MT1-MMP, and instead requires the tumor necrosis factor α–converting enzyme ADAM17 (a disintegrin and metalloprotease 17), which demonstrates a novel role for this “sheddase” in regulating an actin-based structure.     

The protein kinase C cascade regulates recruitment of matrix metalloprotease 9 to podosomes and its release and activation

Podosomes are transient cell surface structures essential for degradation of extracellular matrix during cell invasion. Protein kinase C (PKC) is involved in the regulation of podosome formation; however, the roles of individual PKC isoforms in podosome formation and proteolytic function are largely unknown. Recently, we reported that PDBu, a PKC activator, induced podosome formation in normal human bronchial epithelial cells. Here, we demonstrate that phorbol-12,13-dibutyrate (PDBu)-induced podosome formation is mainly mediated through redistribution of conventional PKCs, especially PKCα, from the cytosol to the podosomes. Interestingly, although blocking atypical PKCζ did not affect PDBu-induced podosome formation, it significantly reduced matrix degradation at podosomes. Inhibition of PKCζ reduced recruitment of matrix metalloprotease 9 (MMP-9) to podosomes and its release and activation. Downregulation of MMP-9 by small interfering RNA (siRNA) or neutralization antibody also significantly reduced matrix degradation. The regulatory effects of PKCζ on matrix degradation and recruitment of MMP-9 to podosomes were PKCζ kinase activity dependent. PDBu-induced recruitment of PKCζ and MMP-9 to podosomes was blocked by inhibition of novel PKC with rottlerin or PKCδ siRNA. Our data suggest that multiple PKC isozymes form a signaling cascade that controls podosome formation and dynamics and MMP-9 recruitment, release, and activation in a coordinated fashion.     

Cdc42 and RhoA have opposing roles in regulating membrane type 1-matrix metalloproteinase localization and matrix metalloproteinase-2 activation

Proteolysis of the basement membrane and interstitial matrix occurs early in the angiogenic process and requires matrix metalloproteinase (MMP) activity. Skeletal muscle microvascular endothelial cells exhibit robust actin stress fibers, low levels of membrane type 1 (MT1)-MMP expression, and minimal MMP-2 activation. Depolymerization of the actin cytoskeleton increases MT1-MMP expression and MMP-2 activation. Rho family GTPases are regulators of actin cytoskeleton dynamics, and their activity can be modulated in response to angiogenic stimuli such as vascular endothelial growth factor (VEGF). Therefore, we investigated their roles in MMP-2 and MT1-MMP production. Endothelial cells treated with H1152 [an inhibitor of Rho kinase (ROCK)] induced stress fiber depolymerization and an increase in cortical actin. Both MMP-2 and MT1-MMP mRNA increased, which translated into greater MMP-2 protein production and activation. ROCK inhibition rapidly increased cell surface localization of MT1-MMP and increased PI3K activity, which was required for MMP-2 activation. Constitutively active Cdc42 increased cortical actin polymerization, phosphatidylinositol 3-kinase activity, MT1-MMP cell surface localization, and MMP-2 activation similarly to inhibition of ROCK. Activation of Cdc42 was sufficient to decrease RhoA activity. Capillary sprout formation in a three-dimensional collagen matrix was increased in cultures treated with RhoAN19 or Cdc42QL and, conversely, decreased in cultures treated with dominant negative Cdc42N17. VEGF stimulation also induced activation of Cdc42 while inhibiting RhoA activity. Furthermore, VEGF-dependent activation of MMP-2 was reduced by inhibition of Cdc42. These results suggest that Cdc42 and RhoA have opposing roles in regulating cell surface localization of MT1-MMP and MMP-2 activation.     

Proactive for invasion: Reuse of matrix metalloproteinase for structural memory

Migratory cells translocate membrane type-1 matrix metalloproteinase (MT1-MMP) to podosomes or invadosomes to break extracellular matrix barriers. In this issue, El Azzouzi et al. (2016. J. Cell. Biol. http://dx.doi.org/10.1083/jcb.201510043) describe an unexpected function for the MT1-MMP cytoplasmic domain in imprinting spatial memory for podosome reformation via assembly in membrane islets.Invasion of most normal and cancer cells across basement membranes and collagen-rich interstitial tissues involves degradation of the ECM by membrane type-1 matrix metalloproteinase (MT1-MMP/MMP14; Willis et al., 2013). To fulfill this activity, MT1-MMP is transported to podosomes, the specialized ECM-degrading membrane protrusions found in highly migratory cells such as activated macrophages, osteoclasts, endothelial cells, and smooth muscle cells (Murphy and Courtneidge, 2011). In cancer cells, MT1-MMP is transported to ECM-degrading invasive structures called invadopodia (Poincloux et al., 2009). Both these membrane protrusions, collectively called invadosomes, are composed of an actin-rich core surrounded by scaffold and adhesion proteins, and numerous mechanisms of invadosome assembly, maturation, and dynamics have been identified (Poincloux et al., 2009; Murphy and Courtneidge, 2011). MT1-MMP activity is regulated at multiple levels to achieve targeted ECM degradation, cell surface protein processing, and protease activation (Sato et al., 1994; Osenkowski et al., 2004; Sugiyama et al., 2013; Willis et al., 2013; Itoh, 2015). Potential regulatory functions of MT1-MMP toward the cytoskeleton have, however, remained unclear. In this issue, El Azzouzi et al. describe an unexpected and novel function for MT1-MMP that goes beyond its traditional proteolytic activity: they show that MT1-MMP accumulates in membrane islets that provide macrophages with spatial information, or memory, in sites of podosome dissolution so as to enable efficient podosome reassembly.El Azzouzi et al. (2016) first used total internal reflection fluorescence microscopy and a pH-sensitive version of MT1-MMP devised to fluoresce only when the MT1-MMP ectodomain is exposed to the extracellular environment’s pH. With this approach, they show that, on the ventral surface of cultured human macrophages, MT1-MMP is localized at two different membrane compartments: underneath the podosome core, as previously suggested based on matrix degradation and colocalization with podosome markers, and in distinct islets devoid of other podosome components, CD44, or integrin-mediated adhesion to the ECM (Fig. 1; Osiak et al., 2005). MT1-MMP islets were dependent on intact cortical actin, but became more apparent and persisted after podosome disruption by pharmacological perturbation of key components of podosome assembly and maturation, such as integrin adhesion, Src kinase activity, and the Arp2/3 complex essential for actin nucleation and branched actin cytoskeleton. Podosomes often reemerge at sites of previous podosome localization, and El Azzouzi et al. (2016) hypothesized that MT1-MMP islets might mark sites of podosome formation. They treated cells with an Arp2/3 inhibitor to disrupt podosomes and induce the appearance of MT1-MMP membrane clusters, and used time-lapse imaging to track what happens upon washout and podosome reformation. Interestingly, they show that these novel MT1-MMP structures serve as remarkably immobile cell membrane anchors capable of rerecruiting the podosomal actin cores/scaffolds to the same islets.Open in a separate windowFigure 1.MT1-MMP islets as memory sites for podosome reformation. Migratory cells translocate MT1-MMP (red) to podosomes or invadosomes to degrade the ECM (green fibers). These membrane structures are composed of an actin-rich core (brown) surrounded by adhesion and scaffold proteins (beige) such as integrins (blue). El Azzouzi et al. (2016) show a function for MT1-MMP accumulation in membrane ”islets” (1), where they imprint spatial memory for podosome reemergence after podosome disassembly (2). Unlike dynamic mature podosomes (3), MT1-MMP assembles in stable islets via anchorage to cortical actin. Future work in the fields of inflammation, cancer, and angiogenesis will need to address the nature of the cytoskeletal dynamics mediating islet formation, the involvement of microtubules in islet formation, the exact islet protein composition, and the relevance of these memory sites to 2D or 3D environments and to other cell types beyond macrophages, including endothelial cells and invasive cancer cells.Further, by expressing mutant MT1-MMP proteins in cells silenced for the endogenous proteinase and using a podosome reformation assay (based on pharmacological dissolution of podosomes via Src inhibition, followed by podosome reformation after washout), El Azzouzi et al. (2016) pinpointed the region of MT1-MMP critical for islet formation, the LLY-sequence in its cytoplasmic domain. Moreover, when attached to the membrane by the MT1-MMP transmembrane domain, the 20–amino acid cytoplasmic tail appeared necessary and sufficient to form the islets. Considering the LLY sequence–dependent actin-binding ability of MT1-MMP (Yu et al., 2012) coupled with the observed necessity of cortical actin for islet appearance and podosome reformation, the direct interaction with unbranched cortical actin was suggested by the authors as a likely decisive mechanism for the remarkable MT1-MMP islet stabilization in podosome-free areas, although a possible indirect interaction was not ruled out. Actin binding through the MT1-MMP cytosolic tail was likewise suggested as a potential means for podosome rerecruitment by MT1-MMP memory islets.Although cortical actin is instrumental for the emergence of the spatially and temporally stable MT1-MMP islets upon podosome dissolution in macrophages and direct actin–MT1-MMP interaction has been proven in vitro and suggested as a means for retaining MT1-MMP in invadopodia, a Src-regulated interaction between MT1-MMP’s cytoplasmic domain and the actin-binding scaffold protein palladin has also been shown to regulate MT1-MMP targeting into invadopodia (Yu et al., 2012; von Nandelstadh et al., 2014). Moreover, the LLY sequence in MT1-MMP’s cytoplasmic tail harbors a Src substrate sequence and mediates an interaction between MT1-MMP and AP-2 that is important for MT1-MMP internalization and dynamics in cell migration and invasion (Uekita et al., 2001; Nyalendo et al., 2007). Intriguingly, El Azzouzi et al. (2016) did not find evidence of involvement of dynamin-dependent membrane trafficking events in the ability of MT1-MMP islets to function as memory sites. However, their results after treatment with the microtubule inhibitor nocodazole indicated that although the islets themselves remained intact, podosome reappearance was mislocalized, suggesting that microtubules contribute by as yet undefined mechanisms to the ability of MT1-MMP islets to provide spatial memory and to facilitate podosome reassembly. Therefore, further identification of drivers and specific regulatory mechanisms of the actin–MT1-MMP interaction dynamics in podosomes, of the stable actin–MT1-MMP interaction and structures in podosome-free areas, and of microtubule-dependent podosome reassembly will be of interest.A striking observation of this study is that MT1-MMP islets do not display degradative activity in matrix degradation assays. In addition, inhibition of the proteolytic activity of MT1-MMP through pharmacological agents or via an inactivating mutation did not impact islet appearance or podosome reemergence at sites of MT1-MMP clustering. Overall, on the extracellular side of the plasma membrane, the apparent lack of contact and degradation of the ECM as well as the relatively minor impact of the N-terminal MT1-MMP ectodomain on islet formation and podosome reemergence are peculiar features of the MT1-MMP islets. However, El Azzouzi et al. (2016) show evidence for somewhat impaired islet formation in cells expressing an MT1-MMP mutant lacking the entire ectodomain, and they demonstrate that endogenous MT1-MMP must be silenced for the LLY MT1-MMP mutant to disrupt islet localization. Based on these results, the authors suggest the possible influence of MT1-MMP oligomerization and of MT1-MMP–ECM binding on islet recruitment and stabilization. Nevertheless, these observations altogether indicate that the adhesive and degradative activities of MT1-MMP memory islets toward the ECM are minor and, intriguingly, do not influence the structure or function of these islets as currently characterized in 2D cultures.Furthermore, the aforementioned results raise questions about the possible contribution of the different molecular forms of MT1-MMP (e.g., cleaved or uncleaved and inhibitor bound or not) to the stabilization and podosome reassembly function of MT1-MMP islets. In cells and conditions in which MT1-MMP activity is high, MT1-MMP turnover is typically fast via autocatalytic cleavage or shedding of the N-terminal catalytic domain (Lehti et al., 1998; Yana and Weiss, 2000; Itoh et al., 2001; Osenkowski et al., 2004). After interaction with inhibitors such as tissue inhibitors of metalloproteinases, active endocytosed MT1-MMP may dissociate from the bound inhibitor to be recycled to the plasma membrane (Jiang et al., 2001; Remacle et al., 2003). However, in the absence of interaction with a protease inhibitor or collagen/matrix substrate, MT1-MMP oligomerization facilitates MT1-MMP turnover via autocatalytic inactivating cleavage (Itoh et al., 2001; Lehti et al., 2002; Osenkowski et al., 2004). In the current study, El Azzouzi et al. (2016) used MT1-MMP proteins with a pH sensor inserted N-terminally to the transmembrane domain, so that the probe is located extracellularly on the surface-exposed protease. The fluorescence signal from these constructs is not expected to be affected by proteolytic processing or shedding of the catalytic domain, so it is unclear whether the MT1-MMP proteins clustered in islets are cleaved or not. However, FRAP results showed that the turnover of MT1-MMP molecules within the islets is relatively slow. It thus remains to be clarified if and how the proteolytically active or possibly processed or protease inhibitor–bound inactive forms of MT1-MMP are stabilized in these MT1-MMP islets.As posodomes are highly dynamic protrusions, their rapid turnover implicates a constant disassembly at the rear and formation at the front of migrating macrophages. Assembly and dissassembly are known to depend on Arp2/3-mediated actin nucleation and fission of preexisting podosomes, respectively (Linder et al., 2000). Both of these mechanisms may contribute to podosome reassembly at MT1-MMP memory sites. Considering that these islets are laterally immobile and overall stable in at least unpolarized cells, it is unclear how migrating cells coordinate their actin and microtubule cytoskeletons for podosome reassembly at the front using islets formed upon podosome dissolution at the rear of the cell (Fig. 1). Moreover, the structural and functional features of MT1-MMP islets in the scenario of 3D cell–ECM microenvironments is intriguing and will need to be investigated at high resolution, as cytoskeletal dynamics, cell polarity, and matrix stiffness greatly differ in 3D tissues and matrices from the simple 2D setting of cultured cells, and all are known to influence cell behavior. Although the transient nature of these MT1-MMP islets in bridging podosome disassembly and reassembly exemplifies and reflects the efficiency of podosome reusage, probing the protein composition of these islets as well as the dynamics of podosome reassembly will likely be challenging. Future studies comparing MT1-MMP state, dynamics, reuse, and turnover in different types of invadosomes, islets, and other subcellular compartments will be instrumental to better understand how cells integrate the different types of MT1-MMP membrane structures and cell–ECM communication with other cellular signals and with drivers of cytoskeletal dynamics.The identification of the molecular mechanisms of structural and functional podosome memory are not only relevant to the fields of macrophage biology and inflammation but also more broadly to those of tissue invasion and matrix remodeling. For instance, endothelial cells, smooth muscle cells, and cancer cells are also known to target MT1-MMP to podosomes or related invadosomes. Examining MT1-MMP memory in such specialized subcellular compartments will be interesting beyond the podosome field, as the podosome counterparts in cancer cells may display and use MT1-MMP or other metalloproteinases in a similar manner. By shedding light on the mechanisms of dynamic protrusion formation and function, this paper not only opens new avenues of investigation into the cellular structures marking protrusion sites as “memory devices” but also brings about a new concept to the fields of cell invasion, angiogenesis, and cancer.     

ALK5 and ALK1 Play Antagonistic Roles in Transforming Growth Factor β-Induced Podosome Formation in Aortic Endothelial Cells

Transforming growth factor β (TGF-β) and related cytokines play a central role in the vascular system. In vitro, TGF-β induces aortic endothelial cells to assemble subcellular actin-rich structures specialized for matrix degradation called podosomes. To explore further this TGF-β-specific response and determine in which context podosomes form, ALK5 and ALK1 TGF-β receptor signaling pathways were investigated in bovine aortic endothelial cells. We report that TGF-β drives podosome formation through ALK5 and the downstream effectors Smad2 and Smad3. Concurrent TGF-β-induced ALK1 signaling mitigates ALK5 responses through Smad1. ALK1 signaling induced by BMP9 also antagonizes TGF-β-induced podosome formation, but this occurs through both Smad1 and Smad5. Whereas ALK1 neutralization brings ALK5 signals to full potency for TGF-β-induced podosome formation, ALK1 depletion leads to cell disturbances not compatible with podosome assembly. Thus, ALK1 possesses passive and active modalities. Altogether, our results reveal specific features of ALK1 and ALK5 signaling with potential clinical implications.     

SSeCKS/Gravin/AKAP12 metastasis suppressor inhibits podosome formation via RhoA- and Cdc42-dependent pathways

Podosomes are poorly understood actin-rich structures notably found in cancer cell lines or in v-Src-transformed cells that are thought to facilitate some of the invasive properties involved in tumor metastasis. The enrichment of the Tks5/Fish protein, a v-Src substrate, is required for formation of podosomes. We showed previously that the tetracycline-regulated reexpression of the Src-suppressed C kinase substrate (SSeCKS, also known as Gravin/AKAP12) inhibited variables of v-Src-induced oncogenic growth in NIH3T3, correlating with the induction of normal actin cytoskeletal structures and cell morphology but not with gross inhibition of Src phosphorylation activity in the cell. Here, we show that SSeCKS reexpression at physiologic levels suppresses podosome formation, correlating with decreases in Matrigel invasiveness, whereas there is no effect on total cellular tyrosine phosphorylation or on the phosphorylation of Tks5/Fish. Activated forms of RhoA and Cdc42 were capable of rescuing podosome formation in v-Src cells reexpressing SSeCKS, and this correlated with the ability of SSeCKS to inhibit RhoA and Cdc42 activity levels by >5-fold. Interestingly, although activated Rac I had little effect on podosome formation, it could partner with activated RhoA to reverse the cell flattening induced by SSeCKS. These data suggest that v-Src-induced Tks5 tyrosine phosphorylation is insufficient for podosome formation in the absence of RhoA- and/or Cdc42-mediated cytoskeletal remodeling. Additionally, they strengthen the notion that SSeCKS suppresses Src-induced oncogenesis by reestablishing actin-based cytoskeletal architecture.     

Gelsolin-independent podosome formation in dendritic cells

Podosomes, important structures for adhesion and extracellular matrix degradation, are claimed to be involved in cell migration. In addition, podosomes are also reported to be of importance in tissue remodelling, e.g., in osteoclast-mediated bone resorption. Podosomes are highly dynamic actin-filament scaffolds onto which proteins important for their function, such as matrix metallo-proteases and integrins, attach. The dynamics of the podosomes require the action of many proteins regulating actin assembly and disassembly. One such protein, gelsolin, which associates to podosomes, has been reported to be important for podosome formation and function in osteoclasts. However, podosome-like structures have been reported in gelsolin-deficient dendritic cells, but the identity of these structures was not confirmed, and their dynamics and function was not investigated. Like many other cells, dendritic cells of the immune system also form matrix degrading podosomes. In the present study, we show that dendritic cells form podosomes independently of gelsolin, that there are no major alterations in their dynamics of formation and disassembly, and that they exhibit matrix-degrading function. Furthermore, we found that gelsolin is not required for TLR4-induced podosome disassembly. Thus, the actin cytoskeleton of podosomes involved in dendritic cell extracellular matrix degradation appears to be regulated differently than the cytoskeleton in podosomes of osteoclasts mediating bone resorption.     

Biophysical Induction of Vascular Smooth Muscle Cell Podosomes

Vascular smooth muscle cell (VSMC) migration and matrix degradation occurs with intimal hyperplasia associated with atherosclerosis, vascular injury, and restenosis. One proposed mechanism by which VSMCs degrade matrix is through the use of podosomes, transient actin-based structures that are thought to play a role in extracellular matrix degradation by creating localized sites of matrix metalloproteinase (MMP) secretion. To date, podosomes in VSMCs have largely been studied by stimulating cells with phorbol esters, such as phorbol 12,13-dibutyrate (PDBu), however little is known about the physiological cues that drive podosome formation. We present the first evidence that physiological, physical stimuli mimicking cues present within the microenvironment of diseased arteries can induce podosome formation in VSMCs. Both microtopographical cues and imposed pressure mimicking stage II hypertension induce podosome formation in A7R5 rat aortic smooth muscle cells. Moreover, wounding using a scratch assay induces podosomes at the leading edge of VSMCs. Notably the effect of each of these biophysical stimuli on podosome stimulation can be inhibited using a Src inhibitor. Together, these data indicate that physical cues can induce podosome formation in VSMCs.     

Matrix metalloproteinases (MMPs) safeguard osteoblasts from apoptosis during transdifferentiation into osteocytes: MT1-MMP maintains osteocyte viability

Osteoblasts undergo apoptosis or differentiate into either osteocytes or bone-lining cells after termination of bone matrix synthesis. In this study, we investigated the role of matrix metalloproteinases (MMPs) in differentiation of osteoblasts, bone formation, transdifferentiation into osteocytes, and osteocyte apoptosis. This was accomplished by using calvarial sections from the MT1-MMP-deficient mouse and by culture of the mouse osteoblast cell line MC3T3-E1 and primary mouse calvarial osteoblasts. We found that a synthetic matrix metalloprotease inhibitor, GM6001, strongly inhibited bone formation in vitro of both primary osteoblasts and MC3T3 cells by approximately 75%. To further investigate at which level of osteoblast differentiation MMP inhibition was attenuating osteoblast function, we found that neither preosteoblast nor mature osteoblast activity was affected. In contrast, cell survival of osteoblasts forced to transdifferentiate into osteocytes in 3D type I collagen gels were inhibited by more than 50% when exposed to 10 microM GM6001 and to Tissue Inhibitor of Metalloproteinase-2 (TIMP-2), a natural MT1-MMP inhibitor. This shows the importance of MMPs in safeguarding osteoblasts from apoptosis when transdifferentiating into osteocytes. By examination of osteoblasts and osteocytes embedded in calvarial bone in the MT1-MMP deficient mice, we found that MT1-MMP deficient mice had 10-fold higher levels of apoptotic osteocytes than wild-type controls. We have previously shown that MT1-MMP activates latent Transforming Growth Factorbeta (TGF-beta). These findings strongly suggest that MT1-MMP-activated TGF-beta maintains osteoblast survival during transdifferentiation into osteocytes, and maintains mature osteocyte viability. Thus, the interrelationship of MMPs and TGF-beta may play an important role in bone formation and maintenance.     

Dendritic Cell Podosome Dynamics Does Not Depend on the F-actin Regulator SWAP-70

In addition to classical adhesion structures like filopodia or focal adhesions, dendritic cells similar to macrophages and osteoclasts assemble highly dynamic F-actin structures called podosomes. They are involved in cellular processes such as extracellular matrix degradation, bone resorption by osteoclasts, and trans-cellular diapedesis of lymphocytes. Besides adhesion and migration, podosomes enable dendritic cells to degrade connective tissue by matrix metalloproteinases. SWAP-70 interacts with RhoGTPases and F-actin and regulates migration of dendritic cells. SWAP-70 deficient osteoclasts are impaired in F-actin-ring formation and bone resorption. In the present study, we demonstrate that SWAP-70 is not required for podosome formation and F-actin turnover in dendritic cells. Furthermore, we found that toll-like receptor 4 ligand induced podosome disassembly and podosome-mediated matrix degradation is not affected by SWAP-70 in dendritic cells. Thus, podosome formation and function in dendritic cells is independent of SWAP-70.     

Self-organized podosomes are dynamic mechanosensors

Podosomes are self-organized, dynamic, actin-containing structures that adhere to the extracellular matrix via integrins [1-5]. Yet, it is not clear what regulates podosome dynamics and whether podosomes can function as direct mechanosensors, like focal adhesions [6-9]. We show here that myosin-II proteins form circular structures outside and at the podosome actin ring to regulate podosome dynamics. Inhibiting myosin-II-dependent tension dissipated podosome actin rings before dissipating the myosin-ring structure. As podosome rings changed size or shape, tractions underneath the podosomes were exerted onto the substrate and were abolished when myosin-light-chain activity was inhibited. The magnitudes of tractions were comparable to those generated underneath focal adhesions, and they increased with substrate stiffness. The dynamics of podosomes and of focal adhesions were different. Torsional tractions underneath the podosome rings were generated with rotations of podosome rings in a nonmotile, nonrotating cell, suggesting a unique feature of these circular structures. Stresses applied via integrins at the apical surface directly displaced podosomes near the basal surface. Stress-induced podosome displacements increased nonlinearly with applied stresses. Our results suggest that podosomes are dynamic mechanosensors in which interactions of myosin tension and actin dynamics are crucial for regulating these self-organized structures in living cells.     

Changes in the balance between caldesmon regulated by p21-activated kinases and the Arp2/3 complex govern podosome formation

Podosomes are dynamic cell adhesion structures that degrade the extracellular matrix, permitting extracellular matrix remodeling. Accumulating evidence suggests that actin and its associated proteins play a crucial role in podosome dynamics. Caldesmon is localized to the podosomes, and its expression is down-regulated in transformed and cancer cells. Here we studied the regulatory mode of caldesmon in podosome formation in Rous sarcoma virus-transformed fibroblasts. Exogenous expression analyses revealed that caldesmon represses podosome formation triggered by the N-WASP-Arp2/3 pathway. Conversely, depletion of caldesmon by RNA interference induces numerous small-sized podosomes with high dynamics. Caldesmon competes with the Arp2/3 complex for actin binding and thereby inhibits podosome formation. p21-activated kinases (PAK)1 and 2 are also repressors of podosome formation via phosphorylation of caldesmon. Consequently, phosphorylation of caldesmon by PAK1/2 enhances this regulatory mode of caldesmon. Taken together, we conclude that in Rous sarcoma virus-transformed cells, changes in the balance between PAK1/2-regulated caldesmon and the Arp2/3 complex govern the formation of podosomes.