Integrin-based Adhesions Research Articles

MiR‐625# and miR‐206 participate to the cellular response to matrix rigidity

The extracellular matrix (ECM) affects many aspects of cell growth and behavior. Not only do cells respond to the composition of the ECM, but they also respond to its physical properties. In a seminal paper, Pelham and Wang observed that cells develop large integrin‐based adhesions on rigid surface, whereas on soft substrate adhesions remain immature and small. Since this cellular response to ECM stiffness is central in various aspects of biology, from physiology to disease, many efforts have been directed recently to understand how cells “sense” and respond to the stiffness of their environment. However this remains, so far, an open question. In this study, we investigated the role of micro RNAs (miRNAs) in the cellular response to matrix rigidity. Comparing miRNAs expression in fibroblast cultured on soft (1kPa) and stiff substrates (25kPa), we observed that ECM rigidity induced a decrease in miR‐625# and miR‐206 expression. Interestingly, inhibition of myosin II increased miR‐625# and miR‐206 expression, indicating that cell‐generated tension regulates miR‐206 and miR‐625# expression. Previous work have shown that fibronectin is a direct target of miR‐206, consistent with this we found that miR‐206 expression in cells cultured on stiff substrates decreased fibronectin expression. Additionally, we found that miR‐625# expression decreased cell spreading and survival on rigid ECM. These data indicate that miR‐206 and miR‐625# regulate the cellular response to ECM rigidity. We are currently pursuing this work to identify miR‐625# targets which impact cell adhesion and survival.

Force transmission during adhesion-independent migration.

When cells move using integrin-based focal adhesions, they pull in the direction of motion with large, ~100 Pa, stresses that contract the substrate1. Integrin-mediated adhesions, however, are not required for in vivo confined migration2. During focal adhesion-free migration, the transmission of propelling forces, and their magnitude and orientation, are not understood. Here, we combine theory and experiments to investigate the forces involved in adhesion-free migration. Using a non-adherent blebbing cell line as a model, we show that actin cortex flows drive cell movement via non-specific substrate friction. Strikingly, the forces propelling the cell forward are several orders of magnitude lower than during focal adhesion-based motility. Moreover, the force distribution in adhesion-free migration is inverted: it acts to expand, rather than contract, the substrate in the direction of motion. This fundamentally different mode of force transmission may have implications for cell-cell and cell-substrate interactions during migration in vivo.

Stiffness Sensing through Myosin II Minifilaments

Tissue cells react sensitively to the stiffness of their environment, which they sense by applying actomyosin-generated forces through integrin-based adhesion contacts. One important aspect of this essential aspect of the life of a tissue cell is the mechanosensitive nature of the adhesion contacts, which harbor a network of molecular force sensors. However, increasing evidence suggests that actomyosin contractility might play a similarly important role in stiffness sensing. Using a stochastic crossbridge model for force generation through a cytoskeletal myosin II minifilament, we show that this contractile unit already shows many aspects that are commonly attributed to cellular rigidity sensing. For small substrate stiffness, minifilaments generate only transient and small forces. Above a threshold in stiffness, they switch into a state of strong contraction. In the cellular context, this functional switch is further modulated by ATP-concentration, myosin II phosphorylation, different myosin II isoforms, the assembly kinetics of the minifilaments and of the actin cytoskeleton, and actin binding proteins like tropomyosin. We will also discuss how our model approach can be extended to include these additional aspects.

Regulation of Stimulated and Basal Release of Weibel-Palade Bodies By Syntaxin-3 Containing SNARE-Complexes

Vascular endothelial cells contain unique rod-shaped secretory granules, called Weibel-Palade bodies (WPBs), which contain a number of haemostatic, angiogenic and inflammatory mediators. Several components that are critical for regulated WPB exocytosis have been identified, including the small GTPase Rab27A and its effector synaptotagmin-like protein 4-a (Slp4-a), but the mechanism remains unclear. We have previously identified syntaxin binding protein 1 (STXBP1) as an endogenous Slp4-a binding partner involved in WPB release, along with the SNARE proteins syntaxin-2 and -3. In this study we investigated the possible role of syntaxin-2 and -3 in WPB exocytosis.We characterized the subcellular location of these syntaxins in endothelial cells using immunocytochemistry. Syntaxin-2 was primarily associated with the plasma membrane where it localized at VE-caderin-based adherens junctions and at integrin-based adhesions to the extracellular matrix. Interestingly, the t-SNARE syntaxin-3 was primarily associated with WPBs. To further explore its role in WPB biology we mapped the endothelial interaction partners of syntaxin-3 through an unbiased mass spectrometry approach using pull downs of lentivirally-expressed mEGFP-syntaxin-3 with anti-GFP nanobeads. Among its interaction partners are various SNAREs and associated proteins such as syntaxin binding proteins 2 and 5 (STXBP2/5), N-ethylmaleimide-sensitive factor (NSF), SNAP23 and α-SNAP, suggesting we successfully pulled down a SNARE complex and its regulatory machinery that are involved in exocytosis. We further addressed the role of syntaxin-3 in stimulated WPB exocytosis using siRNA-mediated knockdowns and found that depletion of syntaxin-3 led to a significant potentiation of Ca2+- as well as cAMP-mediated VWF secretion. In contrast, we observed a decrease in basal (unstimulated) VWF secretion after silencing of syntaxin-3, which amounts to a significantly increased intracellular VWF content. The potentiation of VWF secretion after depletion of syntaxin-3 was almost completely attributable to an increased WPB pool size; when corrected for increased WPB content the probability of stimulated release of a WPB was unaltered in the absence of syntaxin-3.Our data position syntaxin-3 as a WPB-linked SNARE-protein that regulates basal secretion of VWF. DisclosuresNo relevant conflicts of interest to declare.

Systems Perspective on Mechanobiology: Producing the Right Proteins in the Right Place at the Right Time

Systems Perspective on Mechanobiology: Producing the Right Proteins in the Right Place at the Right Time

Quantitative imaging of focal adhesion dynamics and their regulation by HGF and Rap1 signaling

Cell migration is crucial in development, tissue repair and immunity and frequently aberrant in pathological processes including tumor metastasis. Focal adhesions (FAs) are integrin-based adhesion complexes that form the link between the cytoskeleton and the extracellular matrix and are thought to orchestrate cell migration. Understanding the regulation of FAs by (oncogenic) signaling pathways may identify strategies to target pathological cell migration. Here we describe the development of a robust FA tracker that enables the automatic, multi-parametric analysis of FA dynamics, morphology and composition from time-lapse image series generated by total internal reflection fluorescence (TIRF) microscopy. In control prostate carcinoma cells, this software recapitulates previous findings that relate morphological characteristics of FAs to their lifetime and their cellular location. We then investigated how FAs are altered when cell migration is induced by the metastasis-promoting hormone HGF and subsequently inhibited by activation of the small GTPase Rap1. We performed a detailed analysis of individual FA parameters, which identified FA size, sliding and intensity as primary targets of Rap1. HGF did not have strong effects on any of the FA parameters within the first hours of its addition. Subsequent Bayesian network inference (BNI), using all measured parameters as input, revealed little correlation between changes in cell migration and FA characteristics in this prostate carcinoma cell line. Instead BNI indicated a concerted coordination of cell size and FA parameters. Thus our results did not reveal a direct relation between the regulation of cell migration and the regulation of FA dynamics.

CD44-mediated adhesion to hyaluronic acid contributes to mechanosensing and invasive motility.

The high-molecular-weight glycosaminoglycan, hyaluronic acid (HA), makes up a significant portion of the brain extracellular matrix. Glioblastoma multiforme (GBM), a highly invasive brain tumor, is associated with aberrant HA secretion, tissue stiffening, and overexpression of the HA receptor CD44. Here, transcriptomic analysis, engineered materials, and measurements of adhesion, migration, and invasion were used to investigate how HA/CD44 ligation contributes to the mechanosensing and invasive motility of GBM tumor cells, both intrinsically and in the context of Arg-Gly-Asp (RGD) peptide/integrin adhesion. Analysis of transcriptomic data from The Cancer Genome Atlas reveals upregulation of transcripts associated with HA/CD44 adhesion. CD44 suppression in culture reduces cell adhesion to HA on short time scales (0.5-hour postincubation) even if RGD is present, whereas maximal adhesion on longer time scales (3 hours) requires both CD44 and integrins. Moreover, time-lapse imaging demonstrates that cell adhesive structures formed during migration on bare HA matrices are more short lived than cellular protrusions formed on surfaces containing RGD. Interestingly, adhesion and migration speed were dependent on HA hydrogel stiffness, implying that CD44-based signaling is intrinsically mechanosensitive. Finally, CD44 expression paired with an HA-rich microenvironment maximized three-dimensional invasion, whereas CD44 suppression or abundant integrin-based adhesion limited it. These findings demonstrate that CD44 transduces HA-based stiffness cues, temporally precedes integrin-based adhesion maturation, and facilitates invasion. This study reveals that the CD44 receptor, which is commonly overexpressed in GBM tumors, is critical for cell adhesion, invasion, and mechanosensing of an HA-based matrix.

Highlights of This Issue

Little is known about the biophysical contributions provided by the hyaluronic acid (HA) receptor CD44. In this study, Kim and colleagues combined HA-based engineered materials with genetic perturbation to demonstrate for the first time that CD44 directly participates in glioma cell mechanotransduction and invasive motility. Genomic and mechanistic evidence supports a new adhesion model in which CD44 provides early adhesive contacts that are later replaced by more robust integrin-based adhesions. Given the increasing use of HA as a materials scaffold, this work brings new molecular insight to the role of CD44 in cancer cell invasion and broadens the understanding of cell-material interactions.Polycomb-group (PcG) proteins are evolutionarily conserved and often associated with epigenetic patterns of heritable gene expression that affect development, cellular plasticity, and tumor progression. In particular, the histone methyltransferase EZH2 is an important PcG component of the mammalian Polycomb repressive complex 2 (PRC2), which promotes gene silencing. EZH2 is linked to aggressive hepatocellular carcinoma (HCC) and has biomarker potential; however, the molecular details downstream of EZH2 and other PcGs are poorly defined. Gao and colleagues used gene profiling and chromatin immunoprecipitation (ChIP) to reveal that PcGs control critical gene networks. Interestingly, some networks had repressive H3K27me3 marks, while others, such as p53, did not, suggesting H3K27me3-independent mechanisms in HCC.Targeted therapeutics have not yet shown a significant impact on malignant pleural mesothelioma (MPM). Using both pharmacologic and molecular approaches, Marek and colleagues identified the tyrosine kinase FGFR1 as a nonmutated growth driver in a subset of MPM cells. Notably, FGFR1 expression was not associated with increased gene copy number (GCN) in multiple cell lines or primary MPM. The results of this study support FGFR1 expression as a biomarker of MPM sensitivity to FGFR-specific tyrosine kinase inhibitors rather than increased GCN, often used in clinical trials for this class of drugs. The findings also indicate that additional oncogenic events in MPM remain to be defined.The signaling pathways operational in macrophages regulating hypoxia-induced HIFα stabilization are a subject of intense investigation. Joshi and colleagues discovered that the PTEN/PI3K/AKT axis controls the degradation of HIF1α and HIF2α in macrophages under hypoxic conditions. Blocking PI3K/AKT signaling genetically or by a pan-PI3K inhibitor (SF1126) promoted the hypoxic degradation of HIFα via a 26S proteasome mechanism. Specifically, a macrophage-dominant PI3K isoform (p110γ) was shown to control tumor growth, angiogenesis, metastasis, and the HIFα–VEGF axis. These findings indicate that PI3K inhibitors induce the hypoxic degradation of HIF and provide evidence that these inhibitors are excellent candidates for the treatment of cancers in which M2 macrophages promote tumor progression.

Heparan Sulfate Saccharides Modify Focal Adhesions: Implication in Mucopolysaccharidosis Neuropathophysiology

Mucopolysaccharidoses type III (MPSIII, Sanfilippo syndrome) are genetic diseases due to deficient heparan sulfate (HS) saccharide digestion by lysosomal exoglycanases. Progressive accumulation of undigested saccharides causes early-onset behavioural and cognitive symptoms. The precise role of these saccharides in the pathophysiological cascade is still unclear. We showed that exposure of wild-type neural cells to exogenous soluble HS fragments of at least eight saccharides activated integrin-based focal adhesions (FAs), which attach cells to the extracellular matrix. FAs were constitutively activated in MPSIII type B astrocytes or neural stem cells unless undigested saccharides were cleared by exogenous supply of the missing exoglycanase. Defective cell polarisation and oriented migration in response to focal extracellular stimuli in affected cells suggest improper sensing of the environment. We consistently observed abnormal organisation of the rostral migratory stream in the brain of adult mice with MPSIII type B. These results suggest that cell polarisation and oriented migration defects participate to the neurological disorders associated with Sanfilippo syndrome.

Three-dimensional cell body shape dictates the onset of traction force generation and growth of focal adhesions.

Cell shape affects proliferation and differentiation, which are processes known to depend on integrin-based focal adhesion (FA) signaling. Because shape results from force balance and FAs are mechanosensitive complexes transmitting tension from the cell structure to its mechanical environment, we investigated the interplay between 3D cell shape, traction forces generated through the cell body, and FA growth during early spreading. Combining measurements of cell-scale normal traction forces with FA monitoring, we show that the cell body contact angle controls the onset of force generation and, subsequently, the initiation of FA growth at the leading edge of the lamella. This suggests that, when the cell body switches from convex to concave, tension in the apical cortex is transmitted to the lamella where force-sensitive FAs start to grow. Along this line, increasing the stiffness resisting cell body contraction led to a decrease of the lag time between force generation and FA growth, indicating mechanical continuity of the cell structure and force transmission from the cell body to the leading edge. Remarkably, the overall normal force per unit area of FA increased with stiffness, and its values were similar to those reported for local tangential forces acting on individual FAs. These results reveal how the 3D cell shape feeds back on its internal organization and how it may control cell fate through FA-based signaling.

FAK is required for tension-dependent organization of collective cell movements in Xenopus mesendoderm

Collective cell movements are integral to biological processes such as embryonic development and wound healing and also have a prominent role in some metastatic cancers. In migrating Xenopus mesendoderm, traction forces are generated by cells through integrin-based adhesions and tension transmitted across cadherin adhesions. This is accompanied by assembly of a mechanoresponsive cadherin adhesion complex containing keratin intermediate filaments and the catenin-family member plakoglobin. We demonstrate that focal adhesion kinase (FAK), a major component of integrin adhesion complexes, is required for normal morphogenesis at gastrulation, closure of the anterior neural tube, axial elongation and somitogenesis. Depletion of zygotically expressed FAK results in disruption of mesendoderm tissue polarity similar to that observed when expression of keratin or plakoglobin is inhibited. Both individual and collective migrations of mesendoderm cells from FAK depleted embryos are slowed, cell protrusions are disordered, and cell spreading and traction forces are decreased. Additionally, keratin filaments fail to organize at the rear of cells in the tissue and association of plakoglobin with cadherin is diminished. These findings suggest that FAK is required for the tension-dependent assembly of the cadherin adhesion complex that guides collective mesendoderm migration, perhaps by modulating the dynamic balance of substrate traction forces and cell cohesion needed to establish cell polarity.

Src kinase determines the dynamic exchange of the docking protein NEDD9 (neural precursor cell expressed developmentally down-regulated gene 9) at focal adhesions.

Dynamic exchange of molecules between the cytoplasm and integrin-based focal adhesions provides a rapid response system for modulating cell adhesion. Increased residency time of molecules that regulate adhesion turnover contributes to adhesion stability, ultimately determining migration speed across two-dimensional surfaces. In the present study we test the role of Src kinase in regulating dynamic exchange of the focal adhesion protein NEDD9/HEF1/Cas-L. Using either chemical inhibition or fibroblasts genetically null for Src together with fluorescence recovery after photobleaching (FRAP), we find that Src significantly reduces NEDD9 exchange at focal adhesions. Analysis of NEDD9 mutant constructs with the two major Src-interacting domains disabled revealed the greatest effects were due to the NEDD9 SH2 binding domain. This correlated with a significant change in two-dimensional migratory speed. Given the emerging role of NEDD9 as a regulator of focal adhesion stability, the time of NEDD9 association at the focal adhesions is key in modulating rates of migration and invasion. Our study suggests that Src kinase activity determines NEDD9 exchange at focal adhesions and may similarly modulate other focal adhesion-targeted Src substrates to regulate cell migration.

A Critical Pull to Polarize the Cell

A Critical Pull to Polarize the Cell

Caveolins redistribute in uterine epithelial cells during early pregnancy in the rat: an epithelial polarisation strategy?

At the time of implantation, uterine luminal epithelial cells undergo a dramatic change in all plasma membrane domains. Changes in the basolateral plasma membrane at the time of implantation include progression from smooth to highly tortuous, as well as a loss of integrin-based focal adhesions. Another aspect of the basolateral plasma membrane that has not been studied in uterine epithelial cells are caveolae, which are omega-shaped invaginations of the plasma membrane known to be involved in endocytosis and contribute to membrane curvature. The current study investigated caveolin, a major protein of caveolae, to explore the possible roles that they play in the remodelling of the basolateral plasma membrane of uterine epithelial cells during early pregnancy in the rat. Morphological caveolae were found at the time of implantation and were significantly increased compared to day 1 of pregnancy. Caveolins 1 and 2 were found to shift to the basolateral plasma membrane of uterine epithelial cells at the time of implantation as well as when treated with progesterone alone, and in combination with oestrogen. A statistically significant increase in the amount of caveolin-1 and a decrease in caveolin-2 protein in uterine epithelial cells was observed at the time of implantation. Caveolin-1 also co-immunoprecipitated with integrin β1 on day 1 of pregnancy, which is a protein that has been reported to be found in integrin-based focal adhesions at the basolateral membrane on day 1 of pregnancy. The localisation and expression of caveolin-1 at the time of implantation is consistent with the presence and increase of morphological caveolae seen at this time. The localisation and expression of caveolins 1 and 2 in luminal uterine epithelium at the time of implantation suggest a role in trafficking proteins and the maintenance of a polarised epithelium.

LIM proteins in actin cytoskeleton mechanoresponse.

The actin cytoskeleton assembles into branched networks or bundles to generate mechanical force for critical cellular processes such as establishment of polarity, adhesion, and migration. Stress fibers (SFs) are contractile actomyosin structures that physically couple to the extracellular matrix through integrin-based focal adhesions (FAs), thereby transmitting force into and across the cell. Recently, LIN-11, Isl1, and MEC-3 (LIM) domain proteins have been implicated in mediating this cytoskeletal mechanotransduction. Among the more well-studied LIM domain adapter proteins is zyxin, a dynamic component of both FAs and SFs. Here we discuss recent research detailing the mechanisms by which SFs adjust their structure and composition to balance mechanical forces and suggest ways that zyxin and other LIM domain proteins mediate mechanoresponse.

CLASPs link focal-adhesion-associated microtubule capture to localized exocytosis and adhesion site turnover.

Turnover of integrin-based focal adhesions (FAs) with the extracellular matrix (ECM) is essential for coordinated cell movement. In collectively migrating human keratinocytes, FAs assemble near the leading edge, grow and mature as a result of contractile forces, and disassemble underneath the advancing cell body. We report that clustering of microtubule-associated CLASP1 and CLASP2 proteins around FAs temporally correlates with FA turnover. CLASPs and LL5β, which recruits CLASPs to FAs, facilitate FA disassembly. CLASPs are further required for FA-associated ECM degradation, and matrix metalloprotease inhibition slows FA disassembly similar to CLASP or LL5β depletion. Finally, CLASP-mediated microtubuletethering at FAs establishes a FA-directed transport pathway for delivery, docking and localized fusion of exocytic vesicles near FAs. We propose that CLASPs couple microtubule organization, vesicle transport and cell interactions with the ECM, establishing a local secretion pathway that facilitates FA turnover by severing cell-matrix connections.

RhoA activation by CNFy restores cell–cell adhesion in kindlin‐2‐deficient keratinocytes

Kindlins are a family of integrin adapter and cell-matrix adhesion proteins causally linked to human genetic disorders. Kindlin-2 is a ubiquitously expressed protein with manifold functions and interactions. The contribution of kindlin-2 to integrin-based cell-matrix adhesions has been extensively explored, while other integrin-independent roles emerge. Because of the early involvement of kindlin-2 in development, no viable animal models with its constitutional knockout are available to study its physiological functions in adult skin. Here, we uncovered a critical physiological role of kindlin-2 in the epidermis by using a skin-equivalent model with shRNA-mediated knock-down of kindlin-2 in keratinocytes. Kindlin-2-deficient keratinocytes built stratified epidermal layers, but displayed impaired dermal-epidermal and intra-epidermal adhesion and barrier function. Co-immunoprecipitation studies demonstrated that kindlin-2 interacts with both integrin- and cadherin-based adhesions. In kindlin-2-deficient keratinocytes, reduced cell-cell adhesion was associated with abnormal cytoplasmic distribution of adherens junctions and desmosomal proteins, which was dependent on RhoA activation. Direct activation of RhoA with recombinant bacterial cytotoxic necrotizing factor y (CNFy) reverted the abnormal phenotype and barrier function of kindlin-2-deficient keratinocytes and skin equivalents. These findings have physiological and pathological significance, since kindlin-2 expression modulates the phenotype in Kindler syndrome, a skin fragility disorder caused by kindlin-1 deficiency. Our results suggest that pharmacological regulation of RhoGTPase activity may represent a therapeutic option for skin fragility.

Cellular Contact Guidance through Dynamic Sensing of Nanotopography

We investigate the effects of surface nanotopography on the migration and cell shape dynamics of the amoeba Dictyostelium discoideum. Multiple prior studies have implicated the patterning of focal adhesions in contact guidance. However, we observe significant contact guidance of Dictyostelium along surfaces with nanoscale ridges or grooves, even though this organism lacks integrin-based adhesions. Cells that move parallel to nanoridges are faster, more protrusive at their fronts, and more elongated than are cells that move perpendicular to nanoridges. Quantitative studies show that nanoridges spaced 1.5 μm apart exhibit the greatest contact guidance efficiency. Because Dictyostelium cells exhibit oscillatory shape dynamics, we model contact guidance as a process in which stochastic cellular harmonic oscillators couple to the periodicity of the nanoridges. In support of this connection, we find that nanoridges nucleate actin polymerization waves of nanoscale width that propagate parallel to the nanoridges.

Bio-chemo-mechanical models for nuclear deformation in adherent eukaryotic cells

Adherent eukaryotic cells are subjected to a broad variety of extracellular and intracellular stimuli regulating their behaviour. These stimuli can be either purely chemical, for example soluble factors binding to the cell membrane, or mechano-chemical, for example integrin-based adhesion complexes stretching the cell cytoskeleton. Here, we focus on mechano-chemical stimuli such as extracellular forces (interstitial flow, pressurization) and intracellular forces (due to cell adhesion), which may combine generating stress-strain states in the cytoskeleton. These states are transferred to the nucleus to influence the transcription of specific genes, likely by changing the chromatin organization and by altering the permeability of the nuclear membrane. While there exists increasing experimental evidence of the mechanosensing role of the cell nucleus, both the underlying molecular mechanisms involved, and the nuclear structural behaviour in response to forces, are still poorly understood. Here, we review the existing literature on computational models developed to investigate the chemo-mechanical behaviour of adherent eukaryotic cells. We analyse two main classes of models of single-cell mechanics, based either on the discrete or on the continuum approaches. We focus on the bio-chemo-mechanical model and modelling techniques accounting for the nuclear body. The modelling techniques are discussed highlighting their ability in predicting cytoskeletal contractility states and nuclear stress-strain states.

Integrin linked kinase (ILK) regulates podosome maturation and stability in dendritic cells

Podosomes are integrin-based adhesions fundamental for stabilisation of the leading lamellae in migrating dendritic cells (DCs) and for extracellular matrix (ECM) degradation. We have previously shown that soluble factors and chemokines such as SDF 1-a trigger podosome initiation whereas integrin ligands promote podosome maturation and stability in DCs. The exact intracellular signalling pathways that regulate the sequential organisation of podosomal components in response to extracellular cues remain largely undetermined. The Wiskott Aldrich Syndrome Protein (WASP) mediates actin polymerisation and the initial recruitment of integrins and associated proteins in a circular configuration surrounding the core of filamentous actin (F-actin) during podosome initiation. We have now identified integrin linked kinase (ILK) surrounding the podosomal actin core. We report that DC polarisation in response to chemokines and the assembly of actin cores during podosome initiation require PI3K-dependent clustering of the Wiskott Aldrich Syndrome Protein (WASP) in puncta independently of ILK. ILK is essential for the clustering of integrins and associated proteins leading to podosome maturation and stability that are required for degradation of the subjacent extracellular matrix and the invasive motility of DCs across connective tissue barriers.We conclude that WASP regulates DCs polarisation for migration and initiation of actin polymerisation downstream of PI3K in nascent podosomes. Subsequently, ILK mediates the accumulation of integrin-associated proteins during podosome maturation and stability for efficient degradation of the subjacent ECM during the invasive migration of DCs.