STIM1- and Orai1-mediated Ca2+ oscillation orchestrates invadopodium formation and melanoma invasion

Ca²⁺ signaling has been increasingly implicated in cancer invasion and metastasis, and yet, the underlying mechanisms remained largely unknown. In this paper, we report that STIM1- and Orai1-mediated Ca²⁺ oscillations promote melanoma invasion by orchestrating invadopodium assembly and extracellular matrix (ECM) degradation. Ca²⁺ oscillation signals facilitate invadopodial precursor assembly by activating Src. Disruption of Ca²⁺ oscillations inhibited invadopodium assembly. Furthermore, STIM1 and Orai1 regulate the proteolysis activity of individual invadopodia. Mechanistically, Orai1 blockade inhibited the recycling of MT1–matrix metalloproteinase (MMP) to the plasma membrane and entrapped MT1-MMP in the endocytic compartment to inhibit ECM degradation. STIM1 knockdown significantly inhibited melanoma lung metastasis in a xenograft mouse model, implicating the importance of this pathway in metastatic dissemination. Our findings provide a novel mechanism for Ca²⁺-mediated cancer cell invasion and shed new light on the spatiotemporal organization of store-operated Ca²⁺ signals during melanoma invasion and metastasis.     

Modulation of the Membrane Type 1 Matrix Metalloproteinase Cytoplasmic Tail Enhances Tumor Cell Invasion and Proliferation in Three-dimensional Collagen Matrices

Increasing evidence suggests that the cytoplasmic tail of membrane type 1 matrix metalloproteinase (MT1-MMP) is subject to phos pho ryl a tion and that this modification may influence its enzymatic activity at the cell surface. In this study, phos pho ryl a ted MT1-MMP is detected using a phospho-specific antibody recognizing a protein kinase C consensus sequence (phospho-TXR), and a MT1-MMP tail peptide is phos pho ryl a ted by exogenous protein kinase C. To characterize the potential role of cytoplasmic residue Thr⁵⁶⁷ in these processes, mutants that mimic a state of either constitutive (T567E) or defective phos pho ryl a tion (T567A) were expressed and analyzed for their functional effects on MT1-MMP activity and cellular behavior. Phospho-mimetic mutants of Thr⁵⁶⁷ exhibit enhanced matrix invasion as well as more extensive growth within a three-dimensional type I collagen matrix. Together, these findings suggest that MT1-MMP surface action is regulated by phos pho ryl a tion at cytoplasmic tail residue Thr⁵⁶⁷ and that this modification plays a critical role in processes that are linked to tumor progression.Largely composed of a mixture of collagens, laminins, and vitronectin, the extracellular matrix (ECM)² serves as both a physical scaffold and a barrier against cell invasion. It has become increasingly evident that the structural condition of the ECM plays a unique role in regulating cell behavior. Proteolysis of integral components of the basement membrane disturbs the barrier provided by the ECM. Without physical restriction, cells invade the surrounding environment in an unregulated manner. The ability of matrix metalloproteinases (MMPs) to collectively degrade nearly all ECM constituents allows this class of enzymes to function in a diverse range of physiological processes (1, 2). Of the anchored MMPs, membrane type 1 matrix metalloproteinase (MT1-MMP) was the first to be discovered and has been most thoroughly characterized. Unlike soluble MMPs, MT1-MMP has a stretch of hydrophobic amino acids that traverse the cell membrane, followed by a short cytoplasmic tail composed of 20 amino acids (3). The advantage of cell surface localization is 2-fold. Surface restriction allows MT1-MMP to modify the immediate pericellular environment, overcoming physical constraints imposed by the ECM (2). Localization at the cell surface also places tethered MMPs in an optimal position to function at invadapodia, highly specialized areas of the cell membrane that form during focalized cell invasion (4). Although information regarding the role of the cytoplasmic tail is relatively limited (5, 6), this domain may function as a bridge to the intracellular machinery.MT1-MMP has an essential role in matrix remodeling during physiological processes (7, 8). Conversely, its enzymatic activity is key to acquiring a metastatic phenotype in a variety of tumor cells, including lung, colon, breast, and cervical carcinomas (2, 9–11). The ability to alter the physical structure of the pericellular environment, while triggering the activation and modification of several cell surface proteins, identifies a central role for MT1-MMP in influencing cellular behavior (12). In return, stringent cellular regulation of MT1-MMP enzymatic activity is necessary to prevent aberrant proteolysis.Increasing evidence suggests that the cytoplasmic tail of MT1-MMP may regulate its activity at the cell surface. It has been demonstrated that MT1-MMP is internalized from the cell surface and that this process requires the presence of the cytoplasmic domain (5, 6). Tail truncation restricts MT1-MMP to the cell surface, suggesting that this domain contains sequence(s) that either mediate internalization or are required for physical interaction with another protein that facilitates its internalization (5, 6). The mechanism regulating this process has yet to be determined. Interestingly, both invasion and migration are down-regulated in cells where MT1-MMP is restricted to the cell surface (5, 6). These data suggest a correlation between internalization and matrix turnover, where MT1-MMP activity is either abrogated or enhanced under appropriate stimuli.Reversible phosphorylation is widely recognized as a key post-translational modification that regulates protein function. The cytoplasmic domain of MT1-MMP has three potential phosphorylation sites: Thr⁵⁶⁷, Tyr⁵⁷³, and Ser⁵⁷⁷. Recent work by Nyalendo et al. (13) indicates that MT1-MMP is phosphorylated at tyrosine residue Tyr⁵⁷³, and that this modification influences cell migration. Several surface proteins are regulated by phosphorylation at multiple residues. In the MT1-MMP cytoplasmic tail, Thr⁵⁶⁷ has homology with the consensus sequence for both protein kinase C (TXR) and ERK1/2 (XTP) (14), suggesting the possibility that active MT1-MMP might also be regulated through phosphorylation of this cytoplasmic tail residue. In the present study, we report that MT1-MMP bears a threonine phosphorylation site in its cytoplasmic tail and that this modification plays an important role in regulating several aspects of carcinoma cell behavior, including invasion and three-dimensional growth.     

Control of microtubule assembly by extracellular matrix and externally applied strain

A number of studies have suggested that externally applied mechanical forces and alterations in the intrinsic cell-extracellular matrix (ECM) force balance equivalently induce changes in cell phenotype. However, this possibility has never been directly tested. To test this hypothesis, we directly investigated the response of the microtubule (MT) cytoskeleton in smooth muscle cells to both mechanical signals and alterations in the ECM. A tensile force that resulted in a positive 10% step change in substrate strain increased MT mass by 34 +/- 10% over static controls, independent of the cell adhesion ligand and tyrosine phosphorylation. Conversely, a compressive force that resulted in a negative 10% step change in substrate strain decreased MT mass by 40 +/- 6% over static controls. In parallel, increasing the density of the ECM ligand fibronectin from 50 to 1,000 ng/cm(2) in the absence of any applied force increased the amount of polymeric tubulin in the cell from 59 +/- 11% to 81 +/- 13% of the total cellular tubulin. These data are consistent with a model in which MT assembly is, in part, controlled by forces imposed on these structures, and they suggest a novel control point for MT assembly by altering the intrinsic cell-ECM force balance and applying external mechanical forces.     

Membrane type I matrix metalloproteinase usurps tumor growth control imposed by the three-dimensional extracellular matrix

Cancer cells are able to proliferate at accelerated rates within the confines of a three-dimensional (3D) extracellular matrix (ECM) that is rich in type I collagen. The mechanisms used by tumor cells to circumvent endogenous antigrowth signals have yet to be clearly defined. We find that the matrix metalloproteinase, MT1-MMP, confers tumor cells with a distinct 3D growth advantage in vitro and in vivo. The replicative advantage conferred by MT1-MMP requires pericellular proteolysis of the ECM, as proliferation is fully suppressed when tumor cells are suspended in 3D gels of protease-resistant collagen. In the absence of proteolysis, tumor cells embedded in physiologically relevant ECM matrices are trapped in a compact, spherical configuration and unable to undergo changes in cell shape or cytoskeletal reorganization required for 3D growth. These observations identify MT1-MMP as a tumor-derived growth factor that regulates proliferation by controlling cell geometry within the confines of the 3D ECM.     

Diffusion of MMPs on the surface of collagen fibrils: the mobile cell surface-collagen substratum interface

Remodeling of the extracellular matrix catalyzed by MMPs is central to morphogenetic phenomena during development and wound healing as well as in numerous pathologic conditions such as fibrosis and cancer. We have previously demonstrated that secreted MMP-2 is tethered to the cell surface and activated by MT1-MMP/TIMP-2-dependent mechanism. The resulting cell-surface collagenolytic complex (MT1-MMP)₂/TIMP-2/MMP-2 can initiate (MT1-MMP) and complete (MMP-2) degradation of an underlying collagen fibril. The following question remained: What is the mechanism of substrate recognition involving the two structures of relatively restricted mobility, the cell surface enzymatic complex and a collagen fibril embedded in the ECM? Here we demonstrate that all the components of the complex are capable of processive movement on a surface of the collagen fibril. The mechanism of MT1-MMP movement is a biased diffusion with the bias component dependent on the proteolysis of its substrate, not adenosine triphosphate (ATP) hydrolysis. It is similar to that of the MMP-1 Brownian ratchet we described earlier. In addition, both MMP-2 and MMP-9 as well as their respective complexes with TIMP-1 and -2 are capable of Brownian diffusion on the surface of native collagen fibrils without noticeable dissociation while the dimerization of MMP-9 renders the enzyme immobile. Most instructive is the finding that the inactivation of the enzymatic activity of MT1-MMP has a detectable negative effect on the cell force developed in miniaturized 3D tissue constructs. We propose that the collagenolytic complex (MT1-MMP)₂/TIMP-2/MMP-2 represents a Mobile Cell Surface – Collagen Substratum Interface. The biological implications of MT1-MMP acting as a molecular ratchet tethered to the cell surface in complex with MMP-2 suggest a new mechanism for the role of spatially regulated peri-cellular proteolysis in cell-matrix interactions.     

Centrosomal BRCA2 is a target protein of membrane type-1 matrix metalloproteinase (MT1-MMP)

BRCA2 localizes to centrosomes between G1 and prophase and is removed from the centrosomes during mitosis, but the underlying mechanism is not clear. Here we show that BRCA2 is cleaved into two fragments by membrane type-1 matrix metalloproteinase (MT1-MMP), and that knockdown of MT1-MMP prevents the removal of BRCA2 from centrosomes during metaphase. Mass spectrometry mapping revealed that the MT1-MMP cleavage site of human BRCA2 is between Asn-2135 and Leu-2136 (²¹³²LSNN/LNVEGG²¹⁴¹), and the point mutation L2136D abrogated MT1-MMP cleavage. Our data demonstrate that MT1-MMP proteolysis of BRCA2 regulates the abundance of BRCA2 on centrosomes.     

Loss of MT1‐MMP causes cell senescence and nuclear defects which can be reversed by retinoic acid

MT1-MMP (MMP14) is a collagenolytic enzyme located at the cell surface and implicated in extracellular matrix (ECM) remodeling. Mmp14^−/− mice present dwarfism, bone abnormalities, and premature death. We demonstrate herein that the loss of MT1-MMP also causes cardiac defects and severe metabolic changes, and alters the cytoskeleton and the nuclear lamina structure. Moreover, the absence of MT1-MMP induces a senescent phenotype characterized by up-regulation of p16^INK4a and p21^CIP1/WAF1, increased activity of senescence-associated β-galactosidase, generation of a senescence-associated secretory phenotype, and somatotroph axis alterations. Consistent with the role of retinoic acid signaling in nuclear lamina stabilization, treatment of Mmp14^−/− mice with all-trans retinoic acid reversed the nuclear lamina alterations, partially rescued the cell senescence phenotypes, ameliorated the pathological defects in bone, skin, and heart, and extended their life span. These results demonstrate that nuclear architecture and cell senescence can be modulated by a membrane protease, in a process involving the ECM as a key regulator of nuclear stiffness under cell stress conditions.     

A Novel Protein Associated with Membrane-type 1 Matrix Metalloproteinase Binds p27kip1 and Regulates RhoA Activation, Actin Remodeling, and Matrigel Invasion

Pericellular proteolysis by membrane-type 1 matrix metalloproteinase (MT1-MMP) plays a pivotal role in tumor cell invasion. Localization of MT1-MMP at the invasion front of cells, e.g. on lamellipodia and invadopodia, has to be regulated in coordination with reorganization of the actin cytoskeleton. However, little is known about how such invasion-related actin structures are regulated at the sites where MT1-MMP localizes. During analysis of MT1-MMP-associated proteins, we identified a heretofore uncharacterized protein. This protein, which we call p27RF-Rho, enhances activation of RhoA by releasing it from inhibition by p27^kip1 and thereby regulates actin structures. p27^kip1 is a well known cell cycle regulator in the nucleus. In contrast, cytoplasmic p27^kip1 has been demonstrated to bind GDP-RhoA and inhibit GDP-GTP exchange mediated by guanine nucleotide exchange factors. p27RF-Rho binds p27^kip1 and prevents p27^kip1 from binding to RhoA, thereby freeing the latter for activation. Knockdown of p27RF-Rho expression renders cells resistant to RhoA activation stimuli, whereas overexpression of p27RF-Rho sensitizes cells to such stimulation. p27RF-Rho exhibits a punctate distribution in invasive human tumor cell lines. Stimulation of the cells with lysophosphatidic acid induces activation of RhoA and induces the formation of punctate actin structures within foci of p27RF-Rho localization. Some of the punctate actin structures co-localize with MT1-MMP and cortactin. Down-regulation of p27RF-Rho prevents both redistribution of actin into the punctate structures and tumor cell invasion. Thus, p27RF-Rho is a new potential target for cancer therapy development.Malignant tumor cells grow invasively and form distant metastases after moving through multiple tissue barriers. Invasion requires cell locomotion together with degradation of the extracellular matrix (ECM)² by matrix metalloproteinases (MMPs) (1). MT1-MMP (MMP-14) is an integral membrane protease that degrades a variety of protein components within the extracellular milieu (2). The substrates of MT1-MMP include a variety of components of the ECM, membrane proteins including cell adhesion molecules, and growth factors and cytokines (3). To degrade the ECM barrier in advance of an invading cell, MT1-MMP localizes to the leading edge of invasion (4) and cellular protrusions called invadopodia (5–7). Therefore, it is of particular interest how reorganization of actin structures is regulated at sites where MT1-MMP localizes.During mass spectrometric analysis of proteins co-purified with MT1-MMP, we identified a protein of unknown function (8). Although this protein did not affect MT1-MMP activity, we observed that enhanced expression or down-regulation of this protein affected activation of RhoA. Thus, we became interested in the possibility that this protein mediates focal reorganization of actin structures close to sites where MT1-MMP localizes.RhoA plays a pivotal role in signal transduction pathways that regulate reorganization of actin structures and does so by assuming active GTP-bound and inactive GDP-bound states, with the transition between the two forms finely regulated by many cellular proteins (9, 10). In addition to the classical modulators, recent studies have revealed that p27^kip1 also regulates activation of RhoA and Rac1 (11, 12). p27^kip1 has been characterized as a cyclin-dependent kinase inhibitor localized to the nucleus, but phosphorylation of p27^kip1 by protein kinase B/Akt or kinase-interacting stathmin (KIS) mediates its translocation from the nucleus to the cytoplasm. Cytoplasmic p27^kip1 binds RhoA and prevents activation of RhoA by GEFs (12, 13). However, it is not known how inhibition of RhoA by p27^kip1 is released to allow activation. The protein we identified binds p27^kip1, thereby preventing its binding to RhoA (schematically illustrated in supplemental Fig. S1). We named this protein p27RF-Rho (p27^kip1 releasing factor from RhoA) based on this activity.     

The single-molecule mechanics of the latent TGF-β1 complex

Background

TGF-β1 controls many pathophysiological processes including tissue homeostasis, fibrosis, and cancer progression. Together with its latency-associated peptide (LAP), TGF-β1 binds to the latent TGF-β1-binding protein-1 (LTBP-1), which is part of the extracellular matrix (ECM). Transmission of cell force via integrins is one major mechanism to activate latent TGF-β1 from ECM stores. Latent TGF-β1 mechanical activation is more efficient with higher cell forces and ECM stiffening. However, little is known about the molecular events involved in this mechanical activation mechanism.

Results

By using single-molecule force spectroscopy and magnetic microbeads, we analyzed how forces exerted on the LAP lead to conformational changes in the latent complex that can ultimately result in TGF-β1 release. We demonstrate the unfolding of two LAP key domains for mechanical TGF-β1 activation: the α1 helix and the latency lasso, which together have been referred to as the “straitjacket” that keeps TGF-β1 associated with LAP. The simultaneous unfolding of both domains, leading to full opening of the straitjacket at a force of ∼40 pN, was achieved only when TGF-β1 was bound to the LTBP-1 in the ECM.

Conclusions

Our results directly demonstrate opening of the TGF-β1 straitjacket by application of mechanical force in the order of magnitude of what can be transmitted by single integrins. For this mechanism to be in place, binding of latent TGF-β1 to LTBP-1 is mandatory. Interfering with mechanical activation of latent TGF-β1 by reducing integrin affinity, cell contractility, and binding of latent TGF-β1 to the ECM provides new possibilities to therapeutically modulate TGF-β1 actions.     

Expression of Human Membrane Type 1 Matrix Metalloproteinase in Pichia pastoris

A soluble, C-terminal truncated form of human membrane type 1 matrix metalloproteinase (MT1-MMP) containing the hemopexin-like domain was expressed in Pichia pastoris strain KM71. High levels of secreted protein were detected. Although the c-DNA for the proenzyme (Ala²¹-Glu⁵²³ called ΔTM-MT1-MMP) was cloned, almost only active MT1-MMP (Tyr¹¹²-Glu⁵²³) with identical N-terminus as described for the wild-type enzyme was isolated. This active enzyme was highly purified and characterized with respect to its biochemical properties. The recombinant protein showed high stability against autolysis and proteolysis by yeast proteases, although the calculated in vivo half-life is rather low. The biochemical properties of this new MT1-MMP species were compared with the well-characterized catalytic domain (Ile¹¹⁴-Ile³¹⁸) of MT1-MMP. The novel form of MT1-MMP exhibited a higher stability against autolysis than the isolated catalytic domain (Ile¹¹⁴-Ile³¹⁸).     

Quantitative Measurement of Invadopodia-mediated Extracellular Matrix Proteolysis in Single and Multicellular Contexts

Cellular invasion into local tissues is a process important in development and homeostasis. Malregulated invasion and subsequent cell movement is characteristic of multiple pathological processes, including inflammation, cardiovascular disease and tumor cell metastasis¹. Focalized proteolytic degradation of extracellular matrix (ECM) components in the epithelial or endothelial basement membrane is a critical step in initiating cellular invasion. In tumor cells, extensive in vitro analysis has determined that ECM degradation is accomplished by ventral actin-rich membrane protrusive structures termed invadopodia^2,3. Invadopodia form in close apposition to the ECM, where they moderate ECM breakdown through the action of matrix metalloproteinases (MMPs). The ability of tumor cells to form invadopodia directly correlates with the ability to invade into local stroma and associated vascular components³. Visualization of invadopodia-mediated ECM degradation of cells by fluorescent microscopy using dye-labeled matrix proteins coated onto glass coverslips has emerged as the most prevalent technique for evaluating the degree of matrix proteolysis and cellular invasive potential^4,5. Here we describe a version of the standard method for generating fluorescently-labeled glass coverslips utilizing a commercially available Oregon Green-488 gelatin conjugate. This method is easily scaled to rapidly produce large numbers of coated coverslips. We show some of the common microscopic artifacts that are often encountered during this procedure and how these can be avoided. Finally, we describe standardized methods using readily available computer software to allow quantification of labeled gelatin matrix degradation mediated by individual cells and by entire cellular populations. The described procedures provide the ability to accurately and reproducibly monitor invadopodia activity, and can also serve as a platform for evaluating the efficacy of modulating protein expression or testing of anti-invasive compounds on extracellular matrix degradation in single and multicellular settings.     

Distinct modes of collagen type I proteolysis by matrix metalloproteinase (MMP) 2 and membrane type I MMP during the migration of a tip endothelial cell: insights from a computational model

Matrix metalloproteinases (MMPs) are a family of enzymes responsible for the proteolytic processing of extracellular matrix (ECM) structural proteins under physiological and pathological conditions. During sprouting angiogenesis, the MMPs expressed by a single "tip" endothelial cell exhibit proteolytic activity that allows the cells of the sprouting vessel bud to migrate into the ECM. Membrane type I matrix metalloproteinase (MT1-MMP) and the diffusible matrix metalloproteinase MMP2, in the presence of the tissue inhibitor of metalloproteinases TIMP2, constitute a system of proteins that play an important role during the proteolysis of collagen type I matrices. Here, we have formulated a computational model to investigate the proteolytic potential of such a tip endothelial cell. The cell expresses MMP2 in its proenzyme form, pro-MMP2, as well as MT1-MMP and TIMP2. The interactions of the proteins are described by a biochemically detailed reaction network. Assuming that the rate-limiting step of the migration is the ability of the tip cell to carry out proteolysis, we have estimated cell velocities for matrices of different collagen content. The estimated velocities of a few microns per hour are in agreement with experimental data. At high collagen content, proteolysis was carried out primarily by MT1-MMP and localized to the cell leading edge, whereas at lower concentrations, MT1-MMP and MMP2 were found to act in parallel, causing proteolysis in the vicinity of the leading edge. TIMP2 is a regulator of the proteolysis localization because it can shift the activity of MT1-MMP from its enzymatic toward its activatory mode, suggesting a tight mechanosensitive regulation of the enzymes and inhibitor expression. The model described here provides a foundation for quantitative studies of angiogenesis in extracellular matrices of different compositions, both in vitro and in vivo. It also identifies critical parameters whose values are not presently available and which should be determined in future experiments.     

Metalloproteinases: A parade of functions in matrix biology and an outlook for the future

This issue of Matrix Biology is devoted to exploring how metalloproteinases – here inclusive of related families of extracellular proteinases – act on extracellular matrix (ECM) proteins to influence an astonishing diversity of biological systems and diseases. Since their discovery in the 1960's, matrix metalloproteinases (MMPs) have oft and widely been considered as the principal mediators of ECM destruction. However, as becomes clear from several articles in this issue, MMPs affect processes that both promote and limit ECM assembly, structure, and quantity. Furthermore, it has become increasingly apparent that ECM proteolysis is neither the exclusive function of MMPs nor their only sphere of influence. Thus, other enzymes may be important participants in ECM proteolysis, and indeed they are. The ADAMTS (a disintegrin-like and metalloproteinase domain with thrombospondin type 1 repeat) proteinases, BMP/tolloid proteases, and meprins have all emerged as major mechanisms of ECM proteolysis. An aggregate view of proteolysis as an exquisitely specific and crucial post-translational modification of secreted proteins emerges from these reviews. The cumulative evidence strongly suggests that although some MMPs can and do cleave ECM components, notably fibrillar collagens, the majority of these proteinases are not key physiological participants in morphogenesis nor in control of matrix metabolism in homeostasis or disease. In contrast, deficiency of ADAMTS proteases leads to a remarkable array of morphogenetic defects and connective tissue disorders consistent with a specialized role in turnover of the embryonic provisional ECM and in ECM assembly. Astacin-related proteases emerge into crucial positions in ECM assembly and turnover, although they also have numerous roles related to morphogen and growth factor regulation. To further turn the traditional view on its head, it is clear that many MMPs are key participants in many, diverse immune and inflammation processes rather than ECM proteolysis. The overlap in the activities within and between these families leads to the view that ECM proteolysis, which is indispensable for life, was over-engineered to an extraordinary extent during vertebrate evolution. That these proteinases, which likely evolved within networks regulating morphogenesis, immunity and regeneration, also participate in diseases is a side effect of human longevity. Attempts to inhibit metalloproteinases in human diseases thus require continuing appraisal of their biological roles and cautious evaluation of potential new therapeutic opportunities.     

SNAP23, Syntaxin4, and vesicle-associated membrane protein 7 (VAMP7) mediate trafficking of membrane type 1–matrix metalloproteinase (MT1-MMP) during invadopodium formation and tumor cell invasion

Movement through the extracellular matrix (ECM) requires cells to degrade ECM components, primarily through the action of matrix metalloproteinases (MMPs). Membrane type 1–matrix metalloproteinase (MT1-MMP) has an essential role in matrix degradation and cell invasion and localizes to subcellular degradative structures termed invadopodia. Trafficking of MT1-MMP to invadopodia is required for the function of these structures, and here we examine the role of N-ethylmaleimide–sensitive factor–activating protein receptor (SNARE)–mediated membrane traffic in the transport of MT1-MMP to invadopodia. During invadopodium formation in MDA-MB-231 human breast cancer cells, increased association of SNAP23, Syntaxin4, and vesicle-associated membrane protein 7 (VAMP7) is detected by coimmunoprecipitation. Blocking the function of these SNAREs perturbs invadopodium-based ECM degradation and cell invasion. Increased level of SNAP23-Syntaxin4-VAMP7 interaction correlates with decreased Syntaxin4 phosphorylation. These results reveal an important role for SNARE-regulated trafficking of MT1-MMP to invadopodia during cellular invasion of ECM.     

Proprotein Convertase Subtilisin/Kexin Type 3 Promotes Adipose Tissue-Driven Macrophage Chemotaxis and Is Increased in Obesity

Background

Matrix metalloproteinase (MMP)-dependent extracellular matrix (ECM) remodeling is a key feature in cardiometabolic syndrome-associated adipogenesis and atherosclerosis. Activation of membrane-tethered (MT) 1-MMP depends on furin (PCSK3). However, the regulation and function of the natural furin-inhibitor serpinB8 and thus furin/MT1-MMP-activity in obesity-related tissue inflammation/remodeling is unknown. Here we aimed to determine the role of serpinB8/furin in obesity-associated chronic inflammation.

Methods and Results

Monocyte → macrophage transformation was characterized by decreases in serpinB8 and increases in furin/MT1-MMP. Rescue of serpinB8 by protein overexpression inhibited furin-dependent pro-MT1-MMP activation in macrophages, supporting its role as a furin-inhibitor. Obese white adipose tissue-facilitated macrophage migration was inhibited by furin- and MMP-inhibition, stressing the importance of the furin-MMP axis in fat tissue inflammation/remodeling. Monocytes from obese patients (body mass index (BMI) >30kg/m²) had higher furin, MT1-MMP, and resistin gene expression compared to normal weight individuals (BMI<25kg/m²) with significant correlations of BMI/furin and furin/MT1-MMP. In vitro, the adipocytokine resistin induced furin and MT1-MMP in mononuclear cells (MNCs), while MCP-1 had no effect.

Conclusions

Acquisition of the inflammatory macrophage phenotype is characterized by an imbalance in serpinB8/furin, leading to MT1-MMP activation, thereby enhancing migration. Increases in MT1-MMP and furin are present in MNCs from obese patients. Dissecting the regulation of furin and its inhibitor serpinB8 should facilitate targeting inflammation/remodeling in cardiometabolic diseases.     

Pericellular Conditions Regulate Extent of Cell-Mediated Compaction of Collagen Gels

Cell-mediated compaction of the extracellular matrix (ECM) plays a critical role in tissue engineering, wound healing, embryonic development, and many disease states. The ECM is compacted as a result of cellular traction forces. We hypothesize that a cell mechanically remodels the nearby ECM until some target conditions are obtained, and then the cell stops compacting. A key feature of this hypothesis is that ECM compaction primarily occurs in the pericellular region and the properties of the ECM in the pericellular region govern cellular force generation. We developed a mathematical model to describe the amount of macroscopic compaction of cell-populated collagen gels in terms of the initial cell and collagen densities, as well as the final conditions of the pericellular environment (defined as the pericellular volume where the collagen is compacted (V^∗) and the mass of collagen within this volume (m^∗)). This model qualitatively predicts the effects of varying initial cell and collagen concentrations on the extent of gel compaction, and by fitting V^∗ and m^∗, provides reasonable quantitative agreement with the extent of gel compaction observed in experiments with endothelial cells and fibroblasts. Microscopic analysis of compacted gels supports the assumption that collagen compaction occurs primarily in the pericellular environment.     

Matrix-dependent proteolysis of surface transglutaminase by membrane-type metalloproteinase regulates cancer cell adhesion and locomotion

Cell invasion requires cooperation between adhesion receptors and matrix metalloproteinases (MMPs). Membrane type (MT)-MMPs have been thought to be primarily involved in the breakdown of the extracellular matrix. Our report presents evidence that MT-MMPs in addition to the breakdown of the extracellular matrix may be engaged in proteolysis of adhesion receptors on tumor cell surfaces. Overexpression of MT1-MMP by glioma and fibrosarcoma cells led to proteolytic degradation of cell surface tissue transglutaminase (tTG) at the leading edge of motile cancer cells. In agreement, structurally related MT1-MMP, MT2-MMP, and MT3-MMP but not evolutionary distant MT4-MMP efficiently degraded purified tTG in vitro. Because cell surface tTG represents a ubiquitously expressed, potent integrin-binding adhesion coreceptor involved in the binding of cells to fibronectin (Fn), the proteolytic degradation of tTG by MT1-MMP specifically suppressed cell adhesion and migration on Fn. Reciprocally, Fn in vitro and in cultured cells protected its surface receptor, tTG, from proteolysis by MT1-MMP, thereby supporting cell adhesion and locomotion. In contrast, the proteolytic degradation of tTG stimulated migration of cells on collagen matrices. Together, our observations suggest both an important coreceptor role for cell surface tTG and a novel regulatory function of membrane-anchored MMPs in cancer cell adhesion and locomotion. Proteolysis of adhesion proteins colocalized with MT-MMPs at discrete regions on the surface of migrating tumor cells might be controlled by composition of the surrounding ECM.     

MT1-MMP: a potent modifier of pericellular microenvironment

Cells are regulated by many different means, and there is more and more evidence emerging that changes in the microenvironment greatly affect cell function. MT1-MMP is a type I transmembrane proteinase which participates in pericellular proteolysis of extracellular matrix (ECM) macromolecules. The enzyme is cellular collagenase essential for skeletal development, cancer invasion, growth, and angiogenesis. MT1-MMP promotes cell invasion and motility by pericellular ECM degradation, shedding of CD44 and syndecan1, and by activating ERK. Thus MT1-MMP is one of the factors that influence the cellular microenvironment and thereby affect cell-signaling pathways and eventually alters cellular behavior. As a proteinase, MT1-MMP is regulated by inhibitors, but it also requires formation of a homo-oligomer complex, localization to migration front of the cells, and internalization to become a "functionally active" cell function modifier. Developing new means to inhibit "functional activity" of MT1-MMP may be a new direction to establish treatments for the diseases that MT1-MMP mediates such as cancer and rheumatoid arthritis.