Yong Ho Bae

A FAK-Cas-Rac-Lamellipodin Signaling Module Transduces Extracellular Matrix Stiffness into Mechanosensitive Cell Cycling

A signaling pathway triggers cell proliferation in response to increased stiffness in the external environment. Cell Proliferation in Hard Environments The extracellular matrix that surrounds cells in tissues and organs is not always of the same rigidity. The stiffness of the extracellular matrix can be changed by disease or injury. In damaged blood vessels, the extracellular matrix becomes stiffer around the site of damage; the smooth muscle cells that surround blood vessels migrate and proliferate to repair the damage. Bae et al. identified a signaling pathway that included the enzyme Rac and the cell migration protein lamellipodin, and that triggered proliferation in cells growing on surfaces that mimicked very stiff extracellular matrix. Mice that lacked Rac in their smooth muscle cells did not efficiently repair damage to blood vessels. Thus, lamellipodin is important in not only regulating cellular migration, but also the cell cycle in response to mechanical cues from the extracellular matrix. Tissue and extracellular matrix (ECM) stiffness is transduced into intracellular stiffness, signaling, and changes in cellular behavior. Integrins and several of their associated focal adhesion proteins have been implicated in sensing ECM stiffness. We investigated how an initial sensing event is translated into intracellular stiffness and a biologically interpretable signal. We found that a pathway consisting of focal adhesion kinase (FAK), the adaptor protein p130Cas (Cas), and the guanosine triphosphatase Rac selectively transduced ECM stiffness into stable intracellular stiffness, increased the abundance of the cell cycle protein cyclin D1, and promoted S-phase entry. Rac-dependent intracellular stiffening involved its binding partner lamellipodin, a protein that transmits Rac signals to the cytoskeleton during cell migration. Our findings establish that mechanotransduction by a FAK-Cas-Rac-lamellipodin signaling module converts the external information encoded by ECM stiffness into stable intracellular stiffness and mechanosensitive cell cycling. Thus, lamellipodin is important not only in controlling cellular migration but also for regulating the cell cycle in response to mechanical signals.

Cardiovascular protection by ApoE and ApoE-HDL linked to suppression of ECM gene expression and arterial stiffening.

Arterial stiffening is a risk factor for cardiovascular disease, but how arteries stay supple is unknown. Here, we show that apolipoprotein E (apoE) and apoE-containing high-density lipoprotein (apoE-HDL) maintain arterial elasticity by suppressing the expression of extracellular matrix genes. ApoE interrupts a mechanically driven feed-forward loop that increases the expression of collagen-I, fibronectin, and lysyl oxidase in response to substratum stiffening. These effects are independent of the apoE lipid-binding domain and transduced by Cox2 and miR-145. Arterial stiffness is increased in apoE null mice. This stiffening can be reduced by administration of the lysyl oxidase inhibitor BAPN, and BAPN treatment attenuates atherosclerosis despite highly elevated cholesterol. Macrophage abundance in lesions is reduced by BAPN in vivo, and monocyte/macrophage adhesion is reduced by substratum softening in vitro. We conclude that apoE and apoE-containing HDL promote healthy arterial biomechanics and that this confers protection from cardiovascular disease independent of the established apoE-HDL effect on cholesterol.

Profilin1 regulates PI(3,4)P2 and lamellipodin accumulation at the leading edge thus influencing motility of MDA-MB-231 cells

Profilin1, a ubiquitously expressed actin-binding protein, plays a critical role in cell migration through actin cytoskeletal regulation. Given the traditional view of profilin1 as a promigratory molecule, it is difficult to reconcile observations that profilin1 is down-regulated in various invasive adenocarcinomas and that reduced profilin1 expression actually confers increased motility to certain adenocarcinoma cells. In this study, we show that profilin1 negatively regulates lamellipodin targeting to the leading edge in MDA-MB-231 breast cancer cells and normal cells; profilin1 depletion increases lamellipodin concentration at the lamellipodial tip (where it binds Ena/VASP), and this mediates the hypermotility. We report that the molecular mechanism underlying profilin1’s modulation of lamellipodin localization relates to phosphoinositide control. Specifically, we show that phosphoinositide binding of profilin1 inhibits the motility of MDA-MB-231 cells by negatively regulating PI(3,4)P2 at the membrane and thereby limiting recruitment of lamellipodin [a PI(3,4)P2-binding protein] and Ena/VASP to the leading edge. In summary, this study uncovers a unique biological consequence of profilin1-phosphoinositide interaction, thus providing direct evidence of profilin1’s regulation of cell migration independent of its actin-related activity.

m-calpain Activation Is Regulated by Its Membrane Localization and by Its Binding to Phosphatidylinositol 4,5-Bisphosphate

m-calpain plays a critical role in cell migration enabling rear de-adhesion of adherent cells by cleaving structural components of the adhesion plaques. Growth factors and chemokines regulate keratinocyte, fibroblast, and endothelial cell migration by modulating m-calpain activity. Growth factor receptors activate m-calpain secondary to phosphorylation on serine 50 by ERK. Concurrently, activated m-calpain is localized to its inner membrane milieu by binding to phosphatidylinositol 4,5-bisphosphate (PIP2). Opposing this, CXCR3 ligands inhibit cell migration by blocking m-calpain activity secondary to a PKA-mediated phosphorylation in the C2-like domain. The failure of m-calpain activation in the absence of PIP2 points to a key regulatory role, although whether this PIP2-mediated membrane localization is regulatory for m-calpain activity or merely serves as a docking site for ERK phosphorylation is uncertain. Herein, we report the effects of two CXCR3 ligands, CXCL11/IP-9/I-TAC and CXCL10/IP-10, on the EGF- and VEGF-induced redistribution of m-calpain in human fibroblasts and endothelial cells. The two chemokines block the tail retraction and, thus, the migration within minutes, preventing and reverting growth factor-induced relocalization of m-calpain to the plasma membrane of the cells. PKA phosphorylation of m-calpain blocks the binding of the protease to PIP2. Unexpectedly, we found that this was due to membrane anchorage itself and not merely serine 50 phosphorylation, as the farnesylation-induced anchorage of m-calpain triggers a strong activation of this protease, leading notably to an increased cell death. Moreover, the ERK and PKA phosphorylations have no effect on this membrane-anchored m-calpain. However, the presence of PIP2 is still required for the activation of the anchored m-calpain. In conclusion, we describe a novel mechanism of m-calpain activation by interaction with the plasma membrane and PIP2 specifically, this phosphoinositide acting as a cofactor for the enzyme. The phosphorylation of m-calpain by ERK and PKA by growth factors and chemokines, respectively, act in cells to regulate the enzyme only indirectly by controlling its redistribution.

Loss of Profilin-1 Expression Enhances Breast Cancer Cell Motility by Ena/VASP Proteins

We previously showed that silencing profilin‐1 (Pfn1) expression increases breast cancer cell motility, but the underlying mechanisms have not been explored. Herein, we demonstrate that loss of Pfn1 expression leads to slower but more stable lamellipodial protrusion thereby enhancing the net protrusion rate and the overall motility of MDA‐MB‐231 breast cancer cells. Interestingly, MDA‐MB‐231 cells showed dramatic enrichment of VASP at their leading edge when Pfn1 expression was downregulated and this observation was also reproducible in other cell types including human mammary epithelial cells and vascular endothelial cells. We further demonstrate that Pfn1 downregulation results in a hyper‐motile phenotype of MDA‐MB‐231 cells in an Ena/VASP‐dependent mechanism. Pfn1‐depleted cells display a strong colocalization of VASP with lamellipodin (Lpd—a PI(3,4)P2‐binding protein that has been previously implicated in lamellipodial targeting of Ena/VASP) at the leading edge. Finally, inhibition of PI3‐kinase (important for generation of PI(3,4)P2) delocalizes VASP from the leading edge. This observation is consistent with a possible involvement of Lpd in enhanced membrane recruitment of VASP that results from loss of Pfn1 expression. Our findings for the first time highlight a possible mechanism of how reduced expression of a pro‐migratory molecule like Pfn1 could actually promote motility of breast cancer cells. J. Cell. Physiol. 219: 354–364, 2009.

Profilin-1 overexpression upregulates PTEN and suppresses AKT activation in breast cancer cells.

Profilin‐1 (Pfn1), a ubiquitously expressed actin‐binding protein, has been regarded as a tumor‐suppressor molecule for breast cancer. Since AKT signaling impacts cell survival and proliferation, in this study we investigated whether AKT activation in breast cancer cells is sensitive to perturbation of Pfn1 expression. We found that even a moderate overexpression of Pfn1 leads to a significant reduction in phosphorylation of AKT in MDA‐MB‐231 breast cancer cells. We further demonstrated that Pfn1 overexpression in MDA‐MB‐231 cells is associated with a significant reduction in the level of the phosphoinositide regulator of AKT, PIP3, and impaired membrane translocation of AKT that is required for AKT activation, in response to EGF stimulation. Interestingly, Pfn1‐overexpressing cells showed post‐transcriptional upregulation of PTEN. Furthermore, when PTEN expression was silenced, AKT phosphorylation was rescued, suggesting PTEN upregulation is responsible for Pfn1‐dependent attenuation of AKT activation in MDA‐MB‐231 cells. Pfn1 overexpression induced PTEN upregulation and reduced AKT activation were also reproducible features of BT474 breast cancer cells. These findings may provide mechanistic insights underlying at least some of the tumor‐suppressive properties of Pfn1. J. Cell. Physiol. 218: 436–443, 2009.

Molecular insights on context-specific role of profilin-1 in cell migration.

Profilin-1 (Pfn1) is a ubiquitously expressed actin-monomer binding protein that has been linked to many cellular activities ranging from control of actin polymerization to gene transcription. Traditionally, Pfn1 has been considered to be an essential control element for actin polymerization and cell migration. Seemingly contrasting this view, a few recent studies have shown evidence of an inhibitory action of Pfn1 on motility of certain types of carcinoma cells. In this review, we summarize biochemistry and functional aspects of Pfn1 in normal cells and bring in newly emerged action of Pfn1 in cancer cells that may explain its context-specific role in cell migration.

N-Cadherin Induction by ECM Stiffness and FAK Overrides the Spreading Requirement for Proliferation of Vascular Smooth Muscle Cells

SUMMARY In contrast to the accepted pro-proliferative effect of cell-matrix adhesion, the proliferative effect of cadherin-mediated cell-cell adhesion remains unresolved. Here, we studied the effect of N-cadherin on cell proliferation in the vasculature. We show that N-cadherin is induced in smooth muscle cells (SMCs) in response to vascular injury, an in vivo model of tissue stiffening and proliferation. Complementary experiments performed with deformable substrata demonstrated that stiffness-mediated activation of a focal adhesion kinase (FAK)-p130Cas-Rac signaling pathway induces N-cadherin. Additionally, by culturing paired and unpaired SMCs on microfabricated adhesive islands of different areas, we found that N-cadherin relaxes the spreading requirement for SMC proliferation. In vivo SMC deletion of N-cadherin strongly reduced injury-induced cycling. Finally, SMC-specific deletion of FAK inhibited proliferation after vascular injury, and this was accompanied by reduced induction of N-cadherin. Thus, a stiffness-and FAK-dependent induction of N-cadherin connects cell-matrix to cell-cell adhesion and regulates the degree of cell spreading needed for cycling.

Matrix metalloproteinase-12 is an essential mediator of acute and chronic arterial stiffening.

Arterial stiffening is a hallmark of aging and risk factor for cardiovascular disease, yet its regulation is poorly understood. Here we use mouse modeling to show that matrix metalloproteinase-12 (MMP12), a potent elastase, is essential for acute and chronic arterial stiffening. MMP12 was induced in arterial smooth muscle cells (SMCs) after acute vascular injury. As determined by genome-wide analysis, the magnitude of its gene induction exceeded that of all other MMPs as well as those of the fibrillar collagens and lysyl oxidases, other common regulators of tissue stiffness. A preferential induction of SMC MMP12, without comparable effect on collagen abundance or structure, was also seen during chronic arterial stiffening with age. In both settings, deletion of MMP12 reduced elastin degradation and blocked arterial stiffening as assessed by atomic force microscopy and immunostaining for stiffness-regulated molecular markers. Isolated MMP12-null SMCs sense extracellular stiffness normally, indicating that MMP12 causes arterial stiffening by remodeling the SMC microenvironment rather than affecting the mechanoresponsiveness of the cells themselves. In human aortic samples, MMP12 levels strongly correlate with markers of SMC stiffness. We conclude that MMP12 causes arterial stiffening in mice and suggest that it functions similarly in humans.

Apolipoprotein E3 Inhibits Rho to Regulate the Mechanosensitive Expression of Cox2

Apolipoprotein E3 (apoE3) is thought to protect against atherosclerosis by enhancing reverse cholesterol transport. However, apoE3 also has cholesterol-independent effects that contribute to its anti-atherogenic properties. These include altering extracellular matrix protein synthesis and inhibiting vascular smooth muscle cell proliferation. Both of these cholesterol-independent effects result from an apoE3-mediated induction of cyclooxygenase-2 (Cox2). Nevertheless, how apoE3 regulates Cox2 remains unknown. Here, we show that apoE3 inhibits the activation of Rho, which reduces the formation of actin stress fibers and focal adhesions and results in cellular softening. Inhibition of Rho-Rho kinase signaling or direct cellular softening recapitulates the effect of apoE3 on Cox2 expression while a constitutively active Rho mutant overrides the apoE3 effect on both intracellular stiffness and Cox2. Thus, our results describe a previously unidentified mechanism by which an atheroprotective apolipoprotein uses Rho to control cellular mechanics and Cox2.