Paola Castagnino

Cell Cycle Control by Physiological Matrix Elasticity and In Vivo Tissue Stiffening

BACKGROUND A number of adhesion-mediated signaling pathways and cell-cycle events have been identified that regulate cell proliferation, yet studies to date have been unable to determine which of these pathways control mitogenesis in response to physiologically relevant changes in tissue elasticity. In this report, we use hydrogel-based substrata matched to biological tissue stiffness to investigate the effects of matrix elasticity on the cell cycle. RESULTS We find that physiological tissue stiffness acts as a cell-cycle inhibitor in mammary epithelial cells and vascular smooth muscle cells; subcellular analysis in these cells, mouse embryonic fibroblasts, and osteoblasts shows that cell-cycle control by matrix stiffness is widely conserved. Remarkably, most mitogenic events previously documented as extracellular matrix (ECM)/integrin-dependent proceed normally when matrix stiffness is altered in the range that controls mitogenesis. These include ERK activity, immediate-early gene expression, and cdk inhibitor expression. In contrast, FAK-dependent Rac activation, Rac-dependent cyclin D1 gene induction, and cyclin D1-dependent Rb phosphorylation are strongly inhibited at physiological tissue stiffness and rescued when the matrix is stiffened in vitro. Importantly, the combined use of atomic force microscopy and fluorescence imaging in mice shows that comparable increases in tissue stiffness occur at sites of cell proliferation in vivo. CONCLUSIONS Matrix remodeling associated with pathogenesis is in itself a positive regulator of the cell cycle through a highly selective effect on integrin-dependent signaling to FAK, Rac, and cyclin D1.

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.

ABCG2 Expression and Side Population Abundance Regulated by a Transforming Growth Factor β–Directed Epithelial-Mesenchymal Transition

We describe here the regulation of ABCG2 expression and side population (SP) abundance in MCF7 human breast cancer cells. The level of ABCG2 mRNA and protein were increased in purified MCF7 SP relative to non-SP cells, and incubation with an ABCG2-specific inhibitor or ABCG2 short interfering RNA eliminated the MCF7 SP. The purified MCF7 SP could generate a heterogeneous population containing both SP and non-SP cells in culture. In vivo tumorigenicity experiments showed that the purified MCF7 SP has an increased ability to colonize the mouse mammary gland. Importantly, the MCF7 SP was depleted by a transforming growth factor-beta (TGFbeta)-directed epithelial-mesenchymal transition (EMT), and this effect was associated with a strong down-regulation of ABCG2 gene expression, and an increased sensitivity to mitoxantrone. ABCG2 expression and SP abundance were restored upon the removal of transforming growth factor-beta and reversion of the cells to an epithelial phenotype. Knock-down of E-cadherin also reduced SP abundance, but this effect was not accompanied by the loss of ABCG2 mRNA or protein. We conclude that ABCG2 expression in MCF7 cells is regulated during an EMT, and that the EMT effect reflects posttranslational regulation of ABCG2 function by E-cadherin as well as transcriptional repression of the ABCG2 gene.

Cell adhesion, cellular tension, and cell cycle control.

Cooperative signaling between growth factor receptor tyrosine kinases, integrins, and the actin cytoskeleton is required for activation of the G1-phase cyclin-dependent kinases and progression through G1-phase. Increasing evidence suggests that there is cell type specificity in these cooperative interactions and that the compliance of the underlying substratum can strongly affect adhesion-dependent signaling to the cell cycle. This chapter reviews our current methods for studying how cell type specificity and changes in substratum compliance can contribute to G1-phase cell cycle control. We also describe several of our current analytical procedures.

Rac-dependent cyclin D1 gene expression regulated by cadherin- and integrin-mediated adhesion

Integrin-mediated adhesion to substratum is required for cyclin D1 induction in mesenchymal cells, but we show here that the induction of cyclin D1 persists despite blockade of ECM-integrin signaling in MCF10A mammary epithelial cells. E-cadherin-mediated cell-cell adhesion also supports cyclin D1 induction in these cells, and the combined inhibition of both E-cadherin and integrin adhesion is required to prevent the expression of cyclin D1 mRNA and protein. Our previous studies described a pro-proliferative effect of E-cadherin in MCF10A cells, mediated by Rac, and we now show that Rac is required for cyclin D1 mRNA induction by both E-cadherin and integrin engagement. The levels of p21Cip1 and p27Kip1, Cdk inhibitors that are also targets of integrin signaling, are not affected by E-cadherin-mediated cell-cell adhesion. Finally, we show that the increased expression of cyclin D1 mRNA associated with E-cadherin-dependent cell-cell adhesion is causally linked to an increased entry into S phase. Our results identify Rac signaling to cyclin D1 as a crucial pro-proliferative effect of E-cadherin-mediated cell-cell adhesion.

miR-221/222 Compensates for Skp2-Mediated p27 Degradation and Is a Primary Target of Cell Cycle Regulation by Prostacyclin and cAMP

p27kip1 (p27) is a cdk-inhibitory protein with an important role in the proliferation of many cell types. SCFSkp2 is the best studied regulator of p27 levels, but Skp2-mediated p27 degradation is not essential in vivo or in vitro. The molecular pathway that compensates for loss of Skp2-mediated p27 degradation has remained elusive. Here, we combine vascular injury in the mouse with genome-wide profiling to search for regulators of p27 during cell cycling in vivo. This approach, confirmed by RT-qPCR and mechanistic analysis in primary cells, identified miR-221/222 as a compensatory regulator of p27. The expression of miR221/222 is sensitive to proteasome inhibition with MG132 suggesting a link between p27 regulation by miRs and the proteasome. We then examined the roles of miR-221/222 and Skp2 in cell cycle inhibition by prostacyclin (PGI2), a potent cell cycle inhibitor acting through p27. PGI2 inhibited both Skp2 and miR221/222 expression, but epistasis, ectopic expression, and time course experiments showed that miR-221/222, rather than Skp2, was the primary target of PGI2. PGI2 activates Gs to increase cAMP, and increasing intracellular cAMP phenocopies the effect of PGI2 on p27, miR-221/222, and mitogenesis. We conclude that miR-221/222 compensates for loss of Skp2-mediated p27 degradation during cell cycling, contributes to proteasome-dependent G1 phase regulation of p27, and accounts for the anti-mitogenic effect of cAMP during growth inhibition.

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.

Post-transcriptional destabilization of p21cip1 by protein kinase C in fibroblasts.

p21cip1 inhibits S phase entry by binding to cyclin-cdk2 (cyclin-dependent kinase-2) complexes. The levels of p21cip1 are rapidly induced after mitogenic stimulation of quiescent fibroblasts and then down-regulate as the cells reach late G1 phase and activate cyclin E-cdk2. In this study, we have shown that pharmacological inhibition of protein kinase C (PKC), expression of dominant negative PKCδ, or knockdown of PKCδ with small interfering RNA elevates p21cip1 protein levels in mouse embryo fibroblasts. This effect is selective, post-transcriptional, and proteasome-dependent but distinct from previously identified post-transcriptional control mechanisms involving cyclin D1 and Skp2. PKCδ inhibition results in a reduced entry into S phase, and this effect is not detected in p21cip1-null cells. Thus, post-transcriptional destabilization of p21cip1 appears to be a major mitogenic effect of PKCδ in fibroblasts.

Cell type- and cell cycle-specific anti-mitogenesis by cicaprost

Stents eluting anti-proliferative drugs limit restenosis, but drugs commonly used to date are relatively non-specific cytostatic agents which inhibit proliferation of intimal endothelial cells as well as medial smooth muscle cells and may thereby contribute to the clinical complications associated with angioplasty. In an effort to identify a more specific anti-proliferative agent, we compared the effects of rapamycin to those of cicaprost, a mimetic of the naturally occurring anti-mitogen, PGI(2). Rapamycin and cicaprost were both strongly anti-mitogenic in vascular smooth muscle cells (VSMCs). But unlike rapamycin, cicaprost did not inhibit mitogenesis in aortic endothelial cells even when used at concentrations >10-fold higher than its ED(50) for VSMCs. Similarly, both rapamycin and cicaprost have been reported to regulate levels of the cdk inhibitor, p27(kip1). But rapamycin remained anti-mitogenic in p27(kip1)-null VSMCs whereas the anti-mitogenic effect of cicaprost was completely dependent on p27(kip1). We conclude that stable PGI(2) mimetics may be highly specific inhibitors of p27(kip1)-dependent VSMC proliferation after vascular injury.