Timing of cyclin D1 expression within G1 phase is controlled by Rho.

The expression of cyclin D1 in mid-G1 phase is associated with sustained ERK activity, and we show here that Rho is required for the sustained ERK signal. However, we also report that Rho inhibits an alternative Rac/Cdc42-dependent pathway, which results in a strikingly early G1-phase expression of cyclin D1. Thus, cyclin D1 is induced in mid-G1 phase because a Rho switch couples its expression to sustained ERK activity rather than Rac and Cdc42. Our results show that Rho is crucial for maintaining the correct timing of cyclin D1 expression in G1 phase and describe a new role for cytoskeletal integrity in the regulation of cell cycle progression.

The adhesion receptor CD44 promotes atherosclerosis by mediating inflammatory cell recruitment and vascular cell activation.

Atherosclerosis causes most acute coronary syndromes and strokes. The pathogenesis of atherosclerosis includes recruitment of inflammatory cells to the vessel wall and activation of vascular cells. CD44 is an adhesion protein expressed on inflammatory and vascular cells. CD44 supports the adhesion of activated lymphocytes to endothelium and smooth muscle cells. Furthermore, ligation of CD44 induces activation of both inflammatory and vascular cells. To assess the potential contribution of CD44 to atherosclerosis, we bred CD44-null mice to atherosclerosis-prone apoE-deficient mice. We found a 50-70% reduction in aortic lesions in CD44-null mice compared with CD44 heterozygote and wild-type littermates. We demonstrate that CD44 promotes the recruitment of macrophages to atherosclerotic lesions. Furthermore, we show that CD44 is required for phenotypic dedifferentiation of medial smooth muscle cells to the "synthetic" state as measured by expression of VCAM-1. Finally, we demonstrate that hyaluronan, the principal ligand for CD44, is upregulated in atherosclerotic lesions of apoE-deficient mice and that the low-molecular-weight proinflammatory forms of hyaluronan stimulate VCAM-1 expression and proliferation of cultured primary aortic smooth muscle cells, whereas high-molecular-weight forms of hyaluronan inhibit smooth muscle cell proliferation. We conclude that CD44 plays a critical role in the progression of atherosclerosis through multiple mechanisms.

Distinct effects of mitogens and the actin cytoskeleton on CREB and pocket protein phosphorylation control the extent and timing of cyclin A promoter activity.

Soluble mitogens and adhesion-dependent organization of the actin cytoskeleton are required for cells to enter S phase in fibroblasts. The induction of cyclin A is also required for S-phase entry, and we now report that distinct effects of mitogens and the actin cytoskeleton on the phosphorylation of CREB and pocket proteins regulate the extent and timing of cyclin A promoter activity, respectively. First, we show that CREB phosphorylation and binding to the cyclic AMP response element (CRE) determines the extent, but not the timing, of cyclin A promoter activity. Second, we show that pocket protein inactivation regulates the timing, but not the extent, of cyclin A promoter activity. CREB phosphorylation and CRE occupancy are regulated by soluble mitogens alone, while the phosphorylation of pocket proteins requires both mitogens and the organized actin cytoskeleton. Mechanistically, cytoskeletal integrity controls pocket protein phosphorylation by allowing for sustained ERK signaling and, thereby, the expression of cyclin D1. Our results lead to a model of cyclin A gene regulation in which mitogens play a permissive role by stimulating early G(1)-phase phosphorylation of CREB and a distinct regulatory role by cooperating with the organized actin cytoskeleton to regulate the duration of ERK signaling, the expression of cyclin D1, and the timing of pocket protein phosphorylation.

Integrins and cell proliferation: regulation of cyclin-dependent kinases via cytoplasmic signaling pathways.

Cell cycle progression in mammalian cells is strictly regulated by both integrin-mediated adhesion to the extracellular matrix and by binding of growth factors to their receptors. This regulation is mediated by G1 phase cyclin-dependent kinases (CDKs), which are downstream of signaling pathways under the integrated control of both integrins and growth factor receptors. Recent advances demonstrate a surprisingly diverse array of integrin-dependent signals that are channeled into the regulation of the G1 phase CDKs. Regulation of cyclin D1 by the ERK pathway may provide a paradigm for understanding how cell adhesion can determine cell cycle progression.

Integrin-mediated adhesion regulates ERK nuclear translocation and phosphorylation of Elk-1.

Integrin-mediated adhesion to the extracellular matrix permits efficient growth factor-mediated activation of extracellular signal-regulated kinases (ERKs). Points of regulation have been localized to the level of receptor phosphorylation or to activation of the downstream components, Raf and MEK (mitogen-activated protein kinase/ERK kinase). However, it is also well established that ERK translocation from the cytoplasm to the nucleus is required for G1 phase cell cycle progression. Here we show that phosphorylation of the nuclear ERK substrate, Elk-1 at serine 383, is anchorage dependent in response to growth factor treatment of NIH 3T3 fibroblasts. Furthermore, when we activated ERK in nonadherent cells by expression of active components of the ERK cascade, subsequent phosphorylation of Elk-1 at serine 383 and Elk-1-mediated transactivation were still impaired compared with adherent cells. Elk-1 phosphorylation was dependent on an intact actin cytoskeleton, as discerned by treatment with cytochalasin D (CCD). Finally, expression of active MEK failed to predominantly localize ERK to the nucleus in suspended cells or adherent cells treated with CCD. These data show that integrin-mediated organization of the actin cytoskeleton regulates localization of activated ERK, and in turn the ability of ERK to efficiently phosphorylate nuclear substrates.

Coordinate signaling by integrins and receptor tyrosine kinases in the regulation of G1 phase cell-cycle progression.

Cell proliferation is dependent upon the activation of receptor tyrosine kinases and integrins by soluble growth factors and extracellular matrix proteins, respectively. It is now apparent that concerted, rather than individual, signaling by these receptors is the critical feature responsible for cell-cycle progression through G1 phase. ERK (extracellular signal-regulated kinase), Rho GTPases and G1-phase cyclin-dependent kinases are all regulated jointly by growth-factor receptors and integrins. Recent studies have begun to reveal how this regulated signaling in the cytoplasm is linked to activation of the G1-phase cyclin-dependent kinases in the nucleus.

Integrating the MAP kinase signal into the G1 phase cell cycle machinery.

Growth factors and the extracellular matrix provide the environmental cues that control the proliferation of most cell types. The binding of growth factors and matrix proteins to receptor tyrosine kinases and integrins, respectively, regulates several cytoplasmic signal transduction cascades, among which activation of the mitogen-activated protein kinase cascade, ras --> Raf --> MEK --> ERK, is perhaps the best characterized. Curiously, ERK activation has been associated with both stimulation and inhibition of cell proliferation. In this review, we summarize recent studies that connect ERK signaling to G1 phase cell cycle control and suggest that the cellular response to an ERK signal depends on both ERK signal intensity and duration. We also discuss studies showing that receptor tyrosine kinases and integrins differentially regulate the ERK signal in G1 phase.

Induction of anchorage-independent growth by transforming growth factor-beta linked to anchorage-independent expression of cyclin D1.

Transforming growth factor-beta (TGF-beta) was originally identified, characterized, and named on the basis of its ability to induce anchorage-independent growth (phenotypic transformation). This effect has received little attention in recent years, probably because the induction of anchorage-independent growth by TGF-beta has been observed only in a few cell lines, of which NRK fibroblasts are among the best studied. We have previously reported that normal rat kidney cells have lost their normal adhesion requirement for expression of cyclin D1, and we now show that this loss is causal for the induction of anchorage-independent growth by TGF-beta. First, we show that TGF-beta fails to induce anchorage-independent growth in NIH-3T3 cells and human fibroblasts that have retained their adhesion requirement for expression of cyclin D1. Second, we show that TGF-beta complements rather than affects cyclin D-cdk4/6 kinase activity in NRK cells. Third, we show that forced expression of cyclin D1 in suspended 3T3 cells renders them susceptible to transformation by TGF-beta. These results may explain why the induction of anchorage-independent growth by TGF-beta is a rare event and yet also describe a molecular scenario in which the mesenchymal response to TGF-beta could indeed involve the acquisition of an anchorage-independent phenotype.

Reduced expression of (alpha)5(beta)1 integrin prevents spreading-dependent cell proliferation.

Cell adhesion to substratum results in the initiation of integrin signaling and an integrin-dependent organization of the cytoskeleton (cell spreading). To address the potential relationships between these events and cell proliferation, we transfected NRK fibroblasts with an antisense cDNA encoding a 1.3 kb ATG-spanning portion of (alpha)5 integrin subunit and obtained stable clones in which the surface expression of (alpha)5(beta)1 integrin was selectively reduced. (alpha)5-antisense NRK cells are less spread than the control transfectants, have poorly defined stress fibers, and an increased amount of cortical actin. The antisense clones remained anchorage-dependent, but they proliferated very slowly. Serum dose-response curves showed that they have an impaired response to mitogens. Importantly, cell spreading and stress fiber formation could be completely restored by plating the antisense cells on collagen, but cell spreading failed to rescue proliferation. These data indicate that cell spreading can be uncoupled from cell proliferation and that cytoskeletal organization is important for NRK cell proliferation because it enforces the proliferative effect of (alpha)5(beta)1 integrin. Our results also indicate that reduced surface expression of (alpha)5(beta)1 integrin is not sufficient to confer the anchorage-independent phenotype to nontransformed cells.

Transforming growth factor-beta overrides the adhesion requirement for surface expression of alpha(5)beta(1) integrin in normal rat kidney fibroblasts. A necessary effect for induction of anchorage-independent growth.

We have previously shown that the expression of alpha(5)beta(1) integrin on the cell surface is dependent upon cell adhesion to the extracellular matrix, and we report here that transforming growth factor-beta (TGF-beta) overcomes this requirement in normal rat kidney (NRK) fibroblasts. Thus, suspended NRK cells treated with TGF-beta show levels of surface alpha(5)beta(1) integrin that are equivalent to those seen in adherent cells. Moreover, several experiments showed that this effect is necessary for the induction of anchorage-independent growth by TGF-beta. First, a kinetic analysis showed that surface expression of alpha(5)beta(1) integrin was restored in TGF-beta-treated NRK cells prior to the induction of anchorage-independent growth. Second, NRK cell mutants that have lost their TGF-beta requirement for surface expression of alpha(5)beta(1) integrin were anchorage-independent in the absence of TGF-beta. Third, an antisense oligonucleotide to the beta(1) integrin subunit or, fourth, stable expression of an alpha(5)-antisense cDNA blocked the ability of TGF-beta to stimulate anchorage-independent growth. Thus, TGF-beta overrides the adhesion requirement for surface expression of alpha(5)beta(1) integrin in NRK cells, and this effect is necessary for the induction of anchorage-independent growth.

Alpha5beta1 integrin controls cyclin D1 expression by sustaining mitogen-activated protein kinase activity in growth factor-treated cells.

Cyclin D1 expression is jointly regulated by growth factors and cell adhesion to the extracellular matrix in many cell types. Growth factors are thought to regulate cyclin D1 expression because they stimulate sustained extracellular signal-regulated kinase (ERK) activity. However, we show here that growth factors induce transient ERK activity when added to suspended fibroblasts and sustained ERK activity only when added to adherent fibroblasts. Cell attachment to fibronectin or anti-alpha5beta1 integrin is sufficient to sustain the ERK signal and to induce cyclin D1 in growth factor-treated cells. Moreover, when we force the sustained activation of ERK, by conditional expression of a constitutively active MAP kinase/ERK kinase, we overcome the adhesion requirement for expression of cyclin D1. Thus, at least in part, fibroblasts are mitogen and anchorage dependent, because integrin action allows for a sustained ERK signal and the expression of cyclin D1 in growth factor-treated cells.

Regulation of p21(cip1) expression by growth factors and the extracellular matrix reveals a role for transient ERK activity in G1 phase.

We have examined the regulation of p21(cip1) by soluble mitogens and cell anchorage as well as the relationship between the expression of p21(cip1) and activation of the ERK subfamily of MAP kinases. We find that p21(cip1) expression in G1 phase can be divided into two discrete phases: an initial induction that requires growth factors and the activation of ERK, and then a subsequent decline that is enhanced by cell anchorage in an ERK-independent manner. In contrast to the induction of cyclin D1, the induction of p21(cip1) is mediated by transient ERK activity. Comparative studies with wild-type and p21(cip1)-null fibroblasts indicate that adhesion-dependent regulation of p21(cip1) is important for proper control of cyclin E-cdk2 activity. These data lead to a model in which mitogens and anchorage act in a parallel fashion to regulate G1 phase expression of p21(cip1). They also show that (a) growth factors and growth factor/extracellular matrix cooperation can have different roles in regulating G1 phase ERK activity and (b) both transient and sustained ERK signals have functionally significant roles in controlling cell cycle progression through G1 phase.

Cell anchorage and the cytoskeleton as partners in growth factor dependent cell cycle progression.

Several studies in the past year have shown that the cell cycle events typically attributed to a response to growth factors actually require signals provided by both growth factors and the extracellular matrix. Moreover, at least some of these matrix-based effects seem to involve matrix-dependent organization of the cytoskeleton rather than cell adhesion per se. Overall, these studies are providing new insights into the long-appreciated concepts of anchorage- and shape-dependent growth.

Control of the G1 phase cyclin-dependent kinases by mitogenic growth factors and the extracellular matrix.

The identification of the nuclear enzymes called cyclin-dependent kinases has profoundly influenced our understanding of cell proliferation. It now seems clear that these enzymes are responsible for mediating progression through each phase of the cell cycle and that the stimulatory effects of both mitogenic growth factors and extracellular matrix on cell proliferation can be fully explained in terms of their effects on the G1 phase cyclin-dependent kinase system. In turn, these effects have provided the long-awaited molecular definitions to the phenotypes of mitogen-dependent and anchorage-dependent growth.

The extracellular matrix and mitogenic growth factors control G1 phase cyclins and cyclin-dependent kinase inhibitors.

Most cell types require both mitogenic growth factors and cell adhesion to the extracellular matrix (ECM) for proliferation. Over the past few years, these growth requirements have received renewed attention and can now be explained by studies showing that signals provided by growth factors and the ECM are jointly required to stimulate the cyclin-dependent kinases (CDKs) that mediate cell-cycle progression through G1 phase. This article summarizes our current understanding of the control of G1 cyclins and CDK inhibitors by growth factors and the ECM. In addition, we have highlighted one or two signal-transduction pathways that presently seem closely linked to regulation of the G1 phase cyclin-CDK system.

Adhesion-dependent cell cycle progression linked to the expression of cyclin D1, activation of cyclin E-cdk2, and phosphorylation of the retinoblastoma protein.

Growth factors and cell anchorage jointly regulate transit through G1 in almost all cell types, but the cell cycle basis for this combined requirement remains largely uncharacterized. We show here that cell adhesion and growth factors jointly regulate the cyclin D1- and E-dependent kinases. Adhesion to substratum regulates both the induction and translation of cyclin D1 mRNA. Nonadherent cells fail to phosphorylate the retinoblastoma protein (Rb), and enforced expression of cyclin D1 rescues Rb phosphorylation and entry into S phase when G1 cells are cultured in the absence of substratum. Nonadherent cells also fail to activate the cyclin E-associated kinase, and this effect can be linked to an increased association of the cdk inhibitors, p21 and p27. These data describe a striking convergence in the cell cycle controls used by the two major signal transduction systems responsible for normal and abnormal cell growth. Taken together with our previous studies showing adhesion-dependent expression of cyclin A, they also establish the cell cycle basis for explaining the combined requirement for growth factors and the extracellular matrix in transit through the Rb checkpoint, entry into S phase, and anchorage-dependent growth.