Heregulin beta1 promotes breast cancer cell proliferation through Rac/ERK-dependent induction of cyclin D1 and p21Cip1

Accumulating evidence indicates that heregulins, EGF (epidermal growth factor)-like ligands, promote breast cancer cell proliferation and are involved in the progression of breast cancer towards an aggressive and invasive phenotype. However, there is limited information regarding the molecular mechanisms that mediate these effects. We have recently established that HRG (heregulin beta1) promotes breast cancer cell proliferation and migration via cross-talk with EGFR (EGF receptor) that involves the activation of the small GTPase Rac1. In the present paper we report that Rac1 is an essential player for mediating the induction of cyclin D1 and p21(Cip1) by HRG in breast cancer cells. Inhibition of Rac function by expressing either the Rac-GAP (GTPase-activating protein) beta2-chimaerin or the dominant-negative Rac mutant N17Rac1, or Rac1 depletion using RNAi (RNA interference), abolished the cyclin D1 and p21(Cip1) induction by HRG. Interestingly, the proliferative effect of HRG was impaired not only when the expression of Rac1 or cyclin D1 was inhibited, but also when cells were depleted of p21(Cip1) using RNAi. Inhibition of EGFR, PI3K (phosphoinositide 3-kinase; kinases required for Rac activation by HRG) or MEK [MAPK (mitogen-activated protein kinase)/ERK (extracellular-signal-regulated kinase) kinase] also blocked the up-regulation of cyclin D1 and p21(Cip1) by HRG. In addition, we found that HRG activates NF-kappaB (nuclear factor kappaB) in a Rac1- and MEK-dependent fashion, and inhibition of NF-kappaB abrogates cyclin D1/p21(Cip1) induction and proliferation by HRG. Taken together, these findings establish a central role for Rac1 in the control of HRG-induced breast cancer cell-cycle progression and proliferation through up-regulating the expression of cyclin D1 and p21(Cip1).     

ERK1/2 and p38 cooperate to delay progression through G1 by promoting cyclin D1 protein turnover

The conditional kinase DeltaMEKK3:ER allows activation of JNK, p38 and ERK1/2 without overt cellular stress or damage and has proved useful in understanding how these pathways regulate apoptosis and cell cycle progression. We have previously shown that activation of DeltaMEKK3:ER causes a sustained G(1) cell cycle arrest which requires p21(CIP1), with ERK1/2 and p38 cooperating to promote p21(CIP1) expression. In cells lacking p21(CIP1), DeltaMEKK3:ER causes only a transient delay in cell cycle re-entry. We now show that this delay in cell cycle re-entry is due to a reduction in cyclin D1 levels. Activation of DeltaMEKK3:ER promotes the proteasome-dependent turnover of cyclin D1; this requires phosphorylation of threonine 286 (T(286)) and expression of cyclin D1T(286)A rescues the delay in G(1)/S progression. DeltaMEKK3:ER-dependent phosphorylation of T(286) does not appear to be mediated by GSK3beta but requires activation of the ERK1/2 and p38 pathways. ERK1/2 can physically associate with cyclin D1 but activation of ERK1/2 alone is not sufficient for phosphorylation of T(286). Rather, cyclin D1 phosphorylation appears to require coincident activation of ERK1/2 and p38. Thus activation of DeltaMEKK3:ER promotes a sustained G(1) cell cycle arrest by a bipartite mechanism involving the rapid destruction of cyclin D1 and the slower more prolonged expression of p21(CIP1). This has parallels with the bipartite response to ionizing radiation and p53-independent mechanisms of G(1) cell cycle arrest in simple organisms such as yeast.     

IkappaB kinase alpha regulates subcellular distribution and turnover of cyclin D1 by phosphorylation

IkappaB kinases (IKKs), IKKalpha and IKKbeta, with a regulatory subunit IKKgamma/NEMO constitute a high molecular weight IKK complex that regulates NF-kappaB activity. Although IKKalpha and IKKbeta share structural and biochemical similarities, IKKalpha has been shown to have distinct biological roles. Here we show that IKKalpha plays a critical role in regulating cyclin D1 during the cell cycle. Analysis of IKKalpha-/- mouse embryo fibroblast cells showed that cyclin D1 is overexpressed and localized in the nucleus compared with parental mouse embryo fibroblasts. IKKalpha associates with and phosphorylates cyclin D1. Analysis on cyclin D1 mutants demonstrated that IKKalpha phosphorylates cyclin D1 at Thr286. Reconstitution of IKKalpha in knockout cells leads to nuclear export and increased degradation of cyclin D1. Further, RNAi-mediated knockdown of IKKalpha results in similar changes as observed in IKKalpha-/- cells. These results suggest a novel role of IKKalpha in regulating subcellular localization and proteolysis of cyclin D1 by phosphorylation of cyclin D1 at Thr286, the same residue earlier found to be a target for glycogen synthase kinase-3beta-induced phosphorylation.     

Angiotensin II-induced transcriptional activation of the cyclin D1 gene is mediated by Egr-1 in CHO-AT(1A) cells

Cyclin D1 protein expression is regulated by mitogenic stimuli and is a critical component in the regulation of G(1) to S phase progression of the cell cycle. Angiotensin II (Ang II) binds to specific G protein-coupled receptors and is mitogenic in Chinese hamster ovary cells stably expressing the rat vascular Ang II type 1A receptor (CHO-AT(1A)). We recently reported that in these cells, Ang II induced cyclin D1 promoter activation and protein expression in a phosphatidylinositol 3-kinase (PI3K)-, SHP-2-, and mitogen-activated protein kinase/extracellular signal-regulated kinase (MAPK/ERK)-dependent manner (Guillemot, L., Levy, A., Zhao, Z. J., Béréziat, G., and Rothhut, B. (2000) J. Biol. Chem. 275, 26349-26358). In this report, transfection studies using a series of deleted cyclin D1 promoters revealed that two regions between base pairs (bp) -136 and -96 and between bp -29 and +139 of the human cyclin D1 promoter contained regulatory elements required for Ang II-mediated induction. Mutational analysis in the -136 to -96 bp region provided evidence that a Sp1/early growth response protein (Egr) motif was responsible for cyclin D1 promoter activation by Ang II. Gel shift and supershift studies showed that Ang II-induced Egr-1 binding involved de novo protein synthesis and correlated well with Egr-1 promoter activation. Both U0126 (an inhibitor of the MAPK/ERK kinase MEK) and wortmannin (an inhibitor of PI3K) abrogated Egr-1 endogenous expression and Egr-1 promoter activity induced by Ang II. Moreover, using a co-transfection approach, we found that Ang II induction of Egr-1 promoter activity was blocked by dominant-negative p21(ras), Raf-1, and tyrosine phosphatase SHP-2 mutants. Identical effects were obtained when inhibitors and dominant negative mutants were tested on the -29 to +139 bp region of the cyclin D1 promoter. Taken together, these findings demonstrate that Ang II-induced cyclin D1 up-regulation is mediated by the activation and specific interaction of Egr-1 with the -136 to -96 bp region of the cyclin D1 promoter and by activation of the -29 to +139 bp region, both in a p21(ras)/Raf-1/MEK/ERK-dependent manner, and also involves PI3K and SHP-2.     

Disruption of cyclin D3 blocks proliferation of normal B-1a cells, but loss of cyclin D3 is compensated by cyclin D2 in cyclin D3-deficient mice

Peritoneal B-1a cells differ from splenic B-2 cells in the molecular mechanisms that control G(0)-S progression. In contrast to B-2 cells, cyclin D2 is up-regulated in a rapid and transient manner in phorbol ester (PMA)-stimulated B-1a cells, whereas cyclin D3 does not accumulate until late G(1) phase. This nonoverlapping expression of cyclins D2 and D3 suggests distinct functions for these proteins in B-1a cells. To investigate the contribution of cyclin D3 in the proliferation of B-1a cells, we transduced p16(INK4a) peptidyl mimetics (TAT-p16) into B-1a cells before cyclin D3 induction to specifically block cyclin D3-cyclin-dependent kinase 4/6 assembly. TAT-p16 inhibited DNA synthesis in B-1a cells stimulated by PMA, CD40L, or LPS as well as endogenous pRb phosphorylation by cyclin D-cyclin-dependent kinase 4/6. Unexpectedly, however, cyclin D3-deficient B-1a cells proliferated in a manner similar to wild-type B-1a cells following PMA or LPS stimulation. This was due, at least in part, to the compensatory sustained accumulation of cyclin D2 throughout G(0)-S progression. Taken together, experiments in which cyclin D3 was inhibited in real time demonstrate the key role this cyclin plays in normal B-1a cell mitogenesis, whereas experiments with cyclin D3-deficient B-1a cells show that cyclin D2 can compensate for cyclin D3 loss in mutant mice.     

Differential regulation of cyclin D1 and D2 in protecting against cardiomyocyte proliferation

Cardiomyocytes withdraw from cell cycle after terminal differentiation due in part to impaired nuclear import of cyclin D1. Thus, we have previously shown that expression of nuclear localization signal-tagged cyclin D1 (D1NLS) and cyclin-dependent kinase 4 promotes cardiomyocyte proliferation both in vitro and in vivo. Here we show that cyclin D2 fails to stimulate cell cycle in cardiomocytes through a mechanism distinct from that of cyclin D1. We demonstrate that cyclin D2 can express in the nucleus much more efficiently than cyclin D1. Cyclin D2, however, was much less effective in activating CDK2 and cell proliferation than cyclin D1 when expressed transiently in the nucleus of cardiomyocytes using nuclear localization signals. Consistent with such an observation, CDK inhibitors p21cip1 and p27kip1 remained bound to CDK2 in cells expressing cyclin D2, whereas p21 and p27 were sequestered to cyclin D1 in cells expressing D1NLS. These data suggest that cyclin D2 has weaker affinities to the CDK inhibitors and therefore is less efficient in activating cell cycle than cyclin D1. According to such a notion, double knockdown of p21 and p27 in cells expressing D2NLS induced activation of CDK2/CDC2 and BrdU incorporation to levels similar to those in cells expressing D1NLS. Taken together, our data suggest that distinct mechanisms keep cyclin D1 and cyclin D2 from activating cell cycle in terminally differentiated cardiomyocytes.     

Antiproliferative action of valproate is associated with aberrant expression and nuclear translocation of cyclin D3 during the C6 glioma G1 phase

Cell cycle progression is tightly regulated by cyclins, cyclin-dependent kinases (cdks) and related inhibitory phophatases. Here, we employed mitotic selection to synchronize the C6 glioma cell cycle at the start of the G1 phase and mapped the temporal regulation of selected cyclins, cdks and inhibitory proteins throughout the 12 h of G1 by immunoblot analysis. The D-type cyclins, D3 and D1, were differentially expressed during the C6 glioma G1 phase. Cyclin D1 was up-regulated in the mid-G1 phase (4-6 h) while cyclin D3 expression emerged only in late G1 (9-12 h). The influence of the anticonvulsant agent valproic acid (VPA) on expression of cyclins and related proteins was determined, since its teratogenic potency has been linked to cell cycle arrest in the mid-G1 phase. Exposure of C6 glioma to VPA induced a marked up-regulation of cyclin D3 and decreased expression of the proliferating cell nuclear antigen. In synchronized cell populations, increased expression of cyclin D3 by VPA was detected in the mid-G1 phase (3-5 h). Immunocytochemical localization demonstrated rapid intracellular translocation of cyclin D3 to the nucleus following VPA exposure, suggesting that VPA-induced cell cycle arrest may be mediated by precocious activation of cyclin D3 in the G1 phase.