Cyclin D1-dependent Kinase Activity Research Articles

Hormone-induced DNA damage response and repair mediated by cyclin D1 in breast and prostate cancer.

Cell cycle control proteins govern events that leads to the production of two identical daughter cells. Distinct sequential temporal phases, Gap 1 (G1), Gap 0 (G0), Synthesis (S), Gap 2 (G2) and Mitosis (M) are negotiated through a series of check points during which the favorability of the local cellular environment is assessed, prior to replicating DNA [1]. Cyclin D1 has been characterized as a key regulatory subunit of the holoenzyme that promotes the G1/S-phase transition through phosphorylating the pRB protein. Cyclin D1 overexpression is considered a driving force in several types of cancers and cdk inhibitors are being used effectively in the clinic for treatment of ERα+ breast cancer [1, 2]. Genomic DNA is assaulted by damaging ionizing radiation, chemical carcinogens, and reactive oxygen species (ROS) which are generated by cellular metabolism. Furthermore, specific hormones including estrogens [3, 4] and androgens [5] govern pathways that damage DNA. Defects in the DNA Damage Response (DDR) pathway can lead to genomic instability and cancer. Evidence is emerging that cyclin D1 bind proteins involved in DNA repair including BRCA1 [6], RAD51 [7], BRCA2 [8] and is involved in the DNA damage and DNA repair processes [7, 8]. Because the repair of damaged DNA appears to be an important and unexpected role for cyclin D1, and inhibitors of cyclin D1-dependent kinase activity are being used in the clinic, the latest findings on the role of cyclin D1 in mediating the DDR including the DDR induced by the hormones estrogen [9] and androgen [10, 11] is reviewed.

Abstract 2347: MicroRNA mediated CDK4/6 inhibitor resistance via extracellular signaling

Abstract Multiple potent and highly selective inhibitors of the cell cycle kinases - CDK4 and CDK6 are in development. One such inhibitor, palbociclib, was recently approved for use in combination with letrozole for the treatment of estrogen receptor positive (ER+) breast cancer. Cyclin D-dependent kinase activity is a driving factor for ER+ breast carcinogenesis, irrespective of CCND1 amplification, making CDK4/6 inhibition a promising approach for this breast cancer subset. However, as with all cancer treatments, resistance will be a major issue limiting the efficacy of this approach. To date, mechanisms of palbociclib resistance have not been extensively investigated. Through interrogation of the generated CDK4/6 inhibition resistant cells we discovered overexpression of CDK6, specifically, mediates resistance. CDK6 depletion reversed resistance and overexpression caused resistance, whereas the same was not true when CDK4 or D cyclin protein levels were manipulated. Interestingly, when generating and analyzing resistant cell populations, we observed a “bystander effect”, by which resistance was transmissible between cells. The “resistant bystander” cells display all characteristics of the drug exposure induced resistant cells, however became resistant in just 48 hours as oppose to 14 weeks. Analysis of conditioned medium revealed that the transmission of resistance is dependent on exosomes, but not protein or DNA. We identified a specific miRNA, present in the exosomes of resistant cells, by microarray which caused resistance when excreted. Additionally, overexpression and inhibition of the miRNA confirmed that it is responsible for causing resistance. miRNA overexpressing cells exhibited the same phenotype as drug induced resistant cells, and furthermore, could cause resistance in neighboring cell populations by exosome mediated signaling. Using Biotin labelled miRNA-mRNA pulldown followed by RNA-seq, we identified the TGFβ pathway as the miRNA target. Downregulation of the TGFβ caused a decrease in the CDK inhibitors, p15 and p21, resulting in an increased CDK6 protein level and palbociclib resistance. We subsequently confirmed these data in patient samples by comparing before treatment and post relapse biopsies. These findings highlight a novel mechanism of conferred drug resistance as well as new insights into acquired CDK4/6 inhibitor resistance. Citation Format: Liam Cornell, Geoffrey I. Shapiro. MicroRNA mediated CDK4/6 inhibitor resistance via extracellular signaling [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 2347. doi:10.1158/1538-7445.AM2017-2347

Selective CDK4/6 inhibition with tumor responses by PD0332991 in patients with mantle cell lymphoma

AbstractMantle cell lymphoma (MCL) carries an unfavorable prognosis and requires new treatment strategies. The associated t(11:14) translocation results in enhanced cyclin D1 expression and cyclin D1–dependent kinase activity to promote cell-cycle progression. A pharmacodynamic study of the selective CDK4/6 inhibitor PD0332991 was conducted in 17 patients with relapsed disease, using 2-deoxy-2-[18F]fluoro-D-glucose (FDG) and 3-deoxy-3[18F]fluorothymidine (FLT) positron emission tomography (PET) to study tumor metabolism and proliferation, respectively, in concert with pre- and on-treatment lymph node biopsies to assess retinoblastoma protein (Rb) phosphorylation and markers of proliferation and apoptosis. Substantial reductions in the summed FLT-PET maximal standard uptake value (SUVmax), as well as in Rb phosphorylation and Ki-67 expression, occurred after 3 weeks in most patients, with significant correlations among these end points. Five patients achieved progression-free survival time of > 1 year (range, 14.9-30.1+ months), with 1 complete and 2 partial responses (18% objective response rate; 90% confidence interval, 5%-40%). These patients demonstrated > 70%, > 90%, and ≥ 87.5% reductions in summed FLT SUVmax and expression of phospho-Rb and Ki67, respectively, parameters necessary but not sufficient for long-term disease control. The results of the present study confirm CDK4/6 inhibition by PD0332991 at a well-tolerated dose and schedule and suggest clinical benefit in a subset of MCL patients. This study is registered at www.clinicaltrials.gov under identifier NCT00420056.

Suppression of Cancer Cell Growth by Promoting Cyclin D1 Degradation

The cyclin D1 proto-oncoprotein is a crucial regulator in cell-cycle progression, and aberrant overexpression of cyclin D1 is linked to tumorigenesis of many different cancer types. By screening ubiquitinated cyclin D1 as a substrate with a deubiquitinase library, we have identified USP2 as a specific deubiquitinase for cyclin D1. USP2 directly interacts with cyclin D1 and promotes its stabilization by antagonizing ubiquitin-dependent degradation. Conversely, USP2 knockdown destabilizes cyclin D1 and induces growth arrest in the human cancer lines where cell growth is dependent on cyclin D1 expression. Of note, cyclin D1 is not universally required for cell-cycle progression. Inactivation of USP2 has either very mild effects on cell growth in normal human fibroblasts or no effect in the cancer cells that do not express cyclin D1. These findings suggest that targeting USP2 is an effective approach to induce growth suppression in the cancer cells addicted to cyclin D1 expression.

Cyclin D1-dependent kinase activity in murine development and mammary tumorigenesis

Cyclin D1 is a multifunctional protein that activates CDK4 and CDK6, titrates Cip/Kip CDK inhibitors to increase CDK2 activity, and modulates the function of certain transcription factors. To specifically test the importance of cyclin D1-associated kinase activity, we generated "knockin" mice expressing mutant cyclin D1 deficient in activating CDK4/6. The development of several cyclin D1-dependent compartments, including mammary glands, proceeds relatively normally in these animals, demonstrating that cyclin D1-associated kinase activity is largely dispensable for development of these tissues. Strikingly, knockin mice were resistant to breast cancers initiated by ErbB-2. These results demonstrate a differential requirement for cyclin D1-CDK4/6 kinase activity in development versus tumorigenesis and strongly support cyclin D1-dependent kinase activity as a specific therapeutic target in breast cancer.

Third place--Resident Research Competition, AAO-2000. Antisense cyclin D1 inhibits growth of head and neck cancer xenografts in nude mice.

Cyclin D1 is a regulatory factor essential in the progression of the cell cycle from G1 through S phase. Amplification and overexpression of cyclin D1 have been observed in many human cancers including head and neck squamous cell carcinoma (HNSCC). We have previously transfected a HNSCC control cell line (CCL23) with an antisense cyclin D1 plasmid and demonstrated inhibition of cell proliferation in vitro. In this study, we examine whether antisense cyclin D1 could inhibit tumor growth in vivo. Methods/measures: The CCL23 and its antisense cyclin D1 transfected clone (CCL23 AS) were injected into the flanks of nude mice. Tumor growth was monitored weekly. After 5 weeks, tumors were removed and studied for tumor size, cyclin D1 expression, cyclin D1-dependent kinase activity, and retinoblastoma (Rb) phosphorylation. Compared with the control tumors, 11 of 19 antisense tumors were smaller, 7 tumors were of equal size, and 1 tumor was larger. Immunohistochemical analysis with an anti-cyclin D1 antibody demonstrated decreased cyclin D1 expression in CCL23 AS and the smaller antisense tumors. Cyclin D1-dependent kinase activity was reduced in CCL23 AS and the smaller antisense tumors, and this was accompanied by a relative decrease in phosphorylated Rb in these samples. Antisense cyclin D1 inhibits growth of HNSCC tumors. Cyclin D1 expression, cyclin D1-dependent kinase activity, and Rb phosphorylation are decreased in these tumors. These findings lend support for the potential use of antisense cyclin D1 as gene therapy for HNSCC.

Antisense cyclin D1 inhibits growth of head and neck cancer xenografts in nude mice: Third Place—Resident Research Competition, AAO-2000

Problem: Cyclin D1 is a regulatory factor essential in the progression of the cell cycle from G1 through S phase. Amplification and overexpression of cyclin D1 have been observed in many human cancers including head and neck squamous cell carcinoma (HNSCC). We have previously transfected a HNSCC control cell line (CCL23) with an antisense cyclin D1 plasmid and demonstrated inhibition of cell proliferation in vitro. In this study, we examine whether antisense cyclin D1 could inhibit tumor growth in vivo. Methods/measures: The CCL23 and its antisense cyclin D1 transfected clone (CCL23 AS) were injected into the flanks of nude mice. Tumor growth was monitored weekly. After 5 weeks, tumors were removed and studied for tumor size, cyclin D1 expression, cyclin D1-dependent kinase activity, and retinoblastoma (Rb) phosphorylation. Results: Compared with the control tumors, 11 of 19 antisense tumors were smaller, 7 tumors were of equal size, and 1 tumor was larger. Immunohistochemical analysis with an anti-cyclin D1 antibody demonstrated decreased cyclin D1 expression in CCL23 AS and the smaller antisense tumors. Cyclin D1-dependent kinase activity was reduced in CCL23 AS and the smaller antisense tumors, and this was accompanied by a relative decrease in phosphorylated Rb in these samples. Conclusion: Antisense cyclin D1 inhibits growth of HNSCC tumors. Cyclin D1 expression, cyclin D1-dependent kinase activity, and Rb phosphorylation are decreased in these tumors. Clinical significance: These findings lend support for the potential use of antisense cyclin D1 as gene therapy for HNSCC. (Otolaryngol Head Neck Surg 2001;124:656-62.)

Cell Cycle and Biochemical Effects of PD 0183812: A POTENT INHIBITOR OF THE CYCLIN D-DEPENDENT KINASES CDK4 AND CDK6

Progression through the G1 phase of the cell cycle requires phosphorylation of the retinoblastoma gene product (pRb) by the cyclin D-dependent kinases CDK4 and CDK6, whose activity can specifically be blocked by the CDK inhibitor p16(INK4A). Misregulation of the pRb/cyclin D/p16(INK4A) pathway is one of the most common events in human cancer and has lead to the suggestion that inhibition of cyclin D-dependent kinase activity may have therapeutic value as an anticancer treatment. Through screening of a chemical library, we initially identified the [2,3-d]pyridopyrimidines as inhibitors of CDK4. Chemical modification resulted in the identification of PD 0183812 as a potent and highly selective inhibitor of both CDK4 and CDK6 kinase activity, which is competitive with ATP. Flow cytometry experiments showed that of the cell lines tested, only those expressing pRb demonstrated a G1 arrest when treated with PD 0183812. This arrest correlated in terms of incubation time and potency with a loss of pRb phosphorylation and a block in proliferation, which was reversible. These results suggest a potential use of this chemical class of compounds as therapeutic agents in the treatment of tumors with functional pRb, possessing cell cycle aberrations in other members of the pRb/cyclin D/p16(INK4A) pathway.

Cyclin D3 Compensates for Loss of Cyclin D2 in Mouse B-lymphocytes Activated via the Antigen Receptor and CD40

Cyclin D2 is the only D-type cyclin expressed in mature mouse B-lymphocytes, and its expression is associated with retinoblastoma protein (pRB) and pRB-related protein phosphorylation and induction of E2F activity, as B-cells enter the cell cycle following stimulation via surface IgM and/or CD40. Cyclin D-dependent kinase activity is required for cell proliferation, yet cyclin D2(-/-) mice have normal levels of mature B-lymphocytes. Here we show that B-lymphocytes from cyclin D2(-/-) mice can proliferate in response to anti-IgM and anti-CD40, but the time taken to enter S-phase is longer than for the corresponding cyclin D2(+/+) cells. This is due to the compensatory induction of cyclin D3, but not cyclin D1, which causes pRb phosphorylation on CDK4-specific sites. This is the first demonstration that loss of a D-type cyclin causes specific expression and functional compensation by another member of the family in vivo and provides a rationale for the presence of mature B-lymphocytes in cyclin D2(-/-) mice.

Regulation of G(1) cyclin-dependent kinases in the liver: role of nuclear localization and p27 sequestration.

Recent studies suggest that cyclin D1 mediates progression of hepatocytes through G(1) phase of the cell cycle. The present study further examines the regulation of cyclin D1-dependent kinase activity and the interplay between cyclin D1 and other G(1) phase regulatory proteins during liver regeneration. After 70% partial hepatectomy in rats, there was upregulation of kinase activity associated with cyclins (A, D1, D3, and E), cyclin-dependent kinases (Cdk2 and Cdk4), and Cdk-inhibitory proteins (p27, p107, and p130). Although cyclin D1/Cdk4 complexes were more abundant in the cytoplasmic fraction after partial hepatectomy, kinase activity was detected primarily in the nuclear fraction. Cytoplasmic cyclin D1/Cdk4 complexes were activated by recombinant cyclin H/Cdk7. Because endogenous Cdk7 activity was found in the nucleus, this suggests that activation of cyclin D1/Cdk4 requires nuclear importation and subsequent phosphorylation by cyclin H/Cdk7. Recombinant cyclin E/Cdk2 was inhibited by extracts from quiescent liver, and cyclin D1 could titrate out this inhibitory activity. Induction of cyclin D1 was accompanied by increased abundance of cyclin D1/p27 complexes, and most p27 was sequestered by cyclin D1 after partial hepatectomy. Thus cyclin D1 appears to play two roles during G(1) phase progression in the regenerating liver: it forms a nuclear kinase complex, and it promotes activation of Cdk2 by sequestering inhibitory proteins such as p27. These experiments underscore the complexity of cyclin/Cdk regulatory networks in the regenerating liver.

Repression of NF-kappaB impairs HeLa cell proliferation by functional interference with cell cycle checkpoint regulators.

NF-kappaB is an inducible transcription factor, which is regulated by interaction with inhibitory IkappaB proteins. Previous studies linked the activity of NF-kappaB to the proliferative state of the cell. Here we have analysed the function of NF-kappaB in the cell cycle. Inhibition of NF-kappaB in HeLa cells by stable overexpression of a transdominant negative IkappaB-alpha protein reduced cell growth. A kinetic analysis of the cell cycle revealed a retarded G1/S transition. The IkappaB-alpha overexpressing cell clones showed a decreased percentage of cells in the S phase and an impaired incorporation of bromodeoxyuridine (BrdU). The amounts of cyclins A, B1, D1, D3, and E were unchanged, but the G1-specific proteins cyclin D2 and cdk2 were strongly elevated in the IkappaB-alpha overexpressing cell clones. These cell clones also displayed an increase in cyclin D1-dependent kinase activity, pointing to a cell cycle arrest at the late G1 phase. IkappaB-alpha overexpression crosstalked to cell cycle checkpoints via a reduction of transcription factor p53 and elevation of p21WAF. Surprisingly, the IkappaB-alpha overexpressing cells showed an enrichment of c-Myc in the nucleoli, although the total amount of c-Myc protein was unchanged. These experiments identify an important contribution of the NF-kappaB/IkappaB system for the growth of HeLa cells.

The p21(Cip1) and p27(Kip1) CDK 'inhibitors' are essential activators of cyclin D-dependent kinases in murine fibroblasts.

The widely prevailing view that the cyclin-dependent kinase inhibitors (CKIs) are solely negative regulators of cyclin-dependent kinases (CDKs) is challenged here by observations that normal up-regulation of cyclin D- CDK4 in mitogen-stimulated fibroblasts depends redundantly upon p21(Cip1) and p27(Kip1). Primary mouse embryonic fibroblasts that lack genes encoding both p21 and p27 fail to assemble detectable amounts of cyclin D-CDK complexes, express cyclin D proteins at much reduced levels, and are unable to efficiently direct cyclin D proteins to the cell nucleus. Restoration of CKI function reverses all three defects and thereby restores cyclin D activity to normal physiological levels. In the absence of both CKIs, the severe reduction in cyclin D-dependent kinase activity was well tolerated and had no overt effects on the cell cycle.

Requirement of cyclin E-Cdk2 inhibition in p16(INK4a)-mediated growth suppression.

Loss-of-function mutations of p16(INK4a) have been identified in a large number of human tumors. An established biochemical function of p16 is its ability to specifically inhibit cyclin D-dependent kinases in vitro, and this inhibition is believed to be the cause of the p16-mediated G1 cell cycle arrest after reintroduction of p16 into p16-deficient tumor cells. However, a mutant of Cdk4, Cdk4(N158), designed to specifically inhibit cyclin D-dependent kinases through dominant negative interference, was unable to arrest the cell cycle of the same cells (S. van den Heuvel and E. Harlow, Science 262:2050-2054, 1993). In this study, we determined functional differences between p16 and Cdk4(N158). We show that p16 and Cdk4(N158) inhibit the kinase activity of cellular cyclin D1 complexes through different mechanisms. p16 dissociated cyclin D1-Cdk4 complexes with the release of bound p27(KIP1), while Cdk4(N158) formed complexes with cyclin D1 and p27. In cells induced to overexpress p16, a higher portion of cellular p27 formed complexes with cyclin E-Cdk2, and Cdk2-associated kinase activities were correspondingly inhibited. Cells engineered to express moderately elevated levels of cyclin E became resistant to p16-mediated growth suppression. These results demonstrate that inhibition of cyclin D-dependent kinase activity may not be sufficient to cause G1 arrest in actively proliferating tumor cells. Inhibition of cyclin E-dependent kinases is required in p16-mediated growth suppression.

Potent Prostaglandin A1 Analogs That Suppress Tumor Cell Growth through Induction of p21 and Reduction of Cyclin E

Although the cyclopentenone prostaglandin A1 (PGA1) is known to arrest the cell cycle at the G1 phase in vitro and to suppress tumor growth in vivo, its relatively weak activity limits its usefulness in cancer chemotherapy. In an attempt to develop antitumor drugs of greater potency and conspicuous biological specificity, we synthesized novel analogs based on the structure of PGA1. Of the newly synthesized analogs, 15-epi-delta7-PGA1 methyl ester (NAG-0092), 12-iso-delta7-PGA1 methyl ester (NAG-0093), and ent-delta7-PGA1 methyl ester (NAG-0022) possess a cross-conjugated dienone structure around the five-member ring with unnatural configurations at C(12) and/or C(15) and were found to be far more potent than native PGA1 in inhibiting cell growth and causing G1 arrest in A172 human glioma cells. These three analogs induced the expression of p21 at both RNA and protein levels in a time- and dose-dependent fashion. Kinase assays with A172 cells treated with these analogs revealed that both cyclin A- and E-dependent kinase activities were markedly reduced, although cyclin D1-dependent kinase activity was unaffected. Immunoprecipitation-Western blot analysis showed that the decrease in cyclin A-dependent kinase activity was due to an increased association of p21 with cyclin A-cyclin-dependent kinase 2 complexes, whereas the decrease in cyclin E-dependent activity was due to a combined mechanism involving reduction in cyclin E protein itself and increased association of p21. Thus, these newly synthesized PGA1 analogs may prove to be powerful tools in cancer chemotherapy as well as in investigations of the structural basis of the antiproliferative activity of A series prostaglandins.

Inhibition of cyclin D1 kinase activity is associated with E2F-mediated inhibition of cyclin D1 promoter activity through E2F and Sp1.

Coordinated interactions between cyclin-dependent kinases (Cdks), their target "pocket proteins" (the retinoblastoma protein [pRB], p107, and p130), the pocket protein binding E2F-DP complexes, and the Cdk inhibitors regulate orderly cell cycle progression. The cyclin D1 gene encodes a regulatory subunit of the Cdk holoenzymes, which phosphorylate the tumor suppressor pRB, leading to the release of free E2F-1. Overexpression of E2F-1 can induce apoptosis and may either promote or inhibit cellular proliferation, depending upon the cell type. In these studies overexpression of E2F-1 inhibited cyclin D1-dependent kinase activity, cyclin D1 protein levels, and promoter activity. The DNA binding domain, the pRB pocket binding region, and the amino-terminal Sp1 binding domain of E2F-1 were required for full repression of cyclin D1. Overexpression of pRB activated the cyclin D1 promoter, and a dominant interfering pRB mutant was defective in cyclin D1 promoter activation. Two regions of the cyclin D1 promoter were required for full E2F-1-dependent repression. The region proximal to the transcription initiation site at -127 bound Sp1, Sp3, and Sp4, and the distal region at -143 bound E2F-4-DP-1-p107. In contrast with E2F-1, E2F-4 induced cyclin D1 promoter activity. Differential regulation of the cyclin D1 promoter by E2F-1 and E2F-4 suggests that E2Fs may serve distinguishable functions during cell cycle progression. Inhibition of cyclin D1 abundance by E2F-1 may contribute to an autoregulatory feedback loop to reduce pRB phosphorylation and E2F-1 levels in the cell.

Regulation of Cyclin D-Dependent Kinase Activity in Rat Liver Regeneration

The regulation of cyclin D-dependent kinase activity in tissue regenerationin vivohas not been fully described. In young adult rat liver after 70% partial hepatectomy, the association of cyclin D1 with cdk4 was significantly promoted during G1 phase and was maximal at 18 hr, corresponding mainly to late G1. Cyclin D1-dependent kinase activity also strongly increased during G1 phase. The timing of the induction of cyclin D1 / cdk4 complex assembly correlated well with that of cyclin D1-dependent kinase activity. At 18 hr after partial hepatectomy, the amounts of CDK inhibitors p21CIP1and p27KIP1were also maximal, while only one-tenth of p21CIP1and of p27KIP1was associated with cyclin D1. These findings suggest that cyclin D1, cdk4 and their association act as promoting factors, and that both p21CIP1and p27KIP1may have physiological functions as adaptor proteins in additions to their roles as CDK inhibitors in rat liver regeneration.

The regulation of cyclin D-dependent kinase activity in regenerative rat liver following partial hepatectomy

The regulation of cyclin D-dependent kinase activity in regenerative rat liver following partial hepatectomy

Inhibition of cyclin D1 phosphorylation on threonine-286 prevents its rapid degradation via the ubiquitin-proteasome pathway.

The expression of D-type G1 cyclins and their assembly with their catalytic partners, the cyclin-dependent kinases 4 and 6 (CDK4 and CDK6), into active holoenzyme complexes are regulated by growth factor-induced signals. In turn, the ability of cyclin D-dependent kinases to trigger phosphorylation of the retinoblastoma (Rb) protein in the mid- to late G1 phase of the cell cycle makes the inactivation of Rb's growth suppressive function a mitogen-dependent step. The ability of D-type cyclins to act as growth factor sensors depends not only on their rapid induction by mitogens but also on their inherent instability, which ensures their precipitous degradation in cells deprived of growth factors. However, the mechanisms governing the turnover of D-type cyclins have not yet been elucidated. We now show that cyclin D1 turnover is governed by ubiquitination and proteasomal degradation, which are positively regulated by cyclin D1 phosphorylation on threonine-286. Although "free" or CDK4-bound cyclin D1 molecules are intrinsically unstable (t1/2 < 30 min), a cyclin D1 mutant (T286A) containing an alanine for threonine-286 substitution fails to undergo efficient polyubiquitination in an in vitro system or in vivo, and it is markedly stabilized (t1/2 approximately 3.5 hr) when inducibly expressed in either quiescent or proliferating mouse fibroblasts. Phosphorylation of cyclin D1 on threonine-286 also occurs in insect Sf9 cells, and although the process is enhanced significantly by the binding of cyclin D1 to CDK4, it does not depend on CDK4 catalytic activity. This implies that another kinase can phosphorylate cyclin D1 to accelerate its destruction and points to yet another means by which cyclin D-dependent kinase activity may be exogenously regulated.

The level of the tissue-specific factor GATA-1 affects the cell-cycle machinery.

GATA-1 is a tissue-specific DNA-binding protein containing two zinc-finger-like domains. It is expressed predominantly in erythrocytes. Consensus binding sites for GATA-1 have been found in the regulatory elements of all erythroid-specific genes examined. GATA-1 protein is required for erythroid differentiation beyond the proerythroblast stage. In this paper, we demonstrate that the overexpression of GATA-1 in murine erythroleukaemia (MEL) cells alleviates DMSO-induced terminal erythroid differentiation. Hence, there is no induction of globin gene transcription and the cells do not arrest in the G1 phase of the cell cycle. Furthermore, we demonstrate that expression of GATA-1 in non-transformed erythroid precursors also affects their proliferative capacity and terminal differentiation, as assayed by adult globin gene transcription. To gain insight into the mechanism of this effect, we studied the levels and activities of regulators of cell-cycle progression during DMSO-induced differentiation. A decrease in cyclin D-dependent kinase activity was observed during the induction of both control and GATA-1-overexpressing MEL cells. However, cyclin E-dependent kinase activity decreased more than 20-fold in control but less than 2-fold in GATA-1-overexpressing MEL cells upon induction. Thus GATA-1 may exert its effects by regulating cyclin E-dependent kinase activity. We also show that GATA-1 binds to the retinoblastoma protein in vitro, but not to the related protein p107, which may indicate that GATA-1 interacts directly with specific members of the cell-cycle machinery in vivo. We conclude that GATA-1 regulates cell fate, in terms of differentiation or proliferation, by affecting the cell-cycle apparatus.

Angiotensin II Activation of Cyclin D1-dependent Kinase Activity

Angiotensin II (AII) binds to specific G protein-coupled receptors and is mitogenic in adrenal, liver epithelial, and vascular smooth muscle cells. Since the cyclin D1 gene encodes the regulatory subunit of the cyclin D1-dependent kinase (CD1K) required for phosphorylation of the retinoblastoma protein (pRB), an essential and rate-limiting step in G1 phase progression of the cell cycle, we examined the effect of AII on cyclin D1 expression and CD1K activity in the human adrenal cell line H295R. AII (10(-6) M) stimulated G1 phase progression within 12 h, with a maximal effect after 72 h. This action was antedated by the induction of cyclin D1 mRNA (3-fold), cyclin D1 nuclear protein abundance (4-fold), and CD1K activity (4-fold). AII induced cyclin D1 promoter activity 4-fold, via the AT1 receptor through an enhancer sequence at -954 base pairs. c-Fos and c-Jun bound the cyclin D1 -954 enhancer sequence, and the abundance of c-Fos within this complex was increased by AII treatment. AII induced extracellular signal-regulated kinase (ERK) activity 7-fold, and dominant-negative mutants of either p21(ras) or ERK reduced AII-stimulated cyclin D1 promoter activity. These findings suggest that AII may stimulate mitogenesis by increasing CD1K activity through a p21(ras)/ERK/activator protein 1 pathway.