Function Of Cyclin D1 Research Articles

Cyclin D1: Mechanism and Consequence of Androgen Receptor Co-repressor Activity

Androgen receptor regulation is pivotal for prostate growth and development. Activation of the receptor is dictated by association with androgen (ligand) and through interaction with co-activators and co-repressors. We have shown previously that cyclin D1 functions as a co-repressor to inhibit ligand-dependent androgen receptor activation. We demonstrate that cyclin D1 directly binds the N terminus of the androgen receptor and that this interaction is independent of ligand. Furthermore, we show that the interaction occurs in the nucleus and does not require the LXXLL motif of cyclin D1. Although two distinct transactivation domains exist in the N terminus (AF-1 and AF-5), the data shown support the hypothesis that cyclin D1 targets the AF-1 transactivation function. The constitutively active AF-5 domain was refractory to cyclin D1 inhibition. By contrast, cyclin D1 completely abolished androgen receptor activity, even in the presence of potent androgen receptor co-activators. This action of cyclin D1 at least partially required de-acetylase activity. Finally, we show that transient, ectopic expression of cyclin D1 results in reduced cell cycle progression in androgen-dependent LNCaP cells independent of CDK4 association. Collectively, our data support a model wherein cyclin D1 has a mitogenic (CDK4-dependent) function and an anti-mitogenic function (dependent on regulation of the AF-1 domain) that can collectively control the rate of androgen-dependent cellular proliferation. These findings provide insight into the non-cell cycle functions of cyclin D1 and provide the impetus to study its pleiotropic effects in androgen-dependent cells, especially prostatic adenocarcinomas.

The Invasion Front of Human Colorectal Adenocarcinomas Shows Co-Localization of Nuclear β-Catenin, Cyclin D 1, and p16 INK4A and Is a Region of Low Proliferation

At the invasion front of well-differentiated colorectal adenocarcinomas, the oncogene beta-catenin is found in the nuclear compartment of tumor cells. Under these conditions, beta-catenin can function as a transcription factor and thus activate target genes. One of these target genes, cyclin D1, is known to induce proliferation. However, invasion front of well-differentiated colorectal adenocarcinomas are known to be zones of low proliferation and express the cell cycle inhibitor p16INK4A. Therefore, we investigated the expression profiles of nuclear beta-catenin, cyclin D1, p16INK4A, and the Ki-67 antigen, a marker for proliferation, in serial sections of well-differentiated colorectal adenocarcinomas. Invasion fronts with nuclear beta-catenin were compared with areas from central parts of the tumors without nuclear beta-catenin, for the expression of cyclin D1, p16INK4A, and Ki-67. It was observed that expression of nuclear beta-catenin, cyclin D1, and p16INK4A at the invasion front are significantly correlated. Such areas exhibit low Ki-67 expression indicating a low rate of proliferation. Thus, in colorectal carcinogenesis the function of beta-catenin and its target gene cyclin D1 does not appear to be the induction of tumor cell proliferation. In particular, the function of cyclin D1 should be reconsidered in view of these observations.

Ras and Rho regulation of the cell cycle and oncogenesis

The important contribution of aberrant Ras activation in oncogenesis is well established. Our knowledge of the signaling pathways that are regulated by Ras is considerable. However, the number of downstream effectors of Ras continues to increase and our understanding of the role of these effector signaling pathways in mediating oncogenesis is far from complete and continues to evolve. Similarly, our understanding of the components that control mitogen-stimulated cell cycle progression is also very advanced. Where our understanding has lagged has been the delineation of the mechanism by which Ras causes a deregulation of cell cycle progression to promote the uncontrolled proliferation of the cancer cell. In this review, we summarize our current knowledge of how deregulated Ras activation alters the function of cyclin D1, p21 Cip1, and p27 Kip1. The two themes that we have emphasized are the involvement of Rho small GTPases in cell cycle regulation and the cell-type differences in how Ras signaling interfaces with the cell cycle machinery.

Cyclin D1 polymorphism and increased risk of colorectal cancer at young age.

Colorectal cancer is the third most common cause of cancer and cancer mortality among men and women in the United States. It is estimated that there will be approximately 130 400 new colorectal cancer cases and 56 700 deaths in the year 2001 (1). Cyclin D1 is involved both in normal regulation of the cell cycle and in neoplasia, where it is frequently overexpressed (2). It plays an important role in the transition from the G1 phase to the S phase of the cell cycle. Amplification or overexpression of the cyclin D1 gene (also known as CCND1) is common in a variety of different cancers and induces proliferation. The cyclin D1 gene has a G to A polymorphism at codon 242 in exon 4 that increases the frequency of alternate splicing (3). In the alternately spliced RNA, intron 4 is not spliced out. Both the normal and altered transcripts encode a protein that contains amino acids 55–161, which are thought to be responsible for the cyclin D1 function (4). The protein encoded by the alternate transcript is missing the last 55 amino acids at the carboxy-terminus that are replaced by a shorter 43-amino-acid sequence encoded by intron 4. As a result, the carboxy-terminal end of the alternate transcript is missing sequences important in protein turnover; therefore, it may have a longer half-life (3). Slight elevations in the levels of cyclin D1 might make the cells less sensitive to signals by the cell-cycle checkpoint machinery. The A allele leads to poorer clinical outcome in patients with non-small-cell lung cancer (3). In a previous study (5), we showed that patients with one or two copies of the polymorphic A allele of the cyclin D1 gene who also carried a mutation in a mismatch repair gene developed hereditary nonpolyposis colorectal cancer (HNPCC) on the average of 11 years earlier than mismatch repair gene mutation carriers with the GG genotype. To extend our findings, we conducted a hospital-based case–control study of nonsyndromic colorectal cancer to determine if the cyclin D1 polymorphism influences risk for this disease. We studied a consecutive series of newly registered patients with nonsyndromic adenocarcinoma of the colon or rectum evaluated at The University of Texas M. D. Anderson Cancer Center, Houston, who agreed to participate in the study. Patients with nonsyndromic colorectal cancer are defined as individuals with no obvious physical characteristics such as occur in familial adenomatous polyposis coli (FAP) or Peutz–Jeghers syndrome. The patients were enrolled during an 11-month period that began in September 1994. From September 20, 1994, through August 17, 1995, a total of 321 patients with confirmed colon or rectal adenocarcinoma consented to participate in the study and provided a blood specimen, representing 69% of the patients originally contacted. Of these 321 patients, 188 (59%) were male and 133 (41%) were female. Most case subjects were Caucasian (75%), with AfricanAmerican, Hispanic, and other ethnic groups accounting for 16%, 8%, and 1%, respectively. Thirty-four percent (n 110) of the cases occurred in individuals less than 50 years old, and 23% (n 75) occurred in individuals less than 45 years old. Because of possible heterogeneity in susceptibility to colorectal cancer among different racial and ethnic groups, we limited our study to Caucasians. Among the Caucasians, we limited the study to case subjects under the age of 60 years, because environmental effects are likely to dominate over genetic effects in older case subjects. This restriction led to our final tally of 156 case subjects, 28 (18%) of whom had rectal cancer (with two subjects having both rectal and colon cancers), and 11 patients (7%) met the Amsterdam criteria (6).

Sonic hedgehog Promotes G1Cyclin Expression and Sustained Cell Cycle Progression in Mammalian Neuronal Precursors

Sonic hedgehog (Shh) signal transduction via the G-protein-coupled receptor, Smoothened, is required for proliferation of cerebellar granule neuron precursors (CGNPs) during development. Activating mutations in the Hedgehog pathway are also implicated in basal cell carcinoma and medulloblastoma, a tumor of the cerebellum in humans. However, Shh signaling interactions with cell cycle regulatory components in neural precursors are poorly understood, in part because appropriate immortalized cell lines are not available. We have utilized primary cultures from neonatal mouse cerebella in order to determine (i) whether Shh initiates or maintains cell cycle progression in CGNPs, (ii) if G(1) regulation by Shh resembles that of classical mitogens, and (iii) whether individual D-type cyclins are essential components of Shh proliferative signaling in CGNPs. Our results indicate that Shh can drive continued cycling in immature, proliferating CGNPs. Shh treatment resulted in sustained activity of the G(1) cyclin-Rb axis by regulating levels of cyclinD1, cyclinD2, and cyclinE mRNA transcripts and proteins. Analysis of CGNPs from cyclinD1(-/-) or cyclinD2(-/-) mice demonstrates that the Shh proliferative pathway does not require unique functions of cyclinD1 or cyclinD2 and that D-type cyclins overlap functionally in this regard. In contrast to many known mitogenic pathways, we show that Shh proliferative signaling is mitogen-activated protein kinase independent. Furthermore, protein synthesis is required for early effects on cyclin gene expression. Together, our results suggest that Shh proliferative signaling promotes synthesis of regulatory factor intermediates that upregulate or maintain cyclin gene expression and activity of the G(1) cyclin-Rb axis in proliferating granule neuron precursors.

Requirement of cyclin D1 in mesangial cell mitogenesis.

Abstract. Hyperplasia of mesangial cells (MC) is a frequent finding in glomerulonephritis. The control and function of cyclin D1, a regulator of cell cycle progression, in MC proliferation in vivo and in vitro were investigated. In a rat model of mesangioproliferative glomerulonephritis, increases in the number of cyclin D1-positive MC nuclei were prominent on day 5 of the disease, preceding the peak of MC hyperplasia. In growth-arrested rat MC in culture, mitogenic stimulation with serum or platelet-derived growth factor (PDGF) led to rapid increases in cyclin D1 protein expression. Transforming growth factor-beta1 inhibited PDGF induction of cyclin D1 protein at 12 h. In an examination of the subcellular distribution of cyclin D1, it was observed that stimulation of MC with PDGF for 6 h caused translocation of cyclin D1 from the cytoplasm into the nucleus. Coincubation with PDGF and transforming growth factor-beta1 completely inhibited this effect, without altering the cellular cyclin D1 protein abundance at that time point. To test whether reduction of cyclin D1 protein levels was sufficient to inhibit mitogenesis, MC were transfected with antisense oligonucleotides (ODN) complementary to rat cyclin D1 mRNA. Antisense ODN against cyclin D1 reduced the serum- or PDGF-induced protein expression of cyclin D1 to 27 or 10% of control levels, respectively. These inhibitory effects were correlated with diminished cyclin-dependent kinase 4 activity. Antisense ODN against cyclin D1 also decreased the PDGF-induced increase in p21(Waf-1) protein levels. The MC proliferation caused by serum or PDGF was markedly inhibited by antisense ODN against cyclin D1, as measured by [(3)H]thymidine uptake and cell counts. It is concluded that increased cyclin D1 protein expression of MC is required for MC proliferation. Targeting cyclin D1 expression may represent an effective means to inhibit MC proliferation in vitro and in vivo.

Activation of the cyclin D1 Gene by the E1A-associated Protein p300 through AP-1 Inhibits Cellular Apoptosis

The adenovirus E1A protein interferes with regulators of apoptosis and growth by physically interacting with cell cycle regulatory proteins including the retinoblastoma tumor suppressor protein and the coactivator proteins p300/CBP (where CBP is the CREB-binding protein). The p300/CBP proteins occupy a pivotal role in regulating mitogenic signaling and apoptosis. The mechanisms by which cell cycle control genes are directly regulated by p300 remain to be determined. The cyclin D1 gene, which is overexpressed in many different tumor types, encodes a regulatory subunit of a holoenzyme that phosphorylates and inactivates PRB. In the present study E1A12S inhibited the cyclin D1 promoter via the amino-terminal p300/CBP binding domain in human choriocarcinoma JEG-3 cells. p300 induced cyclin D1 protein abundance, and p300, but not CBP, induced the cyclin D1 promoter. cyclin D1 or p300 overexpression inhibited apoptosis in JEG-3 cells. The CH3 region of p300, which was required for induction of cyclin D1, was also required for the inhibition of apoptosis. p300 activated the cyclin D1 promoter through an activator protein-1 (AP-1) site at -954 and was identified within a DNA-bound complex with c-Jun at the AP-1 site. Apoptosis rates of embryonic fibroblasts derived from mice homozygously deleted of the cyclin D1 gene (cyclin D1(-/-)) were increased compared with wild type control on several distinct matrices. p300 inhibited apoptosis in cyclin D1(+/+) fibroblasts but increased apoptosis in cyclin D1(-/-) cells. The anti-apoptotic function of cyclin D1, demonstrated by sub-G(1) analysis and annexin V staining, may contribute to its cellular transforming and cooperative oncogenic properties.

Over-expression of cyclin D1 induces glioma invasion by increasing matrix metalloproteinase activity and cell motility.

In order to define the role of cyclin D1 in the progression of malignant glioma, cells over-expressing cyclin D1 were constructed (a-1 cells). They exhibited significantly increased invasiveness as compared with mock-transfected cells. Since cellular invasion is thought to depend on extracellular-matrix degradation, we determined whether cyclin-D1 expression modifies the activity of matrix metalloproteinases (MMPs). Increased gelatinolytic activity of latent type MMP-2 (proMMP-2) and active MMP-2 was observed in a-1 cells. Moreover, cyclin-D1 expression was associated with increased activation of proMMP-9 through MMP-3. Wound assays showed an increase of cell motility in a-1 cells. Cyclin-D1 expression was found to be associated with up-regulation of Rac1, which modulates the formation of ruffling membranes and cell motility. Our results show that cyclin D1 may modulate invasive ability by increasing MMP activity and cell motility, and suggests a novel function of cyclin D1 in the progression of malignant gliomas.

P/CAF associates with cyclin D1 and potentiates its activation of the estrogen receptor.

Cyclin D1 is overexpressed in a significant percentage of human breast cancers, particularly in those that also express the estrogen receptor (ER). We and others have demonstrated previously that experimentally overexpressed cyclin D1 can associate with the ER and stimulate its transcriptional functions in the absence of estrogen. This effect is separable from the established function of cyclin D1 as a regulator of cyclin-dependent kinases. Here, we demonstrate that cyclin D1 can also interact with the histone acetyltransferase, p300/CREB-binding protein-associated protein (P/CAF), thereby facilitating an association between P/CAF and the ER. Ectopic expression of P/CAF potentiates cyclin D1-stimulated ER activity in a dose-dependent manner. This effect is largely dependent on the acetyltransferase activity of P/CAF. These results suggest that cyclin D1 may trigger the activation of the ER through the recruitment of P/CAF, by providing histone acetyltransferase activity and, potentially, links to additional P/CAF-associated transcriptional coactivators.

Estrogen regulation of cell cycle progression in breast cancer cells

Estrogens are potent mitogens in a number of target tissues including the mammary gland where they play a pivotal role in the development and progression of mammary carcinoma. The demonstration that estrogen-induced mitogenesis is associated with the recruitment of non-cycling, G 0, cells into the cell cycle and an increased rate of progression through G 1 phase, has focused attention on the estrogenic regulation of molecules with a known role in the control of G 1–S phase progression. These experiments provide compelling evidence that estrogens regulate the expression and function of c-Myc and cyclin D1 and activate cyclin E-Cdk2 complexes, all of which are rate limiting for progression from G 1 to S phase. Furthermore, these studies reveal a novel mechanism of activation of cyclin E-Cdk2 complexes whereby estrogens promote the formation of high molecular weight complexes lacking the CDK inhibitor p21. Inducible expression of either c-Myc or cyclin D1 can mimic the effects of estrogen in activating the cyclin E-Cdk2 complexes and promoting S phase entry, providing evidence for distinct c-Myc and cyclin D1 pathways in estrogen-induced mitogenesis which converge on the activation of cyclin E-Cdk2. These data provide new mechanistic insights into the known mitogenic effects of estrogens and identify potential downstream targets that contribute to their role in oncogenesis.

Parathyroid Tumor Suppressor on 1p: Analysis of the p18 Cyclin-Dependent Kinase Inhibitor Gene As a Candidate

Loss of chromosome arm 1p DNA is the most common molecular defect thus far observed in human parathyroid adenomas, suggesting that 1p is the location of a putative tumor suppressor gene (or genes) whose inactivation contributes frequently to parathyroid tumorigenesis. To narrow the genomic location of this tumor suppressor gene, we analyzed 25 sporadic parathyroid adenomas for allelic loss of polymorphic DNA loci on chromosome 1 using 11 microsatellite markers not previously scored for this set of tumors. Allelic loss on chromosome arm 1p DNA was observed in 8 of 25 adenomas. Marker deletion patterns showed some complexity, with the regions most commonly deleted in these tumors being 1p36 and 1p35-p31. The 1p35-p31 region contains an excellent candidate tumor suppressor gene, p18, whose product is a cell cycle regulator that inhibits the cyclin D1-associated kinase CDK6. Given that cyclin D1 is a parathyroid oncogene, inactivation of an inhibitor of cyclin D1 function, like p18, might also cause excessive parathyroid growth. To examine the involvement of p18 in parathyroid tumorigenesis, we analyzed 25 parathyroid adenomas for mutations of the p18 coding exons by single strand conformational polymorphism analysis and sequencing. No point mutations were found in any of the 25 adenomas. These observations indicate that inactivating mutation of the p18 gene occurs uncommonly, if at all, in parathyroid adenomas. In addition, the data raise the important possibility that more than a single tumor suppressor gene on 1p could contribute to parathyroid neoplasia.

Cyclins and breast cancer.

Recent advances in the understanding of cell cycle control by cyclins and cyclin-dependent kinases provide a basis for delineating the molecular mechanisms of proliferation control by steroids and the development and progression of hormone-dependent cancers. Cyclin D1 is necessary, rate-limiting and sufficient for G1 progression in breast cancer cells and regulation of cyclin D1 expression or function is an early response to steroid and steroid antagonist regulation of proliferation. The cyclin D1 gene is amplified in approximately 15%, and its product overexpressed in 40-50%, of primary breast carcinomas. The strong evidence that cyclin D1 plays a major role in cell cycle control in breast epithelial cells suggests that its deregulated expression may have effects on disease progression and phenotype including sensitivity to endocrine therapies.

Happenstance, circumstance or enemy action: Cyclin D1 in breast, eye and brain

Two recent reports of mice homozygously deleted for cyclin D1 provide unequivocal evidence that the critical G1 cyclin, cyclin D1, is by itself rate-limiting for growth in some mammalian tissues. Cyclin D1 knockout mice are small and exhibit behavioral abnormalities. Specific hypoplasias of retinal and mammary tissues suggest an unusual dependence on cyclin D1 function for tissue growth in those organs. The odd coincidences that cyclin D1 functions as the retinoblastoma gene kinase, together with associations between increased cyclin D1 expression and breast cancer, suggest, but do not prove, a special function of cyclin D1 in those tissues.

Sequential activation of cyclin E and cyclin A gene expression by human papillomavirus type 16 E7 through sequences necessary for transformation

To investigate E7-dependent biochemical changes which are involved in cellular transformation, we analyzed the influence of human papillomavirus type 16 (HPV-16) E7 on the expression of cell cycle regulatory proteins. Expression of E7 in established rodent fibroblasts (NIH 3T3), which was shown to be sufficient for transformation of these cells, leads to constitutive expression of the cyclin E and cyclin A genes in the absence of external growth factors. Surprisingly, expression of the cyclin D1 gene, which encodes a major regulator of G1 progression, is unaltered in E7-transformed cells. In transient transfection experiments, the cyclin A gene promoter is activated by E7 via an E2F binding site. In 14/2 cells, which were used as a model system to analyze the role of HPV-16 E7 in the transformation of primary cells, we observed rapid E7-dependent activation of cyclin E gene expression, which can be uncoupled from activation of the cyclin A gene, since the latter requires additional protein synthesis. E7-driven induction of cyclin E and cyclin A gene expression was accompanied by an increase in the associated kinase activities. Two domains of the E7 oncoprotein, which are designated cd1 and cd2, are essential for transformation of rodent fibroblasts. It is shown here that growth factor-independent expression of the cyclin E gene requires cd2 but not cd1, while activation of cyclin A gene expression requires cd1 function in addition to that of cd2. These data suggest that cyclin A gene expression is controlled by two distinct negative signals, one of which also restricts expression of the cyclin E gene. The ability of E7 to separately override each of these inhibitory signals, via cd1 and cd2, cosegregates with its ability to fully transform rodent fibroblasts. Unlike serum growth factors, E7 induces S-phase entry without activating cyclin D1 gene expression, in keeping with the finding that cyclin D1 function is not required in cells transformed by DNA tumor viruses.

Amplification of chromosome band 11q13 and a role for cyclin D1 in human breast cancer.

In this paper we describe how research on the mouse mammary tumor virus model of breast cancer resulted in the identification of an amplified region of DNA on human chromosome 11 band q13. This amplification occurs in approximately 15% of primary breast cancers. Several candidate oncogenes map within the amplicon but by analysing expression of these genes a strong case can be made for a role for cyclin D1 in tumorigenesis. Immunohistochemical staining indicates that cyclin D1 is expressed at elevated levels in around 40% of breast cancers, including those with the 11q13 amplification. The potential function of cyclin D1 as a regulator of early cell division cycle events would be consistent with a role in neoplasia.

Cyclin D1-mediated inhibition of repair and replicative DNA synthesis in human fibroblasts.

Cyclin D1 is a key regulator of the G1 phase of the cell cycle. Inhibition of cyclin D1 function results in cell cycle arrest, whereas unregulated expression of the protein accelerates G1. Cyclin D1 is localized to the nucleus during G1. We found that during repair DNA synthesis, subsequent to UV-induced DNA damage, G1 cells readily lost their cyclin D1 while the proliferating cell nuclear antigen (PCNA) tightly associated with nuclear structures. Microinjection of cyclin D1 antisense accelerated DNA repair, whereas overexpression of cyclin D1 prevented DNA repair and the relocation of PCNA after DNA damage. Coexpression of cyclin D1 with its primary catalytic subunit, Cdk4, or with Cdk2, also prevented repair. In contrast, coexpression of PCNA, which is also a cyclin D1-associated protein, restored the ability of cells to repair their DNA. Acute overexpression of cyclin D1 in fibroblasts prevented them from entering S phase. Again, these effects were abolished by coexpression of cyclin D1 together with PCNA, but not with Cdk4 or Cdk2. Altogether, these results indicate that down-regulation of cyclin D1 is necessary for PCNA relocation and repair DNA synthesis as well as for the start of DNA replication. Cyclin D1 appears to be an essential component of a G1-checkpoint.

Cyclin D1 protein expression and function in human breast cancer.

Cyclin D1 is a cell-cycle regulator essential for G1 phase progression and a candidate proto-oncogene implicated in pathogenesis of several human tumour types, including breast carcinomas. In spite of the accumulating genetic evidence, however, there are no data regarding abundance and properties of the cyclin D1 protein in breast cancer. We now report aberrant nuclear overexpression/accumulation of the cyclin D1 protein in about half of the 170 primary breast carcinoma specimens analyzed by monoclonal antibody immunohistochemistry, indicating that the frequency of cyclin D1 abnormalities may be considerably higher than previously deduced from DNA amplification studies. A comparison of the expression patterns in matched lesions at different stages of tumour progression revealed that the cyclin D1 protein aberration appears to reflect a relatively early event and that, when acquired by a tumour, it is maintained throughout breast cancer progression including metastatic spread. In both tumour tissues and breast cancer cell lines, the abundance of this protein shows characteristic variations consistent with a cell-cycle oscillation and the peak levels expressed in G1. In all 7 cell lines whose retinoblastoma (Rb) protein is mutant or complexed to SV40 T antigen, exceptionally low levels of cyclin D1 protein and mRNA were found. Antibody-mediated and anti-sense oligonucleotide knockout experiments demonstrate the requirement for the cell-cycle regulatory function of cyclin D1 in breast cancer lines with single or multiple copies of the gene and reveal the absence of such a requirement in the cell lines with Rb defects. Our data are consistent with the notion that the emerging "Rb-cyclin D1 pathway" represents a frequent target of oncogenic abnormalities in breast cancer.

DNA tumor virus oncoproteins and retinoblastoma gene mutations share the ability to relieve the cell's requirement for cyclin D1 function in G1.

The retinoblastoma gene product (pRB) participates in the regulation of the cell division cycle through complex formation with numerous cellular regulatory proteins including the potentially oncogenic cyclin D1. Extending the current view of the emerging functional interplay between pRB and D-type cyclins, we now report that cyclin D1 expression is positively regulated by pRB. Cyclin D1 mRNA and protein is specifically downregulated in cells expressing SV40 large T antigen, adenovirus E1A, and papillomavirus E7/E6 oncogene products and this effect requires intact RB-binding, CR2 domain of E1A. Exceptionally low expression of cyclin D1 is also seen in genetically RB-deficient cell lines, in which ectopically expressed wild-type pRB results in specific induction of this G1 cyclin. At the functional level, antibody-mediated cyclin D1 knockout experiments demonstrate that the cyclin D1 protein, normally required for G1 progression, is dispensable for passage through the cell cycle in cell lines whose pRB is inactivated through complex formation with T antigen, E1A, or E7 oncoproteins as well as in cells which have suffered loss-of-function mutations of the RB gene. The requirement for cyclin D1 function is not regained upon experimental elevation of cyclin D1 expression in cells with mutant RB, while reintroduction of wild-type RB into RB-deficient cells leads to restoration of the cyclin D1 checkpoint. These results strongly suggest that pRB serves as a major target of cyclin D1 whose cell cycle regulatory function becomes dispensable in cells lacking functional RB. Based on available data including this study, we propose a model for an autoregulatory feedback loop mechanism that regulates both the expression of the cyclin D1 gene and the activity of pRB, thereby contributing to a G1 phase checkpoint control in cycling mammalian cells.