Inhibition of G1 cyclin expression in normal rat kidney cells by inostamycin, a phosphatidylinositol synthesis inhibitor

We previously reported that inostamycin, an inhibitor of CDP-DG: inositol transferase, inhibited cell proliferation in normal rat kidney (NRK) cells by blocking cell cycle progression at the G1 phase. In the present paper, we report the effect of inostamycin on the serum-induced activation of Ser/Thr protein kinases that are involved in G1 progression. In quiescent NRK cells mitogen-activated protein kinase (MAP kinase) and casein kinase II were activated within 15 min after serum addition. Neither activation was affected by the treatment with inostamycin. However, in the inostamycin-treated cell, cyclin-dependent kinase 2 (CDK2) failed to be activated after serum stimulation. Since serum-induced expression of cyclin E was also suppressed by inostamycin, this inhibitor would appear to block CDK2 activation by inhibiting cyclin E expression. Furthermore, inostamycin also inhibited cyclin D1 expression induced by serum; and consequently, hyperphosphorylation of retinoblastoma protein (pRB) by RB-kinases such as CDK4 and CDK2 was abolished, which would result in elimination of functional inactivation of pRB. Thus, early G1 arrest in NRK cells by inostamycin is due to the inhibition of cyclin D1 and E expressions.     

Activation of cyclin-dependent kinases by Myc mediates induction of cyclin A, but not apoptosis

The activation of conditional alleles of Myc induces both cell proliferation and apoptosis in serum-deprived RAT1 fibroblasts. Entry into S phase and apoptosis are both preceded by increased levels of cyclin E- and cyclin D1-dependent kinase activities. To assess which, if any, cellular responses to Myc depend on active cyclin-dependent kinases (cdks), we have microinjected expression plasmids encoding the cdk inhibitors p16, p21 or p27, and have used a specific inhibitor of cdk2, roscovitine. Expression of cyclin A, which starts late in G1 phase, served as a marker for cell cycle progression. Our data show that active G1 cyclin/cdk complexes are both necessary and sufficient for induction of cyclin A by Myc. In contrast, neither microinjection of cdk inhibitors nor chemical inhibition of cdk2 affected the ability of Myc to induce apoptosis in serum-starved cells. Further, in isoleucine-deprived cells, Myc induces apoptosis without altering cdk activity. We conclude that Myc acts upstream of cdks in stimulating cell proliferation and also that activation of cdks and induction of apoptosis are largely independent events that occur in response to induction of Myc.     

Cell cycle regulation and differentiation in the human podocyte lineage

Mature podocytes are regarded as growth-arrested cells with characteristic phenotypic features that underlie their function. To determine the relationship between cell cycle regulation and differentiation, the spatiotemporal expression of cyclin A, cyclin B1, cyclin D1, the cyclin-dependent kinase inhibitors (CKIs) p27 and p57, and markers of differentiating podocytes in developing human kidneys was investigated by immunohistochemistry. In S-shaped body stage, Ki-67, a cell proliferation marker that labels the G1/S/G2/M phase, was expressed in the majority (more than 80%) of presumptive podocytes, along with cyclin A (approximately 20% of the Ki-67-positive cells) and cyclin B1 (less than 5% of Ki-67-positive cells) expression. Among these cells), cyclin D1 and CKIs were markedly down-regulated. At the capillary-loop stage, by contrast, CKIs and cyclin D1 were intensely positive in podocytes, whereas no Ki-67, cyclin B1, or cyclin A expression was seen. Moreover, double-immunolabeling and serial-section analysis provided evidence that CKIs and markers specific for differentiating podocytes, namely PHM-5 (podocalyxin-like protein in humans), synaptopodin (a foot process-related protein), and C3b receptor, were co-expressed at the capillary-loop stage. Podocytes were the only cells within the glomeruli that expressed CKIs at immunohistochemically detectable levels. Furthermore, bcl-2 (an apoptosis inhibitory protein) showed a reciprocal expression pattern to that of CKI. These results suggest that 1) the cell cycle of podocytes is regulated by cyclin and CKIs, 2) CKIs may act to arrest the cell cycle in podocytes at the capillary-loop stage, and 3) the specific cell cycle system in podocytes may be closely correlated with their terminal differentiation in humans.     

Cyclin D2 is a moderately oscillating nucleoprotein required for G1 phase progression in specific cell types

To explore regulation and function of cyclin D2, a candidate cell cycle-regulatory proto-oncogene, we examined subcellular localisation, cell type- and cell cycle-dependent expression, and requirement of cyclin D2 protein for G1 progression, in a panel of 40 human normal and cancer cell types. Except for lymphoid cells and sarcoma cell lines, expression of cyclin D2 was considerably more restricted than that of cyclin D1, whereas both D-type cyclin proteins were low or undetectable in cells lacking functional retinoblastoma gene product. In G1 cells, the cyclin D2 protein was more resistant to extraction and localised predominantly to nuclei, whereas it became more soluble and distributed in both nuclei and cytoplasm from G1/S transition onwards. Centrifugal elutriation and multiparameter flow cytometry analyses of several cell types showed moderate cell cycle oscillation with maximum levels of the cyclin D2 protein reached in late G1. Microinjection and/or electroporation of antibodies to cyclin D2 during G1 arrested the cyclin D2-expressing lymphocytes, breast myoepithelium, and U-2-OS sarcoma cells in G1 phase, whereas cyclin D2-negative cell types were unaffected by such treatment. Consistent with the putative proto-oncogenic role of cyclin D2 in specific cell types, our data show that this G1 cyclin has properties closely resembling those of cyclin D1, including the essential positive role in regulation of G1.     

Ginsenoside-Rh2 blocks the cell cycle of SK-HEP-1 cells at the G1/S boundary by selectively inducing the protein expression of p27kip1

The mechanism of action by which ginsenoside-Rh2 (G-Rh2) suppresses the proliferation of SK-HEP-1 cells is reported. The results from flow cytometric analyses show that G-Rh2 arrested the cell cycle at the G1/S transition phase. The cyclin E-dependent kinase activity which had been immunoprecipitated with cyclin E-specific antibody was down-regulated in the cells in response to G-Rh2. The IC50 value required to down-regulate the kinase activity by 50% was approximately 0.75 microM. Immunoblotting analyses show that G-Rh2 selectively induced the expression of p27kip1 in a dose-dependent manner whereas it had no effect on the levels of cyclin E, cdk2, and p21WAF1. In addition, our data show that G-Rh2 reduced the protein levels of cdc25A at doses higher than 10 microM. Collectively, these data suggest that ginsenoside-Rh2 arrests the cell cycle at the G1/S transition phase by selectively inducing protein expression of p27Kip1 and, as a consequence, down-regulating cyclin E-dependent kinase activity.     

Induction of cell proliferation in quiescent NIH 3T3 cells by oncogenic c-Raf-1

The c-Raf-1 kinase is activated by different mitogenic stimuli and has been shown to be an important mediator of growth factor responses. Fusion of the catalytic domain of the c-Raf-1 kinase with the hormone binding domain of the estrogen receptor (deltaRaf-ER) provides a hormone-regulated form of oncogenic activated c-Raf-1. We have established NIH 3T3 cells stably expressing a c-Raf-1 deletion mutant-estrogen receptor fusion protein (c-Raf-1-BxB-ER) (N-BxB-ER cells). The transformed morphology of these cells is dependent on the presence of the estrogen antagonist 4-hydroxytamoxifen. Addition of 4-hydroxytamoxifen to N-BxB-ER cells arrested by density or serum starvation causes reentry of these cells into cell proliferation. Increases in the cell number are obvious by 24 h after activation of the oncogenic c-Raf-1 protein in confluent cells. The onset of proliferation in serum-starved cells is further delayed and takes about 48 h. In both cases, the proliferative response of the oncogenic c-Raf-1-induced cell proliferation is weaker than the one mediated by serum and does not lead to exponential growth. This is reflected in a markedly lower expression of the late-S- and G2/M-phase-specific cyclin B protein and a slightly lower expression of the cyclin A protein being induced at the G1/S transition. Oncogenic activation of c-Raf-1 induces the expression of the heparin binding epidermal growth factor. The Jnk1 kinase is putatively activated by the action of the autocrine growth factor. The kinetics of Jnk1 kinase activity is delayed and occurs by a time when we also detect DNA synthesis and the expression of the S-phase-specific cyclin A protein. This finding indicates that oncogenic activation of the c-Raf-1 protein can trigger the entry into the cell cycle without the action of the autocrine growth factor loop. The activation of the c-Raf-1-BxB-ER protein leads to an accumulation of high levels of cyclin D1 protein and a repression of the p27Kip1 cyclin-dependent kinase inhibitor under all culture conditions tested.     

TGF-beta1 effects on proliferation of rat intestinal epithelial cells are due to inhibition of cyclin D1 expression

Transforming growth factor-beta 1 (TGF-beta1) arrests intestinal epithelial cells (RIE-1 and IEC-6) in the G1 phase of the cell cycle and inhibits cyclin D1 expression. This report describes experiments designed to elucidate the mechanism of cyclin D1 inhibition and to determine whether inhibition of cyclin D1 expression is the cause, rather than the result, of TGF-beta1-mediated cell cycle arrest. TGF-beta1 inhibition of IEC-6 cell proliferation was associated with a decrease in the abundance of cyclin D1/Cdk4 complexes and a corresponding decrease in Cdk4-dependent phosphorylation of the retinoblastoma protein. Metabolic labeling studies indicated that TGF-beta1 inhibited cyclin D1 synthesis without altering the rate of cyclin D1 protein degradation. Cyclin D1 antisense oligonucleotides blocked serum-stimulated induction of cyclin D1 and DNA synthesis, whereas cyclin D1 sense oligonucleotides had no effect. RIE-1 cells were engineered to overexpress human cyclin D1 under the control of a tetracycline-repressible promoter. These cells entered S phase in the presence of TGF-beta1 only when human cyclin D1 was derepressed by the withdrawal of tetracycline. These data indicate that TGF-beta1 inhibits the synthesis of cyclin D1 in gut epithelial cells and that this inhibition is the cause, rather than the result, of TGF-beta1-mediated arrest of intestinal epithelial cell proliferation.     

A rate limiting function of cdc25A for S phase entry inversely correlates with tyrosine dephosphorylation of Cdk2

The cdc25A phosphatase removes inhibitory phosphates from threonine-14 and tyrosine-15 of cyclin dependent kinase-2 (cdk2) in vitro, and it is therefore widely assumed that cdc25A positively regulates cyclin E- and A-associated cdk2 activity at the G1 to S phase transition of the mammalian cell division cycle. Human cdc25A was introduced into mouse NIH3T3 fibroblasts co-expressing a form of the colony-stimulating factor-1 (CSF-1) receptor that is partially defective in transducing mitogenic signals. Cdc25A enabled these cells to form colonies in semisolid medium containing serum plus human recombinant CSF-1 in a manner reminiscent of cells rescued by c-myc. However, cdc25A-rescued cells could not proliferate in chemically defined medium containing CSF-1 and continued to require c-myc function for S phase entry. When contact-inhibited cells overexpressing cdc25A were dispersed and stimulated to synchronously enter the cell division cycle, they entered S phase 2-3 h earlier than their parental untransfected counterparts. Shortening of G1 phase temporally correlated with more rapid degradation of the cdk inhibitor p27Kip1 and with premature activation of cyclin A-dependent cdk2. Paradoxically, tyrosine phosphorylation of cdk2 increased considerably as cells entered S phase, and cdc25A overexpression potentiated rather than diminished this effect. At face value, these results are inconsistent with the hypothesis that cdc25A acts directly on cdk2 to activate its S phase promoting function.     

Cyclin E2, a novel G1 cyclin that binds Cdk2 and is aberrantly expressed in human cancers

A novel cyclin gene was discovered by searching an expressed sequence tag database with a cyclin box profile. The human cyclin E2 gene encodes a 404-amino-acid protein that is most closely related to cyclin E. Cyclin E2 associates with Cdk2 in a functional kinase complex that is inhibited by both p27(Kip1) and p21(Cip1). The catalytic activity associated with cyclin E2 complexes is cell cycle regulated and peaks at the G1/S transition. Overexpression of cyclin E2 in mammalian cells accelerates G1, demonstrating that cyclin E2 may be rate limiting for G1 progression. Unlike cyclin E1, which is expressed in most proliferating normal and tumor cells, cyclin E2 levels were low to undetectable in nontransformed cells and increased significantly in tumor-derived cells. The discovery of a novel second cyclin E family member suggests that multiple unique cyclin E-CDK complexes regulate cell cycle progression.     

Hormone-induced proliferation and differentiation of granulosa cells: a coordinated balance of the cell cycle regulators cyclin D2 and p27Kip1

The proliferation and terminal differentiation of granulosa cells are critical for normal follicular growth, ovulation, and luteinization. Therefore, the in situ localization and hormonal regulation of cell cycle activators (cyclin D1, D2, and D3) and cell cycle inhibitors (p27Kip1 and p21Cip1) were analyzed in ovaries of mice and rats at defined stages of follicular growth and differentiation. Cyclin D2 mRNA was specifically localized to granulosa cells of growing follicles, while cyclin D1 and cyclin D3 were restricted to theca cells. In hypophysectomized (H) rats, cyclin D2 mRNA and protein were increased in granulosa cells by treatment with estradiol or FSH and were increased maximally by treatment with both hormones. In serum-free cultures of rat granulosa cells, cyclin D2 mRNA was rapidly elevated in response to FSH, forskolin, and estradiol, indicating that estradiol as well as cAMP can act directly and independently to increase cyclin D2 expression. The levels of p27Kip1 protein were not increased in response to estradiol or FSH. In contrast, when ovulatory doses of human CG (LH) were administered to hormonally primed H rats to stimulate luteinization, cyclin D2 mRNA and protein were rapidly decreased and undetectable within 4 h, specifically in granulosa cells of large follicles. Also in response to LH, the expression of the cell cycle inhibitor p27Kip1 was induced between 12 and 24 h (p21Cip1 was induced within 4 h) and remained elevated specifically in luteal tissue. A critical role for cyclin D2 in the hormone-dependent phase of follicular growth is illustrated by the ovarian follicles of cyclin D2-/- mice, which do not undergo rapid growth in response to hormones, but do express markers of FSH/LH action, cell cycle exit, and terminal differentiation. Collectively, these data indicate that FSH and estradiol regulate granulosa cell proliferation during the development of preovulatory follicles by increasing levels of cyclin D2 relative to p27Kip1 and that LH terminates follicular growth by down-regulating cyclin D2 concurrent with up-regulation of p27Kip1 and p21Cip1.     

IL-2-dependent induction of G1 cyclins in primary T cells is not blocked by rapamycin or cyclosporin A

Autocrine stimulation of the IL-2 receptor (IL-2R) is required for commitment of a T cell to enter the cell cycle and may involve transmission of the IL-2R signal to cell cycle control proteins. Candidates for such proteins are the D-type cyclins which are expressed in G1. Short-term cultures of primary human T cells were used to show that expression of cyclins D2 and D3 is regulated by IL-2 in a concentration- and time-dependent manner. Cyclin D2 RNA was induced rapidly to peak levels well before initiation of DNA synthesis and gradually declined during the remainder of G1. Cyclin D3 RNA and protein showed a slower induction during G1 to maximal levels as cells initiated DNA synthesis that remained high throughout S phase. Induction of cyclins D2 and D3 was independent of the cyclosporin A-sensitive calcineurin pathway and of rapamycin-sensitive pathways, despite the ability of rapamycin to severely inhibit entry into S phase. These observations suggest that cyclins D2 and D3 may monitor the IL-2R signal but that their induction does not guarantee entry into S phase. Rapamycin was found to target a pathway late in G1 that is distal to induction of D-type cyclin gene expression but proximal to DNA replication, perhaps involving the function of the D-type cyclin proteins or their associated kinases.     

Expression of cyclins A, D2 and D3 in individual normal mitogen stimulated lymphocytes and in MOLT-4 leukemic cells analyzed by multiparameter flow cytometry

Cyclins are regulatory subunits of the cyclin dependent kinases (CDKs), the enzymes that drive the cell through the respective phases and check-points of the cell cycle. The expression of cyclins in non-tumor cells, regulated by timely induction of their synthesis and proteolysis, is scheduled, occurring at discrete periods of the cell cycle. Using multiparameter flow cytometry we have recently observed that expression of cyclins B1 and E in individual normal lymphocytes mitogenically stimulated by phytohemagglutinin (PHA) and lymphocytic leukemic MOLT-4 cells was similar, restricted to particular phases of the cycle: cyclin B1 was detected only in G2+M- and cyclin E in late G1 and early S-phase cells. In the present study we have measured the expression of cyclins A, D2 and D3 in these cells. The presence of cyclin A was restricted to late S and G2 phases, both in the case of lymphocytes and of MOLT-4 cells. Over 95% of the non-stimulated lymphocytes were both cyclin D2 and D3 negative. Mitogenic stimulation with PHA-induced expression of cyclins D2 and D3 in over 50% cells, which corresponds to the percentage of cells that respond to this mitogen in cultures. Expression of these proteins peaked between 8 and 24 h after addition of PHA, and then decreased at the time of cell entrance to S. During exponential growth (48-72 h after stimulation with PHA) expression of the D-type cyclins was diminished: only between 5-10% of the lymphocytes had levels of cyclin D3 as high as G1 cells between 8-24 h after PHA stimulation. Populations of proliferating lymphocytes and MOLT-4 cells were very heterogeneous in terms of expression of D-type cyclins by individual cells. While expression of cyclin D2 in exponentially growing MOLT-4 cells was similar to that of proliferating lymphocytes, the percent of cells expressing cyclin D3 as well as the degree of expression, was higher in MOLT-4 cells, regardless of the phase of the cycle. These results, with our earlier observations of the untimely expression of cyclins B1 and E in several other tumor lines, suggest that altered expression of cyclins may be a frequent feature of malignancy.     

Cyclin E2: a novel CDK2 partner in the late G1 and S phases of the mammalian cell cycle

We report here the cloning and characterization of human and mouse cyclin E2, which define a new subfamily within the vertebrate E-type cyclins, while all previously identified family-members belong to the cyclin El subfamily. Cyclin E2/CKD2 and cyclin E/CDK2 complexes phosphorylate histone H1 in vitro with similar specific activities and both are inhibited by p27Kip1. Cyclin E2 mRNA levels in human cells oscillate throughout the cell cycle and peak at the G1/S boundary, in parallel with the cyclin E mRNA. In cells, cyclin E2 is complexed with CDK2, p27 and p21. Like cyclin E, cyclin E2 is an unstable protein in vivo and is stabilized by proteasome inhibitors. Cyclin E2-associated kinase activity rises in late G1 and peaks very close to cyclin E activity. In two malignantly transformed cell lines, cyclin E2 activity is sustained throughout S phase, while cyclin E activity has already declined and cyclin A activity is only beginning to rise. We speculate that cyclin E2 is not simply redundant with cyclin E, but may regulate distinct rate-limiting pathway(s) in G1-S control.     

G1 arrest of U937 cells by onconase is associated with suppression of cyclin D3 expression, induction of p16INK4A, p21WAF1/CIP1 and p27KIP and decreased pRb phosphorylation

Onconase is a 12 kDa protein homologous to pancreatic RNase A isolated from amphibian oocytes which shows cytostatic and cytotoxic activity in vitro, inhibits growth of tumors in mice and is in phase III clinical trials. The present study was aimed to reveal mechanisms by which onconase perturbs the cell cycle progression. Human histiocytic lymphoma U937 cells were treated with onconase and expression of cyclins D3 and E, as well as of the cyclin-dependent kinase inhibitors (CKIs) p16INK4A, p21WAF1/CIP1 and p27KIP1 (all detected immunocytochemically) was measured by multiparameter flow cytometry, in relation to the cell cycle position. Also monitored was the status of phosphorylation of retinoblastoma protein (pRb) by a novel method utilizing mAb which specifically detects underphosphorylated pRb in individual cells. Cell incubation with 170 nM onconase for 24 h and longer led to their arrest in G1 which was accompanied by a decrease in expression of cyclin D3, no change in cyclin E, and enhanced expression of all three CKIs. pRb was underphosphorylated in the onconase arrested G1 cells but was phosphorylated in the cells that were still progressing through S and G2/M in the presence of onconase. The cytostatic effect of onconase thus appears to be mediated by downregulation of cyclin D3 combined with upregulation of p27KIP1, p16INK4A and p21WAF1/CIP1, the events which may prevent phosphorylation of pRb during G0/1 and result in cell arrest at the restriction point controlled by Cdk4/6 and D type cyclins.     

Total hip arthroplasty with use of an acetabular reinforcement ring in patients who have congenital dysplasia of the hip. Results at five to fifteen years

In this report, we explore the mechanisms underlying cell cycle progression in T cells stimulated with an altered peptide ligand (APL) versus wild-type peptide. APL stimulation did not induce proliferation compared to wild-type peptide stimulation. To determine the point at which cell cycle progression is blocked, we have examined molecules responsible for regulating the retinoblastoma tumor suppressor gene product, pRb, which in its active state prevents G1/S progression. The majority of cells stimulated with an APL did not progress beyond G1; however, a small population did make the G1/S transition. These few cells passed the late G1 restriction point, divided and subsequently arrested at the next G1 phase. The lack of sustained signaling events following stimulation with an APL failed to induce cyclin E:cdk2 activity, a regulator which hyper-phosphorylates and inactivates pRb. Exogenous IL-2 addition did not compensate for the lack of proliferation following APL stimulation. Furthermore, the inability of the cells to enter S phase during partial T cell activation cannot be accounted for by p27Kip1 inhibition of cyclin E:cdk2 complexes. Upon APL stimulation, an increase in association of p27Kip1 with cyclin E:cdk2 complex was not observed, suggesting that instead, decreased cyclin E:cdk complex formation might contribute to the failure to progress from G1/S. Therefore, while for a majority of cells, wild-type stimulation results in cell cycle progression, APL stimulation is not sufficient to drive cells beyond G1.     

p21WAF1/CIP1/SDI1 is elevated through a p53-independent pathway by mimosine

Tumor suppressor p53 is a nuclear protein that is induced by DNA damage and is involved in G1 and G2 phase control of the cell cycle. p21WAF1/CIP1/SDI1 (p21), a cyclin-dependent kinase inhibitor, is a downstream target and effector of p53 to induce G1 arrest. Mimosine is a potent reversible late G1 phase blocker of the cell cycle. In this study, we showed that mimosine can increase both p21 mRNA and protein levels, indirectly inhibit cyclin E-associated kinase activity without affecting the cyclin E protein level, block human breast cancer cells (21PT) in the late G1 phase of the cell cycle, and induce a p53-independent p21 pathway in these cells. These results support the possibility of restoring a G1 checkpoint by use of mimosine. They also suggest that the mechanism of the effect of mimosine is complex and may have more than one target in the cell.     

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.     

Primary keratinocytes have an adhesion dependent S phase checkpoint that is absent in immortalized cell lines

In order to understand the mechanism through which loss of anchorage inhibits growth, we have investigated the events that occur in murine keratinocytes upon substratum detachment utilizing both primary cells and established immortalized cell lines. Our data has revealed that while both primary and immortalized cells undergo growth arrest in suspension, the nature of this arrest is markedly different. Primary cells exhibit a growth arrest that is characterized by rapid cessation of DNA synthesis resulting in a static S phase population. In contrast, an immortalized non-tumorgenic cell line, Balb MK, exhibits growth arrest as measured by thymidine incorporation, but does not prevent cells that have entered S phase from continuing into G2/M, and accumulating as a 4N population. In contrast to both primary and MK cells, the tumorigenic SLC-1 cell line did not accumulate in a specific cell cycle interval and were able to undergo continuous growth in suspension. Examination of cyclin A protein and its associated activity revealed that cyclin A protein levels decreased in primary but not MK cells; suggesting the continued presence of cyclin A may allow continued DNA synthesis observed in MK cells. Furthermore, we demonstrate the accumulation of suspension cultured MK cells as a 4N population correlated with the loss of cyclin A/cdk2 kinase activity, which in turn occurred through the accumulation of p27kip1, whereas neither p27kip1 accumulation nor loss of cyclin A activity was observed in SLC-1 cells. Our results clearly reveal that the process of growth inhibition in suspension cultured cells may occur in several forms with distinct characteristics that are dependent on the status of cyclin/cdk complexes and CKI proteins. Tumor derived cells in suspension did not lose cyclin A dependent kinase activity and thus continued to grow and divide.