Levels and interactions of p27, cyclin D3, and CDK4 during the formation and maintenance of the corpus luteum in mice

The cyclin-dependent kinase (CDK) inhibitor p27, the regulator of the cell cycle, is required for proper functioning of luteinizing/luteinized cells in vivo. Since different members of the CDK family may be targeted by p27 during luteinization-associated cell cycle exit, this in vivo study further analyzed the organization of the network of cell cycle regulators that may underlie both the establishment and maintenance of the luteal phenotype. Most importantly, it shows that the luteinization process is associated with down-regulation of CDK2 and cyclin D1, and up-regulation of p27 and cyclin D3. Both p27 and cyclin D3 proteins not only accumulated during initial phases of luteinization, but they remained elevated until termination of the luteal function. Along with its accumulation, p27 lost physical contact with CDK2 and instead became associated with CDK4. In fully luteinized cells, all cyclin D3 was incorporated into complexes with p27, some complexes being p27/cyclin D3/CDK4 trimers. Despite the significant amounts of CDK4 and CDK6, only nonphosphorylated forms of retinoblastoma protein were detectable in fully luteinized cells. Together, our data indicate that while inhibition of proliferation is underlaid by the progressive loss of positive regulators of the cell cycle, including cyclins and CDK2, maintenance of the luteal phenotype is driven by up-regulated levels of p27 and cyclin D3, at least partially owing to formation of p27/cyclin D3/CDK4 trimers.     

Evidence for coordinated interaction of cyclin D3 with p21 and cdk6 in directing the development of uterine stromal cell decidualization and polyploidy during implantation.

Uterine decidualization, characterized by stromal cell proliferation, and differentiation into specialized type of cells (decidual cells) with polyploidy, during implantation is critical to the pregnancy establishment in mice. The mechanisms by which the cell cycle events govern these processes are poorly understood. The cell cycle is tightly regulated at two particular checkpoints, G1-S and G2-M phases. Normal operation of these phases involves a complex interplay of cyclins, cyclin-dependent kinases (cdks) and cdk inhibitors (CKIs). We previously observed that upregulation of uterine cyclin D3 at the implantation site is tightly associated with decidualization in mice. To better understand the role of cyclin D3 in this process, we examined cell-specific expression and associated interactions of several cell cycle regulators (cyclins, cdks and CKIs) specific to different phases of the cell cycle during decidualization in mice. Among the various cell cycle molecules examined, coordinate expression and functional association of cyclin D3 with cdk4 suggest a role for proliferation and, that of cyclin D3 with p21 and cdk6 is consistent with the development of polyploidy during stromal cell decidualization.     

Differential regulation of cyclin D1 and D3 expression in the control of astrocyte proliferation induced by endothelin-1

We have previously shown that the mitogenic effect of endothelin-1 (ET-1) in primary astrocytes is dependent on activation of both extracellular signal-regulated kinase (ERK)- and cytoskeleton (CSK)-dependent pathways. In this study, we evaluated the contribution of each of these pathways to the expression and activation of proteins mediating cell cycle progression. Our results suggest that ET-1-induced expression of cyclins D1 and D3 is dependent on the ERK- and CSK-dependent pathways, respectively; moreover, a decrease in the levels of the cyclin-dependent kinase inhibitor (CKI) p27 was observed as a consequence of ERK activation. Expression of both cyclins D1 and D3 together with a decrease in the p27 levels are essential for retinoblastoma protein (pRB) phosphorylation and cyclin A expression. Furthermore, the molecular events responsible for cell-cell contact inhibition of astrocyte proliferation were found to be independent of the mitogenic pathways leading to D-type cyclin expression. Cell growth arrest in confluent astrocytes was found to be correlated with increased expression of CKI p21, resulting in inhibition of D-type cyclin-associated pRB phosphorylation and cyclin A expression. Taken together, these results indicate that cyclins D1 and D3, which constitute the key mediators of the proliferative response of primary astrocytes to ET-1, are regulated by distinct signaling pathways.     

The role of p27(Kip1) in maintaining the levels of D-type cyclins in vivo

This in vivo study employs p27-deficient mice to investigate the significance of p27 for the metabolism of D-type cyclins in differentiated cells. The absence of p27 results in decreased levels of cyclins D2 and/or D3 in some organs. As demonstrated on Leydig cells of testis, such dependency is only restricted to certain cell types including terminally differentiated ones, and the absence of p27 in these cells can interfere with their differentiation. The decrease of cyclin D caused by the absence of p27 equals the amount of cyclin D physically associated with p27 in non-mutant animals. The data indicate that it is the proportion of p27-associated cyclin D that determines the response to p27 deficiency. Cells in which the level of D-type cyclin is dependent on p27 do not up-regulate the activity of their CDK2 and CDK4 upon loss of p27, and these cells have a negligible amount of p27 bound to CDK2 and/or cyclin A/E under normal conditions. Together, the findings suggest the existence of a dual role for p27, one being a classical regulation of cell cycle via inhibition of cyclin-dependent kinases (CDK), and the other being participation in the establishment and/or maintenance of differentiated status that is realized in conjunction with D-type cyclins.     

Transforming activity of Fbxo7 is mediated specifically through regulation of cyclin D/cdk6

D cyclins (D1, D2 and D3) and their catalytic subunits (cyclin-dependent kinases cdk4 and cdk6) have a facilitating, but nonessential, role in cell cycle entry. Tissue-specific functions for D-type cyclins and cdks have been reported; however, the biochemical properties of these kinases are indistinguishable. We report that an F box protein, Fbxo7, interacted with cellular and viral D cyclins and distinguished among the cdks that bind D-type cyclins, specifically binding cdk6, in vitro and in vivo. Fbxo7 specifically regulated D cyclin/cdk6 complexes: Fbxo7 knockdown decreased cdk6 association with cyclin and its overexpression increased D cyclin/cdk6 activity and E2F activity. Fbxo7 interacted with p27, but its enhancement of cyclin D/cdk6 activity was p21/p27 independent. Fbxo7 overexpression transformed murine fibroblasts, rendering them tumorigenic in athymic nude mice. Transformed phenotypes were dependent on cdk6, as knockdown of cdk6 reversed them. Fbxo7 was highly expressed in epithelial tumors, but not in normal tissues, suggesting that it may have a proto-oncogenic role in human cancers.     

The expression and activity of D-type cyclins in F9 embryonal carcinoma cells: modulation of growth by RXR-selective retinoids

The growth rate of malignant F9 embryonal carcinoma cells slows considerably following all-trans-retinoic acid-induced differentiation into benign parietal endoderm. To determine the mechanism of this process, we examined the expression of cyclins D1, D2, and D3 and the activity of their associated kinases. Cyclin D1 and D3 mRNA levels decreased during complete differentiation induced by all-trans-retinoic acid and dibutyryl cAMP, while the levels of cyclin D2 and the cyclin-dependent kinase (Cdk) inhibitor p27 mRNAs increased. Ultimately, terminally differentiated cells possessed 50% of the Cdk4-associated kinase activity observed in undifferentiated cells. Since numerous genes are differentially regulated during parietal endoderm differentiation, it is difficult to determine whether retinoic acid affects cell cycle gene expression directly or if these changes are caused by differentiation. We found that the retinoid X receptor (RXR)-selective agonists LG100153 and LG100268 significantly inhibited F9 cell growth without causing overt terminal differentiation as assessed by anchorage-independent growth and differentiation-associated gene expression. As seen in cells induced to differentiate by the RAR agonist all-trans-retinoic acid, RXR activation led to an increase in the number of cells in G1 phase. RXR agonists also sharply induced the levels of the Cdk regulatory subunits, cyclin D2 and D3. However, Cdk4-dependent kinase activity was reduced by RXR-selective retinoid treatment. These observations suggest that some retinoids can directly inhibit proliferation and regulate Cdk4-dependent kinase activity without inducing terminal differentiation.     

Ectopic expression of cyclin D1 but not cyclin E induces anchorage-independent cell cycle progression.

Normal fibroblasts are dependent on adhesion to a substrate for cell cycle progression. Adhesion-deprived Rat1 cells arrest in the G1 phase of the cell cycle, with low cyclin E-dependent kinase activity, low levels of cyclin D1 protein, and high levels of the cyclin-dependent kinase inhibitor p27kip1. To understand the signal transduction pathway underlying adhesion-dependent growth, it is important to know whether prevention of any one of these down-regulation events under conditions of adhesion deprivation is sufficient to prevent the G1 arrest. To that end, sublines of Rat1 fibroblasts capable of expressing cyclin E, cyclin D1, or both in an inducible manner were used. Ectopic expression of cyclin D1 was sufficient to allow cells to enter S phase in an adhesion-independent manner. In contrast, cells expressing exogenous cyclin E at a level high enough to overcome the p27kip1-imposed inhibition of cyclin E-dependent kinase activity still arrested in G1 when deprived of adhesion. Moreover, expression of both cyclins D1 and E in the same cells did not confer any additional growth advantage upon adhesion deprivation compared to the expression of cyclin D1 alone. Exogenously expressed cyclin D1 was down-regulated under conditions of adhesion deprivation, despite the fact that it was expressed from a heterologous promoter. The ability of cyclin D1-induced cells to enter S phase in an adhesion-independent manner disappears as soon as cyclin D1 proteins disappear. These results suggest that adhesion-dependent cell cycle progression is mediated through cyclin D1, at least in Rat1 fibroblasts.     

Down-regulation of p27Kip1 promotes cell proliferation of rat neonatal cardiomyocytes induced by nuclear expression of cyclin D1 and CDK4. Evidence for impaired Skp2-dependent degradation of p27 in terminal differentiation

Mammalian cardiomyocytes lose their capacity to proliferate during terminal differentiation. We have previously reported that the expression of nuclear localization signal-tagged cyclin D1 (D1NLS) and its partner cyclin-dependent kinase 4 (CDK4) induces proliferation of rat neonatal cardiomyocytes. Here we show that the D1NLS/CDK4 cells, after their entry into the cell cycle, accumulated cyclin-dependent kinase inhibitor p27 in the nuclei and decreased the cyclin-dependent kinase 2 (CDK2) activity, leading to early cell cycle arrest. Biochemical analysis demonstrated that Skp2-dependent p27 ubiquitylation was remarkably suppressed in cardiomyocytes, whereas Skp2, a component of Skp1-Cullin-F-box protein ubiquitin ligase, was more actively ubiquitylated compared with proliferating rat fibroblasts. Specific degradation of p27 by co-expressing Skp2 or p27 small interfering RNA caused an increase of CDK2 activity and overrode the limited cell cycle. These data altogether indicate that the impaired Skp2-dependent p27 degradation is causally related to the loss of proliferation in cardiomyocytes. This provides a novel insight in understanding the molecular mechanism by which mammalian cardiomyocytes cease to proliferate during terminal differentiation.     

Identification of G1 kinase activity for cdk6, a novel cyclin D partner.

A family of vertebrate cdc2-related kinases has been identified, and these kinases are candidates for roles in cell cycle regulation. Here, we show that the human PLSTIRE gene product is a novel cyclin-dependent kinase, cdk6. The cdk6 kinase is associated with cyclins D1, D2, and D3 in lysates of human cells and is activated by coexpression with D-type cyclins in Sf9 insect cells. Furthermore, we demonstrate that endogenous cdk6 from human cell extracts is an active kinase which can phosphorylate pRB, the product of the retinoblastoma tumor suppressor gene. The activation of cdk6 kinase occurs during mid-G1 in phytohemagglutinin-stimulated T cells, well prior to the activation of cdk2 kinase. This timing suggests that cdk6, and by analogy its homolog cdk4, links growth factor stimulation with the onset of cell cycle progression.     

Genetic evidence for the interactions of cyclin D1 and p27(Kip1) in mice

The cell cycle of cultured cells appears to be regulated by opposing actions of the cyclins together with their partners, the cyclin-dependent kinases (Cdk), and their inhibitors (Cki). Consistent with this situation null mutations in the genes for cyclin D1 and Cki p27(Kip1) in mice give opposite phenotypes of dwarfism and gigantism. To test their genetic interactions, we generated mice nullizygous for both genes. Correction of cyclin D1 or p27 null to wild-type phenotypes was observed for many but not all traits. These included, for cyclin D1(-/-) mice, body weight, early lethality, retinal hypoplasia, and male aggressiveness and, for p27(-/-) mice, body weight, retinal hyperplasia, and embryo implantation. p27(-/-) traits that were not corrected were the aberrant estrus cycles, luteal cell proliferation, and susceptibility to pituitary tumors. This mutual correction of these phenotypes is the first genetic demonstration of the interaction of these inhibitory and stimulatory cell cycle-regulatory molecules in vivo. The molecular basis for the correction was analyzed in the neonatal retina. Retinal cellularity was rescued in the cyclin D1 null mouse by loss of p27 with only a partial restoration of phosphorylation of retinoblastoma protein (Rb) and Cdk4 activity but with a dramatic elevation of Cdk2 activity. Our data provide in vivo genetic validation of cell culture experiments that indicated that p27 acts as a negative regulator of cyclin E-Cdk2 activity and that it can be titrated away by cyclin D-Cdk4 complexes. It also supports the suggestion that the cyclin E/Cdk2 pathway can largely bypass Rb in regulating the cell cycle in vivo.     

Cyclic AMP-dependent phosphorylation of cyclin D3-bound CDK4 determines the passage through the cell cycle restriction point in thyroid epithelial cells

According to current concepts, the cell cycle commitment after restriction (R) point passage requires the sustained stimulation by mitogens of the synthesis of labile d-type cyclins, which associate with cyclin-dependent kinase (CDK) 4/6 to phosphorylate pRb family proteins and sequester the CDK inhibitor p27kip1. In primary cultures of dog thyroid epithelial cells, the cAMP-dependent cell cycle induced by a sustained stimulation by thyrotropin or forskolin differs from growth factor mitogenic pathways, as cAMP does not upregulate d-type cyclins but increases p27 levels. Instead, cAMP induces the assembly of required cyclin D3-CDK4 complexes, which associate with nuclear p27. In this study, the arrest of forskolin stimulation rapidly slowed down the entry of dog thyrocytes into S phase and the phosphorylation of pRb family proteins. The pRb kinase activity, but not the formation, of the cyclin D3-CDK4-p27 complex was strongly reduced. Using two-dimensional gel electrophoresis, a phosphorylated form of CDK4 was separated. It appeared in response to forskolin and was bound to both cyclin D3 and p27, presumably reflecting the activating Thr-172 phosphorylation of CDK4. Upon forskolin withdrawal or after cycloheximide addition, this CDK4 phosphoform unexpectedly persisted in p27 complexes devoid of cyclin D3 but it disappeared from the more labile cyclin D3 complexes. These data demonstrate that the assembly of the cyclin D3-CDK4-p27 holoenzyme and the subsequent phosphorylation and activation of CDK4 depend on distinct cAMP actions. This provides a first example of a crucial regulation of CDK4 phosphorylation by a mitogenic cascade and a novel mechanism of cell cycle control at the R point.     

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.     

Inhibition of D1, D2, and a cyclin expression in HL-60 cells by the lipid peroxydation product 4-hydroxynonenal

4-Hydroxynonenal (HNE), a product of lipid peroxidation, is an highly reactive aldehyde that, at concentration similar to those found in normal cells, blocks proliferation and induces a granulocytic-like differentiation in HL-60 cells. These effects are accompained by a marked increase in the proportion G0/G1 cells. The mechanisms of HNE action were investigated by analyzing the expression of the cyclins and cyclin-dependent protein kinases (CDKs), controlling the cell cycle progression. Data obtained by exposing cells to dimethyl sulfoxide (DMSO) were used for comparison. 4-Hydroxynonenal downregulated both mRNA and protein contents of cyclins D1, D2, and A until 24 h from the treatments, whereas DMSO inhibited cyclin D1 and D2 expression until the end of experiment (2 days) and induces an increase of cyclin A until 1 day. Cyclins B and E, and protein kinase CDK2 and CDK4 expressions were not affected by HNE, whereas DMSO induced an increase of cyclin E, B, and CDK2 from 8 h to 1 day. These data are in agreement with previous results indicating a different time-course of accumulation in G0/G1 phases of cells treated with HNE and DMSO and suggest that the HNE inhibitory effect on proliferation and cell cycle progression may depend by the downregulation of D1, D2, and A cyclin expression.     

Threshold expression of cyclin E but not D type cyclins characterizes normal and tumour cells entering S phase

Complexes of cyclin-dependent kinases (cdk) and their partner cyclins drive the cell through the cell cycle, each such complex phosphorylating a distinct set of proteins at a particular check-point or phase of the cycle. Immunocytochemical detection of cyclins combined with measurement of cellular DNA content by flow cytometry makes it possible to relate expression of each of these proteins with the actual cell cycle position, without the necessity of cell synchronization. In the present study, we have investigated expression of E and D type cyclins in G₁ cells and in cells entering S phase, in eight different human hematopoietic and solid tumour cell lines (two leukaemias, a lymphoma, three breast carcinomas, a colon carcinoma and a bladder transitional cell carcinoma) during their exponential phase of growth, as well as in normal mitogen stimulated lymphocytes. In all the cell types studied, the average level of D type cyclin expression was invariable throughout the cell cycle. A great intercellular variability, in particular of the G₁ cell subpopulations, and the presence of a large fraction of G₁, S and G₂+ M cells that were cyclin D negative (20–40% in tumour cell lines and about 80% among lymphocytes), were other characteristic features of D type cyclin expression. In contrast to D type cyclins, the expression of cyclin E was discontinuous during the cycle, peaking at the time of cell entrance to S. Also, a well defined threshold in expression of cyclin E characterized cells that were entering S phase, and virtually no cyclin E negative cells were seen during the early portion of S phase. The data indicate that while cell entrance to S phase is unrelated to expression of D type cyclins (at the time of entrance), accumulation of cyclin E up to critical level is a prerequisite for initiation of DNA replication. The great intercellular variability in expression of D type cyclins and their invariant average level across the cell cycle suggest that these cyclins, in addition to their acknowledged function in promoting cell progression through mid- to late-G₁ may have other role(s), related or unrelated to the cell cycle progression. The presence of a large number of D type cyclin negative cells in all phases of the cycle suggests that during exponential growth the cells may not express this protein and yet may traverse the cycle, including G₁ phase.     

The cyclin D3-CDK4-p27kip1 holoenzyme in thyroid epithelial cells: activation by TSH, inhibition by TGFbeta, and phosphorylations of its subunits demonstrated by two-dimensional gel electrophoresis

The cAMP-dependent mitogenic stimulation elicited by thyroid-stimulating hormone (TSH) in primary cultures of canine thyroid epithelial cells is unique as it upregulates the cyclin-dependent kinase (CDK) inhibitor p27kip1 but not D-type cyclins. TSH and cAMP promote the assembly of required cyclin D3-CDK4 complexes and their nuclear import. Here, the nuclear translocation of these complexes strictly correlated in individual cells with the enhanced presence of nuclear p27. p27, like cyclin D3, supported the TSH-stimulated pRb-kinase activity of the CDK4 complex and, as demonstrated using the high-resolution power of the two-dimensional (2D) gel electrophoresis, the phosphorylation of CDK4, presumably by the nuclear CDK-activating kinase. In the presence of TSH, transforming growth factor beta (TGFbeta) did not affect the assembly of cyclin D3-CDK4, but it strongly inhibited the pRb-kinase activity associated with both cyclin D3 and p27, not only by preventing the nuclear import of cyclin D3-CDK4 and its binding to p27, but also by inhibiting CDK4 phosphorylation within residual p27-bound cyclin D3-CDK4 complexes. No alterations of the relative abundance of multiple (un)phosphorylated forms of cyclin D3 and p27 demonstrated by 2D-gel electrophoresis were associated with these processes. This study suggests a crucial positive role of p27 in the TSH-stimulated nuclear import, phosphorylation, and catalytic activity of cyclin D3-bound CDK4. Moreover, it demonstrates a technique to directly assess the in vivo phosphorylation of endogenous CDK4, which might appear as a last regulated step targeted by the antagonistic cell cycle effects of TSH and TGFbeta.     

Inhibitory effect of 22-oxa-1,25-dihydroxyvitamin D3, maxacalcitol, on the proliferation of pancreatic cancer cell lines

Effective chemotherapy for pancreatic cancer is urgently needed. The aim of this study was to compare the anti-proliferative activity on pancreatic cancer cell lines of the vitamin D(3) analog, 22-oxa-1,25-dihydroxyvitamin D(3), maxacalcitol, with that of 1,25-dihydroxyvitamin D(3), calcitriol, with analysis of vitamin D receptor status and the G(1)-phase cell cycle-regulating factors. Antiproliferative effects of both agents were compared using the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide method and by measuring the tumor size of xenografts inoculated into athymic mice. Scatchard analysis of vitamin D receptor contents, and mutational analysis of receptor complementary DNA were performed. Levels of expression of cyclins, cyclin-dependent kinases and cyclin-dependent kinase inhibitors, p21 and p27, were analysed by western blotting. In vitro, maxacalcitol and calcitriol markedly inhibited the proliferation and caused a G(1) phase cell cycle arrest with the appearance of numerous domes. In vivo, maxacalcitol inhibited the growth of BxPC-3 xenografts more significantly than calcitriol, without inducing hypercalcemia. Responsive cells had abundant functional vitamin D receptors. However, Hs 766T, showing no response to either agent, had the second highest receptor contents with no abnormalities in its primary structure deduced by receptor complementary DNA. In the responsive cells, p21 and p27 were markedly up-regulated after 24h of treatment with both agents. In non-responsive cells, no such changes were observed. In conclusion, maxacalcitol and calcitriol up-regulate p21 and p27 as an early event, which in turn could block the G(1)/S transition and induce growth inhibition in responsive cells, and maxacalcitol may provide a more useful tool for the chemotherapy of pancreatic cancer than calcitriol because of its low toxicity.     

Increased levels of cyclins D1 and D3 after inhibition of gap junctional communication in astrocytes

We showed previously that the inhibition of gap junctional communication in astrocytes increased bromodeoxyuridine (BrdU) incorporation and promoted changes in the metabolic phenotype destined to fulfil the requirements of cell proliferation. In the present study we investigated the changes in the cell cycle of astrocytes promoted by the inhibition of intercellular communication through gap junctions. Thus, the presence of endothelin-1 and carbenoxolone, two gap junction uncouplers, promoted an increase in the percentage of astrocytes found in the S, G2 and M phases of the cell cycle, with a concomitant decrease in G0 and G1 phases. In addition, the levels of Ki-67, a protein present during all active phases of the cell cycle but absent from resting cells, increased after the inhibition of gap junctional communication. These effects were not observed when the inhibition of gap junctions was prevented with tolbutamide, indicating that the inhibition of gap junctional communication promotes the entry of astrocytes into the cell cycle. The passage of the cells from a quiescent state to the cell cycle is ultimately regulated by the degree of retinoblastoma phosphorylation. Inhibition of gap junctions increased the phosphorylation of retinoblastoma at Ser 780 but not at Ser 795 or Ser 807/811. In addition, the levels of cyclins D1 and D3 increased, whereas those of p21 and p27 were not significantly modified. Because D-type cyclins are key regulators of retinoblastoma protein phosphorylation, it is suggested that the phosphorylation of retinoblastoma protein at Ser 780, observed under our experimental conditions, is a consequence of the increase in the levels of cyclins D1 and D3. Our work provides evidence for the involvement of cyclins D1 and D3 as sensors of the inhibition of gap junctional communication in astrocytes.     

How to keep proliferative neural stem/progenitor cells: A critical role of asymmetric inheritance of cyclin D2

It has long been argued that cell cycle regulators such as cyclins, cyclin-dependent kinases and their inhibitors affect the fate of neuronal progenitor cells. Recently, we identified that cyclin D2, which localizes at the basal tip of the radial glial cell (i.e., the neural progenitor in the developing neocortex), functions to give differential cell fates to its daughter cells just after cell division. This basally biased localization is due to transportation of cyclin D2 mRNA via its unique cis-regulatory sequence and local translation into cyclin D2 protein at the basal endfoot. During division of the neural progenitor cells, cyclin D2 protein is inherited by the daughter cell that retain the basal process, resulting in asymmetric distribution of cyclin D2 protein between the two daughter cells. Cyclin D2 is similarly localized in the human fetal cortical primordium, suggesting a common mechanism for the maintenance of neural progenitors and a possible scenario in evolution of primate brains. Here we introduce our recent findings and discuss how cyclin D2 functions in mammalian brain development and evolution.     

Genetic replacement of cyclin D1 function in mouse development by cyclin D2

D cyclins (D1, D2, and D3) are components of the core cell cycle machinery in mammalian cells. It is unclear whether each of the D cyclins performs unique, tissue-specific functions or the three proteins have virtually identical functions and differ mainly in their pattern of expression. We previously generated mice lacking cyclin D1, and we observed that these animals displayed hypoplastic retinas and underdeveloped mammary glands and a presented developmental neurological abnormality. We now asked whether the specific requirement for cyclin D1 in these tissues reflected a unique pattern of D cyclin expression or the presence of specialized functions for cyclin D1 in cyclin D1-dependent compartments. We generated a knock-in strain of mice expressing cyclin D2 in place of D1. Cyclin D2 was able to drive nearly normal development of retinas and mammary glands, and it partially replaced cyclin D1's function in neurological development. We conclude that the differences between these two D cyclins lie mostly in the tissue-specific pattern of their expression. However, we propose that subtle differences between the two D cyclins do exist and they may allow D cyclins to function in a highly optimized fashion. We reason that the acquisition of multiple D cyclins may allow mammalian cells to drive optimal proliferation of a diverse array of cell types.