Uncovering residues that regulate cyclin D1 proteasomal degradation.

Cyclin D1 regulates G1 cell-cycle progression and is aberrantly expressed in carcinogenesis. Proteasomal degradation of cyclin D1 was highlighted as a cancer chemopreventive mechanism. To understand this mechanism better, residues responsible for degradation and ubiquitination of cyclin D1 were investigated. Eighteen lysines in cyclin D1 had single, double or multiple mutations engineered before transfection into BEAS-2B human bronchial epithelial (HBE) cells to evaluate stabilities after all-trans-retinoic acid (RA) or cycloheximide treatments. Specific mutations stabilized cyclin D1, including substitutions of lysines surrounding the cyclin box domain that inhibited RA-mediated degradation and extended the cyclin D1 half-life. Mutation of all cyclin D1 lysines blocked polyubiquitination. N-terminus (but not C-terminus) modification stabilized cyclin D1. Ubiquitination-resistant mutants preferentially localized cyclin D1 to the nucleus, directly implicating subcellular localization in regulating cyclin D1 degradation. Taken together, these findings uncover specific residues conferring ubiquitination of cyclin D1. These provide a mechanistic basis for proteasomal degradation of cyclin D1.

Cyclin D1 proteolysis: a retinoid chemoprevention signal in normal, immortalized, and transformed human bronchial epithelial cells.

BACKGROUND: Retinoids (derivatives of vitamin A) are reported to reduce the occurrence of some second primary cancers, including aerodigestive tract tumors. In contrast, beta-carotene does not reduce the occurrence of primary aerodigestive tract cancers. Mechanisms explaining these effective retinoid and ineffective carotenoid chemoprevention results are poorly defined. Recently, the all-trans-retinoic acid (RA)-induced proteolysis of cyclin D1 that leads to the arrest of cells in G1 phase of the cell cycle was described in human bronchial epithelial cells and is a promising candidate for such a mechanism. In this study, we have investigated this proteolysis as a common signal used by carotenoids or receptor-selective and receptor-nonselective retinoids. METHODS: We treated cultured normal human bronchial epithelial cells, immortalized human bronchial epithelial cells (BEAS-2B), and transformed human bronchial epithelial cells (BEAS-2BNNK) with receptor-selective or receptor-nonselective retinoids or with carotenoids and studied the effects on cell proliferation by means of tritiated thymidine incorporation and on cyclin D1 expression by means of immunoblot analysis. We also examined whether calpain inhibitor I, an inhibitor of the 26S proteasome degradation pathway, affected the decline (i.e., proteolysis) of cyclin D1. RESULTS: Receptor-nonselective retinoids were superior to the carotenoids studied in mediating the decline in cyclin D1 expression and in suppressing the growth of bronchial epithelial cells. Retinoids that activated retinoic acid receptor beta or retinoid X receptor pathways preferentially led to a decrease in the amount of cyclin D1 protein and a corresponding decline in growth. The retinoid-mediated degradation of cyclin D1 was blocked by cotreatment with calpain inhibitor I. CONCLUSIONS: Retinoid-dependent cyclin D1 proteolysis is a common chemoprevention signal in normal and neoplastic human bronchial epithelial cells. In contrast, carotenoids did not affect cyclin D1 expression. Thus, the degradation of cyclin D1 is a candidate intermediate marker for effective retinoid-mediated cancer chemoprevention in the aerodigestive tract.

Specific retinoid receptors cooperate to signal growth suppression and maturation of human embryonal carcinoma cells.

This study addresses the contributions of specific retinoid receptors during all-trans-retinoic acid (RA)-mediated differentiation and growth suppression of human embryonal carcinoma cells. The pleiotropic effects of RA are mediated by retinoic acid receptors (RARs) and retinoid X receptors (RXRs), members of the nuclear receptor family of transcription factors. After RA-treatment the multipotent human embryonal carcinoma cell line NTERA-2 clone D1 (NT2/D1) displays limited proliferative potential, reduced tumorigenicity, and morphologic and immunophenotypic neuronal maturation. RARgamma over-expression in NT2/D1 cells signals mesenchymal NT2/D1 terminal differentiation while RARalpha and RARbeta do not and RARgamma overcomes retinoid resistance in an NT2/D1 clone (NT2/D1-RI) having deregulated RARgamma expression. Since RARgamma transfectants do not display neuronal maturation, this study sought to identify cooperating retinoid receptors engaged in NT2/D1 differentiation. Through gain of function experiments, this report highlights RXRbeta as playing an important role along with RARgamma in signaling differentiation of NT2/D1 cells. Stable over-expression of RXRbeta, but not RXRalpha or RXRgamma, was found to signal NT2/D1 growth suppression and to induce a non-neuronal morphology and immunophenotype. Notably, co-transfection of RARgamma and RXRbeta resulted in marked growth suppression and for the first time, expression of typical neuronal markers of NT2/D1 differentiation. To clarify the role of RXRbeta and RARgamma in this differentiation program, a modified transient fibroblast growth factor-4 (FGF4) promoter-enhancer reporter assay that reflects effective RA-mediated differentiation of NT2/D1 cells was employed. Transfection of RARgamma or RXRbeta in NT2/D1 cells augments transcriptional repression of the FGF4 reporter and RARgamma and RXRbeta co-transfection markedly repressed reporter activity, indicating the combined role of these receptors in RA-induced NT2/D1 differentiation. Taken together, these findings reveal specific retinoid receptors must cooperate to signal terminal growth suppression and maturation of NT2/D1 cells. Since the transcriptional repression of FGF4 is coupled to the effective maturation of human embryonal carcinoma cells, the described co-transfection strategy should prove useful to identify genes with positive or negative effects on the differentiation program of these tumor cells.

Retinoic acid activates p53 in human embryonal carcinoma through retinoid receptor-dependent stimulation of p53 transactivation function.

Although retinoids are known to regulate gene transcription by activating retinoid receptors, the targets of retinoid receptors are largely unknown. This study indicates effective all-trans retinoic acid (RA)-induced differentiation of human embryonal carcinoma cells engages p53. Unexpectedly, RA has been found to activate the transactivation function of p53 in the human embryonal carcinoma cell line, NT2/D1, in a retinoid receptor-dependent manner. A derived RA-resistant line, NT2/D1-R1, is deficient in this activity and is co-resistant to cisplatin. This indicates that RA and cisplatin responses may share a common pathway involving p53 in embryonal carcinomas. RA has no effect on p53 steady-state protein levels in either line. RA enhances endogenous p53 transactivation activity in NT2/D1 but not NT2/D1-R1 cells. In addition, RA induces transactivation activity of a gal4-p53 fusion protein, suggesting that RA activates p53 independent of increasing p53 levels or sequence-specific DNA binding. This activity is absent in retinoic acid receptor gamma (RARgamma)-deficient NT2/D1-R1 cells but can be restored upon co-transfection with specific RARs. Transient transfection of a dominant-negative p53 construct in NT2/D1 cells blocks the RA-mediated transcriptional decline of a differentiation-sensitive reporter plasmid and enhances survival of NT2/D1 cells following cisplatin treatment. Taken together, these findings indicate that RA activates the intrinsic activation function of p53 by a novel mechanism independent of effects on p53 stability or DNA binding and that this activation may be a general mechanism that contributes to RA-mediated G1 arrest.

Posttranslational regulation of cyclin D1 by retinoic acid: a chemoprevention mechanism.

The retinoids are reported to reduce incidence of second primary aerodigestive cancers. Mechanisms for this chemoprevention are previously linked to all-trans retinoic acid (RA) signaling growth inhibition at G1 in carcinogen-exposed immortalized human bronchial epithelial cells. This study investigated how RA suppresses human bronchial epithelial cell growth at the G1-S cell cycle transition. RA signaled growth suppression of human bronchial epithelial cells and a decline in cyclin D1 protein but not mRNA expression. Exogenous cyclin D1 protein also declined after RA treatment of transfected, immortalized human bronchial epithelial cells, suggesting that posttranslational mechanisms were active in this regulation of cyclin D1 expression. Findings were extended by showing treatment with ubiquitin-dependent proteasome inhibitors: calpain inhibitor I and lactacystin each prevented this decreased cyclin D1 protein expression, despite RA treatment. Treatment with the cysteine proteinase inhibitor, E-64, did not prevent this cyclin D1 decline. High molecular weight cyclin D1 protein species appeared after proteasome inhibitor treatments, suggesting that ubiquitinated species were present. To learn whether RA directly promoted degradation of cyclin D1 protein, studies using human bronchial epithelial cell protein extracts and in vitro-translated cyclin D1 were performed. In vitro-translated cyclin D1 degraded more rapidly when incubated with extracts from RA treated vs. untreated cells. Notably, this RA-signaled cyclin D1 proteolysis depended on the C-terminal PEST sequence, a region rich in proline (P), glutamate (E), serine (S), and threonine (T). Taken together, these data highlight RA-induced cyclin D1 proteolysis as a mechanism signaling growth inhibition at G1 active in the prevention of human bronchial epithelial cell transformation.

Retinoic acid promotes ubiquitination and proteolysis of cyclin D1 during induced tumor cell differentiation.

Mechanisms by which differentiation programs engage the cell cycle are poorly understood. This study demonstrates that retinoids promote ubiquitination and degradation of cyclin D1 during retinoid-induced differentiation of human embryonal carcinoma cells. In response to all-trans-retinoic acid (RA) treatment, the human embryonal carcinoma cell line NT2/D1 exhibits a progressive decline in cyclin D1 expression beginning when the cells are committed to differentiate, but before onset of terminal neuronal differentiation. The decrease in cyclin D1 protein is tightly associated with the accumulation of hypophosphorylated forms of the retinoblastoma protein and G(1) arrest. In contrast, retinoic acid receptor gamma-deficient NT2/D1-R1 cells do not growth-arrest or accumulate in G(1) and have persistent cyclin D1 overexpression despite RA treatment. Notably, stable transfection of retinoic acid receptor gamma restores RA-mediated growth suppression and differentiation to NT2/D1-R1 cells and restores the decline of cyclin D1. The proteasome inhibitor LLnL blocks this RA-mediated decline in cyclin D1. RA treatment markedly accelerates ubiquitination of wild-type cyclin D1, but not a cyclin D1 (T286A) mutant. Transient expression of cyclin D1 (T286A) in NT2/D1 cells blocks RA-mediated transcriptional decline of a differentiation-sensitive reporter plasmid and represses induction of immunophenotypic neuronal markers. Taken together, these findings strongly implicate RA-mediated degradation of cyclin D1 as a means of coupling induced differentiation and cell cycle control of human embryonal carcinoma cells.