Montserrat Jaumot

The Protein SET Regulates the Inhibitory Effect of p21Cip1on Cyclin E-Cyclin-dependent Kinase 2 Activity

The cyclin-dependent kinase (CDK) inhibitor p21Cip1 has a dual role in the regulation of the cell cycle; it is an activator of cyclin D1-CDK4 complexes and an inhibitor of cyclins E/A-CDK2 activity. By affinity chromatography with p21Cip1-Sepharose 4B columns, we purified a 39-kDa protein, which was identified by microsequence analysis as the oncoprotein SET. Complexes containing SET and p21Cip1 were detected in vivo by immunoprecipitation of Namalwa cell extracts using specific anti-p21Cip1 antibodies. We found that SET bound directly to p21Cip1 in vitro by the carboxyl-terminal region of p21Cip1. SET had no direct effect on cyclin E/A-CDK2 activity, although it reversed the inhibition of cyclin E-CDK2, but not of cyclin A-CDK2, induced by p21Cip1. This result is specific for p21Cip1, since SET neither bound to p27Kip1 nor reversed its inhibitory effect on cyclin E-CDK2 or cyclin A-CDK2. Thus, SET appears to be a modulator of p21Cip1 inhibitory function. These results suggest that SET can regulate G1/S transition by modulating the activity of cyclin E-CDK2.

Binding of Calmodulin to the Carboxy-Terminal Region of p21 Induces Nuclear Accumulation via Inhibition of Protein Kinase C-Mediated Phosphorylation of Ser153

ABSTRACT Intracellular localization plays an important role in the functional regulation of the cell cycle inhibitor p21. We have previously shown that calmodulin binds to p21 and that calmodulin is essential for the nuclear accumulation of p21. Here, we analyze the mechanism of this regulation. We show that calmodulin inhibits in vitro phosphorylation of p21 by protein kinase C (PKC) and that this inhibition is dependent upon calmodulin binding to p21. Two-dimensional electrophoresis analysis of cells expressing the p21 wild type or p21S153A, a nonphosphorylatable mutant of p21 at position 153, indicates that Ser153 of p21 is a phosphorylable residue in vivo. Furthermore, Western blot analysis using phospho-Ser153-specific antibodies indicates that Ser153 phosphorylation in vivo is induced when PKC is activated and calmodulin is inhibited. The mutation of Ser153 to aspartate, a pseudophosphorylated residue, inhibits the nuclear accumulation of p21. Finally, whereas wild-type p21 translocates to the cytoplasm after PKC activation in the presence of calmodulin inhibitors, p21 carrying a nonphosphorylatable residue at position 153 remains in the nucleus. We propose that calmodulin binding to p21 prevents its phosphorylation by PKC at Ser153 and consequently allows its nuclear localization. When phosphorylated at Ser153, p21 is located at the cytoplasm and disrupts stress fibers.

P38SAPK2 phosphorylates cyclin D3 at Thr-283 and targets it for proteasomal degradation

Cyclin D3 plays a critical role in maturation of precursor T cells and their levels are tightly regulated during this process. Alteration of cyclin D3 levels has been proposed to be important in the development of different human cancers, including malignancies of the lymphoid system. Thus, we have analysed the mechanisms involved in the regulation of cyclin D3 levels. Our results indicate that cyclin D3 is degraded via proteasome and that Thr-283 is essential for its degradation. Wild-type cyclin D3 but not the Thr-283A mutant accumulated ubiquitylated forms after treatment with proteasome inhibitors. We also observed that different type of stresses promote the Thr-283-dependent in vivo degradation of cyclin D3. The analysis of the kinases involved in Thr-283 phosphorylation indicates that all the members of the p38SAPK family of serine–threonine kinases are able to phosphorylate cyclin D3 at this specific site. Moreover, we found that the overexpression of p38αSAPK2 induce the decrease of cyclin D3 in vivo. These results indicate that p38SAPK might be involved in the regulation of cyclin D3 levels and suggest that this mechanism is involved in the maturation of precursor T-cells. Alterations of this mechanism might be important for oncogenesis.

Ikaros-1 couples cell cycle arrest of late striatal precursors with neurogenesis of enkephalinergic neurons.

During central nervous system development, several transcription factors regulate the differentiation of progenitor cells to postmitotic neurons. Here we describe a novel role for Ikaros‐1 in the generation of late‐born striatal neurons. Our results show that Ikaros‐1 is expressed in the boundary of the striatal germinal zone (GZ)/mantle zone (MZ), where it induces cell cycle arrest of neural progenitors by up‐regulation of the cyclin‐dependent kinase inhibitor (CDKi) p21Cip1/Waf1. This effect is coupled with the neuronal differentiation of late precursors, which in turn is critical for the second wave of striatal neurogenesis that gives rise to matrix neurons. Consistently, Ikaros−/− mice had fewer striatal projecting neurons and, in particular, enkephalin (ENK)‐positive neurons. In addition, overexpression of Ikaros‐1 in primary striatal cultures increases the number of calbindin‐ and ENK‐positive neurons. Our results also show that Ikaros‐1 acts downstream of the Dlx family of transcription factors, insofar as its expression is lost in Dlx1/2 double knockout mice. However, we demonstrate that Ikaros‐1 and Ebf‐1 independently regulate the final determination of the two populations of striatal projection neurons of the matrix compartment, ENK‐ and substance P‐positive neurons. In conclusion, our findings identify Ikaros‐1 as a modulator of cell cycle exit of neural progenitors that gives rise to the neurogenesis of ENK‐positive striatal neurons. J. Comp. Neurol. 518:329–351, 2010.

Heterogeneous nuclear ribonucleoprotein A2 is a SET-binding protein and a PP2A inhibitor

The oncoprotein SET participates in a diversity of cellular functions including cell proliferation. Its role on cell cycle progression is likely mediated by inhibiting cyclin B-cdk1 and the protein phosphatase 2A (PP2A). On identifying new SET cellular partners, we found that SET interacts in vitro and in vivo with the heterogeneous nuclear ribonucleoprotein A2 (hnRNPA2); a protein involved in various aspects of mRNA biogenesis. The SET-binding region of hnRNPA2 is the RNP1 sequence that belongs to the RNA-binding domain (RBD) of this protein. We also found that hnRNPA2 has much higher affinity for single-standed DNA than for SET. On analysing the effect of hnRNPA2 on PP2A inhibition by SET, we observed that hnRNPA2 cooperates with SET on PP2A inhibition. This is because we found that hnRNPA2 is also a PP2A inhibitor. HnRNPA2 interacts with PP2A by the RNP1 sequence; however, to inhibit PP2A activity, the complete RBD is needed. We also observed that overexpression of hnRNPA2 inhibits PP2A activity and stimulates cell proliferation. Interestingly, the overexpression of the complete RBD is sufficient to stimulate proliferation. As hnRNPA2 is overexpressed in a variety of human tumors, our results suggest that hnRNPA2 might participate in oncogenesis by stimulating cell proliferation.

Phosphorylation at Ser-181 of oncogenic KRAS is required for tumor growth.

KRAS phosphorylation has been reported recently to modulate the activity of mutant KRAS protein in vitro. In this study, we defined S181 as a specific phosphorylation site required to license the oncogenic function of mutant KRAS in vivo. The phosphomutant S181A failed to induce tumors in mice, whereas the phosphomimetic mutant S181D exhibited an enhanced tumor formation capacity, compared with the wild-type KRAS protein. Reduced growth of tumors composed of cells expressing the nonphosphorylatable KRAS S181A mutant was correlated with increased apoptosis. Conversely, increased growth of tumors composed of cells expressing the phosphomimetic KRAS S181D mutant was correlated with increased activation of AKT and ERK, two major downstream effectors of KRAS. Pharmacologic treatment with PKC inhibitors impaired tumor growth associated with reduced levels of phosphorylated KRAS and reduced effector activation. In a panel of human tumor cell lines expressing various KRAS isoforms, we showed that KRAS phosphorylation was essential for survival and tumorigenic activity. Furthermore, we identified phosphorylated KRAS in a panel of primary human pancreatic tumors. Taken together, our findings establish that KRAS requires S181 phosphorylation to manifest its oncogenic properties, implying that its inhibition represents a relevant target to attack KRAS-driven tumors.

Differential association of p21Cip1 and p27Kip1 with cyclin E-CDK2 during rat liver regeneration

BACKGROUND/AIMS The cell cycle inhibitors p21Cip1 and p27Kip1 regulate liver regeneration by modulating the activity of cyclin-dependent kinases (CDKs). However, the specific role of these inhibitors in the regulation of CDK2 activity during liver regeneration remains unknown. The aim of this study was to examine the association of p21Cip1 and p27Kip1 with cyclin E-CDK2 and cyclin A-CDK2 complexes during rat liver regeneration and to correlate the association of both inhibitors with CDK2 activity. METHODS The association of p21Cip1 or p27Kip1 with cyclin E-CDK2 or cyclin A-CDK2 and the activities of these complexes were analyzed by immunoprecipitation of rat liver homogenates obtained at different times after a partial hepatectomy (PH), followed by Western blotting or kinase assays. RESULTS High amounts of p27Kip1 bound to cyclin E-CDK2 were observed during the first 13 h after PH, when CDK2 activity was very low. At 24 h, when CDK2 activity was maximal, the amount of bound-p27Kip1 decreased strongly. The amount of p21Cip1 bound to these complexes was low during the first 13 h but subsequently increased. No cyclin A-CDK2 complexes were found during the first 13 h after PH. At 24 h, complexes containing low levels of both inhibitors were detected and at 28 h, a significant increase in p21Cip1 and p27Kip1 associated with cyclin A-CDK2 was observed. CONCLUSIONS p27Kip1 acts as a brake on cyclin E-CDK2 activity during the first 13 h after a PH. Both p21Cip1 and p27Kip1 down-regulate cyclin A-CDK2 activity at 28 h after PH, after its maximal activation.

Proteomic analysis of SET-binding proteins.

The protein SET is involved in essential cell processes such as chromatin remodeling, apoptosis and cell cycle progression. It also plays a critical role in cell transformation and tumorogenesis. With the aim to study new SET functions we have developed a system to identify SET‐binding proteins by combining affinity chromatography, MS, and functional studies. We prepared SET affinity chromatography columns by coupling the protein to activated Sepharose 4B. The proteins from mouse liver lysates that bind to the SET affinity columns were resolved with 2‐DE and identified by MS using a MALDI‐TOF. This experimental approach allowed the recognition of a number of SET‐binding proteins which have been classified in functional clusters. The identification of four of these proteins (CK2, eIF2α, glycogen phosphorylase (GP), and TCP1‐β) was confirmed by Western blotting and their in vivo interactions with SET were demonstrated by immunoprecipitation. Functional experiments revealed that SET is a substrate of CK2 in vitro and that SET interacts with the active form of GP but not with its inactive form. These data confirm this proteomic approach as a useful tool for identifying new protein–protein interactions.

CaM interaction and Ser181 phosphorylation as new K-Ras signaling modulators

The small G-protein Ras was the first oncogene to be identified and has a very important contribution to human cancer development (20-23% prevalence). K-RasB, one of the members of the Ras family, is the one that is most mutated and plays a prominent role in pancreatic, colon and lung cancer development. Ras proteins are membrane bound GTPases that cycle between inactive, GDP-bound, and active, GTP-bound, states. Most of the research into K-RasB activity regulation has focused on the analysis of how GTP-exchange factors (GEFs) and GTPase activating proteins (GAPs) are regulated by external and internal signals. In contrast, oncogenic K-RasB has a very low GTPase activity and furthermore is not deactivated by GAPs. Consequently, the consensus was that activity of oncogenic K-RasB was not modulated. In this extra view we recapitulate some recent data showing that calmodulin binding to K-RasB inhibits phosphorylation of K-RasB at Ser181, near to the membrane anchoring domain, modulating signaling of both non-oncogenic and oncogenic K-RasB. This may be relevant to normal cell physiology, but also opens new therapeutic perspectives for the inhibition of oncogenic K-RasB signaling in tumors.

The diverging roles of calmodulin and PKC in the regulation of p21 intracellular localization.

Intracellular localization plays an important role in the functional regulation of the cyclindependentkinase inhibitor p21. While nuclear functions have been linked to the tumorsuppressor activity of p21, cytoplasmatic functions are oncogenic. We have recently shownthat Ser153 phosphorylation of p21 by PKC contributes to its cytoplasmatic accumulation,and that this phosphorylation is inhibited by Ca2+-dependent calmodulin binding to the Cterminalregion of p21. Consequently, PKC and calmodulin/Ca2+ play diverging roles inthe regulation of p21 intracellular localization. Other kinases such as AKT andMIRK/dyrk1B also phosphorylate p21 near the nuclear localization signal, thus inhibitingits nuclear accumulation. We discuss here the effects of such phosphorylations on p21functionality, as well as its relevance to cell cycle progression and differentiation.