RIP140 inhibits glycolysis-dependent proliferation of breast cancer cells by regulating GLUT3 expression through transcriptional crosstalk between hypoxia induced factor and p53.

Glycolysis is essential to support cancer cell proliferation, even in the presence of oxygen. The transcriptional co-regulator RIP140 represses the activity of transcription factors that drive cell proliferation and metabolism and plays a role in mammary tumorigenesis. Here we use cell proliferation and metabolic assays to demonstrate that RIP140-deficiency causes a glycolysis-dependent increase in breast tumor growth. We further demonstrate that RIP140 reduces the transcription of the glucose transporter GLUT3 gene, by inhibiting the transcriptional activity of hypoxia inducible factor HIF-2α in cooperation with p53. Interestingly, RIP140 expression was significantly associated with good prognosis only for breast cancer patients with tumors expressing low GLUT3, low HIF-2α and high p53, thus confirming the mechanism of RIP140 anti-tumor activity provided by our experimental data. Overall, our work establishes RIP140 as a critical modulator of the p53/HIF cross-talk to inhibit breast cancer cell glycolysis and proliferation.

The E3 ubiquitin ligase thyroid hormone receptor-interacting protein 12 targets pancreas transcription factor 1a for proteasomal degradation.

Pancreas transcription factor 1a (PTF1a) plays a crucial role in the early development of the pancreas and in the maintenance of the acinar cell phenotype. Several transcriptional mechanisms regulating expression of PTF1a have been identified. However, regulation of PTF1a protein stability and degradation is still unexplored. Here, we report that inhibition of proteasome leads to elevated levels of PTF1a and to the existence of polyubiquitinated forms of PTF1a. We used the Sos recruitment system, an alternative two-hybrid system method to detect protein-protein interactions in the cytoplasm and to map the interactome of PTF1a. We identified TRIP12 (thyroid hormone receptor-interacting protein 12), an E3 ubiquitin-protein ligase as a new partner of PTF1a. We confirmed PTF1a/TRIP12 interaction in acinar cell lines and in co-transfected HEK-293T cells. The protein stability of PTF1a is significantly increased upon decreased expression of TRIP12. It is reduced upon overexpression of TRIP12 but not a catalytically inactive TRIP12-C1959A mutant. We identified a region of TRIP12 required for interaction and identified lysine 312 of PTF1a as essential for proteasomal degradation. We also demonstrate that TRIP12 down-regulates PTF1a transcriptional and antiproliferative activities. Our data suggest that an increase in TRIP12 expression can play a part in PTF1a down-regulation and indicate that PTF1a/TRIP12 functional interaction may regulate pancreatic epithelial cell homeostasis.

The transcriptional coregulator RIP140 represses E2F1 activity and discriminates breast cancer subtypes.

PURPOSE: Receptor-interacting protein of 140 kDa (RIP140) is a transcriptional cofactor for nuclear receptors involved in reproduction and energy homeostasis. Our aim was to investigate its role in the regulation of E2F1 activity and target genes both in breast cancer cell lines and in tumor biopsies. EXPERIMENTAL DESIGN: Glutathione S-transferase pull-down assays, coimmunoprecipitation experiments, and chromatin immunoprecipitation analysis were used to evidence interaction between RIP140 and E2F1. The effects of RIP140 expression on E2F1 activity were determined using transient transfection and quantification of E2F target mRNAs by quantitative real-time PCR. The effect on cell cycle was assessed by fluorescence-activated cell sorting analysis on cells overexpressing green fluorescent protein-tagged RIP140. A tumor microarray data set was used to investigate the expression of RIP140 and E2F1 target genes in 170 breast cancer patients. RESULTS: We first evidenced the complex interaction between RIP140 and E2F1 and showed that RIP140 represses E2F1 transactivation on various transiently transfected E2F target promoters and inhibits the expression of several E2F1 target genes (such as CCNE1 and CCNB2). In agreement with a role for RIP140 in the control of E2F activity, we show that increasing RIP140 levels results in a reduction in the proportion of cells in S phase in various human cell lines. Finally, analysis of human breast cancers shows that low RIP140 mRNA expression was associated with high E2F1 target gene levels and basal-like tumors. CONCLUSION: This study shows that RIP140 is a regulator of the E2F pathway, which discriminates luminal- and basal-like tumors, emphasizing the importance of these regulations for a clinical cancer phenotype.

The nuclear receptor transcriptional coregulator RIP140.

The nuclear receptor superfamily comprises ligand-regulated transcription factors that control various developmental and physiological pathways. These receptors share a common modular structure and regulate gene expression through the recruitment of a large set of coregulatory proteins. These transcription cofactors regulate, either positively or negatively, chromatin structure and transcription initiation. One of the first proteins to be identified as a hormone-recruited cofactor was RIP140. Despite its recruitment by agonist-liganded receptors, RIP140 exhibits a strong transcriptional repressive activity which involves several inhibitory domains and different effectors. Interestingly, the RIP140 gene, located on chromosome 21 in humans, is finely regulated at the transcriptional level by various nuclear receptors. In addition, the protein undergoes several post-translational modifications which control its repressive activity. Finally, experiments performed in mice devoid of the RIP140 gene indicate that this transcriptional cofactor is essential for female fertility and energy homeostasis. RIP140 therefore appears to be an important modulator of nuclear receptor activity which could play major roles in physiological processes and hormone-dependent diseases.

Intravenous delivery of PTH/PTHrP type 1 receptor cDNA to rats decreases heart rate, blood pressure, renal tone, renin angiotensin system, and stress-induced cardiovascular responses.

While parathyroid hormone type 1 receptor (PTH1R)-mediated vasodilatory, cardiac stimulatory, and renin-activating effects of exogenous PTH/PTH-related protein (PTHrP) are acknowledged, interactions of endogenous PTHrP with these systems remain unclear, mainly because the unavailability of viable PTHrP/PTH1R knockout mice. Transgenic mice overexpressing PTH1R in smooth muscle strongly have supported the PTHrP/PTH1R system as a cardiovascular system (CVS) regulator, but the consequences on renovascular (RVS) and renin-angiotensin systems (RAS) have not been explored in these studies. The aim was to develop a model in which one could study the consequences on CVS, RVS, and RAS of generalized PTH1R overexpression. Systemic PTH1R cDNA plasmid delivery was used in adult rats, a system that is amenable to studies in isolated perfused kidneys and that minimizes development-induced compensatory mechanisms. Intravenous administration of hPTH1R or green fluorescence protein-tagged hPTH1R in pcDNA3 resulted 3 wk later, in generalized expression of hPTH1R (mRNA and protein), especially in vessels, liver, heart, kidney, and central nervous system, where it is expressed physiologically. As expected, PTH1R overexpression decreased BP and renal tone. Unexpected, however, PTH1R overexpression decreased heart rate. These studies also revealed that endogenous PTHrP actually inhibits renin release and that hPTH1R overexpression tends to increase that effect. Striking, liver production and circulatory level of angiotensinogen and hence plasma renin activity were markedly reduced. Thus, abrupt PTH1R overexpression in adult rats profoundly alters the CVS, RVS, and RAS, strongly supporting the PTH/PTHrP/PTH1R system as crucial for heart and vascular tone regulation. In addition, these results revealed that PTH1R-mediated mechanisms might have protective effects against cardiovascular stress-induced responses, including stimulations in heart rate and RAS.

Transcript expression of the tuberoinfundibular peptide (TIP)39/PTH2 receptor system and non-PTH1 receptor-mediated tonic effects of TIP39 and other PTH2 receptor ligands in renal vessels.

Although lower than in brain, the type 2 PTH receptor (PTH2-R) has been shown to be expressed throughout the cardiovascular system. Tuberoinfundibular peptide (TIP) purified from brain is thought to be the endogenous selective ligand of the PTH2-R. In the present studies, TIP and PTH2-R mRNA expressions were evidenced by RT-PCR in rat intrarenal arteries as well as in renovascular smooth muscle cells cultured from these arteries. In the isolated perfused rat kidney (IPK), peptides known to bind to both PTH1- and PTH2-Rs, such as rat PTH (1-34) and the hybrid PTH/PTHrP peptide, [Ile(5), Trp(23)]PTHrP (1-36), failed to exhibit improved vasodilatory effect, compared with human PTHrP (1-36), which binds only to the PTH1-R. Thus, a non-PTH1-R seemed not to be involved in the vasodilatory effects of these peptides. On the other hand, TIP exhibited complex vasoactivity, constricting the IPK at 10 nM and dilating the IPK at 1, 100, and 1000 nM. Moreover, [p-benzoyl-L-Phe(4),Ile(5),Trp(23)]PTHrP (1-36), initially described as a selective PTH2-R antagonist, also displayed a strong vasodilatory effect and therefore could not be used to check that TIP-induced vasoactivity was mediated by the PTH2-R. However, both [p-benzoyl-L-Phe(4),Ile(5),Trp(23)]PTHrP (1-36) and TIP displayed similar or even enhanced vasodilation in IPK in which PTH1-R-induced vasodilation was fully desensitized by sustained exposure to human PTHrP (1-36). Importantly, in IPK desensitized to the vasodilatory action of PTHrP (1-36), the hybrid PTH/PTHrP peptide and rat PTH (1-34), whose vasodilatory responses appeared exclusively PTH1-R dependent in naive IPK, produced a new and strong vasodilation. In conclusion, TIP and PTH2-R mRNAs are expressed in renal vessels and TIP appears as a new vasoactive peptide. Whether TIP interacts with PTH2-R could not be shown. However, these studies reveal the ability of TIP, as well as of other peptides known to bind to the PTH2-R, to dilate renal vessels in a PTH1-R-independent manner. Moreover, results obtained in IPK desensitized to the vasodilatory action of PTHrP (1-36) strongly suggest that TIP, along with PTHrP, might be coordinately involved in the regulation of renal hemodynamics.

Type 1 parathyroid hormone receptor expression level modulates renal tone and plasma renin activity in spontaneously hypertensive rat.

These studies examine whether PTHrP(1-36), a vasodilator, modulates BP and renal vascular resistance (RVR) in spontaneously hypertensive rat (SHR). Within the kidney of normotensive rats, PTHrP(1-36) was enriched in vessels. In vessels of SHR, PTHrP was upregulated by 40% and type 1 PTH receptor (PTH1R) was downregulated by 65% compared with normotensive rats. To investigate the role of endogenous PTHrP in the regulation of BP and RVR, SHR were subjected to somatic human (h)PTH1R gene delivery. Three weeks after a single intravenous injection of pcDNA1.1 plasmid containing the hPTH1R gene under the control of the cytomegalovirus promoter, hPTH1R mRNA was detected in all of the main organs. Within the kidney, the transgene was enriched in vessels. In the isolated perfused kidney, RVR was reduced by 23% and PTHrP(1-36)-induced vasodilation, which is depressed in SHR, was restored and a vasoconstrictory response to PTH(3-34), a PTH1R antagonist, was revealed. These effects were not observed in control SHR treated with empty plasmid. BP remained unchanged, and plasma renin activity increased by 60%. Thus, in SHR renal vessels, a reduced number of PTH1R contributes to the high RVR, despite the higher expression of vasodilatory PTHrP. Moreover, these studies provide evidence for a direct link between the density of PTH1R and plasma renin activity, which might be responsible for the absence of effect of PTH1R gene delivery on BP in SHR. Overall, PTHrP significantly contributes to the homeostasis of renal and systemic hemodynamics in SHR.