Sumudra Periyasamy

Essential Role for Co-Chaperone FKBP52 but not FKBP51 in Androgen Receptor-Mediated Signaling and Physiology

Fkbp52 and Fkbp51 are tetratricopeptide repeat proteins found in steroid receptor complexes, and Fkbp51 is an androgen receptor (AR) target gene. Although in vitro studies suggest that Fkbp52 and Fkbp51 regulate hormone binding and/or subcellular trafficking of receptors, the roles of Fkbp52 and Fkbp51 in vivo have not been extensively investigated. Here, we evaluate their physiological roles in Fkbp52-deficient and Fkbp51-deficient mice. Fkbp52-deficient males developed defects in select reproductive organs (e.g. penile hypospadias and prostate dysgenesis but normal testis), pointing to a role for Fkbp52 in AR-mediated signaling and function. Surprisingly, ablation of Fkbp52 did not affect AR hormone binding or nuclear translocation in vivo and in vitro. Molecular studies in mouse embryonic fibroblast cells uncovered that Fkbp52 is critical to AR transcriptional activity. Interestingly, Fkbp51 expression was down-regulated in Fkbp52-deficient males but only in affected tissues, providing further evidence of tissue-specific loss of AR activity and suggesting that Fkbp51 is an AR target gene essential to penile and prostate development. However, Fkbp51-deficient mice were normal, showing no defects in AR-mediated reproductive function. Our work demonstrates that Fkbp52 but not Fkbp51 is essential to AR-mediated signaling and provides evidence for an unprecedented Fkbp52 function, direct control of steroid receptor transcriptional activity.

FKBP51 and Cyp40 are Positive Regulators of Androgen-dependent Prostate Cancer Cell Growth and the Targets of FK506 and Cyclosporin A

Prostate cancer (PCa) growth is dependent on androgens and on the androgen receptor (AR), which acts by modulating gene transcription. Tetratricopeptide repeat (TPR) proteins (FKBP52, FKBP51 and Cyp40) interact with AR in PCa cells, suggesting roles in AR-mediated gene transcription and cell growth. We report here that FKBP51 and Cyp40, but not FKBP52, are significantly elevated in PCa tissues and in androgen-dependent (AD) and androgen-independent (AI) cell lines. Overexpression of FKBP51 in AD LNCaP cells increased AR transcriptional activity in the presence and absence of androgen, whereas siRNA knockdown of FKBP51 dramatically decreased AD gene transcription and proliferation. Knockdown of Cyp40 also inhibited androgen-mediated transcription and growth in LNCaP cells. However, disruption of FKBP51 and Cyp40 in AI C4-2 cells caused only a small reduction in proliferation, indicating that Cyp40 and FKBP51 predominantly regulate AD cell proliferation. Under knockdown conditions, the inhibitory effects of TPR ligands, cyclosporine A (CsA) and FK506, on AR activity were not observed, indicating that Cyp40 and FKBP51 are the targets of CsA and FK506, respectively. Our findings show that FKBP51 and Cyp40 are positive regulators of AR that can be selectively targeted by CsA and FK506 to achieve inhibition of androgen-induced cell proliferation. These proteins and their cognate ligands thus provide new strategies in the treatment of PCa.

Control of Glucocorticoid and Progesterone Receptor Subcellular Localization by the Ligand-binding Domain is Mediated by Distinct Interactions with Tetratricopeptide Repeat Proteins

The TPR proteins FKBP52, FKBP51, Cyp40, and PP5 are found in steroid receptor (SR) complexes, but their receptor-specific preferences and roles remain unresolved. We have undertaken a systematic approach to this problem by examining the contribution of all four TPRs to the localization properties of glucocorticoid (GR) and progesterone (PR) receptors. The GR of L929 cells was found in the cytoplasm in a complex containing PP5 and FKBP51, while the GR of WCL2 cells was nuclear and contained PP5 and FKBP52. Cyp40 did not interact with the GR in either cell line. To test whether FKBP interaction determined localization, we overexpressed Flag-tagged FKBP51 in WCL2 cells and Flag-FKBP52 in L929 cells. In WCL2 cells, the GR exhibited a shift to greater cytoplasmic localization that correlated with recruitment of Flag-FKBP51. In contrast, Flag-FKBP52 was not recruited to the GR of L929 cells, and no change in localization was observed, suggesting that both cell-type-specific mechanisms and TPR abundance contribute to the SR-TPR interaction. As a further test, GR-GFP and PR-GFP constructs were expressed in COS cells. The GR-GFP construct localized to the cytoplasm, while the PR-GFP construct was predominantly nuclear. Similar to L929 cells, the GR in COS interacted with PP5 and FKBP51, while PR interacted with FKBP52. Analysis of GR-PR chimeric constructs revealed that the ligand-binding domain of each receptor determines both TPR specificity and localization. Lastly, we analyzed GR and PR localization in cells completely lacking TPR. PR in FKBP52 KO cells showed a complete shift to the cytoplasm, while GR in FKBP51 KO and PP5 KO cells showed a moderate shift to the nucleus, indicating that both TPRs contribute to GR localization. Our results demonstrate that SRs have distinct preferences for TPR proteins, a property that resides in the LBD and which can now explain long-standing differences in receptor subcellular localization.

Kappa opioid receptors stimulate phosphoinositide turnover in rat brain

The effects of various subtype-selective opioid agonists and antagonists on the phosphoinositide (PI) turnover response were investigated in the rat brain. The kappa-agonists U-50,488H and ketocyclazocine produced a concentration-dependent increase in the accumulation of IPs in hippocampal slices. The other kappa-agonists Dynorphin-A (1-13) amide, and its protected analog D[Ala]2-dynorphin-A (1-13) amide also produced a significant increase in the formation of [3H]-IPs, whereas the mu-selective agonists [D-Ala2-N-Me-Phe4-Gly5-ol]-enkephalin and morphine and the delta-selective agonist [D-Pen2,5]-enkephalin were ineffective. The increase in IPs formation elicited by U-50,488H was partially antagonized by naloxone and more completely antagonized by the kappa-selective antagonists nor-binaltorphimine and MR 2266. The formation of IPs induced by U-50,488H varies with the regions of the brain used, being highest in hippocampus and amygdala, and lowest in striatum and pons-medulla. The results indicate that brain kappa- but neither mu- nor delta-receptors are coupled to the PI turnover response.

Repression of transforming growth factor-β receptor type I promoter expression by Sp1 deficiency

In this report, we describe the mechanism of TGF-β receptor type I (RI) repression in the GEO human colon carcinoma cells. Treatment of GEO cells with the DNA methyltransferase inhibitor, 5 azacytidine induced RI expression and restored TGF-β response. A stably transfected RI promoter-reporter construct (RI-Luc) expressed higher activity in the 5 aza C treated GEO cells, suggesting the activation of a transactivator for RI transcription. Gel shift analysis indicated enhanced binding of proteins from the 5 aza C treated nuclear extracts to radiolabeled Sp1 oligonucleotides specifically contained in the RI promoter. Protein stability studies after cyclohexamide treatment suggested an increase in the Sp1 protein stability from the 5 aza C treated GEO cells. Further, transfection of Sp1 cDNA into untreated GEO control cells increased RI promoter activity and thus induced RI expression. 5 aza C mediated Sp1 expression in Sp1 deficient GEO colon and MCF-7 breast cancer cells also enhanced the activity of several other Sp1 dependent promoters such as TGF-β receptor type II (RII), Cyclin A and p21/waf1/cip1. These results indicate that restoration of Sp1 in several different types of Sp1 deficient cells leads to enhanced activation of a wide range of Sp1 dependent promoters.

Targeted Ablation Reveals a Novel Role of FKBP52 in Gene-Specific Regulation of Glucocorticoid Receptor Transcriptional Activity

FKBP52 is a tetratricopeptide repeat (TPR) protein with peptidyl-prolyl isomerase activity and is found in steroid receptor complexes, including glucocorticoid receptor (GR). It is generally accepted that FKBP52 has a stimulatory effect on GR transcriptional activity. However, the mechanism by which FKBP52 controls GR is not yet clear, with reports showing effects on GR hormone-binding affinity and/or hormone-induced nuclear translocation. To address this issue, we have generated mice with targeted ablation of the FKBP52 gene. To date, no overt defects of GR-regulated physiology have been found in these animals, demonstrating that FKBP52 is not an essential regulator of global GR activity. To better assess the impact of FKBP52 on GR, mouse embryonic fibroblasts (MEFs) were generated from wild-type (WT) and FKBP52-deficient (KO) animals. Analysis of GR activity at reporter genes showed an approximate 70% reduction of activity in 52KO MEF cells, with no effect of FKBP52 loss on thyroid receptor. Interestingly, GR activity at endogenous genes was not globally affected in 52KO cells, with reduced activity at GILZ and FKBP51, but not at SGK and p21. Thus, FKBP52 appears to be a gene-specific modulator of GR. To investigate the mechanism of this action, analyses of GR heterocomplex composition, hormone-binding affinity, and ability to undergo hormone-induced nuclear translocation and DNA-binding were performed. Interestingly, no effect of FKBP52 loss was found for any of these GR properties, suggesting that the main function of FKBP52 is a heretofore-unknown ability to control GR activity at target genes. Lastly, loss of FKBP52 did not affect the ability of GR to undergo hormone-induced autologous down-regulation, showing that FKBP52 does not contribute to all branches of GR signaling. The implications of these results to the potential actions of FKBP52 on GR activity in vivo are discussed.

Biochemical and behavioral responses of pilocarpine at muscarinic receptor subtypes in the CNS. Comparison with receptor binding and low-energy conformations

Pilocarpine was tested biochemically in vitro for its ability to stimulate phosphoinositide (PI) turnover in the hippocampus (M1/M3 responses) where it displayed 35% of the maximal carbachol response with an EC50 value of 18 microM, and low-Km GTPase in the cortex (M2 response), where it had 50% of the maximal carbachol response with an EC50 value of 4.5 microM. Behaviorally, pilocarpine was able to restore deficits in a representational memory task (sensitive to M1 antagonists) produced by intrahippocampal injections of AF64A. Twenty-three low-energy conformations of protonated pilocarpine were generated using the program MacroModel. The data indicate that pilocarpine is a partial agonist at both M1 and M2 muscarinic receptors in the CNS. Behaviorally, with respect to the memory task, M1 effects of pilocarpine apparently predominate. It also is conceivable that different conformations of pilocarpine are active as agonists at different muscarinic receptor subtypes.

Synthesis and biochemical activity of novel amidine derivatives as m1 muscarinic receptor agonists

As part of a continuing effort aimed at the development of selective, efficacious, and centrally active m1 muscarinic agonists for the treatment of Alzheimers disease, a series of amide and hydrazide amidine derivatives (2a-e and 3b-d) was synthesized and examined for muscarinic agonist activity. Preliminary biochemical studies indicated that 2b, 2d, and 3d bound to muscarinic receptors in rat brain and stimulated phosphoinositide (PI) metabolism in rat cerebral cortex. Compounds 2b and 2d were also highly efficacious at m1 muscarinic receptors expressed in cultured A9 L cells. Molecular modeling studies suggest slightly different modes of interaction with m1 receptors for the ester and amide derivatives. Also, hydrogen-bond formation with a Thr residue may be important for m1 muscarinic agonist potency. The data suggest that the amide moiety can replace the ester group found in muscarinic agonists and provide further support for the utility of amidine derivatives in the development of efficacious m1 agonists.

Inhibition of carbachol-stimulated phosphoinositide turnover by U-50,488H in rat hippocampus — involvement of GTP-binding protein

The effect of U-50,488H, a selective kappa-opioid agonist, on carbachol-stimulated phosphoinositide (PI) turnover response in rat hippocampal slices was examined. U-50,488H which stimulates PI turnover response in this preparation (Periyasamy and Hoss, 1990, Life Sci. 47, 219), inhibited carbachol-stimulated PI turnover in a concentration-dependent manner with an IC50 value of 33 +/- 9.0 microM. The inhibitory effect of U-50,488H was not blocked by the kappa-selective antagonists, e.g., nor-binaltorphimine (10 microM), and MR2266 (10 microM), or tetrodotoxin (1 microM) suggesting that the effect of U-50,488H was mediated neither through the kappa-receptors nor through the release of an endogenous neurotransmitter(s). A Lineweaver-Burke plot of the stimulation of PI turnover by carbachol in the presence and absence of U-50,488H showed that the Km was not changed (11.4 +/- 3.4 and 11.5 +/- 2.6 microM) whereas the Vmax was reduced from 3849 +/- 460 to 1534 +/- 31 cpm indicating that the inhibition was non-competitive. U-50,488H also inhibited guanosine 5-[beta, gamma-imido]triphosphate (Gpp[NH]p)-stimulated PI turnover in rat hippocampal membranes in a concentration-dependent manner with an IC50 value of 33 +/- 12 microM.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of the Phosphoinositide Cascade by Polyamines in Brain

Abstract: The endogenous polyamines spermidine and spermine enhanced guanosine 5′‐O‐(3‐thiotriphosphate) (GTP‐γ‐S)‐stimulated phosphoinositide turnover with EC50 values of 100 ± 30 and 50 ± 15 µM, respectively, whereas the synthetic polyamines N,N′‐bis(3‐aminopropyl)‐1,3‐propanediamine and ‐ethylenediamine inhibited GTP‐γ‐S‐stimulated phosphoinositide turnover, with maximal inhibition at 1 mM. Kinetic analysis of GTP‐γ‐S‐stimulated phosphoinositide turnover in the absence and presence of spermidine showed that the Km for GTP‐γ‐S was not changed (1,303 ± 270 and 1,069 ± 214 nM, respectively), whereas the Vmax was increased by 206% (1,566 ± 141 and 4,792 ± 84 cpm, respectively), indicating that spermidine and GTP‐γ‐S acted at different sites. Spermidine also enhanced Ca2+‐stimulated phosphoinositide turnover in the absence of GTP‐γ‐S by decreasing the Ca2+ requirement of the phosphoinositide‐specific phospholipase C. Arcaine and agmatine, polyamine antagonists at the NMDA receptor complex, did not block the effects of spermidine on GTP‐γ‐S‐ and Ca2+‐induced phosphoinositide turnover, suggesting that the spermidine effects are not mediated through these specific polyamine sites. Furthermore, spermidine increased the level of [3H]phosphatidylinositol 4‐phosphate (EC50 = 120 ± 10 µM), without affecting significantly the levels of [3H]phosphatidylinositol and [3H]phosphatidylinositol 4,5‐bisphosphate. Collectively these data indicate that the enhanced phosphoinositide turnover induced by spermidine in the presence of GTP‐γ‐S or Ca2+ is mediated through multiple levels of the phosphoinositide turnover cascade.