- Email: [email protected]
Thyromimetic effect of peroxisome proliferators
Biochimie (1993) 75,257-261 © Soci6t6 fran~aise de biochimie et biologie mol6culaire / Elsevier, Paris
257
Thyromimetic effect of peroxisome proliferators R Hertz, B Kalderon, J B a r - T a n a * Department of Human Nutrition and Metabolism, Hebrew University, Hadassah Medical School, PO Box 1172, Jerusalem 91010, Israel (Received 1 December 1992; accepted 19 January 1993)
Summary - - Xenobiotic amphipathic carboxylates of varying hydrophobic backbones, known collectively as 'peroxisome proliferators' (PP), affect lipoprotein metabolism, calorigenesis, liver redox and phosphate potentials and adipose conversion. Some biological effects exerted by PP are strikingly similar to those exerted by thyroid hormones (TH). Furthermore, similarly to TH, these compounds have been recently found to induce in euthyroid as well as thyroidectomized rats or in rat hepatocytes cultured in TH-free media, liver activities classically considered as TH-dependent, eg malic enzyme (ME) and S 14. The thyromimetic effect of PP could be accounted for by transcriptional activation of TH-dependent genes as verified by run-on transcription assays. The thyromimetic effect of PP was found not to be mediated by the TH nuclear receptor. Moreover, in contrast to TH, PP were ineffective as thyromimetic agents in the rat heart or pituitary cells, suggesting a tissue specificity different from that of TH. The overall thyromimetic effect of PP appears to involve transcriptional activation of TH-dependent genes, yet being mediated by a novel transduction pathway.
peroxisome proliferators / thyroid hormones Peroxisome proliferators The number of liver peroxisomes is relatively small under normal conditions, but may be markedly increased (10--40-fold) by treatment of rodents and other species with hypolipidemic drugs of the fibrate type (clofibric acid, bezafibrate, fenofibrate, nafenopin and others) [I, 2], substituted long chain dicarboxylic acids (MEDICA compounds [3]), thia acids [4], perfluoro acids [5], phthalate and adipate plasticizers [6] as well as other xenobiotics collectively defined as 'peroxisome proliferators' (PP). The increase in peroxisomes induced by PP is accompanied by a specific and differential induction (20-100-fold) of specific peroxisomal proteins (eg CN-insensitive palmitoylCoA oxidase, enoyl-CoA hydratase, and others) while other peroxisomal proteins are less affected (eg catalase). The induction of peroxisomal activities by PP may be accounted for by transcriptional activation of respective peroxisomal genes [7]. Chronic treatment * Correspondence and reprints
of rodents with PP may result in hepatic transformation. Hepatic transformation by PP does not involve direct DNA damage similar to that observed with genotoxic carcinogenes. It may result from excess peroxisomal H20:, formation leading to DNA damage and tumor initiation, or alternatively, could reflect the capacity of PP to act as liver tumor promoters. Similarly to the in vivo effects of PP, peroxisorne proliferation may be induced in rat hepatocytes cultured with PP [8, 9]. The pattern observed in culture is morphologically and biochemically similar to that generated in vivo. In both systems, the induction of peroxisomal proteins is accounted for by an increase in the rate of transcription of the respective genes with a concomitant increase in respective mRNA species ll0, 11]. In spite of their apparent structural heterogeneity, PP may have a common structural denominator. Indeed, most PP appear to consist of a carboxylic function carried on a hydrophobic backbone to yield an amphipathic carboxylate [3, 9, 12]. The carboxylic function may either be present initially (MEDICA,
258 fibrates, WY-14,6431) or may be derived by metabolic oxidation of respective alcohols or aldehydes (eg tiadenol, phthalate plasticizers). The free carboxylic function or a derivative thereof may thus be directly involved in the inductive process, whereas the nature of the hydrophobic backbone may determine the respective efficacy of PP. Recently, a new member of the steroid/TH receptors superfamily has been cloned using consensus sequences (and some of their variations) for the DNA binding domains of the h-glucocorticoid, estrogen, vitD3, retinoic acid and TH receptors [13]. The cloned receptor (PPAR) was found to mediate PP-induced chloramphenicol transacetylase (CAT) expression in COS-I cells transfected with an expression vector for a chimeric construct consisting of the ligand binding domain of PPAR linked to the DNA binding domain of either the glucocorticoid or the estrogen receptors, together with a CAT reporter plasmid linked to DNA sequences coding for the glucocorticoid (GRE) or the estrogen (ERE) response elements, respectively. This experimental system was further exploited to screen the efficiency of various PP as transcriptional activators of peroxisomal acyI-CoA oxidase [13]. The observed efficiency was correlated with the capacity of PP as inducers of peroxisome proliferation in rodents. Moreover, the PPAR cDNA was observed to hybridize with two major mRNA species of about 2.0 kb detectable in liver, kidney and heart, but not in brain or testis, in line with the tissue specificity of peroxisome proliferation induced by PP. However, PP did not bind to the expressed PPAR, possibly because of their apparent low affinity tbr PPAR or because of their possible indirect action in inducing peroxisomal activities mediated by PPAR. The DNA binding domain of PPAR contains a sequence-specific DNA binding site (Cys(ll9)-GiuGly-Cys-Lys-Gly) expected to recognize the DNA motif TGACC. Indeed, two cis-acting regulatory sequences have been recently characterized by Osumi et al [141 in the peroxisome proliferator responsive enhancer of rat peroxisomal acyl-CoA oxidase. One sequence (-578/-520) was tbund to exert a positive regulation of transcription, whereas the other one (--472/-129) exerted a negative action, The positive enhancer consists of a TGACCTTTGTCC sequence (-570/-559) and may putatively be considered as a peroxisome proliferator response element (PPRE) mediating transcriptional activation of respective peroxisomal genes by PPAR and PP [15].
Thyroid hormones and thyroid hormone dependent genes The pleiotropic actions of thyroid hormones (TH) consist of modulating differentiation and develop-
ment, calorie metabolism, lipoprotein metabolism, cardiac and skeletal muscle functions and others (reviewed in [16-19]). The pleiotropic actions of TH may be partly accounted for by tissue-specific transcriptional activation/inhibition of TH dependent genes (reviewed in [20]), such as those coding for pituitary growth hormone (GH) and tx-/~-TSH, liver malic enzyme (ME), mitochondrial glycerol-3-phosphate dehydrogenase, S 14, fatty acid synthetase, HMG-CoA reductase, glucokinase, PFK-2 and LDL-receptor, cardiac o~-/~l-myosin heavy chain kinase (MHC) and CaATPase, Na-K ATPase (liver, kidney, muscle), and others. In addition to transcriptional regulation of THdependent genes, TH may affect mRNAs stability (eg GH, ME, S14, apolipoprotein AI), mRNA editing (eg apolipoprotein B 100/48) or degradation of respective proteins (eg tadpole liver carbamyl phosphate synthetase, brain tubulin). It is unclear whether post-transcriptional effects of TH on specific gene expression are secondarily mediated by factors which are transcriptionally regulated by TH. The 'nuclear pathway' of TH action is initiated by TH binding to TH nuclear receptors (reviewed in [20, 21]). Transcriptional activation results from interaction of the TH nuclear receptors with DNA sequences that act as thyroid hormone response elements (TRE) of TH-dependent genes. Using v-erbA sequences as probes, a number of highly related c-erbA clones were identified from avian, mammalian and Xenopus cDNA libraries which encode proteins with properties of TH receptors, namely, high affinity TH binding, binding to TREs of TH-dependent genes as well as conferring TH-dependent regulation of transcription in TH receptor-negative cells. The ic-erbA gene products were found to be highly related to other members of the steroid/TH super-family of nuclear receptors [22], all being characterized by a highly conserved cysteine-rich Zn-finger domain that functions in sequence-specific DNA binding together with a ligand binding domain which binds the respective specific ligands. Two mammalian c-erbA genes have been identified. The tx-form is localized (in humans) on chromosome 17 and gives rise through alternative splicing to the 0q, o~2 and other (rev erb/ear 7) TH receptor subtypes [23]. The ~l-fonn is localized in humans on chromosome 3 and gives rise to the ~-TH receptor subtypes [241. The o~2 variant is not capable of TH binding but still may act as a modulator of TH receptors function. Transcriptional activation by TH receptors is mediated by their binding to respective TREs having specific sequence determinants. A core binding consensus motif based on comparing TRE sequences of various TH dependent genes (rGH, rTSH, rotMHC, MoMLV, rME) appears to consist of two half site (A/G)GG(T/A)(C/G)(A/G) sequences flanked by a
259 cluster of G residues (ME) [21, 25]. A somewhat different sequence ((G/A)GGGCCTG) has been recently suggested based on defining the S14 TREs [26]. The core binding motif usually is a direct tandem repeat or an inverse repeat or a palindrome, suggesting dimerization of receptors upon their binding to respective TREs. Dimerization is believed to be governed by amino acids constituting the D box of the 2nd Znfinger [27] as well as dimerization motifs within the ligand binding domain [28]. Moreover, the interaction of TH receptors with their TREs may be modulated by TH receptor-auxiliary proteins (TRAP) [29], other receptors related to the superfamily (eg RXR, c-erbAtt2) [30] or other transcriptional factors (eg AP-1).
Thyromimetic effect of PP The biological activity of PP is not limited to induction of peroxisomal activities. Activities induced by PP appear to be very similar to those induced by TH. a) TH [18] and PP [31, 32] are potent hypolipidemic agents. Their hypo-lipidemic effect is due to inhibition of liver VLDL production together with activation of plasma lipoproteins clearance [33, 34]. b) TH [16. 35] and PP [36-38] act as potent effectors of adipose mass. Lipolysis is initiated by a left shift in the response curve to lipolytic hormones with a concomitant decrease in fatty acid re-esterification. The enhanced iipolytic response is accompanied by an increase in mitochondrial liver uptake of free fatty acids (due to a decrease in mitochondrial malonyl-CoA [39, 40]), with a concomitant increase in mitochondrial oxidation of long chain fatty acids and ketogenesis [ 18, 41 ]. c) The calorigenic-hypolipidemic effects of TH and PP may be partially reduced to basic principles related to liver redox and phosphate potentials [42, 43]. Treatment of rats with either TH or MEDICA resulted in decreases of liver cytosolic redox potential (2.0- and 3.5-fold, respectively) concomitant with an increase in the liver capacity of handling an ethanol or xylitol load. The apparent liver cytosolic phosphate potential was found to remain unaffected by TH or MEDICA while the apparent mitochondrial phosphate potential was substantially decreased by both treatments. d) The similarity of effects exerted by PP and TH on hypolipidemia, calorigenesis and liver redox/phosphate potentials may indicate that the thyromimetic effect of PP reflects their capacity to act as transcriptional activators in general and of TH dependent genes in particular. Several PP have been recently found by Hertz et al [ 11] to induce in euthyroid, thyroidectomized rats or in rats made hypothyroid by methimazole liver activi-
ties classically considered as TH-dependent, eg malic enzyme (ME) mitochondrial glycerol-3-phosphate dehydrogenase, glucose 6-phosphate dehydrogenase and S14. The maximal inductive potential of PP with respect to the above activities was similar to that of TH. However, the doses required for inducing the thyromimetic response in vivo were in the mg/kg-range for PP and the ~tg/kg-range for TH. e) The thyromimetic effect of PP with respect to ME, S14 and mitochondrial glycerol-3-phosphate dehydrogenase was similarly observed in rat hepatocytes cultured in TH-free media and in the presence of PP added to the culture medium [11]. The concentrations of PP required in culture were in 104-105 fold higher (l.tM range) than those of TH (pM range). However, the maximal activities of ME and S14 induced by PP were similar to or higher than those induced by TH. f) As for TH, the thyromimetic inductive effects of PP with respect to liver malic enzyme and S14 were found to result from increases in the corresponding mRNA contents, and the increases in liver ME and S14 mRNAs induced by PP were accounted for by transcriptional activation of the S14 genes as verified by run-on transcription assays [ 11]. g) The thyromimetic effect of PP is not accounted for by modulating plasma TH levels. No significant differences in plasma T4, T3, TSH and T3-uptake were noted in PP-treated euthyroid rats [43]. Furthermore, the thyromimetic effect of PP was observed in thyroidectomized rats, in methimazole-induced hypothyroid rats and in rat hepatocytes cultured in TH-free media. h) In contrast to TH, the thyromimetic effect of PP is not mediated by the TH nuclear receptor. TH binding to isolated liver nuclei or to liver nuclear extract was competitively displaced by some, but not all, PP capable of inducing TH-dependent liver activities [11]. The thyromimetic effect o1: PP is mediated by a transduction pathway different from that involved in the thyromimetic effect induced by TH. i) The tissue specificity of the thyromimetic effect of PP is different from that of TH. No increase in growth honnone (GH) mRNA was observed in cultured GHI pituitary cells incubated in the presence of PP under conditions where TH was found to induce GH mRNA [11]. Heart high energy intermediates were observed to be dramatically affected by TH but not by MEDICA treatment, in contrast to liver where both TH and MEDICA were found to affect cellular high energy adenine nucleotides and phosphate content [43]. Similarly, mitochondrial glycerol-3phosphate dehydrogenase and ME could be induced by both treatment modes in liver, whereas the two cardiac activities (including ME mRNA) 'were induced by TH only while MEDICA was without effect. This
260 tissue selectivity of PP could reflect selectivity in transport, or tissue specific metabolic conversion into an active immediate effector (eg CoA thioester) or a transduction pathway other than that mediating the effect exerted by TH. Conclusions
The scope of the effects induced by xenobiotic amphipathic carboxylates collectively defined as 'peroxisomal proliferators' may indicate that these compounds should be realized as eminent biological effectors capable of modulating transcriptional activation of genes other than those related to peroxisomes. Some of the major therapeutic/toxic effects induced by PP should be considered within the framework of their thyromimetic activity. Searching for a transduction pathway mediating the thyromimetic activity of PP may result in novel mechanisms involved in their pleiotropic action. References
! 2
3
4
5
6 7
8
9
Reddy JK, Warren JR, Reddy MK, Lalwani ND (1982) Hepatic and renal effects of peroxisome proliferators: Biological implications. Ann NY Acad Sci 386, 81-108 Fahimi HD, Reinicke A, Sujatta M, Yokota S, Ozel M, Hartig E Stegmier K (1982) The shot- and long-term effects of bezatibrate in the rat. Ann NY Acad Sci 386, 111-132 Hertz R. Bar-Tana J, Sujatta M, Pill J, Schmidt FH, Fahimi DH (1988) The induction of liver peroxisomal proliferation by [3,[3'-methyl-substituted hexadecanedioic acid. Biochem Pharmaco137, 3571-3577 Berge RK, Aarsland A, Kryvi H, Bremer J, Aarsaether N (1989) Akylthio-aceti¢ acid (3-thia fatty acids)- a new group of non-[3-oxidizable, peroxisome-inducing fatty acid analogues. Biochim Biophys Acta 1004, 345-356 Ikeda 1", Aiba K, Fukude K, Tanaka M (1985) The induction of peroxisome proliferation in rat liver by perfluorihated fatty acids, metabolically inert derivatives of fatty acids. J Biochem 98, 475-482 Moody DE, Reddy JK (1978) Hepatic peroxisome (microbody) proliferation in rats fed plasticizers and related compounds. Toxicol App Pharmaco145, 497-504 Reddy JK, Goel SK, Nemali MR, Carvino JJ, Laffier TG, Reddy MK, Sperbeck ST, Osumi T, Hashimoto T, Lalwani ND, Rao MS (1986) Transcriptional regulation of peroxisomal fatty acyl-CoA oxidase and enoyl-CoA hydratase/3hydroxyacyl-CoA dehydrogenase in rat liver by peroxisome proliferators. Proc Natl Acad Sci USA 83, 1747- ! 75 I Gray TJB, Beamand JA, Lake BG, Foster JR, Gangolli SD (1982) Peroxisome proliferation in cultured rat hepatocytes produced by clofibrate and phthalate ester metabolites. Toxicoi Lett 10, 273-279 Hertz R, Arnon J, Bar-Tana J (1985) The effect of bezafibrate and long chain fatty acids on peroxisomai activities in cultured rat hepatocytes. Biochim Biophys Acta 836, 192-200
10 Ozasa H, Miyazawa S, Furuta S, Osumi T, Hashimoto T (1985) Induction of peroxisomal [3-oxidation enzymes in primary cultured rat hepatocytes by clofibric acid. J Biochem 97, 1273-1278 1i Hertz R, Aurbach R, Hashimoto T, Bar-Tana J (1991) Thyromimetic effect of peroxisomal proliferators in rat liver. Biochem J, 274, 745-751 12 Intrasuksri U, Feller DR (1991) Comparison of the effects of selected monocarboxylic, dicarboxylic and perfluorinated fatty acids on peroxisome proliferation in cultured rat hepatocytes. Biochem Pharmaco142, 18:l--188 13 Issemann I, Green S (1990) Activation of a member of the steroid hormone receptor superfamily by peroxisome proiiferators. Nature 347, 645-650 14 Osumi T, Wen J-K, Hashimoto T (1991) Two cis-acting regulatory sequences in the peroxisome proliferator responsive enhancer of rat acyl-CoA oxidase gene. Biochem Biophys Res Commun 175,866-871 15 Tugwood JD, Issemann I, Anderson RG, Bundell KR, McPheat WL, Green S (1992) The mouse peroxisome proliferator activated receptor recognizes a response element in the 5'-flanking sequence of the rat acyl-CoA oxidase gene. EMBO J 11,433-439 16 Sestoft L (1980) Metabolic aspects of the calorigenic effect of thyroid hormone in mammals. Clin Endocrinol 13. 489-506 17 Muller MJ, Seitz HJ (1984) Pleiotropic action of thyroid hormones at the target cell level. Biochem Pharmacol 33, 1579-1584 18 Heimberg M, Olubadew JO, Wilcox HG (1985) Plasma iipoproteins and regulation of hepatic metabolism of fatty acids in altered thyroid states. Endocrinoi Rev 6, 590-607. 19 Oppenheimer JH, Schwartz HL, Mariash CN, Kinlaw WB, Wang NCW, Freake HC (1987) Advances in our understanding of thyroid hormone action at the cellular level. Endocrinoi Rev 8, 288-308 20 Glass CK, Holloway JM (1990) Regulation of gene expression by thyroid hormone. Biochim Biophys Acta 1032, 157-176 21 Samueis HH, Forman BM, Horowitz Z, Zheng-Sheng Y (1988) Regulation of gene expression by the thyroid hormone receptor. J Clin Invest 81,957-967 22 Evans RM (1988) The steroid thyroid hormone receptor supeffamily. Science 240, 889-895. 23 Thompson CC, Weinberger C, Lebo R, Evans RM (1987) Identification of a novel thyroid hormone receptor expressed in the mammalian control nervous system. Science 237, 1610-1614 24 Koenig RJ, Warne RL, Brent GA, Harvey JW, Larsen PR, Moore DD (1988) Isolation of a cDNA clone encoding a biologically active thyroid hormone receptor. Proc Natl Acad Sci USA 65, 5031-5035 25 Petty KJ, Desvergne B, Mitsuhashi T, Nikodem VM (1990) Identification of a thyroid hormone response element in the malic enzyme gene. J Biol Chem 265, 7395-7400 26 Zilz ND, Murray MB, Towle HC (1990) Identification of multiple thyroid hormone response elements located far upsteam from the rat S14 promoter. J Biol Chem 266, 8136-8143 27 Umesono K, Evans RM (1989) Determinants of target gene specificity for steroid/thyroid hormone receptors. Cell 57, 1139-1146 28 Fawell SE, Lees JA, White R, Parker MG (1990) Characterization and colocalization of steroid binding and dime-
261 rization activities in the mouse estrogen receptor. Cell 60, 953-962 29 Rosen ED, O'Donnell AC, Koenig RJ (1991) Protein-protein interactions involving erbA superfamily receptors: through the TRAP door. Mol Cell Endocrinol 78, C83--C89 30 Forman BM, Yang C-R, Au M, Casanova J, Ghysdael J, Samuels HH (1989) A domain containing leucine zipper like motifs mediates novel in vivo interactions between the thyroid hormone and retinoic acid receptors. Mol Endocrinoi 3, 1610--1626 31 Sintoni CR, Francheschini G (1988) Effects of fibrates on serum lipids and atherosclerosis. Pharmacol Ther 34, 167-191 32 Bar-Tana J, Rose-Kahn G, Frenkel B, Shafer Z, Fainaru M (1988) The hypolipidemic effect of [3,13'-methyl-substituted hexadecanedioic acid in normal and nephrotic rats. JLipidRes 29, 431-441 33 Kahn-Rose G, Bar-Tana J (1985) Inhibition of lipid synthesis by [~,13'-tetramethyl-substituted C14-C22a, dicarboxylic acids in cultured rat hepatocytes. J Biol Chem 260, 8411-8315 34 Frenkel B, Mayorek N, Hertz R, Bar-Tana J (1988) The hypochylomicronemic effect of 13,13'-methyl-substituted hexadecanedioic acid is mediated by a decrease in apolipoprotein C-Ill. J Biol Chem 263, 8491-8497 35 Oppenheimer JH, Schwartz HL, Lane JT, Thompson MP (1991) Functional relationship of thyroid hormoneinduced lipogenesis, lipolysis and thermogenesis in the rat. J Clin Invest 87, 125-132
36
37 38
39
40
41 42 43
Tzur R, Rose-Kahn G, Adler J, Bar-Tana J (1988) The hypolipidemic, antiobesity and hypoglycemic effects of [3,13'-methyl-substituted hexa-decanedioic acid in sand rats. Diabetes 37, 1618-1624 Tzur R, Smith E, Bar-Tana J (1989) Adipose reduction by [3,13'-tetra-methyl-substituted hexadecanedioic acid. Int J Obesity 13, 313-326 Assimacopoulus-Jeannet F, Monat M, Muzzin P., Colomb C, Jeanrenaud B, Girardier L, Giacobino JP, Seydonx V (1991) Effects of a peroxisome proliferator on [3-oxidation and overall energy balance in obese (fa/fa) rats. Am J Physio1260, R278-R283 Bar-Tana J, Kahn-Rose G, Srebnik B (1985) Inhibition of lipid synthesis by 13,[3'-tetramethyl-substituted C14-C22, a, dicarboxylic acids in the rat in vivo. J Biol Chem 260, 8404-8410 Lund H, Stakkestad JA, Skrede S (1986) Effects of thyroid state and fasting in the concentrations of CoA and malonyl-CoA in rat liver. Biochim Biophys Acta 876, 685-687 Bartels PD, Kistensen LO, Heding LG, Sestoft L (1979) Development of ketonemia in fasting patients with hyperthyroidsm. Acta Med Scand Supp1624, 43-47 Kalderon B, Hertz R, Bar-Tana J (1992) Effect of thyroid hormone treatment on redox and phosphate potentials in rat liver. Endocrinology 131,399--407 Kalderon B, Hertz R, Bar-Tana J (1992) Tissue selective modulation of redox and phosphate potentials by [3,13'methyl-substituted hexadecanedioic acid. Endocrinology 131, 1629-1635
257
Thyromimetic effect of peroxisome proliferators R Hertz, B Kalderon, J B a r - T a n a * Department of Human Nutrition and Metabolism, Hebrew University, Hadassah Medical School, PO Box 1172, Jerusalem 91010, Israel (Received 1 December 1992; accepted 19 January 1993)
Summary - - Xenobiotic amphipathic carboxylates of varying hydrophobic backbones, known collectively as 'peroxisome proliferators' (PP), affect lipoprotein metabolism, calorigenesis, liver redox and phosphate potentials and adipose conversion. Some biological effects exerted by PP are strikingly similar to those exerted by thyroid hormones (TH). Furthermore, similarly to TH, these compounds have been recently found to induce in euthyroid as well as thyroidectomized rats or in rat hepatocytes cultured in TH-free media, liver activities classically considered as TH-dependent, eg malic enzyme (ME) and S 14. The thyromimetic effect of PP could be accounted for by transcriptional activation of TH-dependent genes as verified by run-on transcription assays. The thyromimetic effect of PP was found not to be mediated by the TH nuclear receptor. Moreover, in contrast to TH, PP were ineffective as thyromimetic agents in the rat heart or pituitary cells, suggesting a tissue specificity different from that of TH. The overall thyromimetic effect of PP appears to involve transcriptional activation of TH-dependent genes, yet being mediated by a novel transduction pathway.
peroxisome proliferators / thyroid hormones Peroxisome proliferators The number of liver peroxisomes is relatively small under normal conditions, but may be markedly increased (10--40-fold) by treatment of rodents and other species with hypolipidemic drugs of the fibrate type (clofibric acid, bezafibrate, fenofibrate, nafenopin and others) [I, 2], substituted long chain dicarboxylic acids (MEDICA compounds [3]), thia acids [4], perfluoro acids [5], phthalate and adipate plasticizers [6] as well as other xenobiotics collectively defined as 'peroxisome proliferators' (PP). The increase in peroxisomes induced by PP is accompanied by a specific and differential induction (20-100-fold) of specific peroxisomal proteins (eg CN-insensitive palmitoylCoA oxidase, enoyl-CoA hydratase, and others) while other peroxisomal proteins are less affected (eg catalase). The induction of peroxisomal activities by PP may be accounted for by transcriptional activation of respective peroxisomal genes [7]. Chronic treatment * Correspondence and reprints
of rodents with PP may result in hepatic transformation. Hepatic transformation by PP does not involve direct DNA damage similar to that observed with genotoxic carcinogenes. It may result from excess peroxisomal H20:, formation leading to DNA damage and tumor initiation, or alternatively, could reflect the capacity of PP to act as liver tumor promoters. Similarly to the in vivo effects of PP, peroxisorne proliferation may be induced in rat hepatocytes cultured with PP [8, 9]. The pattern observed in culture is morphologically and biochemically similar to that generated in vivo. In both systems, the induction of peroxisomal proteins is accounted for by an increase in the rate of transcription of the respective genes with a concomitant increase in respective mRNA species ll0, 11]. In spite of their apparent structural heterogeneity, PP may have a common structural denominator. Indeed, most PP appear to consist of a carboxylic function carried on a hydrophobic backbone to yield an amphipathic carboxylate [3, 9, 12]. The carboxylic function may either be present initially (MEDICA,
258 fibrates, WY-14,6431) or may be derived by metabolic oxidation of respective alcohols or aldehydes (eg tiadenol, phthalate plasticizers). The free carboxylic function or a derivative thereof may thus be directly involved in the inductive process, whereas the nature of the hydrophobic backbone may determine the respective efficacy of PP. Recently, a new member of the steroid/TH receptors superfamily has been cloned using consensus sequences (and some of their variations) for the DNA binding domains of the h-glucocorticoid, estrogen, vitD3, retinoic acid and TH receptors [13]. The cloned receptor (PPAR) was found to mediate PP-induced chloramphenicol transacetylase (CAT) expression in COS-I cells transfected with an expression vector for a chimeric construct consisting of the ligand binding domain of PPAR linked to the DNA binding domain of either the glucocorticoid or the estrogen receptors, together with a CAT reporter plasmid linked to DNA sequences coding for the glucocorticoid (GRE) or the estrogen (ERE) response elements, respectively. This experimental system was further exploited to screen the efficiency of various PP as transcriptional activators of peroxisomal acyI-CoA oxidase [13]. The observed efficiency was correlated with the capacity of PP as inducers of peroxisome proliferation in rodents. Moreover, the PPAR cDNA was observed to hybridize with two major mRNA species of about 2.0 kb detectable in liver, kidney and heart, but not in brain or testis, in line with the tissue specificity of peroxisome proliferation induced by PP. However, PP did not bind to the expressed PPAR, possibly because of their apparent low affinity tbr PPAR or because of their possible indirect action in inducing peroxisomal activities mediated by PPAR. The DNA binding domain of PPAR contains a sequence-specific DNA binding site (Cys(ll9)-GiuGly-Cys-Lys-Gly) expected to recognize the DNA motif TGACC. Indeed, two cis-acting regulatory sequences have been recently characterized by Osumi et al [141 in the peroxisome proliferator responsive enhancer of rat peroxisomal acyl-CoA oxidase. One sequence (-578/-520) was tbund to exert a positive regulation of transcription, whereas the other one (--472/-129) exerted a negative action, The positive enhancer consists of a TGACCTTTGTCC sequence (-570/-559) and may putatively be considered as a peroxisome proliferator response element (PPRE) mediating transcriptional activation of respective peroxisomal genes by PPAR and PP [15].
Thyroid hormones and thyroid hormone dependent genes The pleiotropic actions of thyroid hormones (TH) consist of modulating differentiation and develop-
ment, calorie metabolism, lipoprotein metabolism, cardiac and skeletal muscle functions and others (reviewed in [16-19]). The pleiotropic actions of TH may be partly accounted for by tissue-specific transcriptional activation/inhibition of TH dependent genes (reviewed in [20]), such as those coding for pituitary growth hormone (GH) and tx-/~-TSH, liver malic enzyme (ME), mitochondrial glycerol-3-phosphate dehydrogenase, S 14, fatty acid synthetase, HMG-CoA reductase, glucokinase, PFK-2 and LDL-receptor, cardiac o~-/~l-myosin heavy chain kinase (MHC) and CaATPase, Na-K ATPase (liver, kidney, muscle), and others. In addition to transcriptional regulation of THdependent genes, TH may affect mRNAs stability (eg GH, ME, S14, apolipoprotein AI), mRNA editing (eg apolipoprotein B 100/48) or degradation of respective proteins (eg tadpole liver carbamyl phosphate synthetase, brain tubulin). It is unclear whether post-transcriptional effects of TH on specific gene expression are secondarily mediated by factors which are transcriptionally regulated by TH. The 'nuclear pathway' of TH action is initiated by TH binding to TH nuclear receptors (reviewed in [20, 21]). Transcriptional activation results from interaction of the TH nuclear receptors with DNA sequences that act as thyroid hormone response elements (TRE) of TH-dependent genes. Using v-erbA sequences as probes, a number of highly related c-erbA clones were identified from avian, mammalian and Xenopus cDNA libraries which encode proteins with properties of TH receptors, namely, high affinity TH binding, binding to TREs of TH-dependent genes as well as conferring TH-dependent regulation of transcription in TH receptor-negative cells. The ic-erbA gene products were found to be highly related to other members of the steroid/TH super-family of nuclear receptors [22], all being characterized by a highly conserved cysteine-rich Zn-finger domain that functions in sequence-specific DNA binding together with a ligand binding domain which binds the respective specific ligands. Two mammalian c-erbA genes have been identified. The tx-form is localized (in humans) on chromosome 17 and gives rise through alternative splicing to the 0q, o~2 and other (rev erb/ear 7) TH receptor subtypes [23]. The ~l-fonn is localized in humans on chromosome 3 and gives rise to the ~-TH receptor subtypes [241. The o~2 variant is not capable of TH binding but still may act as a modulator of TH receptors function. Transcriptional activation by TH receptors is mediated by their binding to respective TREs having specific sequence determinants. A core binding consensus motif based on comparing TRE sequences of various TH dependent genes (rGH, rTSH, rotMHC, MoMLV, rME) appears to consist of two half site (A/G)GG(T/A)(C/G)(A/G) sequences flanked by a
259 cluster of G residues (ME) [21, 25]. A somewhat different sequence ((G/A)GGGCCTG) has been recently suggested based on defining the S14 TREs [26]. The core binding motif usually is a direct tandem repeat or an inverse repeat or a palindrome, suggesting dimerization of receptors upon their binding to respective TREs. Dimerization is believed to be governed by amino acids constituting the D box of the 2nd Znfinger [27] as well as dimerization motifs within the ligand binding domain [28]. Moreover, the interaction of TH receptors with their TREs may be modulated by TH receptor-auxiliary proteins (TRAP) [29], other receptors related to the superfamily (eg RXR, c-erbAtt2) [30] or other transcriptional factors (eg AP-1).
Thyromimetic effect of PP The biological activity of PP is not limited to induction of peroxisomal activities. Activities induced by PP appear to be very similar to those induced by TH. a) TH [18] and PP [31, 32] are potent hypolipidemic agents. Their hypo-lipidemic effect is due to inhibition of liver VLDL production together with activation of plasma lipoproteins clearance [33, 34]. b) TH [16. 35] and PP [36-38] act as potent effectors of adipose mass. Lipolysis is initiated by a left shift in the response curve to lipolytic hormones with a concomitant decrease in fatty acid re-esterification. The enhanced iipolytic response is accompanied by an increase in mitochondrial liver uptake of free fatty acids (due to a decrease in mitochondrial malonyl-CoA [39, 40]), with a concomitant increase in mitochondrial oxidation of long chain fatty acids and ketogenesis [ 18, 41 ]. c) The calorigenic-hypolipidemic effects of TH and PP may be partially reduced to basic principles related to liver redox and phosphate potentials [42, 43]. Treatment of rats with either TH or MEDICA resulted in decreases of liver cytosolic redox potential (2.0- and 3.5-fold, respectively) concomitant with an increase in the liver capacity of handling an ethanol or xylitol load. The apparent liver cytosolic phosphate potential was found to remain unaffected by TH or MEDICA while the apparent mitochondrial phosphate potential was substantially decreased by both treatments. d) The similarity of effects exerted by PP and TH on hypolipidemia, calorigenesis and liver redox/phosphate potentials may indicate that the thyromimetic effect of PP reflects their capacity to act as transcriptional activators in general and of TH dependent genes in particular. Several PP have been recently found by Hertz et al [ 11] to induce in euthyroid, thyroidectomized rats or in rats made hypothyroid by methimazole liver activi-
ties classically considered as TH-dependent, eg malic enzyme (ME) mitochondrial glycerol-3-phosphate dehydrogenase, glucose 6-phosphate dehydrogenase and S14. The maximal inductive potential of PP with respect to the above activities was similar to that of TH. However, the doses required for inducing the thyromimetic response in vivo were in the mg/kg-range for PP and the ~tg/kg-range for TH. e) The thyromimetic effect of PP with respect to ME, S14 and mitochondrial glycerol-3-phosphate dehydrogenase was similarly observed in rat hepatocytes cultured in TH-free media and in the presence of PP added to the culture medium [11]. The concentrations of PP required in culture were in 104-105 fold higher (l.tM range) than those of TH (pM range). However, the maximal activities of ME and S14 induced by PP were similar to or higher than those induced by TH. f) As for TH, the thyromimetic inductive effects of PP with respect to liver malic enzyme and S14 were found to result from increases in the corresponding mRNA contents, and the increases in liver ME and S14 mRNAs induced by PP were accounted for by transcriptional activation of the S14 genes as verified by run-on transcription assays [ 11]. g) The thyromimetic effect of PP is not accounted for by modulating plasma TH levels. No significant differences in plasma T4, T3, TSH and T3-uptake were noted in PP-treated euthyroid rats [43]. Furthermore, the thyromimetic effect of PP was observed in thyroidectomized rats, in methimazole-induced hypothyroid rats and in rat hepatocytes cultured in TH-free media. h) In contrast to TH, the thyromimetic effect of PP is not mediated by the TH nuclear receptor. TH binding to isolated liver nuclei or to liver nuclear extract was competitively displaced by some, but not all, PP capable of inducing TH-dependent liver activities [11]. The thyromimetic effect o1: PP is mediated by a transduction pathway different from that involved in the thyromimetic effect induced by TH. i) The tissue specificity of the thyromimetic effect of PP is different from that of TH. No increase in growth honnone (GH) mRNA was observed in cultured GHI pituitary cells incubated in the presence of PP under conditions where TH was found to induce GH mRNA [11]. Heart high energy intermediates were observed to be dramatically affected by TH but not by MEDICA treatment, in contrast to liver where both TH and MEDICA were found to affect cellular high energy adenine nucleotides and phosphate content [43]. Similarly, mitochondrial glycerol-3phosphate dehydrogenase and ME could be induced by both treatment modes in liver, whereas the two cardiac activities (including ME mRNA) 'were induced by TH only while MEDICA was without effect. This
260 tissue selectivity of PP could reflect selectivity in transport, or tissue specific metabolic conversion into an active immediate effector (eg CoA thioester) or a transduction pathway other than that mediating the effect exerted by TH. Conclusions
The scope of the effects induced by xenobiotic amphipathic carboxylates collectively defined as 'peroxisomal proliferators' may indicate that these compounds should be realized as eminent biological effectors capable of modulating transcriptional activation of genes other than those related to peroxisomes. Some of the major therapeutic/toxic effects induced by PP should be considered within the framework of their thyromimetic activity. Searching for a transduction pathway mediating the thyromimetic activity of PP may result in novel mechanisms involved in their pleiotropic action. References
! 2
3
4
5
6 7
8
9
Reddy JK, Warren JR, Reddy MK, Lalwani ND (1982) Hepatic and renal effects of peroxisome proliferators: Biological implications. Ann NY Acad Sci 386, 81-108 Fahimi HD, Reinicke A, Sujatta M, Yokota S, Ozel M, Hartig E Stegmier K (1982) The shot- and long-term effects of bezatibrate in the rat. Ann NY Acad Sci 386, 111-132 Hertz R. Bar-Tana J, Sujatta M, Pill J, Schmidt FH, Fahimi DH (1988) The induction of liver peroxisomal proliferation by [3,[3'-methyl-substituted hexadecanedioic acid. Biochem Pharmaco137, 3571-3577 Berge RK, Aarsland A, Kryvi H, Bremer J, Aarsaether N (1989) Akylthio-aceti¢ acid (3-thia fatty acids)- a new group of non-[3-oxidizable, peroxisome-inducing fatty acid analogues. Biochim Biophys Acta 1004, 345-356 Ikeda 1", Aiba K, Fukude K, Tanaka M (1985) The induction of peroxisome proliferation in rat liver by perfluorihated fatty acids, metabolically inert derivatives of fatty acids. J Biochem 98, 475-482 Moody DE, Reddy JK (1978) Hepatic peroxisome (microbody) proliferation in rats fed plasticizers and related compounds. Toxicol App Pharmaco145, 497-504 Reddy JK, Goel SK, Nemali MR, Carvino JJ, Laffier TG, Reddy MK, Sperbeck ST, Osumi T, Hashimoto T, Lalwani ND, Rao MS (1986) Transcriptional regulation of peroxisomal fatty acyl-CoA oxidase and enoyl-CoA hydratase/3hydroxyacyl-CoA dehydrogenase in rat liver by peroxisome proliferators. Proc Natl Acad Sci USA 83, 1747- ! 75 I Gray TJB, Beamand JA, Lake BG, Foster JR, Gangolli SD (1982) Peroxisome proliferation in cultured rat hepatocytes produced by clofibrate and phthalate ester metabolites. Toxicoi Lett 10, 273-279 Hertz R, Arnon J, Bar-Tana J (1985) The effect of bezafibrate and long chain fatty acids on peroxisomai activities in cultured rat hepatocytes. Biochim Biophys Acta 836, 192-200
10 Ozasa H, Miyazawa S, Furuta S, Osumi T, Hashimoto T (1985) Induction of peroxisomal [3-oxidation enzymes in primary cultured rat hepatocytes by clofibric acid. J Biochem 97, 1273-1278 1i Hertz R, Aurbach R, Hashimoto T, Bar-Tana J (1991) Thyromimetic effect of peroxisomal proliferators in rat liver. Biochem J, 274, 745-751 12 Intrasuksri U, Feller DR (1991) Comparison of the effects of selected monocarboxylic, dicarboxylic and perfluorinated fatty acids on peroxisome proliferation in cultured rat hepatocytes. Biochem Pharmaco142, 18:l--188 13 Issemann I, Green S (1990) Activation of a member of the steroid hormone receptor superfamily by peroxisome proiiferators. Nature 347, 645-650 14 Osumi T, Wen J-K, Hashimoto T (1991) Two cis-acting regulatory sequences in the peroxisome proliferator responsive enhancer of rat acyl-CoA oxidase gene. Biochem Biophys Res Commun 175,866-871 15 Tugwood JD, Issemann I, Anderson RG, Bundell KR, McPheat WL, Green S (1992) The mouse peroxisome proliferator activated receptor recognizes a response element in the 5'-flanking sequence of the rat acyl-CoA oxidase gene. EMBO J 11,433-439 16 Sestoft L (1980) Metabolic aspects of the calorigenic effect of thyroid hormone in mammals. Clin Endocrinol 13. 489-506 17 Muller MJ, Seitz HJ (1984) Pleiotropic action of thyroid hormones at the target cell level. Biochem Pharmacol 33, 1579-1584 18 Heimberg M, Olubadew JO, Wilcox HG (1985) Plasma iipoproteins and regulation of hepatic metabolism of fatty acids in altered thyroid states. Endocrinoi Rev 6, 590-607. 19 Oppenheimer JH, Schwartz HL, Mariash CN, Kinlaw WB, Wang NCW, Freake HC (1987) Advances in our understanding of thyroid hormone action at the cellular level. Endocrinoi Rev 8, 288-308 20 Glass CK, Holloway JM (1990) Regulation of gene expression by thyroid hormone. Biochim Biophys Acta 1032, 157-176 21 Samueis HH, Forman BM, Horowitz Z, Zheng-Sheng Y (1988) Regulation of gene expression by the thyroid hormone receptor. J Clin Invest 81,957-967 22 Evans RM (1988) The steroid thyroid hormone receptor supeffamily. Science 240, 889-895. 23 Thompson CC, Weinberger C, Lebo R, Evans RM (1987) Identification of a novel thyroid hormone receptor expressed in the mammalian control nervous system. Science 237, 1610-1614 24 Koenig RJ, Warne RL, Brent GA, Harvey JW, Larsen PR, Moore DD (1988) Isolation of a cDNA clone encoding a biologically active thyroid hormone receptor. Proc Natl Acad Sci USA 65, 5031-5035 25 Petty KJ, Desvergne B, Mitsuhashi T, Nikodem VM (1990) Identification of a thyroid hormone response element in the malic enzyme gene. J Biol Chem 265, 7395-7400 26 Zilz ND, Murray MB, Towle HC (1990) Identification of multiple thyroid hormone response elements located far upsteam from the rat S14 promoter. J Biol Chem 266, 8136-8143 27 Umesono K, Evans RM (1989) Determinants of target gene specificity for steroid/thyroid hormone receptors. Cell 57, 1139-1146 28 Fawell SE, Lees JA, White R, Parker MG (1990) Characterization and colocalization of steroid binding and dime-
261 rization activities in the mouse estrogen receptor. Cell 60, 953-962 29 Rosen ED, O'Donnell AC, Koenig RJ (1991) Protein-protein interactions involving erbA superfamily receptors: through the TRAP door. Mol Cell Endocrinol 78, C83--C89 30 Forman BM, Yang C-R, Au M, Casanova J, Ghysdael J, Samuels HH (1989) A domain containing leucine zipper like motifs mediates novel in vivo interactions between the thyroid hormone and retinoic acid receptors. Mol Endocrinoi 3, 1610--1626 31 Sintoni CR, Francheschini G (1988) Effects of fibrates on serum lipids and atherosclerosis. Pharmacol Ther 34, 167-191 32 Bar-Tana J, Rose-Kahn G, Frenkel B, Shafer Z, Fainaru M (1988) The hypolipidemic effect of [3,13'-methyl-substituted hexadecanedioic acid in normal and nephrotic rats. JLipidRes 29, 431-441 33 Kahn-Rose G, Bar-Tana J (1985) Inhibition of lipid synthesis by [~,13'-tetramethyl-substituted C14-C22a, dicarboxylic acids in cultured rat hepatocytes. J Biol Chem 260, 8411-8315 34 Frenkel B, Mayorek N, Hertz R, Bar-Tana J (1988) The hypochylomicronemic effect of 13,13'-methyl-substituted hexadecanedioic acid is mediated by a decrease in apolipoprotein C-Ill. J Biol Chem 263, 8491-8497 35 Oppenheimer JH, Schwartz HL, Lane JT, Thompson MP (1991) Functional relationship of thyroid hormoneinduced lipogenesis, lipolysis and thermogenesis in the rat. J Clin Invest 87, 125-132
36
37 38
39
40
41 42 43
Tzur R, Rose-Kahn G, Adler J, Bar-Tana J (1988) The hypolipidemic, antiobesity and hypoglycemic effects of [3,13'-methyl-substituted hexa-decanedioic acid in sand rats. Diabetes 37, 1618-1624 Tzur R, Smith E, Bar-Tana J (1989) Adipose reduction by [3,13'-tetra-methyl-substituted hexadecanedioic acid. Int J Obesity 13, 313-326 Assimacopoulus-Jeannet F, Monat M, Muzzin P., Colomb C, Jeanrenaud B, Girardier L, Giacobino JP, Seydonx V (1991) Effects of a peroxisome proliferator on [3-oxidation and overall energy balance in obese (fa/fa) rats. Am J Physio1260, R278-R283 Bar-Tana J, Kahn-Rose G, Srebnik B (1985) Inhibition of lipid synthesis by 13,[3'-tetramethyl-substituted C14-C22, a, dicarboxylic acids in the rat in vivo. J Biol Chem 260, 8404-8410 Lund H, Stakkestad JA, Skrede S (1986) Effects of thyroid state and fasting in the concentrations of CoA and malonyl-CoA in rat liver. Biochim Biophys Acta 876, 685-687 Bartels PD, Kistensen LO, Heding LG, Sestoft L (1979) Development of ketonemia in fasting patients with hyperthyroidsm. Acta Med Scand Supp1624, 43-47 Kalderon B, Hertz R, Bar-Tana J (1992) Effect of thyroid hormone treatment on redox and phosphate potentials in rat liver. Endocrinology 131,399--407 Kalderon B, Hertz R, Bar-Tana J (1992) Tissue selective modulation of redox and phosphate potentials by [3,13'methyl-substituted hexadecanedioic acid. Endocrinology 131, 1629-1635