Analysis of metabolomics profile in hypothyroid patients before and after thyroid hormone replacement.

PURPOSE: The serum metabolic changes occurring during the transition from hypothyroidism to euthyroidism are not known. This study aimed to determine the metabolomic profile in hypothyroid patients before (HypoT0) and after (HypoT1) euthyroidism achieved through levothyroxine (L-T4) treatment. METHODS: Eighteen patients with overt primary hypothyroidism were recruited for the study. All patients were treated with L-T4 to achieve euthyroidism. Thyrotropin (TSH), free thyroxine (FT4), free triiodothyronine (FT3) and metabolomics profiles were measured before and after 3 months of treatment. The euthyroid control group consisted of 28 healthy volunteers. Metabolomics analysis was performed using Nuclear Magnetic Resonance (NMR) spectroscopy. RESULTS: 1H NMR-based metabolomics profiling of patients with newly diagnosed hypothyroidism (HypoT0) showed significantly higher levels of citrate, creatinine, glycerol, myo-inositol and serine, and lower levels of proline and taurine compared to controls. Interestingly, some metabolic changes were persistent three months after pharmacological treatments, despite normal serum TSH and thyroid hormone concentrations (HypoT1). When an Orthogonal Partial Least Squares Discriminant Analysis (OPLS-DA) model was built to evaluate possible differences in the metabolic profile between HypoT0 and HypoT1, the data obtained were not significantly different. CONCLUSION: These results suggest that metabolic changes in the patients with hypothyroidism may persist after normalization of serum levels of FT3, FT4, and TSH, which currently represent the gold standard in laboratory testing for diagnosis and evaluation of thyroid pathology. So, the metabolomics approach may contribute to integrate classical hormone assays and to determine the euthyroid status achievement with greater efficacy.

Triiodothyronine stimulates hepatocyte proliferation in two models of impaired liver regeneration.

OBJECTIVES: Liver regeneration is attenuated in old age and is substantially slower after 90% than after 70% partial hepatectomy (PH). We have previously demonstrated that the proliferative response to a primary mitogen is intact in aged mice, indicating that impaired liver regeneration is not due to loss of proliferative capacity. Here, we have investigated whether mitogenic effects of triiodothyronine (T3) could reverse the impaired regeneration of ageing or 90% hepatectomy, in the rat. MATERIALS AND METHODS: T3 (20 microg/100 g body weight) was administered to 14-month-old rats subjected to 70% PH or to young rats subjected to 90% PH. Cell-proliferative capacity was determined by bromodeoxyuridine incorporation and microscopy and changes of cell cycle-related proteins were analysed by Western blot analysis. RESULTS: Treatment of old intact rats with T3 increased cyclin D(1) expression that was followed by an enhanced proliferative response, the labelling index (LI), being 7.8% versus 1.3% of controls. T3 given before 70% PH stimulated regenerative response (LI was 10.8% versus 2.28%), and expression of cyclin D(1) and proliferating cell nuclear antigen (PCNA) 24 h after PH. Pre-treatment with T3 also improved the regenerative response of the liver after 90% hepatectomy (LI was 27.9% versus 14.2%). CONCLUSIONS: These findings show in principle that mitogen-induced hyperplasia could be applied to human therapy in patients with reduced regenerative capacity or massive loss of hepatocytes.

Increased ROS generation and p53 activation in alpha-lipoic acid-induced apoptosis of hepatoma cells.

Alpha-lipoic acid (alpha-LA) is an antioxidant used for the treatment of a variety of diseases, including liver cirrhosis, heavy metal poisoining, and diabetic polyneuropathy. In addition to its protective effect against oxidative stress, alpha-LA induces apoptosis in different cancer cells types. However, whether alpha-LA acid induces apoptosis of hepatoma cells is unknown. Herein, we investigated whether alpha-LA induces apoptosis in two different hepatoma cell lines FaO and HepG2. The results showed that alpha-LA inhibits the growth of both cell lines as indicated by the reduction in cell number, the reduced expression of cyclin A and the increased levels of the cyclin/CDKs inhibitors, p27(Kip1) and p21(Cip1). Cell cycle arrest was associated with cell loss, and DNA laddering indicative of apoptosis. Apoptosis was preceded by increased generation of reactive oxygen species, and associated with p53 activation, increased expression of Bax, release of cytochrome c from mitochondria, caspases activation, decreased levels of survivin, induction of pro-apoptotic signaling (i.e JNK) and inhibition of anti-apoptotic signaling (i.e. PKB/Akt) pathways. In conclusion, this study provides evidence that alpha-LA induces apoptosis in hepatoma cells, describes a possible sequence of molecular events underlying its lethal effect, and suggests that it may prove useful in liver cancer therapy.

Induction of pancreatic acinar cell proliferation by thyroid hormone.

Thyroid hormone is known to elicit diverse cellular and metabolic effects in various organs, including mitogenesis in the rat liver. In the present study, experiments were carried out to determine whether thyroid hormone is able to stimulate cell proliferation in another quiescent organ such as the pancreas. 3,5,3'-L-tri-iodothyronine (T3) added to the diet at a concentration of 4 mg/kg caused a striking increase in nuclear bromodeoxyuridine (BrdU) incorporation of rat acinar cells 7 days after treatment (the labeling index was 46.7% in T3-treated rats vs 7.1% in controls). BrdU incorporation was limited to the acinar cells, with duct cells and islet cells being essentially negative. The increase in DNA synthesis was accompanied by the presence of several mitotic figures. Histological examination of the pancreas did not exhibit any sign of T3-induced toxicity. Determination of the apoptotic index, measurement of the serum levels of alpha-amylase and lipase, and glycemia determination did not show any increase over control values, suggesting that the enhanced proliferation of acinar cells was a direct effect induced by T3 and not a regenerative response consequent to acinar or beta-cell injury. Additional experiments showed that DNA synthesis was induced as early as 2 days after T3 treatment (the labeling index was 9.4 vs 1.9% in controls) and was associated with increased protein levels of cyclin D1, cyclin A and proliferating cell nuclear antigen, with no substantial differences in the expression of the cyclin-dependent kinase inhibitor p27. The mitogenic effect of T3 on the pancreas was not limited to the rat, since extensive acinar cell proliferation was also observed in the pancreas of mice treated with T3 for 1 week (the labeling index was 28% in T3-treated mice vs 1.8% in controls). Treatment with three other ligands of nuclear receptors, ciprofibrate, all-trans retinoic acid and 1,4-bis[2-(3,5-dichloropyridyloxy)]benzene, induced little or no pancreatic cell proliferation. These results demonstrated that T3 is a powerful inducer of cell proliferation in the pancreas and suggested that pancreatic acinar cell proliferation by selected agents may have potential for therapeutic use.

Induction of hepatocyte proliferation by retinoic acid.

Retinoids have been shown to exert an anticarcinogenic effect through suppression of the cell cycle, induction of apoptosis and/or differentiation. In rat liver, in particular, retinoic acid has been shown to inhibit regeneration after partial hepatectomy, most probably through repression of the expression of c-fos and c-jun. Surprisingly enough, in spite of the proposed therapeutic effects of all-trans retinoic acid (tRA) no data are available on its effect on normal adult liver. Here, we show that tRA administration in the diet (150 mg/kg) increased DNA synthesis in mouse liver, at 1 and 2 weeks, with a return to control values at 4 weeks (labelling index was 16.5, 8.3 and 3.3%, respectively, versus control values of 1.4, 1.3 and 2.5%). Increase in mitotic index paralleled that of bromodeoxyuridine incorporation. Kinetic studies showed that entry into S phase began between 24 and 48 h, with a peak between 96 and 120 h. Histological observation of the liver and biochemical evaluation of the levels of serum glutamate-pyruvate transaminases did not reveal any evidence of cell death demonstrating that increased DNA synthesis was not due to tRA-induced liver damage and regeneration, but rather the consequence of a direct mitogenic effect. In addition, analysis of total hepatic DNA content after a 7-day treatment showed a significant increase in tRA-fed mice compared with controls (21.11 mg/100 g body wt in tRA-fed mice versus 15.67 mg/100 g body wt of controls). Hepatocyte proliferation in tRA-fed mice was associated with increased hepatic levels of cyclin D1, E and A, and enhanced expression of the member of pRb family, p107. In conclusion, the results showed that tRA induces hepatocyte proliferation in the absence of cell death, similarly to other ligands of steroid/thyroid hormone nuclear receptor superfamily. The mitogenic effect of tRA cautions about its possible use for antitumoral purposes in liver carcinogenesis.

Peroxisome proliferator-activated receptor-alpha mice show enhanced hepatocyte proliferation in response to the hepatomitogen 1,4-bis [2-(3,5-dichloropyridyloxy)] benzene, a ligand of constitutive androstane receptor.

Previously, we have suggested that liver cell proliferation induced by certain mitogens is dependent on their binding and activation of nuclear receptors of the steroid/thyroid superfamily. More recently, it was shown that absence of the nuclear receptors peroxisome proliferator-activated receptor-alpha (PPARalpha) and constitutive androstane receptor (CAR) completely abolishes the proliferative response of hepatocytes to the mitogenic stimulus exerted by their specific ligands, peroxisome proliferators (PPs) and 1,4-bis[2-(3,5-dichloropyridyloxy)] benzene (TCPOBOP), respectively. Here we show that deletion of the PPARalpha gene accelerates and enhances the proliferative response evoked by the xenobiotic 1,4-bis[2-(3,5-dichloropyridyloxy)] benzene (TCPOBOP), a powerful mouse-liver mitogen and a ligand of the nuclear receptor CAR. Indeed, the number of hepatocytes entering S phase 24 hours after mitogen treatment was much greater in PPARalpha(-/-) mice compared with that of wild type mice (labeling indices 21.4% and 7.5%, respectively). Labeling index of hepatocytes from PPARalpha(-/-) mice was found to be higher than that of wild type mice up to 36 hours after treatment, indicating that lack of PPARalpha not only accelerated but also enhanced the overall proliferative response of the liver. The accelerated entry into S phase observed in hepatocytes from PPARalpha(-/-) mice was associated with a very rapid induction of cyclin D1. No major differences between TCPOBOP-treated PPARalpha(-/-) and wild type mice were observed in the expression of the 2 inhibitors of cyclin/CDKs complexes, p27 and p21. The results suggest that PPARalpha may play a role in modulating CAR-signaling pathways in the cell, in particular those leading to hepatocyte proliferation.

Cyclin D1 is an early target in hepatocyte proliferation induced by thyroid hormone (T3).

The thyroid hormone (T3) affects cell growth, differentiation, and regulates metabolic functions via its interaction with the thyroid hormone nuclear receptors (TRs). The mechanism by which TRs mediate cell growth is unknown. To investigate the mechanisms responsible for the mitogenic effect of T3, we have determined changes in activation of transcription factors, mRNA levels of immediate early genes, and levels of proteins involved in the progression from G1 to S phase of the cell cycle. We show that hepatocyte proliferation induced by a single administration of T3 to Wistar rats occurred in the absence of activation of AP-1, NF-kappa B, and STAT3 or changes in the mRNA levels of the immediate early genes c-fos, c-jun, and c-myc. These genes are considered to be essential for liver regeneration after partial hepatectomy (PH). On the other hand, T3 treatment caused an increase in cyclin D1 mRNA and protein levels that occurred much more rapidly compared to liver regeneration after 2/3 PH. The early increase in cyclin D1 expression was associated with accelerated onset of DNA synthesis, as demonstrated by a 20-fold increase of bromodeoxyuridine-positive hepatocytes at 12 h after T3 treatment and by a 20-fold increase in mitotic activity at 18 h. An early increase of cyclin D1 expression was also observed after treatment with nafenopin, a ligand of a nuclear receptor (peroxisome proliferator-activated receptor alpha) of the same superfamily of steroid/thyroid receptors. T3 treatment also resulted in increased expression of cyclin E, E2F, and p107 and enhanced phosphorylation of pRb, the ultimate substrate in the pathway leading to transition from G1 to S phase. The results demonstrate that cyclin D1 induction is one of the earlier events in hepatocyte proliferation induced by T3 and suggest that this cyclin might be a common target responsible for the mitogenic activity of ligands of nuclear receptors.

Ciprofibrate and triiodothyronine do not suppress in vivo induction of placental glutathione S-transferase expression in rat hepatocytes.

Studies on hepatocyte primary cultures have suggested that loss of expression of the placental form of glutathione S-transferase in peroxisome proliferator (PP)-induced hepatocarcinogenesis is due to inhibition of glutathione S-transferase P (GSTP) transcription by the PPs. In the present study, we have analyzed the effect of a PP, ciprofibrate, and of another ligand of nuclear receptors, 3,3', 5-triiodo-L-thyronine (T3), on GSTP mRNA and protein levels in an in vivo model where GSTP expression was induced in Wistar rats by pre-treatment with a single dose of lead nitrate. Results indicate that administration of ciprofibrate or T3, immediately after lead nitrate treatment, did not exert any inhibitory effect on GSTP mRNA and protein levels, as revealed by both Western and immunohistochemical analysis. The results indicate that PPs do not inhibit hepatocyte GSTP expression induced in vivo by lead nitrate and suggest that inhibition of GSTP expression by PPs may not necessarily be the cause for the rapid disappearance of GSTP-positive preneoplastic lesions observed after a short term exposure to these agents.

Early increase in cyclin-D1 expression and accelerated entry of mouse hepatocytes into S phase after administration of the mitogen 1, 4-Bis[2-(3,5-Dichloropyridyloxy)] benzene.

We have previously demonstrated that hepatocyte proliferation induced by the mitogen 1,4-bis[2-(3,5-dichloropyridyloxy)] benzene (TCPOBOP) is independent of changes in cytokines, immediate early genes, and transcription factors that are considered to be necessary for regeneration of the liver after partial hepatectomy (PH) or necrosis. To further investigate the differences between mitogen-induced mouse hepatocyte proliferation and liver regeneration after PH, we have measured the expression of cyclin D1, cyclin D3, cyclin E, and cyclin A and of the cyclin-dependent kinases CDK2, CDK4, and CDK6. The involvement of the cyclin-dependent kinase inhibitors p21 and p27 and of the oncosuppressor gene p53 was also examined at different times after stimulation of hepatocyte proliferation. Results showed that a single administration of TCPOBOP caused a very rapid increase in the levels of cyclin D1, a G1 protein, when compared with two thirds PH (8 hours versus 30 hours). The early increase in cyclin D1 protein levels was associated with a faster onset of increased expression of S-phase-associated cyclin A (24 hours versus 36 hours with PH mice). Accordingly, measurement of bromodeoxyuridine (BrdU) incorporation revealed that, although approximately 8% of hepatocytes were BrdU-positive as early as 24 hours after TCPOBOP, no significant changes in BrdU incorporation were observed at the same time point after two thirds PH. The expression of other proteins involved in cell cycle control, such as cyclin-dependent kinases (CDK4, CDK2, CDK6), was also analyzed. Results showed that expression of CDK2 was induced much more rapidly in TCPOBOP-treated mice (2 hours) than in mice subjected to PH (36 hours). A different pattern of expression in the two models of hepatocyte proliferation, although less dramatic, was also observed for CDK4 and CDK6. Expression of the CDK inhibitors p21 and p27 and the oncosuppressor gene p53 variably increased after two thirds PH, whereas basically no change in protein levels was found in TCPOBOP-treated mice. The results demonstrate that profound differences in many cell cycle-regulatory proteins exist between direct hyperplasia and compensatory regeneration. Cyclin D1 induction is one of the earlier events in hepatocyte proliferation induced by the primary mitogen TCPOBOP and suggests that a direct effect of the mitogen on this cyclin may be responsible for the rapid onset of DNA synthesis observed in TCPOBOP-induced hyperplasia.

Cell proliferation induced by 3,3',5-triiodo-L-thyronine is associated with a reduction in the number of preneoplastic hepatic lesions.

Previous studies have suggested that liver cell proliferation is fundamental for the growth of carcinogen-initiated cells. To gain further information on the association between cell proliferation and hepatocarcinogenesis, we have examined the effect of the hormone 3,3',5-triiodo-L-thyronine (T3), a strong liver mitogen, on the growth of diethylnitrosamine (DENA)-induced hepatic lesions positive for the placental form of glutathione S-transferase (GSTP). Two weeks after a single initiating dose of DENA (150 mg/kg), cycles of liver cell proliferation were induced in male Fischer rats by feeding a T3-supplemented diet (4 mg/kg) 1 week/month for 7 months. Rats were killed at the end of the seventh cycle or 1 month later. Results indicate that, in spite of an increased labelling index, a 70% reduction in the number/cm(2) of GSTP-positive minifoci occurred in T3-treated rats. A decrease in the number of GSTP-positive foci was also observed in T3-treated rats killed 1 month after the last exposure to the hormone (40, versus 67 foci/cm(2) in controls), indicating that the reduction was not due to an inhibitory effect on GSTP exerted by the concomitant presence of T3. In a second series of experiments where DENA-treated rats were fed T3 for 1 week and then subjected to the resistant hepatocyte (RH) model, it was found that T3 treatment prior to promotion resulted in a decrease in the number of GSTP-positive foci (16 GSTP(+) foci/cm(2) in T3-fed animals versus 45 in the control group). The results indicate that cell proliferation associated with T3 treatment: (i) reduces the number of carcinogen-induced GSTP-positive lesions; (ii) does not exert any differential effect on the growth of the remaining foci; (iii) inhibits the capacity of putative DENA-initiated cells to be promoted by the RH model. Data suggest that cell proliferation may not necessarily represent a stimulus for the growth of putative preneoplastic lesions.

Liver cell proliferation induced by nafenopin and cyproterone acetate is not associated with increases in activation of transcription factors NF-kappaB and AP-1 or with expression of tumor necrosis factor alpha.

Our previous studies have shown a different pattern of immediate early gene and growth factor gene expression between compensatory liver regeneration occurring after cell loss/death and direct hyperplasia induced by primary mitogens. In the present study, modifications in the activation of two transcription factors, NF-kappaB and AP-1; steady-state levels of tumor necrosis factor alpha (TNF-alpha) messenger RNA (mRNA); and induction of the inducible nitric oxide synthase (iNOS) were examined in rat liver during different types of cell proliferation. Compensatory regeneration was induced in male Wistar rats by partial hepatectomy of two thirds (PH) or a necrogenic dose of CCl4 (2 mL/kg), whereas direct hyperplasia was induced by a single administration of the primary mitogens lead nitrate (LN, 100 micromol/kg), cyproterone acetate (CPA, 60 mg/kg), or nafenopin (NAF, 200 mg/kg). Liver regeneration after treatment with CCl4 was associated with an increase in steady-state levels of TNF-alpha mRNA, activation of NF-kappaB and AP-1, and induction of iNOS. A strong and prolonged activation of NF-kappaB but not of AP-1 was observed in LN-induced hyperplasia. LN also induced an increase in hepatic levels of TNF-alpha and iNOS mRNA. On the other hand, direct hyperplasia induced by two other primary mitogens, NAF and CPA, occurred in the complete absence of modifications in the hepatic levels of TNF-alpha mRNA, activation of NF-kappaB and AP-1, or induction of iNOS, although the number of hepatocytes entering S phase 18 to 24 hours after NAF was similar to that seen after PH. These results add further support to the hypothesis that cell proliferation occurring in the absence of cell loss/death may be triggered by unknown signaling pathways different from those responsible for the transition of hepatocytes from G0 to G1 after PH or cell necrosis.

Increased expression of c-fos, c-jun and LRF-1 is not required for in vivo priming of hepatocytes by the mitogen TCPOBOP.

The notion that an increased expression of immediate early genes such as c-fos and c-jun is an absolute requirement for the G0-G1 transition of the hepatocytes has recently been challenged by the finding that rat liver cell proliferation induced by primary mitogens may occur in the absence of such changes (Columbano and Shinozuka, 1996). To further investigate the relationship between immediate early genes and hepatocyte proliferation, we have compared the hepatic levels of c-fos, c-jun and LRF-1 transcripts during mouse liver cell proliferation in two conditions: (i) direct hyperplasia induced by the non-genotoxic hepatocarcinogen 1,4-bis[2-(3,5-dichloropyridyloxy)]benzene, and (ii) compensatory regeneration caused by a necrogenic dose of carbon tetrachloride. The results show striking differences in the activation of early genes. In spite of a rapid stimulation of S phase by 1,4-bis[2-(3,5-dichloropyridyloxy)]benzene (approximately 8% of hepatocytes were BrdU-positive as early as 24 h after mitogen treatment versus 1% of labelled hepatocytes after 2/3 partial hepatectomy), no changes in the expression of c-fos, c-jun and LRF-1 could be observed. Moreover, no change in steady state mRNA hepatic levels of IGFBP-1 (a gene highly expressed in rat liver following partial hepatectomy), and only a slight increase in c-myc and PRL-1, was found after mitogen administration. On the contrary, a rapid, massive and transient increase in the hepatic mRNA levels of all these genes was observed during carbon tetrachloride induced regeneration. The results indicate that increased expression of immediate early genes may be dependent upon the nature of the proliferative stimulus, and it may not be a prerequisite in certain in vivo conditions such as proliferation induced in the absence of liver tissue damage.

Chronic treatment with SCH 23390 increases the production rate of dopamine D1 receptors in the nigro-striatal system of the rat.

The effects of chronic treatment with the selective dopamine D1 receptor antagonist, SCH 23390, on the steady-state densities and turnover rates of these receptors were investigated in the striatum and substantia nigra of the rat. To this aim, we assessed the repopulation kinetics of [3H]SCH 23390 binding sites after irreversible inactivation of dopamine D1 receptors induced by a single dose of N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline (EEDQ, 10 mg/kg s.c.) in rats chronically treated with SCH 23390. The receptor repopulation was analyzed using a theoretical model that assumes a constant rate of receptor production and a first-order receptor degradation rate. The repeated administration of SCH 23390 (0.05 mg/kg s.c., thrice daily for 21 days) enhanced the steady-state density of dopamine D1 receptors in the striatum (+30%) and substantia nigra (+24%). This treatment also increased the production rates of dopamine D1 receptors in the striatum (+44%) and substantia nigra (+54%). By contrast, the rate constants of dopamine D1 receptor degradation were unchanged in both brain areas. These results suggest that the up-regulation of dopamine D1 receptors induced by chronic treatment with SCH 23390 is determined by modifications in the processes that control the rate of receptor production but not of receptor degradation.

Differential turnover rates of D1 dopamine receptors in the brain and retina of adult and senescent rats.

The present study was designed to investigate the turnover rates of D1 dopamine receptors in the brain and retina of adult and aged rats. To this aim, we monitored the increase in the density of 3H-SCH 23390 binding sites after the administration of the irreversible antagonist N-ethoxycarbonyl-2-ethoxy-1,2 dihydroquinoline (EEDQ). The results indicate that, in aged rats, the production rate of D1 receptors decreases by 41% to 61% in the striatum, nucleus accumbens and substantia nigra, whereas a smaller reduction in the degradation rate of these receptors is observed (-21% to -40%). In contrast, the production rate of D1 receptors in the retina of aged rats remains unchanged, whilst the degradation rate decreases by 25%. These alterations in the rates of receptor production and degradation may account for the age-related decrease in the density of D1 dopamine receptors in the striatum, nucleus accumbens and substantia nigra as well as for the increase in the density of these receptors in the retina of aged rats.

Age-related changes in the turnover rates of D1-dopamine receptors in the retina and in distinct areas of the rat brain.

The steady-state density and the turnover rates of D1-dopamine receptors were investigated in the striatum, nucleus accumbens, substantia nigra, and retina of adult (3-month-old) and aged (23-month-old) rats. The turnover rates were measured by monitoring the repopulation kinetics of D1-dopamine receptors labeled with [3H]-SCH 23390 after the irreversible inactivation induced by a single dose of N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline (EEDQ, 10 mg/kg, s.c.). In all the neural tissues examined, the repopulation of D1 dopamine receptors could be adequately described by a theoretical model that assumes a constant rate of receptor production (i.e. zero order) and a rate of degradation that is dependent on the receptor density at any time (i.e. first order). The results obtained indicate that the reduction in the density of D1-dopamine receptors in the striatum, nucleus accumbens and substantia nigra of aged rats is the result of a larger decrease in the receptor production rate (-44 to -60%) than in the receptor degradation rate (-21 to -46%). By contrast, the production rate of D1-dopamine receptors in the retina of aged rats remains unchanged, whilst the degradation rate is reduced by 25%. This results in an age-related increase in the density of D1-dopamine receptors in the rat retina.

Differential turnover rates of D1 dopamine receptors in the retina and in distinct areas of the rat brain.

The present study was designed to examine the steady-state density and the turnover rates of D1 dopamine (DA) receptors in the striatum, nucleus accumbens, substantia nigra, and retina of the rat. The turnover rates were measured by monitoring the repopulation kinetics of D1 DA receptors labelled with [3H]SCH 23390 after the irreversible inactivation induced by a single dose of N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline (10 mg/kg s.c.). The repopulation of D1 DA receptors could be described adequately in all the neural tissues investigated by a theoretical model that assumes a constant rate of receptor production (i.e., zero order) and a rate of degradation that is dependent on the receptor density at any time (i.e., first order). The quantitative analysis of the experimental data using this theoretical model revealed significant regional differences in the rates of receptor production and degradation. Thus, the receptor production rates determined in the nucleus accumbens and striatum (8.03 and 9.96 fmol/mg of protein/h, respectively) were four- to sixfold larger than those measured in the substantia nigra (1.80 fmol/mg of protein/h) and retina (1.50 fmol/mg of protein/h). On the other hand, the receptor degradation rates in the striatum, nucleus accumbens, and retina (0.0093 h-1, 0.0110 h-1, and 0.0123 h-1, respectively) were 2.6-3.5-fold larger than the receptor degradation rate in the substantia nigra (0.0035 h-1).

The neutral endopeptidase-24.11 (enkephalinase) inhibitor, SCH 32615, increases dopamine metabolism in the nucleus accumbens of the rat.

SCH 32615 is a novel inhibitor of the enzyme, neutral endopeptidase (NEP, E.C. 3.4.24.11), the so called 'enkephalinase', which plays a functional role in the degradation of [Met5]- and [Leu5]enkephalin. The present study was designed to assess whether SCH 32615 is able to modify the activity of dopaminergic neurons as reflected by changes in the content of the major dopamine metabolite, dihydroxyphenylacetic acid (DOPAC), in three different areas of the rat brain: the nucleus accumbens, the striatum, and the prefrontal cortex. When administered at analgesically active doses (1-100 mg/kg s.c., 60 min before killing), SCH 32615 induced a dose-dependent increase in dopamine metabolism in the nucleus accumbens but was ineffective in the striatum and in the prefrontal cortex. This effect appears to be mediated via opioid receptors, since it was completely prevented by naloxone (5 mg/kg s.c.). The increase in DOPAC content in the prefrontal cortex elicited by foot-shock was unaffected by pretreatment with SCH 32615. In the nucleus accumbens, dopamine metabolism was increased to the same extent by foot-shock and SCH 32615 administered separately, but these effects were not additive, suggesting that SCH 32615 and foot-shock act via a common mechanism. Taken together, these results support the hypothesis that inhibition of the in vivo degradation of enkephalins induced by the systemic administration of SCH 32615 increases the enkephalinergic tone in the central nervous system and thereby activates the mesolimbic dopaminergic neurons.