Hepatocyte Nuclear Factor-1α Increases Fibrinogen Gene Expression in Liver and Plasma Fibrinogen Concentration in Rats with Experimental Chronic Renal Failure.

Chronic kidney disease (CKD) is associated with elevated plasma fibrinogen concentration. However, the underlying molecular mechanism for elevated plasma fibrinogen concentration in CKD patients has not yet been clarified. We recently found that HNF1α was significantly upregulated in the liver of chronic renal failure (CRF) rats, an experimental model of CKD in patients. Given that the promoter region of the fibrinogen gene possesses potential binding sites for HNF1α, we hypothesized that the upregulation of HNF1α can increase fibrinogen gene expression and consequently plasma fibrinogen concentration in the experimental model of CKD. Here, we found the coordinated upregulation of Aα-chain fibrinogen and Hnfα gene expression in the liver and elevated plasma fibrinogen concentrations in CRF rats, compared with pair-fed and control animals. Liver Aα-chain fibrinogen and HNF1α mRNAs levels correlated positively with (a) liver and plasma fibrinogen levels and (b) liver HNF1α protein levels. The positive correlation between (a) liver Aα-chain fibrinogen mRNA level, (b) liver Aα-chain fibrinogen level, and (c) serum markers of renal function suggest that fibrinogen gene transcription is closely related to the progression of kidney disease. Knockdown of Hnfα in the HepG2 cell line by small interfering RNA (siRNA) led to a decrease in fibrinogen mRNA levels. Clofibrate, an anti-lipidemic drug that reduces plasma fibrinogen concentration in humans, decreased both HNF1α and Aα-chain fibrinogen mRNAs levels in (a) the liver of CRF rats and (b) HepG2 cells. The obtained results suggest that (a) an elevated level of liver HNF1α can play an important role in the upregulation of fibrinogen gene expression in the liver of CRF rats, leading to an elevated concentration of plasma fibrinogen, a protein related to the risk of cardiovascular disease in CKD patients, and (b) fibrates can decrease plasma fibrinogen concentration through inhibition of HNF1α gene expression.

Hepatocyte Nuclear Factor 1α Proinflammatory Effect Linked to the Overexpression of Liver Nuclear Factor-κB in Experimental Model of Chronic Kidney Disease.

Chronic kidney disease (CKD) is associated with low-grade inflammation that activates nuclear factor-κB (NF-κB), which upregulates the expression of numerous NF-κB responsive genes, including the genes encoding IL-6, ICAM-1, VCAM-1, and MCP-1. Herein, we found the coordinated overexpression of genes encoding RelA/p65 (a subunit of NF-κB) and HNF1α in the livers of chronic renal failure (CRF) rats-an experimental model of CKD. The coordinated overexpression of RelA/p65 and HNF1α was associated with a significant increase in IL-6, ICAM-1, VCAM-1, and MCP-1 gene expressions. A positive correlation between liver RelA/p65 mRNA levels and a serum concentration of creatinine and BUN suggest that RelA/p65 gene transcription is tightly related to the progression of renal failure. The knockdown of HNF1α in the HepG2 cell line by siRNA led to a decrease in Rel A/p65 mRNA levels. This was associated with a decrease in IL-6, ICAM-1, VCAM-1, and MCP-1 gene expressions. The simultaneous repression of HNF-1α and RelA/p65 by clofibrate is tightly associated with the downregulation of IL-6, ICAM-1, VCAM-1, and MCP-1 gene expression. In conclusion, our findings suggest that NF-κB could be a downstream component of the HNF1α-initiated signaling pathway in the livers of CRF rats.

Inhibition of LPS-stimulated ecto-adenosine deaminase attenuates endothelial cell activation.

Vascular inflammation is an important factor in the pathophysiology of cardiovascular diseases, such as atherosclerosis. Changes in the extracellular nucleotide and in particular adenosine catabolism may alter a chronic inflammation and endothelial activation. This study aimed to evaluate the relation between vascular ecto-adenosine deaminase (eADA) activity and endothelial activation in humans and to analyze the effects of LPS-mediated inflammation on this activity as well as mechanisms of its increase. Moreover, we investigated a therapeutic potential of ADA inhibition by deoxycofromycin (dCF) for endothelial activation. We demonstrated a positive correlation of vascular eADA activity and ADA1 mRNA expression with endothelial activation parameters in humans with atherosclerosis. The activation of vascular eADA was also observed under LPS stimulation in vivo along with endothelial activation, an increase in markers of inflammation and alterations in the lipid profile of a rat model. Ex vivo and in vitro studies on human specimen demonstrated that at an early stage of vascular pathology, eADA activity originated from activated endothelial cells, while at later stages also from an inflammatory infiltrate. We proposed that LPS-stimulated increase in endothelial adenosine deaminase activity could be a result of IL-6/JAK/STAT pathway activation, since the lack of IL-6 in mice was associated with lower vascular and plasma eADA activities. Furthermore, the inhibitors of JAK/STAT pathway decreased LPS-stimulated adenosine deaminase activity in endothelial cells. We demonstrated that cell surface eADA activity could be additionally regulated by transcytosis pathways, as exocytosis inhibitors including lipid raft inhibitor, methyl-ß-cyclodextrin decreased LPS-induced eADA activity. This suggests that cholesterol-dependent protein externalization mediated by lipid rafts could be an important factor in the eADA increase. Moreover, endocytosis inhibitors and exocytosis activators increased this activity on the cell surface. Furthermore, the inhibition of adenosine deaminase in endothelial cells in vitro attenuated LPS-mediated IL-6 release and soluble ICAM-1 and VCAM-1 concentration in the incubation medium through the restoration of the extracellular adenosine pool and adenosine receptor-dependent pathways. This study demonstrated that the vascular endothelial eADA activity remains under control of inflammatory mediators acting through JAK/STAT pathway that could be further modified by dyslipidemic-dependent exocytosis and transcytosis pathways. Inhibition of eADA blocked endothelial activation suggesting a crucial role of this enzyme in the control of vascular inflammation. This supports the concept of eADA targeted vascular protection therapy.

Up-regulation of PCSK9 gene expression and diminished level of LDL-receptor in rat liver as a potential cause of post-lipectomy hypercholesterolemia.

Studies designed to examine effects of fat mass reduction (including lipodystrophy and lipectomy) on human serum total and LDL-cholesterol concentrations are inconsistent. The purpose of this study was to examine effect of partial lipectomy in rats (as an experimental model of fat mass reduction in humans) on (1) circulating total cholesterol, LDL-cholesterol + VLDL-cholesterol and HDL-cholesterol concentrations, and (2) factors which may affect serum cholesterol concentrations such as: (a) liver LDL-receptor level, (b) expression of liver PCSK9 and (c) circulating PCSK9 concentration. Reduction of rat adipose tissue mass resulted in an increase in circulating total and LDL + VLDL-cholesterol concentrations, which was associated with (a) decrease in liver LDL-R level, (b) increase in liver PCSK9 expression, and (c) increase in circulating PCSK9 concentration as compared with sham controls. These changes were accompanied by elevated liver HNF1α (and HNF4α) mRNA levels. Silencing HNF1α in HepG2 cells by siRNA led to decrease in PCSK9 mRNA levels. This suggests that overexpression of HNF1α gene in liver of lipectomized rats can lead to overproduction of PCSK9. In conclusion, up-regulation of PCSK9, due to overexpression of HNF1α gene in liver of lipectomized rats and subsequently increase in circulating PCSK9 concentration lead to decrease in liver LDL-R level. This may contribute, at least in part, to an increase in the concentration of circulating cholesterol in rats with reduced fat mass. These findings provide a possible explanation for the molecular mechanism of hypercholesterolemia observed sometimes after reduction of fat mass in human.

Hepatocyte nuclear factors as possible C-reactive protein transcriptional inducer in the liver and white adipose tissue of rats with experimental chronic renal failure.

Inflammation related to chronic kidney disease (CKD) is an important clinical problem. We recently determined that hepatocyte nuclear factor 1α (HNF1α) was upregulated in the livers of chronic renal failure (CRF) rats-experimental model of CKD. Considering that the promoter region of gene encoding C-reactive protein (CRP) contains binding sites for HNF1α and that the loss-of-function mutation in the Hnfs1α leads to significant reduction in circulating CRP levels, we hypothesized that HNF1α can activate the Crp in CRF rats. Here, we found coordinated upregulation of genes encoding CRP, interleukin-6 (IL-6), HNF1α, and HNF4α in the livers and white adipose tissue (WAT) of CRF rats, as compared to the pair-fed and control animals. This was accompanied by elevated serum levels of CRP and IL-6. CRP and HNFs' mRNA levels correlated positively with CRP and HNFs' protein levels in the liver and WAT. Similar upregulation of the Crp, Il-6, and Hnfs in the liver and WAT and increased serum CRP and IL-6 concentrations were found in lipopolysaccharide (LPS)-induced systemic inflammation in rats. Moreover, silencing HNF1α in HepG2 cells by small interfering RNA led to decrease in CRP mRNA levels. Our results suggests that (a) HNFs act in concert with IL-6 in the upregulation of CRP production by the liver and WAT, leading to an increase in circulating CRP concentration in CRF rats and (b) CRF-related inflammation plays an important role in the upregulation of genes that encode HNFs and CRP in the liver and WAT of CRF rats.

Up-regulation of Hnf1α gene expression in the liver of rats with experimentally induced chronic renal failure - A possible link between circulating PCSK9 and triacylglycerol concentrations.

BACKGROUND: The aim of this study was to verify if an increase in Hnf1α gene expression could be a possible link between circulating proprotein convertase subtilisin/kexin type 9 (PCSK9) and TAGs concentrations in chronic renal failure (CRF). METHODS: Rats underwent 5/6 nephrectomy or a sham surgery. Liver expressions of Pcsk9, Mttp, ApoB-100, Hnf1α, Hnf4α, lipogenic enzymes and ß-actin genes were quantified by qPCR. Liver levels of proteins coding by these genes were analyzed by Western blotting. Serum apoB-100 and PCSK9 concentration were estimated with an immunoassay. RESULTS: CRF rats showed an increase in circulating concentrations of TAGs, VLDL, apoB-100 and PCSK9, along with an enhanced liver VLDL-TAG secretion rate and a coordinated liver up-regulation of genes coding: a) lipogenic enzymes; b) Mttp and ApoB-100; c) Pcsk9; d) Hnf1α and Hnf4α. Positive correlations were found between serum creatinine concentrations and: a) the liver levels of HNF1α mRNA (r = 0.79, p < 0.01) and HNF4α (r = 0.76, p < 0.01); b) the liver levels of PCSK9 mRNA (r = 0.88, p < 0.01) and serum PCSK9 concentrations (r = 0.73, p < 0.01); c) the liver levels of apoB-100 mRNA (r = 0.83, p < 0.01) and serum apoB-100 concentrations (r = 0.87, p < 0.01). Clofibrate treatment was shown to concomitantly decrease the liver levels of HNF1α, HNF4α and PCSK9 mRNA, as well as serum PCSK9, TAGs and total cholesterol concentrations in CRF rats. CONCLUSION: The results presented are consistent with a cause-effect relationship between the enhanced liver expression of Hnf1α gene and its target genes the products of which are involved in synthesis, assembly and secretion of VLDL, as well as Pcsk9 gene in CRF rats. This may at least in part explain an association between circulating PCSK9 and TAGs in CRF rats and possibly also in humans with chronic kidney disease (CKD).

Up-regulation of liver Pcsk9 gene expression as a possible cause of hypercholesterolemia in experimental chronic renal failure.

Dyslipidemia commonly present in patients with chronic kidney disease (CKD) has been recently linked to increased proprotein convertase subtilisin/kexin type 9 (PCSK9) serum concentration. We tested a hypothesis that increased liver PCSK9 biosynthesis could be partially responsible for the elevated circulating PCSK9 level, and subsequently contribute to hypercholesterolemia observed in subjects with CKD. Rat model of chronic renal failure (CRF) was used in the study. Animals underwent a 5/6 nephrectomy or a sham operation. Liver expression of Pcsk9, sterol regulatory element-binding transcription factor 2 (Srebf-2), and ß-actin were quantified by real-time RT-PCR. Liver protein levels of PCSK9, LDL-receptor (LDL-R), and SREBF-2 were analyzed using Western blotting. Serum PCSK9 concentration was estimated by immunoassay. Rats with an experimental CRF as compared to pair-fed and control ones were characterized by: (a) an up-regulation of liver Pcsk9 and Srebf-2 genes expression with parallel increase of serum PCSK9 concentration; (b) a decrease in liver LDL-R protein level, and (c) an increase of serum total and LDL-cholesterol concentrations. We also found significant correlations between serum creatinine and liver PCSK9 mRNA levels (r = 0.88, p < 0.001) and between serum creatinine and circulating PCSK9 levels (r = 0.73, p < 0.001). The results suggest that a rat model of CRF is associated with an increased liver Pcsk9 gene expression. The coordinated up-regulation of Pcsk9 and Srebf-2 genes expression suggests that SREBF-2 may play a key role in regulation of Pcsk9 gene expression, circulating PCSK9 level, and hypercholesterolemia in experimental CRF.

High serum chemerin level in CKD patients is related to kidney function, but not to its adipose tissue overproduction.

Chemerin is an adipokine modulating inflammatory response and affecting glucose and lipid metabolism. These disturbances are common in CKD. The aim of the study was: (a) to evaluate circulating chemerin level at different stages of CKD; (b) to measure subcutaneous adipose tissue chemerin gene expression; (c) to estimate the efficiency of renal replacement therapy in serum chemerin removal. 187 patients were included into the study: a) 58 patients with CKD; (b) 29 patients on hemodialysis; (c) 20 patients after kidney transplantation. 80 subjects constituted control group. Serum chemerin concentration was estimated by ELISA. The adipose tissue chemerin mRNA level was measured by RT-qPCR. The mean serum chemerin concentration in CKD patients was 70% higher than in the control group (122.9 ± 33.7 vs. 72.6 ± 20.7 ng/mL; p < 0.001) and it negatively correlated with eGFR (r = -0.71, p < 0.001). The equally high plasma chemerin level was found in HD patients and a HD session decreased it markedly (115.7 ± 17.6 vs. 101.5 ± 16.4 ng/mL; p < 0.001). Only successful kidney transplantation allowed it to get down to the values noted in controls (74.8 ± 16.0 vs. 72.6 ± 20.7 ng/mL; n.s.). The level of subcutaneous adipose tissue chemerin mRNA in CKD patients was not different than in patients of the control group. The study demonstrates that elevated serum chemerin concentration in CKD patients: (a) is related to kidney function, but not to increased chemerin production by subcutaneous adipose tissue, and (b) it can be efficiently corrected by hemodialysis treatment and normalized by kidney transplantation.

Elevated circulating PCSK-9 concentration in renal failure patients is corrected by renal replacement therapy.

BACKGROUND: A high level of circulating PCSK9 binds to the LDL receptor, reduces its cell's surface density and leads to hypercholesterolemia. The aim of this study was to examine the circulating PCSK9 level in patients with kidney disease. METHODS: Out of the patients treated in our Departments we selected: (a) 44 patients with CKD stage 3 and 4 (b) 29 patients with CKD stage 5 on maintenance hemodialysis treatment; and (c) 20 patients after successful renal transplantation. Thirty-four subjects, without CKD formed the control group. Serum biochemical parameters' concentrations were assayed by a certified laboratory. Serum PCSK9 concentration was estimated by a commercially available ELISA kit. RESULTS: The mean serum concentration of PCSK9 in patients with kidney disease was higher than in the control group (238.7 ± 64.5 vs. 536.7 ± 190.4; p < 0.001). A strong negative correlation between serum PCSK9 concentration and eGFR was found (r = -0.66; p < 0.001), as well as between serum concentrations of PCSK9 and total- (r = 0.482; p < 0.05) or LDL-cholesterol (r = 0.533; p < 0.05), but exclusively in patients not receiving statins. The elevated serum concentration of PCSK9 in patients before hemodialysis session declined afterwards, reaching the values observed in patients after kidney transplantation and in the control group. CONCLUSION: The circulating PCSK9 concentration is increased in patients with CKD; however, this is not accompanied by hypercholesterolemia. The positive correlations between PCSK9/TCh and PCSK9/LDL-Ch have been found only in patients not treated with statins. The elevated circulating PCSK9 level is corrected by maintenance hemodialysis treatment and normalized by a successful kidney transplantation.

Enhanced food intake by progesterone-treated female rats is related to changes in neuropeptide genes expression in hypothalamus.

INTRODUCTION: Progesterone-treated females eat more food, but the mechanism underlying this effect is not well understood. The aim of the study was to analyse the effect of progesterone on neuropeptide genes expression in rat hypothalamus. MATERIAL AND METHODS: Experiments were carried out on female and male Wistar rats. Animals were treated with progesterone (100 mg per rat) for 28 days. NPY and CART mRNA levels in hypothalamus were quantified by real-time PCR. The serum progesterone concentration was determined by radioimmunoassay. RESULTS: Progesterone administration to females caused an increase in food intake, body mass, and white adipose tissue mass. Elevated circulating progesterone concentration up-regulated NPY and down-regulated CART genes expression in hypothalamus of females. In males, elevated blood progesterone concentration had no effect on food intake, body and fat mass and on the neuropeptide genes expression in hypothalamus. Moreover, administration of progesterone in females resulted in decrease of PR mRNA level in hypothalamus. No effect of progesterone administration on PR mRNA level in hypothalamus of males was found. CONCLUSIONS: The changes in neuropeptide genes expression in hypothalamus may lead to stimulation of appetite and might explain the observed increase in food intake, body and adipose tissue mass in progesterone-treated females.

Differential effect of prolonged food restriction and fasting on hypothalamic malonyl-CoA concentration and expression of orexigenic and anorexigenic neuropeptides genes in rats.

Several lines of evidence suggest that malonyl-CoA in the hypothalamus plays an important role in monitoring and modulating body energy balance. In fasted state the level of malonyl-CoA concentration significantly decreases. Simultaneously, orexigenic neuropeptides (NPY - neuropeptide Y, AgRP - agouti-related peptide) genes are expressed at high level, whereas anorexigenic neuropeptides (CART - cocaine-and amphetamine-regulated transcript, POMC - proopiomelanocortin) genes are expressed at low level. When food intake resumes, opposite effect is observed. This study examined the effect of prolonged food restriction, common in humans trying to lose body weight on expression of orexigenic and anorexigenic neuropeptides genes and on malonyl-CoA content in rat whole hypothalamus. We observed an increase of NPY and AgRP mRNA levels in hypothalamus of rats kept on 30 days-long food restriction (50% of the amount of food consumed by controls). Simultaneously, a decrease of CART and POMC mRNA levels occurred. Refeeding caused a decrease in NPY and POMC mRNA levels without effect on AgRP and CART mRNA. Surprisingly, both prolonged food restriction and food restriction/refeeding caused the increase of malonyl-CoA level in whole hypothalamus. In contrast, fasting for 24h caused the decrease of malonyl-CoA level, which was associated with the up-regulation of NPY and AgRP genes expression and down-regulation of CART and POMC genes expression. After refeeding opposite effect was observed. These results indicate that prolonged food restriction and acute fasting, conditions in which energy expenditure exceeds intake, differentially affect malonyl-CoA concentration and similarly affect orexigenic and anorexigenic neuropeptide genes expression in whole rat hypothalamus.

Refeeding after prolonged food restriction differentially affects hypothalamic and adipose tissue leptin gene expression.

Rat adipose tissue is the principal site of leptin synthesis, however, leptin gene expression has been demonstrated in many rat tissues. Some data indicate that leptin produced by human brain and adipose tissue could cooperate in the regulation of food intake. In this case the regulation of leptin gene expression in hypothalamus and in adipose tissue should be coordinately regulated. Food restriction is often undertaken by many humans trying to lose body weight. Thus, the current study was aimed to analyze whether leptin gene expression in rat hypothalamus and in adipose tissue is regulated synchronously by prolonged food restriction and prolonged food restriction/refeeding. We demonstrate here that although leptin gene is expressed at very low level in rat hypothalamus, its expression in hypothalamus was down-regulated by prolonged food restriction similarly as in the white adipose tissue. Refeeding after prolonged food restriction caused both an increase of leptin gene expression in white adipose tissue and the increase in serum leptin concentration. In contrast, no significant effect of prolonged food restriction/refeeding on hypothalamic leptin gene expression was observed. The reduction of leptin gene expression in both hypothalamus and white adipose tissue by prolonged food restriction was associated with a significant increase of NPY gene (a target of leptin signaling) expression in hypothalamus. Refeeding after prolonged food restriction caused the decrease of NPY gene expression in hypothalamus, however NPY mRNA level remained higher than in controls. The results presented in this paper indicate that prolonged food restriction/refeeding differentially affects leptin gene expression in adipose tissue and in hypothalamus. Moreover, obtained data suggest that in rats leptin synthesized in hypothalamus exerts marginal effect on NPY gene expression and on serum leptin concentration.

Feedback inhibition of cholesterol biosynthesis by dietary cholesterol in experimental chronic renal failure.

OBJECTIVE: Enhanced liver cholesterol synthesis is present in experimental chronic renal failure (CRF), even though cholesterol concentrations in blood and liver are increased, suggesting that CRF results in disturbed cholesterolegenesis feedback regulation. DESIGN: This study sought to elucidate whether dietary cholesterol exerts inhibitory effects on liver cholesterologenesis in CRF rats. METHODS: Male Wistar rats were used. Experimental CRF was achieved by a 5/6 nephrectomy model. Cholesterologenesis was measured (1) in vivo by tritiated water incorporation into cholesterol, and (2) in vitro (using liver slices) by [(14)C]-acetate and [(3)H]-mevalonate incorporation into cholesterol. In addition, the mRNA abundance of 3-hydroxy-3-methylglutaryl-CoA reductase, a rate-limiting enzyme in cholesterologenesis pathway, as well as its activity, was determined. Finally, the mRNA level of liver sterol regulatory element-binding protein-2, a nuclear transcription factor engaged in intracellular cholesterol homeostasis, was measured. RESULTS: Experimental CRF was associated with significantly increased concentrations of serum and liver cholesterol. In vitro and in vivo cholesterologenesis was enhanced in CRF rats. A cholesterol-enriched diet resulted in a significant decrease in (1) in vivo and in vitro cholesterol synthesis, (2) 3-hydroxy-3-methylglutaryl-CoA reductase gene expression, and (3) the level of liver sterol regulatory element-binding protein-2 mRNA in CRF rats. CONCLUSIONS: Despite elevated plasma and liver cholesterol concentrations, cholesterologenesis is increased in CRF rats. It is, however, inhibited by dietary cholesterol. These results suggest that a feedback inhibition of cholesterologenesis by dietary cholesterol is preserved in experimental CRF.

Chronic food restriction differentially affects NPY mRNA level in neurons of the hypothalamus and in neurons that innervate liver.

Neuropeptide Y (NPY) is found in neurons of the brain and in the neurons that innervate abdominal organs including liver. Major biological function of hypothalamic NPY is regulation of appetite and body weight homeostasis. In the periphery, biological function of NPY varies, depending on the organ/tissue. Increased hypothalamic NPY mRNA level in response to chronic caloric restriction is a well documented phenomenon. The effect of food restriction on NPY mRNA level in neurons that innervate liver has not been published so far. To evaluate how chronic food restriction affects liver (and other abdominal organs) NPY mRNA level, we compared NPY mRNA abundance in liver, kidney cortex, perirenal white adipose tissue and in hypothalamus of rats maintained on chronic restricted diet. Data presented in this paper indicate that chronic food restriction: (a) caused the increase of NPY mRNA level in the hypothalamus, (b) caused the decrease of NPY mRNA level in the liver, and (c) was without effect on NPY mRNA level in kidney cortex and perirenal white adipose tissues. Moreover, rats maintained on restricted diet displayed lower serum NPY, leptin and insulin concentrations and higher serum corticosterone concentration. Together, these data suggest that hypothalamus and liver (and other abdominal organs) NPY gene expression is differentially regulated by caloric restriction. It seems that liver NPY gene expression in contrast to the hypothalamus NPY gene expression is not suppressed by leptin.

Increased gene expression of liver SREBP-2 in experimental chronic renal failure.

Sterol regulatory element-binding protein-2 (SREBP-2) is a transcription factor regarded as the main regulator of cholesterol homeostasis. Therefore, increased level of SREBP-2 could be responsible for hypercholesterolemia, which is observed in experimental chronic renal failure (CRF). This study was designed primary to evaluate the impact of experimental CRF (5/6 nephrectomy model) on rat liver SREBP-2 gene expression. In CRF rats, a twofold increase in SREBP-2 mRNA level, as well as in mature SREBP-2 protein abundance was found, when compared to control animals. It was associated with enhanced activity and mRNA abundance of liver HMG-CoA reductase, a rate-limiting enzyme for cholesterol biosynthesis. A twofold increase in liver cholesterologenesis rate was also noted. We conclude that experimental CRF is associated with increased liver SREBP-2 gene expression. This is probably the cause for enhanced HMG-CoA reductase gene expression and, consequently, for increase in liver cholesterol synthesis in CRF rats. Despite increased SREBP-2 gene expression we found LDL-receptor mRNA level to be lower than in controls, suggesting SREBP-2 independent mechanisms of LDL-receptor transcriptional regulation in CRF rats. Enhanced cholesterol synthesis and decreased LDL-receptor mRNA level are probably responsible for an almost fourfold increase in serum cholesterol concentration in CRF rats.

Up-regulation of NPY gene expression in hypothalamus of rats with experimental chronic renal failure.

Anorexia is possibly one of the most important causes of malnutrition in uremic patients. The cause of this abnormality is still unknown. Considering that: (a) NPY is one of the most important stimulants of food intake; (b) eating is a central nervous system regulated process and (c) NPY is expressed in hypothalamus, we hypothesized that the decrease of NPY gene expression in the hypothalamus could be an important factor contributing to anorexia associated with uremic state. In contrast to the prediction, the results presented in this paper indicate that the NPY gene expression in the hypothalamus of chronic renal failure (CRF) rats was significantly higher than in the hypothalamus of control (pair-fed) rats. Moreover, we found that serum NPY concentration in CRF rats was higher than in control (pair-fed) animals. The increase of plasma NPY concentration in CRF rats may be due to the greater synthesis of the neuropeptide in liver, since higher level of NPY mRNA was found in liver of CRF rats. The results obtained revealed that experimental chronic renal failure is associated with the increase of NPY gene expression in hypothalamus and liver of rats.

Leptin decreases lipogenic enzyme gene expression through modification of SREBP-1c gene expression in white adipose tissue of aging rats.

Aging is associated with a significant reduction of lipogenic enzyme gene expression and lipogenesis in white adipose tissue (WAT). The age-related increase of lep gene expression could be, in part, responsible for these changes. Considering that sterol regulatory element binding protein 1c (SREBP-1c) plays an important role in regulation of lipogenic enzyme gene expression, it is likely that the age-related decrease of WAT lipogenic potential could be a consequence of the inhibition of SREBP-1c gene expression by leptin. We determined whether the increase of lep gene expression would account for the age-related decrease in SREBP-1c and its direct target, main lipogenic enzymes acetyl-CoA carboxylase (ACC) and fatty acid synthase (FAS), by assaying the messenger RNA (mRNA) levels of SREBP-1c, FAS, ACC, and leptin in WAT of 2-month-old (young) and 20-month-old (old) rats. Leptin mRNA level was much higher in the old animals, whereas in contrast, old rats displayed much lower mRNA levels of SREBP-1c and lipogenic enzymes. Moreover, experimentally increased plasma leptin concentration in young rats to the value observed in old rats resulted in the decrease of SREBP-1c, FAS, and ACC mRNA levels in WAT. Thus, the increase of lep gene expression could, in part, account for the reduced SREBP-1c gene expression and, consequently, the diminished lipogenic activity in WAT of old animals.

Diversity of SREBP-1 gene expression in rat adipose tissue depots in response to refeeding after food restriction.

The SREBP-1c mRNA level and precursor (microsomal) form of SREBP-1 abundance were significantly higher in epididymal and perirenal than in subcutaneous white adipose tissue of control rats. Moreover, the SREBP-1c mRNA level and an amount of precursor form of SREBP-1 were significantly higher in the epididymal and perirenal white adipose tissue of rats maintained on restricted diet and refed ad libitum for 48 h as compared to the control animals. No significant effects of food restriction/refeeding on SREBP-1c mRNA level and an amount of precursor form of SREBP-1 were found in subcutaneous white adipose tissue. The mature (nuclear) form of SREBP-1 was significantly increased in the epididymal, perirenal and subcutaneous white adipose tissue of the food restricted/refed animals. The activity, protein level and the mRNA abundance of malic enzyme (one of the target genes for SREBP-1) increased significantly in the epididymal, perirenal and subcutaneous white adipose tissue of the food restricted/refed rats as compared to the control animals, however the increase in perirenal and epididymal was higher than in the subcutaneous white adipose tissue. The results presented suggest that SREBP-1c is differently expressed in various rat white adipose tissue depots both under basal (control) and dieting conditions.