Estrogens play a key role in various target tissues. Enzymes involved in the biosynthesis and metabolism of these sex steroids also regulate estrogenic actions in these tissues. Estrone sulfate (E1S) is a major circulating plasma estrogen that is converted into the biologically active estrogen, estrone (E1), by steroid sulfatase (STS). E1 is also sulfated and reverted into E1S by estrogen sulfotransferase (EST). These two enzymes have recently been shown to play important roles in the in situ estrogen actions of various sex steroid-dependent human tumors. However, the distribution of STS and EST in normal adult and fetal human tissues remains largely unknown. Therefore, in this study, in addition to examining the tissue distribution of both STS and EST mRNA in human adult and fetal tissues using RT followed by quantitative PCR, we studied the activity of these enzymes using 3 H-labeled E1/E1S as substrates in the homogenates of various human adult tissues. We also examined the localization of STS and EST protein in human adult and fetal tissues using immunohistochemistry, and that of EST mRNA in the adult kidney using laser dissection microscopy and PCR. STS mRNA, enzyme activity, and immunoreactivity were either absent or detected at very low levels in all adult and fetal tissues examined in this study. EST mRNA expression, however, was detected in all of the tissues examined, except for adult spleen and pancreas. EST enzyme activities were consistent with those of mRNA expression in the great majority of the tissues examined. Marked EST immunoreactivity was detected in hepatocytes, adrenal gland (adult, zona fasciculate to the reticularis; fetus, fetal zone), and epithelial cells of the gastrointestinal tract, smooth muscle cells of the tunica media in aorta, Leydig cells of the testis, and syncytiotrophoblast of the placenta. Patterns of EST immunolocalization were similar between adult and fetal human tissues, but EST immunoreactivity was detected in the urinary tubules of adult kidney, whereas in the fetal kidney, it was localized in the interstitial cells surrounding the urinary tubules. In the adult kidney, the presence of EST mRNA was also confirmed in the cells of urinary tubules using laser dissection microscopy and RT-PCR.Although the number of human tissues available for examination in this study was limited, our results suggest that between the enzymes involved in estrogen activation or inactivation, EST and not STS is the more widely expressed enzyme in various peripheral tissues in humans. We speculate that EST may play an important role in protecting peripheral tissues from possible excessive estrogenic effects. (J Clin Endocrinol Metab 87: 5760 -5768, 2002)
The obese ZDFxSHHF-fa/fa(cp) model was developed by crossing lean female Zucker Diabetic Fatty (ZDF +/fa) and lean male Spontaneously Hypertensive Heart Failure (SHHF/Mcc-fa(cp), +/fa) rats. The purpose of the present study was to determine renal function and morphology, hemodynamics, and metabolic status in ZDFxSHHF rats. Two sets of experiments were conducted. First, we evaluated heart and kidney function and metabolic status in aged (46 weeks old) male obese ZDFxSHHF and age matched obese SHHF rats, lean Spontaneously Hypertensive (SHR) and lean normotensive Wistar Kyoto (WKY) rats. In the second set of experiments, renal function and structure as well as metabolic and lipid status were determined in lean (LN) and obese (OB) adult (29-weeks of age) ZDFxSHHF rats. At 46 weeks of age ZDFxSHHF rats are hypertensive expressing marked cardiac hypertrophy associated with diastolic dysfunction and preserved contractile function. Fasted hyperglycemia and hyperinsulinemia are accompanied by moderate hypercholesterolemia and hypertriglyceridemia. Obese aged ZDFxSHHF have marked renal hypertrophy, a 3-8 fold decrease in creatinine clearance (compared with SHHF, SHR and WKY), a high percent of segmental + global glomerulosclerosis (59.8%+/-10.8), and severe tubulointerstitial and vascular changes. Obese ZDFxSHHF rats die at an early age (approximately 12 months) from end-stage renal failure. Studies conducted in 29-week animals showed that, although both LN and OB 29-week old animals are hypertensive, OB animals have more severely compromised renal function and structure as compared with lean litter-mates (kidney weight: 2.56+/-0.16 vs. 1.61+/-0.12 g; creatinine clearance: 0.42+/-0.04 vs. 1.24+/-0.13 L/g kid/day; renal vascular resistance 12.39+/-1.4 vs. 6.14+/-0.42 mmHg/mL/min/g kid; protein excretion: 556+/-16 vs. 159+/-9mg/day/g kid, p < 0.05, OB vs. LN, respectively). Obesity is also associated with hyperglycemia (424+/-37 vs. 115+/-11 mg/dL), hyperinsulinemia (117.2+/-8.8 vs. 42.3+/-3.5 microU/mL), hypertriglyceridemia (5200+/-702 vs. 194+/-23 mg/dL), hypercholesterolemia (632+/-39 vs. 109+/-4mg/dL), and presence of segmental + global glomerulosclerosis (20.1+/-3.2% vs. 0.1+/-0.1%) with prominent tubular and interstitial changes (p < 0.05, OB vs. LN, respectively). In summary, the present study indicates that the crossing of rat strains of nephropathy produces hybrids that carry a high risk for severe renal dysfunction. The ZDFxSHHF rats express insulin resistance, hypertension, dislipidemia and obesity and develop severe renal dysfunction. In addition, the hybrids do not develop some of the complications (hydronephrosis or congestive heart failure) common for the parental strains that may compromise studies of renal function and structure. Therefore, the ZDFxSHHF rat may be a useful model fore valuating risk factors and pharmacological interventions in chronic renal failure.
Adenosine is a purine nucleoside and modulates a variety of physiological functions by interacting with cell-surface adenosine receptors. Under several adverse conditions, including ischemia, trauma, stress, seizures and inflammation, extracellular levels of adenosine are increased due to increased energy demands and ATP metabolism. Increased adenosine could protect against excessive cellular damage and organ dysfunction. Indeed, several protective effects of adenosine have been widely reported (e.g., amelioration of ischemic heart and brain injury, seizures and inflammation). However, the effects of adenosine itself are insufficient because extracellular adenosine is rapidly taken up into adjacent cells and subsequently metabolized. Adenosine uptake inhibitors (nucleoside transport inhibitors) could retard the disappearance of adenosine from the extracellular space by blocking adenosine uptake into cells. Therefore, it is expected that adenosine uptake inhibitors will have protective effects in various diseases, by elevating extracellular adenosine levels. Protective or ameliorating effects of adenosine uptake inhibitors in ischemic cardiac and cerebral injury, organ transplantation, seizures, thrombosis, insomnia, pain, and inflammatory diseases have been reported. Preclinical and clinical results indicate the possibility of therapeutic application of adenosine uptake inhibitors.
The aim of this study was to investigate the mechanism of inhibition of Eg5 (kinesin spindle protein), a mitotic kinesin that plays an essential role in establishing mitotic spindle bipolarity, by the novel small molecule inhibitor K858. K858 was selected in a phenotype-based forward chemical genetics screen as an antimitotic agent, and subsequently characterized as an inhibitor of Eg5. K858 blocked centrosome separation, activated the spindle checkpoint, and induced mitotic arrest in cells accompanied by the formation of monopolar spindles. Long-term continuous treatment of cancer cells with K858 resulted in antiproliferative effects through the induction of mitotic cell death, and polyploidization followed by senescence. In contrast, treatment of nontransformed cells with K858 resulted in mitotic slippage without cell death, and cell cycle arrest in G 1 phase in a tetraploid state. In contrast to paclitaxel, K858 did not induce the formation of micronuclei in either cancer or nontransformed cells, suggesting that K858 has minimal effects on abnormalities in the number and structure of chromosomes. K858 exhibited potent antitumor activity in xenograft models of cancer, and induced the accumulation of mitotic cells with monopolar spindles in tumor tissues. Importantly, K858, unlike antimicrotubule agents, had no effect on microtubule polymerization in cell-free and cellbased assays, and was not neurotoxic in a motor coordination test in mice. Taken together, the Eg5 inhibitor K858 represents an important compound for further investigation as a novel anticancer therapeutic. [Cancer Res 2009;69(9):3901-9]
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