Adrenocortical function in young adults with diabetes mellitus type 1.

In 75 young adults with diabetes mellitus type 1 (DM 1) we have performed a cross-sectional study to gain more information about their adrenocortical function. We have found in a surprisingly large portion of patients (25%) a subnormal response (<500 nmol/L, low responders) of the serum cortisol during low-dose Synacthen test, accompanied by significantly decreased stimulated values of aldosterone and salivary cortisol. Basal serum cortisol, aldosterone, and dehydroepiandrosterone sulphate (in women only) were significantly reduced in low responders as well, while ACTH, cortisol binding globulin, plasma renin activity, urinary free cortisol/24h, and salivary cortisol did not differ. The results indicate that the disorder of adrenocortical function in low responders occurs in all adrenocortical zones. The patients with the highest risk in respect to revealed hypocorticalism were DM 1 with autoimmune thyroiditis, 13 out of 36 in contrast to 5 out of 39 suffered from isolated form of DM 1, with onset around 30 years, independently on sex. The biorhythm of salivary cortisol in low responders under real-life conditions did not significantly differ from normal responders, except of the decreased values in the morning. Antibodies against 21-hydroxylase and adrenal cortex were negative in the entire group of diabetics studied. In conclusion, this is the first study to demonstrate in as much as 25% of young adults with DM 1 patients without any signs of adrenal autoimmunity decreased both basal and stimulated serum cortisol and aldosterone levels, implying existence of subclinical primary hypocorticalism.

Steroid metabolome in plasma from the umbilical artery, umbilical vein, maternal cubital vein and in amniotic fluid in normal and preterm labor.

The boost in placental production of CRH in late pregnancy is specific for human. CRH receptors are expressed in the fetal zone of the fetal adrenal (FZFA). Hence, we evaluated the associations between the steroid metabolome and gestational age (GA). The levels of 69 steroids and steroid polar conjugates such as 3beta-hydroxy-5-ene steroids (3betaOH5S), 3-oxo-4-ene steroids (3O4S), progesterone 5alpha/beta-reduced metabolites, 20alpha-hydroxy-metabolites of C21 steroids, C19 5alpha/beta-reduced metabolites, 7alpha/beta-hydroxy-metabolites of 3betaOH5S, estrogens and 16alpha-hydroxy-metabolites of 3betaOH5S and 3O4S, were measured by GC-MS in plasma from the umbilical artery (UA), umbilical vein (UV), and maternal cubital vein (MV) and in amniotic fluid (AF) in 12 women at normal labor and 38 women at preterm labor due to pathologies unrelated to steroid status. Using multivariate regression, prediction models for GA were completed for the individual body fluids. The conjugated 3betaOH5S (the key products of the FZFA), estrogens, some polar conjugates of progesterone 5alpha/beta-reduced metabolites and some steroid 7alpha/beta- and 16alpha-hydroxy-metabolites showed strong positive correlations with the GA. The predictivity decreased in the following sequence UV (R=0.950), UA (R=0.945), MV (R=0.895), and AF (R=0.891). Although the predictivity of steroids in maternal blood was slightly less effective when compared with the UV and UA, it was the best solution for further practice.

Steroid sulfatase and sulfuryl transferase activities in human brain tumors.

Neuroactive steroids (dehydroepiandrosterone, pregnenolone) and their sulfates act as modulators of glutamate and gamma-aminobutyrate type A receptors in the brain The physiological ratio of these neuromodulators is maintained by two enzymes present in the brain, namely, steroid sulfatase (STS) and steroid sulfuryl transferase (SULT). Following previous determination of their activities in monkey brains, their activities were evaluated in human brain tumors. Radioimmunoassay and GC-MS were used for determination of products. Both enzyme activities were measured in the 55 most frequent human brain tumors (glioblastomas, pituitary adenomas, meningiomas, astrocytomas). Significant differences were found in STS activity among investigated types of tumors except the pair of pituitary adenomas-glioblastomas, while significant differences were found in SULT activity among investigated types of tumors. Spontaneous tendency to form clusters was revealed when both enzyme activities were taken as coordinates. Clustering indicated an individual metabolic behavior of glioblastomas and 72.7% of pituitary adenomas. Astrocytomas, meningiomas and remaining 27.3% pituitary adenomas showed similarities in both enzymes' activities. Differences in STS and SULT activity did not depend on the sex or age of subjects.

Aminothiols in human brain tumors.

BACKGROUND: Aminothiols are sulfur-containing amino acids involved in methionine metabolism. Changes in their levels play negative roles in the genesis of many diseases. These mechanisms involve direct toxicity, either on glutamate neurotransmitter receptors or cerebrovascular endothelium, and have an indirect inhibitory effect on transmethylation reactions. Oxidative stress and excitotoxicity are factors that may rise as a consequence of increased homocysteine levels in brain tissues. We discovered new information concerning concentrations of the main aminothiols in human neoplastic brain tissues. METHODS: The cytosolic fractions of 73 tissue samples from human brain tumors were used for the determination of total homocysteine, total cysteine and methionine levels. Gas chromatography with flame ionization detection after reduction of disulfide bonds was the method used. RESULTS: Average concentrations of the aminothiols examined were as follows: total homocysteine, 0.58-1.51 nmol/mg; methionine, 1.16-2.07 nmol/mg; and total cysteine 5.08-7.82 nmol/mg of total protein. Significantly higher levels of total homocysteine were found in pituitary adenoma and glioblastoma multiforme compared with other types of tumors. Methionine and cysteine concentrations did not differ significantly according to diagnosis. CONCLUSIONS: This is the first work concerning the concentrations of aminothiols in brain tissues. The results obtained indicate the metabolic pathways that are involved in tumor formation and/or its progress, including the toxic effects of homocysteine.

Steroid sulfatase and sulfuryl transferase activity in monkey brain tissue.

Dehydroepiandrosterone and its sulfated form are commonly known as modulators of gamma-aminobutyrate A and N-methyl-D-aspartate receptors. In spite of poor permeability of the blood-brain barrier for sulfated steroids, high concentrations of dehydroepiandrosterone and also its sulfate have been found in brain tissue. Physiological concentrations of these neuromodulators are maintained by two enzymes present in the blood and many peripheral tissues, including the brain, namely, steroid sulfatase and neurosteroid sulfuryl transferase (NSST). This prompted us to investigate activities of these enzymes in primate brain tissue. Rather low neurosteroid sulfuryl transferase activity was detectable in in vitro incubations of cytosol fractions from male and female Macaca mulatta brains, dissected to cerebral cortex, subcortex, and cerebellum. In male monkeys, the highest activity was found in the cerebellum followed by cortex and subcortex. On the other hand, in female monkeys, the highest activity was determined in the cortex followed by subcortex and cerebellum. Steroid sulfatase activity was determined in in vitro microsomal samples from each of the above-mentioned brain regions. Specific activities in female cerebral regions declined in the order: cerebellum, cortex, and subcortex. In male monkeys, no significant difference among the studied regions was observed. Using dehydroepiandrosterone sulfate as a substrate, the apparent kinetic characteristics of steroid sulfatase were determined as follows: K(M) 36.10 +/- 8.33 microM, V(max) 8.38 +/- 1.68 nmol/h/mg protein. These results will serve as a basis for further studies concerning the pathophysiology of human brain tumors.