Production of cortisol from cortisone by the isolated,perfused fetal rabbit lung

Perfusion of the isolated 26 day fetal rabbit lung with ³H-cortisone resulted in its conversion to ³H-cortisol and release into the perfusate. Little conversion of ¹⁴C-cortisol to ¹⁴C-cortisone occurred. Quantitative study of homogenized fetal rabbit lung revealed the development of both the cofactor and the enzyme for 11β-hydroxy steroid dehydrogenase activity between 21 and 29 days gestation. These results suggest increasing production of cortisol from cortisone by the fetal rabbit lung as a function of gestational age. This conversion may be of significance with respect to both lung development and parturition, both events being accelerated by cortisol treatment.     

Uptake and metabolism of cortisone and cortisol by the fetal rabbit lung

Lungs of rabbit fetuses at 28 days of gestation were incubated with tritium-labeled cortisone (17α,21-dihydroxy-4-pregnene-3,11,20-trione) or Cortisol (11β,17α,21-trihydroxy-4-pregnene-3,20-dione). The fetal lungs metabolized efficiently cortisone yielding cortisol as the major product (64–71% conversion). Cortisol was poorly metabolized, only 10–14% being converted to cortisone and 68–75% of the substrate being recovered unchanged. A small amount of cortisone (5–7% of tissue radioactivity) was also found in the lungs twenty minutes after injection of labeled cortisol to the fetus $\text{in utero}$. Incubation of fetal lungs with labeled cortisone at 37° resulted in specific uptake and binding of radioactivity (predominantly cortisol) to nuclear macromolecules. The amount of cortisol bound to nuclear macromolecules was similar whether the tissue was incubated with cortisol or cortisone. These results demonstrate that the lungs of the rabbit fetus have the capacity to convert the biologically inactive cortisone to the biologically active cortisol, the reverse reaction occurring only to a limited extent.     

Conversion and binding of tetraiodothyronine in developing rat brain

In this study we have examined whether rat brain nuclear thyroid hormone receptors bind T₄ or metabolites of T₄ and whether there is a developmental change in brain T₄ metabolism and binding. Developing animals were injected with trace [¹²⁵I]3,5-tetraiodothyronine ([¹²⁵I]T₄) and after sacrifice brain nuclear and cytoplasmic fractions were examined to determine whether their radioactivity was represented by the injected [¹²⁵I]T₄ or any of its metabolites. Of the radiothyronines specifically bound to the nucleus, 90% was found to be triiodothyronine ([¹²⁵I] T₃) and 10% was [¹²⁵I]T₄. Of the cytoplasmic, protamine sulfate-precipitable fraction, 40% was [¹²⁵I]T₄ and 60% [¹²⁵I]T₃. Inasmuch as the percentage of [¹²⁵I] T₃ found in plasma during the same postinjection interval was similar to that present as contaminant of the injected material, it was concluded that brain [¹²⁵I] T₃ derives from local monodeiodination of T₄ to T₃. The main developmental change observed was a marked decline in the total cytoplasmic and nuclear [¹²⁵I] T₄ uptake. However, with development, the T₃/T₄ ratio remained constant in the nuclear fraction while it decreased in the cytoplasmic fraction. It is concluded that although T₃, deriving from monodeiodianation of T₄, is the main form of thyroid hormone that regulates brain development by its binding to brain nuclear receptors, the fact that T₄ is the most available from during the critical period makes it, indirectly, very important to brain development. Further, the decline observed with development in T₄ uptake and monodeiodination to T₃, may contribute to the concomitantly declining role of thyroid hormones on brain tissue.     

Conversion of propionate to acetate and methane by syntrophic consortia

Summary The anaerobic degradation of propionate to acetate and methane by a defined sulfidogenic syntrophic co-culture consisting of Syntrophobacter wolinii and Desulfovibrio G11, and a new thermophilic, methanogenic consortium T13 was studied. Tracer experiments using (¹⁴C) propionate produced evidence for the generally accepted biochemical pathway involving methylmalonyl-CoA as an intermediate in the degradation of propionate. The degradation of (1-¹⁴C) propionate led exclusively to the formation of ¹⁴CO₂ by S. wolinii/D. G11 and to the formation of ¹⁴CH₄ by the methanogenic consortium T13. The conversion of either (2-¹⁴) or (3-¹⁴) propionate by S. wolinii/D. G11 resulted in uniform labelled acetate as the endproduct. The methanogenic consortium formed (U-¹⁴C) acetate from (2-¹⁴) and (3-¹⁴) propionate as an intermediary product followed by aceticlastic splitting to yield equivalent amounts of ¹⁴CO₂ and ¹⁴CH₄.     

P-45011 beta-dependent conversion of cortisol to cortisone, and 19-hydroxyandrostenedione to 19-oxoandrostenedione

Purified bovine adrenal P-45011 beta has been shown to catalyze conversions of cortisol to cortisone (11-oxidase activity), and 19-hydroxyandrostenedione to 19-oxoandrostenedione (19-oxidase activity), in the reconstituted system consisting of NADPH, NADPH:adrenodoxin reductase, and adrenodoxin. The turnover numbers (mol of product formed/min/mol of P-450) were 1.2 for the 11-oxidase activity and 1.4 for the 19-oxidase activity. No reactions took place when any one of the electron-donating components were omitted either in the presence or in the absence of added NADP+. Likewise, rabbit antibody prepared against P-45011 beta immunoprecipitated the 11-oxidase activity with concomitant loss of deoxycorticosterone 11 beta-hydroxylase activity.     

A new defect in the peripheral conversion of cortisone to cortisol

A steroid disorder is described in two sisters, aged 13 and 17 years, in which the metabolism of cortisol results almost exclusively in urinary excretion of tetrahydro-cortisone (11-keto) derivatives. The evidence implies the existence of a deficiency in the peripheral enzymatic conversion of cortisone to cortisol.     

Increased ratio of serum cortisol to cortisone in acute-phase response

BACKGROUND/OBJECTIVES: 11beta-Hydroxysteroid dehydrogenase (11beta-HSD) enzymes convert cortisol into inactive cortisone and vice versa. While 11beta-HSD type 2 (mainly localized in the kidney) unidirectionally inactivates cortisol to cortisone, type I isoform (mainly localized in the liver) acts bidirectionally and can thus potentially restore cortisone to active cortisol. The aim of this pilot study was to investigate whether the serum cortisol:cortisone ratio is altered during the acute-phase response, possibly due to altered modulation of 11beta-hydroxysteroid dehydrogenase isoforms. METHODS: Using liquid chromatography electrospray tandem mass spectrometry, cortisol and cortisone were measured in the serum of hospitalized patients with normal and abnormal CRP concentrations, the latter indicating acute-phase response. Fifteen unselected samples were analyzed, all with a CRP concentration within one of the following ranges to cover a wide range of CRP concentrations evenly: <5, 5-20, 21-50, 51-100, 101-200, and >200 mg/l. RESULTS: In the heterogeneous study population, increased CRP concentrations significantly correlated with an increased cortisol:cortisone ratio (p < 0.001; r = 0.65, Spearman correlation coefficient). This correlation was independent of increased serum cortisol concentrations found by multivariate regression analysis. The median ratio was 6.4 (interquartile range 5.5-7.4; n = 30) in patients with a CRP concentration < or =20 mg/l, and 11.2 (interquartile range 8.8-13.9; n = 60) in patients with CRP >20 mg/l (p < 0.01). CONCLUSION: The balance between serum cortisol and cortisone is altered during acute-phase response with a shift towards active cortisol, suggesting that 11beta-HSD isoenzymes play a role in the modulation of systemically available cortisol during acute illness.     

Glucose, pyruvate, and acetate metabolism by developing soybean seeds

Developing soybean cotyledons were incubated with glucose-¹⁴C,pyruvate-¹⁴C, and acetate-¹⁴C. Glucose was metabolized by boththe Embden-Meyerhof-Parnas pathway and the pentose phosphatepathway. Developing soybean cotyledons also have the capacityto synthesize sucrose since ¹⁴C was found in fructose and sucrosefrom glucose incubations. Complete analysis showed that thecarbons from glucose were directed into CO₂, lipid, and solids.Pyruvate was metabolized to a C-2 unit which is presumably acetylCoA. After conversion to the C-2 unit, the carbons of pyruvatewere metabolized in the same manner as acetate. Both pyruvateand acetate carbons were directed predominately into lipids. (Received January 6, 1976; )     

Role of the primate placenta in cortisol secretion by the maternal adrenals

Peripheral serum cortisol levels were measured throughout gestation in 5 intact pregnant rhesus monkeys (Macaca mulatta) and 3 hypophysectomized-fetectomized monkeys, leaving the placentas in situ and viable. These monkeys, as well as 4 other groups used to separately control for effects of pregnancy, hypophysectomy, or fetectomy, were unilaterally (left) adrenalectomized to permit comparisons of adrenal gland weights. Circulating cortisol levels of intact pregnant monkeys tended to rise slightly with advancing gestation. However, hypophysectomy at 70 to 73 days after fertilization caused a marked decline (p < 0.01) in serum cortisol concentrations to about 1/2 the preoperative level. These monkeys were fetectomized at 107 to 114 days without further reduction in circulating cortisol levels. In hypophysectomized-fetectomized monkeys, either surgical removal of the placentas near term or abortion was followed by a rapid decrease in peripheral cortisol to undetectable concentrations. Their cortisol levels were 5 to 12 times higher in left adrenal venous effluent than in peripheral circulation on the day of placental delivery. The presence of a viable placenta protected against the extensive adrenocortical involution seen in nonpregnant hypophysectomized monkeys (p < 0.01). Fetectomy, alone or in combination with hypophysectomy, did not alter left adrenal gland weights from those of intact pregnant monkeys. Thus, continued cortisol secretion and maintenance of adrenal weight in hypophysectomized-fetectomized monkeys, in the presence of a functional placenta, supports the existence of a placental adrenocorticotropin in this primate.     

Radioimmunoassay of corticosterone,cortisol and cortisone: Their application to human cord and maternal plasma

A critical analysis of the applicability of corticosterone, cortisone and cortisol radioimmunoassays in human plasma is presented. Rabbits immunized with corticosteroid-3-CMO-BSA conjugates yielded specific antisera. Yet, their specificity may become insufficient when the concentrations of weakly cross-reacting steroids are much higher than that of the steroid to be assayed. In these particular instances, appropriate and simple purification steps, such as hexane extraction or celite chromatography, must be added. Normal values for pregnant women at delivery and their babies are presented.     

Depot-specific regulation of the conversion of cortisone to cortisol in human adipose tissue

Objective: Our main objective was to compare the regulation of cortisol production within omental (Om) and abdominal subcutaneous (Abd sc) human adipose tissue. Methods and Procedures: Om and Abd sc adipose tissue were obtained at surgery from subjects with a wide range of BMI. Hydroxysteroid dehydrogenase (HSD) activity (³H‐cortisone and ³H‐cortisol interconversion) and expression were measured before and after organ culture with insulin and/or dexamethasone. Results: Type 1 HSD (HSD1) mRNA and reductase activity were mainly expressed within adipocytes and tightly correlated with adipocyte size within both depots. There was no depot difference in HSD1 expression or reductase activity, while cortisol inactivation and HSD2 mRNA expression (expressed in stromal cells) were higher in Om suggesting higher cortisol turnover in this depot. Culture with insulin decreased HSD reductase activity in both depots. Culture with dexamethasone plus insulin compared to insulin alone increased HSD reductase activity only in the Om depot. This depot‐specific increase in reductase activity could not be explained by an alteration in HSD1 mRNA or protein, which was paradoxically decreased. However, in Om only, hexose‐6‐phosphate dehydrogenase (H6PDH) mRNA levels were increased by culture with dexamethasone plus insulin compared to insulin alone, suggesting that higher nicotinamide adenine dinucleotide phosphate‐oxidase (NADPH) production within the endoplasmic reticulum (ER) contributed to the higher HSD reductase activity. Discussion: We conclude that in the presence of insulin, glucocorticoids cause a depot‐specific increase in the activation of cortisone within Om adipose tissue, and that this mechanism may contribute to adipocyte hypertrophy and visceral obesity.