Production and characterization of monoclonal antibodies to dehydroepiandrosterone sulfate: application to direct enzyme-linked immunosorbent assays of dehydroepiandrosterone sulfate and androsterone/epiandrosterone sulfates in plasma.

Mice were immunized with 5-androstene-3 beta-ol-7,17-dione-7-CMO:bovine serum albumin (DHEA-7-O-CMO-BSA) or 5-androstene-3 beta-ol-17-one hemisuccinate-bovine serum albumin (DHEA-3HS-BSA) conjugates and monoclonal antibodies were produced, characterized, and selected for maximum DHEAS binding. Of these hybridomas, four clones from DHEA-3HS-BSA-immunized mice had acceptable criteria for the development of a competitive enzyme-linked immunosorbent assay (ELISA) for DHEAS in plasma. One hybridoma supernatant from DHEA-7-O-CMO-BSA-immunized mice showed 360% cross-reactivity to both androsterone sulfate and epiandrosterone sulfate. This allows the possibility of the direct determination of androsterone sulfate and epiandrosterone sulfate in plasma after correction for the DHEAS contribution. Both ELISAs employ a DHEA-3HS-thyroglobulin conjugate adsorbed to the wells of a standard 96-well microtiter plate. DHEAS in the standards or diluted plasma sample competes with immobilized DHEA-3HS-thyroglobulin for antibody-binding sites. Antibody is detected with anti-mouse-lg peroxidase by further washing, adding o-phenylenediamine substrate, and reading the absorbance at 492 nm. The ELISAs are simple, reproducible, and reliable and, to our knowledge, they are the first tests employing monoclonal antibodies to DHEAS.

Short-term response of nonurea organic osmolytes in human kidney to a water load and water deprivation.

The cells of the inner medulla of the mammalian kidney accumulate high concentrations of nonurea organic osmolytes. The organic osmolytes found in the kidney include glycine betaine and sorbitol. This study was designed to measure changes in the urinary excretion of glycine betaine and sorbitol and the plasma concentration of glycine betaine in response to an acute water load (20 ml/kg) or acute water deprivation in young healthy males. In response to a water load the urinary excretion of glycine betaine and sorbitol increased parallel with or shortly after urinary urea excretion. The increase in urinary urea and sorbitol excretions preceded maximum minute volume, whereas peak glycine betaine excretion was closely related to maximum urine minute volume. Subsequently, urea, sorbitol, and glycine betaine excretion rates returned to baseline. In contrast, during water deprivation no change in glycine betaine, sorbitol, and urea urinary excretions occurred during the study period. Plasma glycine betaine concentration was stable during both diuresis and antidiuresis. We conclude that the organic osmolytes glycine betaine and sorbitol are components of a physiological and dynamic system in response to an acute water diuresis.

Abnormal glycine betaine content of the blood and urine of diabetic and renal patients.

In normal human plasma the concentrations of the renal osmolyte, glycine betaine, are usually between 20 and 70 mumol/l, in adult males (median 44 mumol/l) higher than in females (34 mumol/l). Concentrations are lower in renal disease (median 28 mumol/l) and normal in diabetes. Urinary excretion of glycine betaine shows no sex difference and is frequently elevated both in renal disease and in diabetes (medians: normal, 6.2, renal 12.3 and diabetes, 39.7 mmol/mol creatinine). The elevation in diabetes does not strongly correlate with known renal disease, nor with either urinary microalbumin or plasma creatinine. There is no correlation with glycated haemoglobin. The positive correlation with the excretions of another renal osmolyte, sorbitol, was highly significant in diabetic subjects. In the diabetic group there was also a significant negative correlation between plasma glycine betaine and urine microalbumin.

Glycine betaine and proline betaine in human blood and urine.

In healthy human subjects, glycine betaine concentrations in the blood plasma are normally between 20 and 60 mumol/l, adult males tending to have higher concentrations than females. Proline betaine concentrations are more variable, ranging from undetectable to about 50 mumol/l. Both betaines are present in urine. Whereas the urinary excretion of proline betaine reflects plasma concentrations, with high clearance rates, there is no correlation between plasma and urine glycine betaine concentrations. The apparent clearance rates are low (usually less than 5%). The proline betaine content of human kidney tissue is less than 0.1% of the glycine betaine content, and this is true also of rabbit tissue despite high concentrations of both betaines in rabbit circulation and urine. These data suggest that glycine betaine, but not proline betaine, is important in human and other mammalian biochemistry.

Organic osmolytes in human and other mammalian kidneys.

Osmotically-active organic solutes, or osmolytes, have been found in high concentration in the renal inner medulla of a wide variety of mammalian species, but their existence in human kidneys has not yet been shown. The aim of this study was to demonstrate the presence of osmolytes in the human kidney. Human tissues were obtained from kidneys removed surgically for diseases which involved only one pole of the kidney; in most cases this was a tumor. Animal kidneys analyzed were from dogs, pigs and rabbits. Inner medulla and cortex tissue samples were analyzed and found to contain the organic osmolytes glycine betaine, myo-inositol, sorbitol and glycerophosphorylcholine. The levels were much higher in the medulla than in the cortex. Further dissection of the human kidneys showed that sorbitol, glycerophosphorylcholine and glycine betaine were maximally concentrated at the papillary tip, while myo-inositol was found in highest concentration at the papillary base. Osmolytes were in low concentrations or undetectable in rabbit skeletal muscle, ureter and bladder. The organic osmolytes detected are likely to be physiologically important in humans. Studies in other mammals can be used as models for the investigation of the osmolyte system in human kidney function.