The type I and type II 11beta-hydroxysteroid dehydrogenase enzymes.

Local tissue concentrations of glucocorticoids are modulated by the enzyme 11β-hydroxysteroid dehydrogenase which interconverts cortisol and the inactive glucocorticoid cortisone in man, and corticosterone and 11-dehydrocorticosterone in rodents. The type I isoform (11β-HSD1) is a bidirectional enzyme but acts predominantly as a oxidoreductase to form the active glucocorticoids cortisol or corticosterone, while the type II enzyme (11β-HSD2) acts unidirectionally producing inactive 11-keto metabolites. There are no known clinical conditions associated with 11β-HSD1 deficiency, but gene deletion experiments in the mouse indicate that this enzyme is important both for the maintenance of normal serum glucocorticoid levels, and in the activation of key hepatic gluconeogenic enzymes. Other important sites of action include omental fat, the ovary, brain and vasculature. Congenital defects in the 11β-HSD2 enzyme have been shown to account for the syndrome of apparent mineralocorticoid excess (AME), a low renin severe form of hypertension resulting from the overstimulation of the non-selective mineralocorticoid receptor by cortisol in the distal tubule of the kidney. Inactivation of the 11β-HSD2 gene in mice results in a phenotype with similar features to AME. In addition, these mice show high neonatal mortality associated with marked colonic distention, and remarkable hypertrophy and hyperplasia of the distal tubule epithelia. 11β-HSD2 also plays an important role in decreasing the exposure of the fetus to the high levels of maternal glucocorticoids. Recent work suggests a role for 11β-HSD2 in non-mineralocorticoid target tissues where it would modulate glucocorticoid access to the glucocorticoid receptor, in invasive breast cancer and as a mechanism providing ligand for the putative 11-dehydrocorticosterone receptor. While previous homologies between members of the SCAD superfamily have been of the order of 20–30% phylogenetic analysis of a new branch of retinol dehydrogenases indicates identities of >60% and overlapping substrate specificities. The availability of crystal structures of family members has allowed the mapping of conserved 11β-HSD domains A–D to a cleft in the protein structure (cofactor binding domain), two parallel β-sheets, and an -helix (active site), respectively.     

Distribution of lactic dehydrogenase in X-irradiated tissues.

Exposure to whole-body X-irradiation in rats causes a marked increase in total lactic dehydrogenase (LDH) activity and decrease in H-LDH/M-LDH ratio in serum and tissues, the maximum effect being observed on the 8th post-irradiation day. While there is an elevation of M-LDH isoenzyme, H-LDH remains relatively constant. Studies on incorporation of DL-leucine-l-14C into heart LDH isoenzymes also revealed increased biosynthesis of M-LDH isoenzyme. This indicates that an adaptive mechanism is operative in the X-irradiated rats, whereby, in order to augment anaerobic glycolysis, synthesis of M-LDH is stimulated. Administration of the radioprotector cystamine does not alter the effects of X-irradiation on serum LDH activity.     

Freezing injury to erythrocytes. I. Freezing patterns and post-thaw hemolysis.

The extent of hemolysis of human red blood cells suspended in different concentrations of glycerol and frozen at various cooling rates was investigated on the basis of morphological observation in the frozen state. Hemolysis of the cells in the absence of glycerol showed a V-shaped curve in terms of cooling rates. There was 70% hemolysis at an optimal cooling rate of approximately 10³ °C/min and 100% hemolysis at all other rates tested. Morphologically, a lower than optimal cooling rate resulted in cellular shrinkage, while a higher than optimal rate resulted in the formation of intracellular ice.The cryoprotective effect of glycerol was dependent upon its concentration and on the cooling rate. Samples frozen at 10³ and 10⁴ °C/min showed freezing patterns which differed from cell to cell. The size of intraand extracellular ice particles became smaller, and there was less shrinkage or deformation of cells as the rate of cooling and concentration of glycerol were increased.There was some correlation between the morphology of frozen cells and the extent of post-thaw hemolysis, but the minimum size of intracellular ice crystals which might cause hemolysis could not be estimated. As a cryotechnique for electron microscopy, the addition of 30% glycerol and ultrarapid freezing at 10⁵ °C/min are minimum requirements for the inhibition of ice formation and the prevention of the corresponding artifacts in erythrocytes.     

Flow cytometry to identify cell types to which enzymes bind. Effect of lactic dehydrogenase virus on enzyme binding

Flow cytometry was used to measure the binding of enzymes (i.e. lactate dehydrogenases 1 and 5, malate dehydrogenase, and asparaginase) to cells. Of the four enzymes studied, asparaginase showed the greatest binding. Single color analysis revealed that asparaginase bound best to preparations enriched in macrophages, and dual color analysis showed that the binding was to macrophages. Studies on continuous cell lines revealed that asparaginase bound to one mouse macrophage line, but not to another or to murine fibroblasts. Inoculation of mice with lactic dehydrogenase virus, a virus that infects macrophages, decreased the in vivo clearance of asparaginase from the circulation and the in vitro binding of asparaginase to peritoneal macrophages. It is concluded that flow cytometry can be used to study the binding of enzymes to cells, to identify the cell type to which the enzyme binds, and to measure changes in the capacity of cells to bind enzymes.