Simultaneous histochemical assay of two dehydrogenases in the same cell

A new approach has been developed for the simultaneous assay of the activities of two enzymes (lactate and succinate dehydrogenases) in the same cell in sections of unfixed liver. The sections, mounted on coverslips, were placed on top of 0.6-mm thick 0.8% low gelling-temperature agarose films containing the substrates of both enzymes (70 mM lactate and 50 mM succinate, respectively) plus 80 mM Tris-HCl buffer (pH 7.5), 5 mM EDTA, 10 mM NaN3, 1.5 mM NAD+, 1.2 mM Nitro BT and 0.26 mM phenazine methosulphate. The integrated absorbance (A) at 585 nm of the final reaction product formazans deposited by the two enzymes in a selected hepatocyte was measured continuously at 37 degrees C as a function of incubation time, using a Vickers M85 microdensitometer. The intercept A0 on the A-axis of the linear regression line of A on time was determined. After a known incubation time t, the absorbance A1, was noted and the section placed on another gel film lacking the substrates in order to estimate the final reaction product either formed in the gel film or lost from the cell. The absorbance A2 of the hepatocyte was remeasured. The reaction velocities (activities) vL and vS of lactate and succinate dehydrogenases, respectively, were calculated from the following equations: vL = [(A1-A2) - A0(1- alpha L)]/(1-alpha L)t and vS = (A2-alpha LA1)/(1-alpha L)t where alpha L = A2/A1 for hepatocytes incubated on gel films containing only lactate as the substrate. This parameter was found to be virtually constant (0.44) over a wide range of vL.(ABSTRACT TRUNCATED AT 250 WORDS)     

A quantitative study of the validity of the histochemical demonstration for pyridine nucleotide-linked dehydrogenases

Summary A quantitative histochemical and biochemical study has been made of the loss of pyridine nucleotide-linked dehydrogenases from frozen histological sections of rat liver. Glucose-6-phosphate, 6-phosphogluconate and lactate dehydrogenases were lost rapidly from the sections during incubation in the histochemical medium, but -OH-butyrate dehydrogenase was lost at a much slower rate. It was shown that a dehydrogenase reaction can occur in a section lacking that particular dehydrogenase if the section is incubated in the presence of another containing the dehydrogenase. The validity of the tetrazolium reaction for demonstrating pyridine-nucleotide-linked dehydrogenases is considered in the light of these results.     

A comparative evaluation of Cephalosporin C production using various immobilization modes

The production of Cephalosporin C was investigated in a lab-scale 1.4 l air-lift reactor (ALR), using various immobilization modes. Bioparticles were developed by forming biofilm of growing hyphae around an inorganic siran particle which contained spores of the organism. Silk sachet was the other immobilization matrix. The maximum specific growth rate of the Cephalosporium acremonium, free cells, pellets, siran carrier and silk sachets were 0.037, 0.003, 0.047, and 0.035 h(-1), and specific antibiotic productivities (as compared to 100% for free cells) were 180, 150, and 125% for siran carrier, silk sachets and pellets, respectively. Immobilization modes exhibited enhanced volumetric oxygen transfer coefficient and well-controlled, three-phase hydrodynamics.     

Factors influencing the histochemical demonstration of coenzyme-dependent dehydrogenases and diaphorases

Procedures for the histochemical demonstration of DPN and TPN diaphorases have been presented by other workers. These techniques rely on the coenzyme-dependent dehydrogenases present in the tissue slice to generate the substrate required by the diaphorases. In vitro studies were carried out on kidney and adrenal tissue of the rat, using NT (neotetrazolium) and INT (2-p-iodophenyl-3-p-nitrophenyl-5-phenyl tetrazolium chloride) with various substrates of DPN-dependent dehydrogenases. The solutions used for study contained alcohol and alcohol dehydrogenase, glutamate and malate, malate, glutamate, beta-hydroxybutyrate, or DPNH. It has been possible to demonstrate (1) that histological distribution of dehydrogenases may differ from that of the flavoprotein oxidizing reduced coenzyme I; (2) characteristic patterns of distribution of particular dehydrogenases in the tissue proper; (3) different levels of dehydrogenase in kidney and adrenal; and (4) differences in dehydrogenase distribution in the kidneys of man and rat. The evidence presented clearly indicates the limitations inherent in the accepted procedures for the demonstration of DPN and TPN diaphorases. The possible application of the tetrazolium salts to the study of particular coenzyme-dependent dehydrogenases and the pitfalls which might occur are also discussed.     

Expression of hornerin in stratified squamous epithelium in the mouse: a comparative analysis with profilaggrin.

We have recently identified a novel protein named hornerin, the structural features of which are most similar to those of profilaggrin, an essential protein for keratinization of epidermal tissues. In this study we examined the expression of hornerin compared with that of profilaggrin in various mouse tissues. Hornerin was expressed in the upper epidermis of newborn mouse skin, as was profilaggrin. In addition, both hornerin and profilaggrin were expressed in the tongue, esophagus, and forestomach. In all four tissues, immunostaining for hornerin and profilaggrin showed a granular pattern, and most of the signals for the two proteins were co-localized on keratohyalin granules. This was confirmed by double immunoelectron microscopy. Within keratohyalin granules, hornerin was detected more frequently in the periphery, whereas profilaggrin was equally distributed. A quantitative RT-PCR revealed that both genes were expressed at highest levels in the forestomach and at the next highest levels in skin. Profilaggrin mRNA was most abundant in the forestomach. In skin, the amount of hornerin mRNA was more than fourfold greater than the amount of profilaggrin mRNA. These results form the basis for a better understanding of possible overlapping and/or differential functions of hornerin and profilaggrin.     

The histochemical distribution of hydroxysteroid dehydrogenases in the human foetal membranes at term

Summary The histochemical distribution of various hydroxysteroid dehydrogenases in human, term, foetal membranes has been investigated using the tetrazolium dye, Nitro-B.T.The trophoblastic layer was the most active, showing 3-, 3-, 11-, 16- and 17-hydroxysteroid dehydrogenase activities, a pattern of activity similar to that of the placental villous trophoblast.The amniotic epithelium showed weak 3-, 3-, 16- and 17-hydroxysteroid dehydrogenase activity; weak 3- and 3-hydroxysteroid dehydrogenase activity was noted in the connective tissue layers.All activity demonstrated was N.A.D.-linked.