Rapid-freezing cytochemistry: preservation of tubular lysosomes and enzyme activity

We show that tubular structures present in phorbol ester-stimulated macrophages are sensitive to commonly used chemical fixatives (i.e., they usually become fragmented during fixation). These structures are well preserved in macrophages that are physically fixed by rapid-freezing and subsequent freeze-substitution in osmium-acetone. We have developed methods that combine rapid-freezing, freeze-substitution, and enzyme cytochemistry for preservation of these tubular structures and for detection of endocytosed material (i.e., horseradish peroxidase). This method of rapid-freeze cytochemistry may be useful in other situations where chemical fixation does not adequately preserve cell structures, particularly of membrane compartments.     

Acrolein as a fixative for enzyme cytochemistry.

Since acrolein can penetrate more quickly and deeply into tissue blocks than glutaraldehyde, the possibility of the use of this aldehyde as a prefixative in enzyme cytochemistry was reinvestigated. At low concentrations, acrolein preserves the activities of the enzymes investigated, including those of glucose-6-phosphatase, which is known as one of the most vulnerable to aldehyde fixation; thus, acrolein is usable in enzyme ultracytochemistry. Enzyme activities are also preserved in tissues fixed with acrolein and glutaraldehyde combined. The rapid penetration of acrolein enables fixation in larger tissue blocks and provides greater freedom in specimen selection, especially important advantages when encountering heterogeneous materials as in pathology.     

Dimethylsulfoxide as carrier in enzyme cytochemistry

Summary Addition of dimethylsulfoxide (DMSO) to the incubation medium of succinate dehydrogenase in a concentration of 10% enhances the staining reaction in the hyphae of the fungus Cercosporella herpotrichoides after an incubation period of 15 min. Controls without DMSO remain unstained. DMSO causes a rapid penetration of the components of the medium through the mucilage that covers the hyphae.     

Freeze-fracture cytochemistry: a new method combining immunocytochemistry and enzyme cytochemistry on replicas.

We describe a new freeze-fracture cytochemical technique consisting of combined immunocytochemistry and enzyme cytochemistry. This technique reveals the relationship between molecules in biological membranes by double labeling with two different cytochemical markers (i.e., immunogold probes and cerium). In this method, antigens were detected with specific primary antibodies and appropriate secondary immunoprobes. Subsequently, alkaline phosphates activity was detected with cerium as the capture agent on the same replicas. Octyl-glucoside (OG) digestion before the cytochemical reactions was crucial to the success of this combined method. OG is an efficient detergent and OG digestion can preserve both immunocytochemical antigenicity and enzyme activity on replicas. As an initial examination, we applied this technique to the study of glycosyl-phosphatidyl-inositol-anchored proteins and adhesion molecules in human neutrophils. The method described here should serve as a unique additional approach for the study of topology and dynamics of molecules in biomembranes.     

Structure-activity of cutinase, a small lipolytic enzyme

Cutinase, a small lipolytic enzyme, is the smallest member of the alpha/beta-hydrolase fold family, to which the other lipases belong. Cutinase has a catalytic activity comparable to that of pancreatic lipase on short chain triglycerides, and retains a significant activity on long chain triglycerides. Cutinase has been extensively studied using site-directed mutagenesis, and we have thoroughly characterized it from a structural point of view. Besides the native enzyme, tens of mutants and several inhibitor complexes have been solved, providing a complete and precise picture of the structure, dynamics and catalytic machinery of cutinase.     

The enzyme cytochemistry and composition of elasmobranch granulocytes

Peroxidase, alkaline phosphatase, acid phosphatase, β-glucuronidase, α-naphthyl acetate esterase (ANAE), α-naphthyl butyrate esterase, naphthol AS-D chloroacetate esterase, acetyl-L-tyrosine-α-naphthyl esterase (ATNE), tosyl-L-lysine-α-naphthyl esterase (TLNE) and periodic acid-Schiff (PAS) were studied in 17 species of elasmobranchs in which granulocytes had previously been identified at the ultrastructural level.
Eosinophils, eosinophilic and neutrophilic granulocytes contained variable acid phosphatase, esterases and PAS, but they were strongest in neutrophilic granulocytes; particularly ANAE. Esterases were released into surrounding plasma and therefore probably function as ectoenzymes. In eosinophils and some neutrophilic granulocytes there were indications of weak peroxidase, but this could not be conclusively demonstrated. Alkaline phosphatase was diffuse between granules in some eosinophils of Pavoraja , and (β-glucuronidase was diffuse in neutrophilic granulocytes of Etmopterus baxteri , otherwise granulocytes lacked these enzymes. Neutrophilic granulocytes stained moderately to strongly for ATNE and weakly and inconsistently for TLNE in Squalus acanthias and Dalatias licha . with a similar reaction in granular lymphocytoid and thrombocytoid cells of Galeorhinus ausiralis and Raja nasuta . The enzyme composition of these granulocytes is discussed.     

Characterization of a novel lipolytic enzyme from Aspergillus oryzae

In this study, we report the characterization of a protein from Aspergillus oryzae, exhibiting sequence identity with paraben esterase from the genus Aspergillus. The coding region of 1,586 bp, including a 77-bp intron, encoded a protein of 502 amino acids. The gene without the signal peptide of 19 amino acids was cloned into a vector, pPICZαC, and expressed successfully in Pichia pastoris as an active extracellular protein. The purified recombinant protein had pH and temperature optima of 7.0–8.0 and 30 °C, respectively, and was stable at the pH range of 7.0–10.0 and up to 40 °C. The optimal substrate for hydrolysis by the purified recombinant protein, among a panel of α-naphthyl esters (C2–C16), was α-naphthyl butyrate (C4), with activity of 0.16 units/mg protein. The considerable hydrolytic activity of the purified recombinant enzyme toward tributyrin was determined. However, no paraben esterase activity was detected toward the ethyl, propyl, and butyl esters of 4-hydroxybenzoic acid. In addition, no activity was detected toward the methyl esters of ferulic, p-coumaric, caffeic, and sinapic acids that would indicate feruloyl esterase activity.     

Glutaraldehyde-fixation of yeast cells: Kinetics of a model system for enzyme cytochemistry

The kinetics of glutaraldehyde inactivation of a protoplasmic (-fructofuranosidase) and an extracytoplasmic (acid phosphatase) enzyme inSaccharomyces rouxii cells were studied at pH 5.5 and 30°C. The effects of glutaraldehyde concentration (0.5–3%), pH value, and temperature were surveyed by varying the fixation conditions. Cells from 1- to 10-day cultures retained 50–75% of their acid phosphatase activity and 15–24% of their -fructofuranosidase activity after 1-h exposures to 0.5% glutaraldehyde. The surviving -fructofuranosidase activity remained physically cryptic and was revealed only after further membrane perturbation with ethyl acetate. This crypticity barrier disappeared after overnight incubation of the treated cells at 4°C, with or without added glutaraldehyde, during which time the enzyme was resistant to further inactivation. The velocity ratio for raffinose versus sucrose, as substrate, decreased in treated cells, and changes inV _max andK _m were indicative of frank destruction of some enzyme molecules as well as modification of survivors. A comparable set of changes was also generated by treating cell-free extract with glutaraldehyde. Glutaraldehyde (0.5%) killed all yeast cells at 30°C within 5 min; at 4°C survival rates were quite high—81% after 15 min and 65% after 1 h. The bearing of these examples of enzyme inactivation, permeability barrier abolition, and structural stabilization on the general problems of yeast cytochemistry is discussed.     

Partial purification of a lipolytic enzyme from Escherichia coli.

An enzyme with phospholipase Al activity was purified some 500-fold from Escherichia coli cell homogenates. Lipase, phospholipase A2, and lysophospholipase copurified with phospholipase A1 and the four activities displayed similar susceptibility to heat treatment. The phospholipase A and lipase activities were recovered in a single band when partially purified preparations were subjected to SDS gel electrophoresis. Phospholipase, lysophospholipase, and lipase all required Ca2+ for activity. Phosphatidylcholine, phosphatidylethanolamine, and their lyso analogues were all hydrolysed at equivalent rates and these were substantially greater than the rate of methylpalmitate or tripalmitoylglycerol hydrolyses under similar incubation conditions. Evidence for a direct but slow hydrolysis of the ester at position 2 of phosphoglyceride was obtained; however, release of fatty acid from this position is mostly indirect involving acyl migration to position 1 and subsequent release of the translocated fatty acid. Escherichia coli, therefore, appears to possess a lipolytic enzyme of broad substrate specificity acting mainly at position 1 but also at position 2 of phosphoglycerides and on triacylglycerols and methyl fatty-acid esters.     

液态型凝乳酶储藏条件的初步研究

为进一步延长液态型凝乳酶的储藏时间,以金属离子、糖类、多羟基醇、大分子助剂和表面活性剂等为稳定剂优化得到最优的复合保护剂配方:山梨醇7.5%、明胶1%、甘油15%、吐温400.25%、氯化钾50 mmol/L;添加0.1 g/L对羟基苯甲酸乙酯可有效抑制在储藏过程中由杂茵繁殖导致的发臭、浑浊。添加复合保护剂和防腐剂的液态型凝乳酶,室温放置90 d,凝乳酶活力保留率为80.8%,比对照组提高41.6%。     

Strategies for improving extracellular lipolytic enzyme production by Thermus thermophilus HB27

In Thermus thermophilus HB27 cultures the localisation of lipolytic activity is extracellular, intracellular and membrane bound, with low percentage for the former. Therefore, the extracellular secretion must be increased in order to simplify the downstream process and to reduce the economic cost. This study focuses on the design of an innovative operational strategy to increase extracellular lipolytic enzyme production by T. thermophilus HB27 at bioreactor scale. In order to favour its secretion, the effect of several operational variables was evaluated. Among them, the presence of oils in the culture medium leads to improvements in growth and lipolytic enzyme activity. Sunflower oil is the most efficient inducer showing better results when added after 10 h of growth. On the other hand, although surfactants lead to an almost complete inhibition of growth and lipolytic enzyme production, their addition along the culture could affect the location of the enzyme. Thus, by addition of surfactants at the stationary phase, a release of intracellular and membrane enzyme which increases the extracellular enzyme proportion is detected. Based on these results, strategies with successive addition of oil and surfactant in several culture phases in shake flask are developed and verified in a laboratory scale stirred tank bioreactor.     

Localization mechanisms in enzyme cytochemistry studied with alkaline phosphatase-loaded erythrocyte ghosts

Erythrocyte ghosts containing varying amounts of alkaline phosphatase were used to study the localization mechanisms of three metal salt and one azo method for this enzyme. For the azo method, the minimal amount of alkaline phosphatase that can be visualized within the ghosts proved only to be limited by the optical properties of the azo compound. In contrast, for the metal salt methods, a certain threshold activity had to be present in the ghosts in order to obtain correct localization of the final reaction product. The localization properties of both azo and metal salt methods conformed to the theories of cytochemical enzyme localization presented to date. By determining the rate constant of the capture reaction and the diffusion constant of the primary product, the localization properties of the azo method could be predicted. Some remaining discrepancies between theory and practice are discussed.     

A simple method for ultrastructural enzyme cytochemistry on small volumes and numbers of isolated cells

Summary A simple technique is described for ultrastructural enzyme cytochemistry using small volumes and numbers of single cells. Small aliquots (1–5 l) of single cells suspended in a glutaraldehyde fixative are incubated on poly-L-lysine-coated glass coverslips. Cells in contact with the coated coverslip become immobilized to that support. All changes of solutions are accomplished without repeated centrifugation.     

Prospects for microscopical cytochemistry

Synopsis This review is devoted mainly to an evaluation of the status of microscopical cytochemistry seen as a discipline aiming at both the localization and the quantification of molecular processes in cells. Its relationships to ultramicrochemistry, as well as, in a broader sense, to biochemistry and cell biology, are discussed from both the historical and the methodological points of view. Recent developments in quantitative cytophysical techniques, such as automated cytophotometry using microscopes fitted with flying spot systems, TV cameras, or scanning stages, and the development of rapid flow cytometers are discussed. Analytical electron microscopy is touched upon too.The main part of the review is devoted to recent trends that strengthen the analytical basis of cytochemical staining methods. The special character of staining procedures as a kind of matrix chemistry is discussed and the potentialities of the use of matrixincorporated compounds for the fundamental study and calibration of microscopical staining procedures are elaborated. Parallel developments in the theory and practice of matrix chemistry in biochemistry are stressed. Growing interrelations between microscopical cytochemistry and related fields of investigation, such as the controlled fragmentation of cells, and methods like ultramicroanalysis of individual cells are indicated.     

Ultrastructural localization of cellulase in Trichoderma reesei using immunocytochemistry and enzyme cytochemistry

Two components of the cellulase complex (E.C. 3.2.1.4) of the fungus Trichoderma reesei were localized at the ultrastructural level. Immunocytochemistry and enzyme cytochemistry demonstrated that cellobiohydrolase and beta-1,4 glucanase were localized within cisternae of endoplasmic reticulum and within membrane complexes of cellulose-grown hyphae. Both enzymes were also present in the culture medium. Glucose-grown control hyphae lacked enzyme-specific staining, and no enzyme activity was detected in the growth medium.