Your search keyword '"Cohn ZA"' showing total 5 results

1. Regulation of cell-mediated immunity in lepromatous leprosy

Author

Kaplan G and Cohn Za

Subjects

Lepromatous leprosy, Immunity, Cellular, business.industry, Macrophages, General Medicine, medicine.disease, Cell mediated immunity, Interferon-gamma, Leprosy, Immunology, medicine, Humans, Interferon gamma, Hypersensitivity, Delayed, business, medicine.drug

Published

1986

2. Cholesterol metabolism in the macrophage. II. Alteration of subcellular exchangeable cholesterol compartments and exchange in other cell types

Author

Werb, Z and Cohn, ZA

Subjects

Latex, Immunology, L Cells (Cell Line), In Vitro Techniques, Tritium, Electron, Medical and Health Sciences, Mice, L Cells, Phagocytosis, Animals, Trypsin, Peritoneal Cavity, Melanoma, Microscopy, Macrophages, Phase-Contrast, Dextrans, Mycobacterium bovis, Microspheres, Pulmonary Alveoli, Kinetics, Cholesterol, Thioglycolates, Pinocytosis, lipids (amino acids, peptides, and proteins), Lysosomes, Subcellular Fractions

Abstract

Macrophage membrane cholesterol is present in two subcellular cholesterol pools, a rapidly exchanging compartment comprising about two-thirds of the total cholesterol, and a slowly exchanging compartment comprising one-third of the total. The morphological identification of the kinetically distinguishable pools proceeded by alteration of each compartment. Trypsin treatment markedly decreased the rate of cholesterol exchange without removing cholesterol from the membrane. Recovery of normal exchange rates took more than 7 hr and required protein synthesis. This suggested that a plasma membrane receptor is involved in positioning of lipoproteins for exchange, and is consistent with the plasma membrane localization of the rapidly exchanging compartment. Extensive pinocytosis by nondegradable dextran, dextran sulfate, or sucrose resulted in the accumulation of many secondary lysosomes, thus increasing the relative proportion of intracellular membranes. The measurable granule membrane area, cholesterol content, phospholipid content, and the relative size of the slowly exchanging cholesterol compartment all increased. The amount of intracellular membrane altered by extensive phagocytosis of latex particles also increased the size of the slowly exchanging cholesterol compartment. This suggested that the slowly exchanging pool of cholesterol represented the intracellular membranes primarily of lysosomal origin. Rabbit alveolar macrophages and thioglycollate-stimulated peritoneal macrophages contain many secondary lysosomes as a result of multiple bouts of in vivo phagocytosis and pinocytosis. In both of these cells the fast and slow pools are equal in size. The increased cholesterol content was attributable to the increase in the relative size of the slowly exchanging compartment. L-cells and melanoma cells also exchange their cholesterol with that of serum lipoproteins. Both cells contain few cholesterol-rich intracellular membranes, and had lower cellular cholesterol contents. In these cells the slowly exchanging pool was a minor contribution to cell cholesterol. Studies with these cells provided further evidence for the lysosomal membrane and plasma membrane localization of the slowly and rapidly exchanging cholesterol compartments.

Published

1971

3. Cholesterol metabolism in the macrophage. I. The regulation of cholesterol exchange

Author

Werb, Z and Cohn, ZA

Subjects

Chromatography, Cultured, Cells, Macrophages, Lipoproteins, Acid Phosphatase, Immunology, Temperature, Esters, Centrifugation, In Vitro Techniques, Tritium, Blood Protein Electrophoresis, Biological, Medical and Health Sciences, Mice, Thin Layer, Kinetics, Cholesterol, Gas, Models, Animals, lipids (amino acids, peptides, and proteins), Subcellular Fractions

Abstract

The cholesterol metabolism of homogeneous populations of mouse peritoneal macrophages was evaluated under in vitro conditions. Macrophages are rich in free cholesterol and maintain a constant cholesterol to protein ratio (12 microg cholesterol/mg protein). No detectable cholesterol ester was present within the cell. More than 95% of total cholesterol was membrane associated and the majority was present in subcellular fractions containing lysosomes and plasma membrane. Less than 0.1% of cell cholesterol was synthesized from acetate-1-(14)C. During in vitro cultivation, macrophages rapidly exchanged their membrane cholesterol with that of lipoproteins of calf serum. About 30% of the cell cholesterol was exchanged per hour in 20% serum medium, and exchange was nearly complete by 5 hr. Exchange proceeded in a rapid exponential phase followed by a slower phase. Calculations based on a two compartment model indicated that the rapidly exchanging cholesterol compartment represented 60-70% of the total cell cholesterol, and the slowly exchanging compartment accounted for 30-40%. The relationship between serum lipoprotein concentration and exchange rate exhibited first-order kinetics. The rate was determined by thermal energy, in keeping with a Q(10) of 2, and an activation energy of 12 kcal/mole. Exchange was independent of bulk transport of lipoproteins by pinocytosis and phagocytosis, and was not linked to energy metabolism. The alpha-lipoproteins were the major class of proteins of calf serum participating in exchange.

Published

1971

4. Contribution of serum and cellular factors in host defense reactions. I. Serumfactors in host resistanc

Author

Cohn Za and Austen Kf

Subjects

Host resistance, biology, Host (biology), business.industry, Phagocytosis, Immune Sera, chemical and pharmacologic phenomena, General Medicine, Complement System Proteins, Antibodies, Immune system, Antigenic stimulation, Immunology, biology.protein, Properdin, Medicine, Humans, Antibody, business, Subclinical infection

Abstract

THE principal noncellular factors definitely involved in host resistance are complement and antibody. Although a specific immune antibody response may be too delayed to protect the immunologically inexperienced host against an overwhelming infection the so-called natural antibodies can contribute to innate or nonspecific resistance. Whether complement and these natural antibodies, which in all likelihood arise as a result of specific or crossreacting subclinical antigenic stimulation, account for all the actions attributed to the properdin system is a matter of much concern and is discussed below. The role of antibody (natural or immune) and complement in mediating serum bactericidal activity against . . .

Published

1963

5. Cholesterol metabolism in the macrophage. 3. Ingestion and intracellular fate of cholesterol and cholesterol esters

Author

Werb, Z and Cohn, ZA

Subjects

Carbon Isotopes, Microscopy, Erythrocytes, Macrophages, Lipoproteins, Phase-Contrast, Hydrolysis, Acid Phosphatase, Immunology, Esterases, Esters, Palmitic Acids, In Vitro Techniques, Tritium, Electron, Medical and Health Sciences, Kinetics, Cholesterol, Linoleic Acids, Phagocytosis, Humans, lipids (amino acids, peptides, and proteins), Lysosomes, Phospholipids

Abstract

Phagocytosis of cholesterol-containing particles resulted in the formation of an intralysosomal cholesterol compartment. Cholesterol was excreted out of the macrophage with a single exponential rate which depended on the concentration of acceptor lipoproteins in the medium. Exchange kinetics performed on cells which had ingested particulate cholesterol suggested that excretion occurred by the same mechanism as exchange. Cholesterol esters as particulate albumin coacervates were taken up by macrophages and hydrolyzed by a lysosomal cholesterol esterase with optimal activity at pH 4.0. Cholesteryl linoleate was hydrolyzed much more readily than cholesteryl palmitate. The amount of cholesterol esterase and its specific activity increased during the in vitro cultivation of macrophages. Intralysosomally, cholesteryl linoleate and palmitate were hydrolyzed to free cholesterol which was excreted from the macrophage and recovered in the medium. Since cholesteryl linoleate was hydrolyzed more rapidly than free cholesterol was excreted into the medium, free cholesterol accumulated intralysosomally. Cholesteryl palmitate was hydrolyzed more slowly, and the rate of hydrolysis was limiting for excretion of the free cholesterol from within the lysosome.

Published

1972