Evidence of the heterogeneity of mast cell population based on their biogenic amine content

The heterogeneity of the mast cells localized in various organs has been demonstrated by histochemical determination in their indole amine and histamine content. The strongest amine reaction was found in the mast cells in the mesenterium and peritoneal fluid where their maturation occurs. The reaction of the subcutaneous connective tissue is weaker; in the thyroid gland the reaction is weak as well as diffuse. In the thymus the mast cells localized along the vessels give a strong histamine reaction. The experiments support previously published data concerning the heterogeneity of mast cell populations.     

Purification and characterization of human skin mast cells. Evidence for human mast cell heterogeneity

Our previous studies of human lung and intestinal mast cells failed to show the heterogeneity found among mast cells in murine species. Recently, we and others have developed techniques for the enzymatic dispersion of human neonatal skin mast cells. In addition, we are now able to make single cell suspensions of mast cells from adult skin and to purify these cells to near homogeneity. Comparative studies of mast cells from these several sources have uncovered several major differences among them. Adult and neonatal skin mast cells themselves differ in that the former are 10-fold less sensitive to goat anti-human IgE, with maximal release occurring at 3.0 and 0.3 microgram/ml, respectively. Skin mast cells also differ in optimal temperature for release: adult mast cells respond maximally at 23 to 30 degrees C and neonatal cells at 37 degrees C. Skin mast cells from both sources are dramatically different from lung and intestinal mast cells in two aspects. First, skin mast cells are quite responsive to several stimuli--morphine sulfate (10(-4) to 10(-6) M), substance P (10(-5) to 10(-7) M), compound 48/80 (10 to 0.1 microgram/ml), f-Met peptide (10(-6) M), and C5a (10(-8) M)--to which the other mast cells fail to respond. Second, although stimulated skin mast cells produce prostaglandin D2, little leikotriene C4, if any, is generated, unlike lung or intestinal mast cells. These differences in inflammatory potential among human mast cells from various sites have important implications for the management of allergic and inflammatory responses.     

The heterogeneity of mast cell tryptase from human lung and skin.

There has long been conjecture over the degree to which there may be structural and functional heterogeneity in the tetrameric serine protease tryptase (EC 3.4.21.59), a major mediator of allergic inflammation. We have applied 2D gel electrophoresis to analyze the extent, nature, and variability of this heterogeneity in lysates of mast cells isolated from lung and skin, and in preparations of purified tryptase. Gels were silver stained, or the proteins transferred to nitrocellulose blots and probed with either tryptase-specific monoclonal antibodies or various lectins. Tryptase was the major protein constituent in mast cell lysates, and presented as an array of 9-12 diffuse immunoreactive spots with molecular masses ranging from 29 to 40 kDa, and pI values from 5.1 to 6.3. Although the patterns obtained for lung and skin tryptase were broadly similar, differences were observed between tissues and between individual donors. Lectin binding studies indicated the presence of mono-antennary or bi-antennary complex-type oligosaccharide with varying degrees of sialylation. Deglycosylation with protein-N-glycosidase F (PNGase F) reduced the size of both lung and skin tryptase, while incubation with PNGase F or neuraminidase narrowed the pI range, indicating variable degrees of glycosylation as a major contributor to the size and charge heterogeneity. Comparison of different purified preparations of lung and skin tryptase revealed no significant difference in pH profiles, but differences were seen in reactivity towards a range of chromogenic substrates, with substantial differences in Km, kcat and degree of cooperativity. Mathematical modeling indicated that the variety in kinetics parameters could not result solely from the sum of varying amounts of isoforms obeying Michaelis-Menten kinetics but with different values of Km and kcat. The heterogeneity demonstrated for tryptase in these studies suggests that there are important differences in tryptase function in different tissues.     

Low density lipoprotein degradation by rat mast cells. Demonstration of extracellular proteolysis caused by mast cell granules

The interaction between rat serosal mast cells and low density lipoproteins (LDL) was studied in vitro. When rat 125I-LDL was incubated with mast cells, it was bound to a binding site on the mast cell surface but was not internalized by the cells. Even though 125I-LDL was not internalized, its protein component, apolipoprotein B, was rapidly degraded. The proteolytic activity responsible for the degradation of apolipoprotein B was present in the extracellular fluid of mast cells. It could be shown that the degradation was caused entirely by specific cell organelles of mast cells, the granules, which were spontaneously released into the extracellular fluid during preparation and incubation of the cells. In contrast to uncontrolled spontaneous degranulation, a controlled specific degranulation of mast cells can be induced by treating the cells with the compound 48/80. When increasing amounts of 48/80 were added to mast cell suspensions, a dose-dependent release of granules was observed and an increase in the rate of 125I-LDL degradation resulted. The increase in 125I-LDL degradation closely followed the increase in granule release. Thus, a quantitative relationship between the amount of granules present in the extracellular fluid and the amount of degradation of 125I-LDL could be established. The apolipoprotein part of LDL was extensively degraded by isolated mast cell granules. Analysis by polyacrylamide gel electrophoresis showed that upon incubation of LDL with isolated granules, the apolipoprotein B band rapidly disappeared with simultaneous appearance of several low molecular weight bands. The degradation of 125I-LDL by mast cell granules proceeded optimally at neutral pH and at physiological ionic strength. The results show that mast cell granules are able to efficiently degrade LDL in vitro, once released from mast cells into the extracellular fluid.     

Single-locus control of the mast cell population in mouse skin

The number of mast cells in connective tissue from dorsal skin varied markedly among mouse strains. Inbred strains of mice were typed into three groups, high (NC and NZB mice), low (B6, B10, and BALB/c mice), and intermediate (C3H/He and DBA/2 mice), by their mast cell content in the skin. However, the strain differences in the number of mast cells was marginal at the age of weaning but became distinct with age. This could be explained mainly by the frequently observed clustering of mast cells in adult NC and NZB mice and the rarely observed clustering in younger mice as well as in adult B10 and BALB/c mice. The breeding experiment revealed that the difference in the number of mast cells between NC and B10 mice was controlled by a single autosomal dominant locus, for which we propose the designation Mcr (mast cell regulator). The role of the Mcr locus with regard to the frequency of the mast cell population in connective tissue is discussed.     

Histochemical heterogeneity of dispersed human lung mast cells.

Cytocentrifuge preparations of enzymatically dispersed human lung parenchymal mast cells were examined by light microscopy after fixation in either Mota's basic lead acetate or 10% neutral buffered formalin followed by toluidine blue staining at pH 0.5. Fixation in Mota's basic lead acetate allowed detection of all mast cells. However, after formalin fixation only 10.8 +/- 1.3%, range 4.7 to 17%, n = 8 remained detectable (i.e., formalin "resistant"). Therefore, the vast majority of human lung mast cells lose their metachromatic staining after formalin fixation (i.e., are formalin "sensitive"). Mast cells were then separated on the basis of diameter by countercurrent elutriation and on the basis of density by discontinuous Percoll gradients. Histochemically distinct populations of mast cell types emerged in all lungs studied. The proportion of formalin-resistant mast cells increased as a function of diameter: less than 5% at diameters of less than or equal to 11 mu and densities less than or equal to 1.063 g/ml, to 30 to 40% in cells of diameters greater than or equal to 16 mu and densities greater than or equal to 1.100 g/ml. Maximum anti-IgE challenge of nearly homogeneous formalin-sensitive mast cells (94.3 +/- 2.1% purity, n = 6) caused the generation of both leukotriene C4 (64.6 +/- 26.4 pg/mast cell) and PGD2 (114.8 +/- 37.5 pg/mast cell). Six- to eight-fold enrichment of formalin-resistant mast cells did not significantly alter the histamine release response or profiles of arachidonate metabolites. Similar results were obtained for the nonimmunologic stimulus ionophore A23187. We conclude that two histochemically distinct subpopulations, of mast cells are present in human lung suspensions. Although formalin-sensitive cells account for almost 90% of lung mast cells, formalin-resistant cells are separable by their large diameters and higher densities. Both subtypes show similar histamine release responses and arachidonate oxidation profiles.     

Effect of sub-diaphragmatic vagotomy on gastric mucosal mast cell population in pylorus ligated rats.

Gastric mucosal mast cell population was studied following sub-diaphragmatic vagotomy in albino rats, 6 and 12 h after pylorus ligation. Sub-diaphragmatic vagotomy significantly increased the gastric mucosal mast cell population in both 6 and 12 h groups, the increase being more in the latter. The results suggest that the vagal impulses act on the gastric mucosal mast cells causing their degranulation. Following vagotomy the contents stay bound within the mast cells. Increase in mast cell population with the longer experimental situation was possibly due to the continuation of normal turnover of the mast cells in the gastric mucosa. The present study, however, does not lead to a conclusion that the vagal influence on mast cell population is similar throughout the gastro-intestinal tract.     

New approaches for the analysis of mast cell maturation, heterogeneity, and function

Mast cells are regarded as potentially critical participants in a wide variety of important biological processes. Yet it has been difficult to ascertain the precise contribution of mast cells to many of these reactions. In part, this reflects recognition that different populations of mast cells may vary in phenotype and therefore may express different functions. Another problem has been the lack of suitable model systems for identifying and quantitating the mast cell's unique roles in biological processes in intact animals. This review will outline the development of promising new approaches for analyzing mouse mast cell differentiation and phenotypic heterogeneity and for studying the roles of mast cells in vivo.     

Effect of liver cell coat acid mucopolysaccharide on the appearance of density-dependent inhibition in hepatoma cell growth.

Yoshida ascites hepatoma 66 (AH 66) cells grown in monolayer cultures show a lack of density-dependent inhibition of growth. When acid mucopolysaccharide (AMPS) isolated from rat liver cell coats is added to growing cultures at concentrations of 50–100 μg/ml, AH 66 cell cultures became markedly inhibited and exhibited density-dependent inhibition of growth at a cell density of 19 × 10⁴ cells/cm². Inhibition reached 84% below control levels. Inhibition is a density-related phenomenon since cells at densities below 19×10⁴ cells/cm² do not exhibit inhibition of growth. AH 66 cells inhibited in the plateau state are capable of resuming growth when AMPS is removed from the cultures. When AMPS is added at a concentration of 0.5 μg/ml, growth of tumor cells is promoted. Promotion reaches 78% above control levels. It is suggested that AMPS may play an important part in the regulation of cellular proliferation.     

Chromatographic heterogeneity of 3-hydroxyproline and its basis.

trans-3-Hydroxy-l-proline is frequently eluted from amino acid analyzer columns as a double or asymmetric peak. This behavior was shown to depend on the size of the hydroxyproline sample, the pH, and the nature of the eluting buffer. Comparison of a number of organic acids used as eluting buffers suggested that the hydroxyl group of malic or citric acid participates in reversible complex formation with 3-hydroxyproline. Evidence for such chemical interaction was obtained by NMR spectrometry.