The mast cells of the mammalian central nervous system

Summary The uptake and turnover of the precursors of heparin and heparan sulphate (³⁵S), and of serotonin (³H-5-hydroxytryptophan; ³H-5-HTP) by mast cells (MCs) and neurolipomastocytoid cells (NLMs) of the mammalian CNS were studied. Rats of varying age from 1 day to early adulthood were injected with ³⁵S (as a solution of sodium sulphate) and ³H-5-HTP, and allowed to survive for different periods. Several fixatives, as well as lengths of exposure to photographic emulsion, were tested. The monoamine oxidase inhibitor, nialamide, needed to be given before uptake of ³H-5-HTP could be adequately demonstrated especially in the CNS. ³⁵S was taken up by structures known to contain a great deal of sulphate, viz., cartilage and goblet cells, as well as by MCs of adult liver and thymus, but not by MCs of adult CNS. All of these structures, including the MCs of CNS, took it up much more avidly in babies than in adults. ³H-5-HTP had a similar effect in that the MCs of younger animals took it up more strongly than did those of adults. In the MCs of the CNS uptake seemed to increase up to 15 days of age but then to decrease as maturity was reached. The MCs are located in the leptomeninges of the cerebral hemispheres as well as the choroid fissures and dorsal thalamus. The NLMs, ubiquitously distributed in the leptomeninges as well as perivascularly, showed less radioactivity with both markers in fewer cells and only in babies. The possible significance of these results is discussed. It is concluded that MCs, and to a lesser extent NLMs, of the CNS do permit entry of these markers, and that the more immature the cells, the heavier the load that enters. Adult cells do not seem to take up precursor suggesting little or no turnover.Supported in part by a grant from the Incentive Plan of the Medical School, American University of Beirut, and by Research Support Grant MA-004 from the College of Graduate Studies, University of Kuwait     

The mast cells of the mammalian central nervous system. III. Ultrastructural characteristics in the adult rat brain.

The brains of young adult male and female Sprague-Dawley rats were studied with the electron microscope to determine the full ultrastructural picture of two types of perivascular granular cell. One of these, referred to here as the type I cell and described by both light and electron microscopy by several authors, including ourselves, has been reported to be a mast cell (MC) almost identical to MCs outside the CNS. The other, referred to here as the type II cell and described by many authors under almost as many names, was dealt with fully by Ibrahim in several reports and regarded by him as a type of MC. It is felt that the results warrant the conclusions that the type I cells are indeed MCs, while the type II cells are closely allied to the type I cells and probably better adapted to the function they subserve in the CNS of mammals. The similarities between the two cell types probably outnumber the dissimilarities and even these have their counterparts in MCs outside the CNS. The problem of the possible confusion between the type II cells and macrophages, whether reportedly within vessel walls or in the form of modified or special 'pericytic' microglia, is discussed. It is concluded that there is no justification for regarding these cells as macrophages. Because of the similarity between the type II cells and MCs, and because of the high lipid content of the type II cells, it is suggested that these elements be called neurolipomastocytes or neurolipomastocytoid cells.     

The mast cells of the mammalian central nervous system V. The effect of compound 48|80 on the neurolipomastocytoid cells and related areas of the CNS: Early changes

Summary The response of the neurolipomastocytoid cells (NLMs) and elements in their vicinity within the central nervous system of various animal species was studied following injection of the animals with the specific mast cell (MC)-discharger compound 48/80. The observed alterations were grouped into those occurring early (0–21 days) and later (up to 18 months). In the present report, only the acute changes are described, light and electron microscopically.Most experimental animals developed prostration, scratching, acral-type reaction, signs of respiratory distress and salivation, and, in the monkey, uncontrollable somnolence. Within about 2 weeks after the injection some animals (especially guinea pigs) manifested various degrees of limb paralysis. The NLMs, like MCs outside the CNS, responded to injection by various degrees of degranulation, vacuolation, marked variation in granule size, apparent cell loss and sometimes an increase in number. Electron microscopically, particulate breakdown products of the granules of the NLMs appeared in the cytoplasm; occasionally there was suggestive evidence that they had passed inward across the vessel wall to reach the lumen, and also outward through the outermost basal lamina. Perivascular astrocytic feet showed swelling and vacuolation shortly after the injection, which was followed by evidence of gliosis and later scarring; occasionally, alterations in the mitochondria were observed. In the spinal cord of the guinea pig, capillary neoformation was observed with endothelial cells and adjacent NLMs taking up tritiated thymidine.The discussion centers on the partial similarity of response to compound 48/80 of the NLMs to that of MCs outside the CNS, and the probable involvement of NLM-damage in the parenchymal changes.The preliminary portion of this work was done with T. Wiedman at Ames Research Center, Moffett Field, California; a short communication has been published (Ibrahim 1970), and part of the study was presented at the Annual Meeting of the American Association of Anatomists (Ibrahim et al. 1976)Supported by a grant from the Incentive Plan of the Medical School, American University of Beirut, Lebanon, by Biomedical Research support Grant RR 05373 from the Biomedical Research Support Branch, Division of Research Facilities and Resources, National Institutes of Health, and by Research Grant No. MA 004 from the College of Graduate Studies, University of Kuwait     

IL-16 regulation of human mast cells/basophils and their susceptibility to HIV-1

AIDS patients often contain HIV-1-infected mast cells (MCs)/basophils in their peripheral blood, and in vivo-differentiated MCs/basophils have been isolated from the blood of asthma patients that are HIV-1 susceptible ex vivo due to their surface expression of CD4 and varied chemokine receptors. Because IL-16 is a ligand for CD4 and/or an undefined CD4-associated protein, the ability of this multifunctional cytokine to regulate the development of human MCs/basophils from nongranulated progenitors residing in cord or peripheral blood was evaluated. After 3 wk of culture in the presence of c-kit ligand, IL-16 induced the progenitors residing in the blood of normal individuals to increase their expression of chymase and tryptase about 20-fold. As assessed immunohistochemically, >80% of these tryptase(+) and/or chymase(+) cells expressed CD4. The resulting cells responded to IL-16 in an in vitro chemotaxis assay, and this biologic response could be blocked by anti-IL-16 and anti-CD4 Abs as well as by a competitive peptide inhibitor corresponding to a sequence in the C-terminal domain of IL-16. The additional finding that IL-16 induces calcium mobilization in the HMC-1 cell line indicates that IL-16 acts directly on MCs and their committed progenitors. IL-16-treated MCs/basophils also are less susceptible to infection by an M/R5-tropic strain of HIV-1. Thus, IL-16 regulates MCs/basophils at a number of levels, including their vulnerability to retroviral infection.     

Myometrial cells induce angiogenesis and salvage damaged myocardium

Characteristically, uterine myometrial cells (MCs) are proliferative, inducing angiogenesis within the female reproductive organ. We evaluated whether MCs implanted into myocardium could also induce angiogenesis and restore heart function after injury. MCs were isolated from the adult rat uterus and cultured for three studies: 1) Intracellular VEGF levels were measured in MCs cultured with progesterone (10(-11), 10(-9), and 10(-7) M) (n = 6 tests per group). 2) Blood vessel density was evaluated 8 days after MCs (3 x 10(6) or 6 x 10(6)), smooth muscle cells (SMCs), or endothelial cells (n = 6 rats per group) were injected with matrigel into the subcutaneous tissue of adult rats. 3) MCs, SMCs (5 x 10(6)/rat), or media were injected into a transmural scar 3 wk after cryoinjury in rat hearts (n = 12 rats per group), and heart function, blood vessel density, and myocardial scar size and thickness were evaluated 5 wk later. In study 1, cultured MCs expressed VEGF, with levels significantly (P < 0.05) upregulated by progesterone at an optimal dose of 10(-11) M. In study 2, MCs injected into the subcutaneous tissue with matrigel induced significantly more blood vessels, especially large-diameter vessels, than did SMCs or endothelial cells (P < 0.01 for all groups). This angiogenic effect was greatest (P < 0.01) at higher doses of MCs and was enhanced by progesterone (10(-11) M). In study 3, MCs implanted into the injured myocardium increased blood vessel density at the implant area, reduced scar size, and improved cardiac function relative to SMCs and media. Overall, MCs induced angiogenesis in vitro and in vivo, prevented cardiac remodeling, and improved heart functional recovery after cardiac injury.     

Senescent jejunal mast cells and eosinophils in the mouse preferentially translocate to the spleen and draining lymph node, respectively, during the recovery phase of helminth infection

Because mice infected with Trichinella spiralis experience a pronounced, but transient, mastocytosis and eosinophilia in their intestine, this disease model was used to follow the fate of senescent T cell-dependent mast cells (MCs) and eosinophils. Very few MCs or eosinophils undergoing apoptosis were found in the jejunum during the resolution phase of the infection, even though apoptotic MCs were common in the large intestine. Although the mesenteric draining lymph nodes contained large numbers of apoptotic eosinophils, MCs were rarely found at this location. During the recovery phase, large numbers of MCs were present in the spleen, and many of these cells possessed segmented nuclei. These splenic MCs were not proliferating. Although MCs from the jejunum and spleen of noninfected mice failed to express mouse MC protease (mMCP) 9, essentially all of the MCs in the jejunal submucosa and spleen of T. spiralis-infected mice expressed this serine protease during the recovery phase. The MCs in the jejunum expressed mMCP-9 before any mMCP-9-containing cells could be detected in the spleen. The fact that mMCP-9-containing MCs were detected in splenic blood vessels as these cells began to disappear from the jejunum supports the view that many jejunal MCs translocate to the spleen during the recovery phase of the infection. During this translocation process, some senescent jejunal MCs undergo nuclear segmentation. These studies reveal for the first time different exit and disposal pathways for T cell-dependent eosinophils and MCs after their expansion in the jejunum during a helminth infection.     

Ultrastructural immunocytochemistry and lectin histochemistry of the subcommissural organ in the snake Natrix maura with particular emphasis on its vascular and leptomeningeal projections

The ependymal cells of the subcommissural organ (SCO) of the snake Natrix maura display long basal processes which terminate either on blood vessels or on the leptomeninges. The cell body and the basal processes contain a secretory material detectable immunocytochemically at the light-microscopic level using an antibody raised against bovine Reissner's fiber. The present investigation deals with the ultrastructural location in these cells of the (i) immunoreactive material; (ii) concanavalin A (Con A)- and wheat-germ agglutinin (WGA)-binding sites. In the subnuclear region the immunoreactive material was located within dilated cisternae of the rough endoplasmic reticulum and had affinity for Con A but not for WGA. In the supranuclear region the secretory material was exclusively located within numerous granules. Since all these granules showed affinity for WGA, they can be regarded as "post-Golgi" elements. Thus, at variance with the situation in the mammalian SCO, in the ophidian SCO most of the secretion is stored in secretory granules rather than in dilated cisternae of the rough endoplasmic reticulum. In the perivascular and leptomeningeal endings the immunoreactive material was located within granules which, because of their affinity for WGA, should also be regarded as true secretory granules derived from the Golgi apparatus. It is concluded that these granules are transported along the basal processes and accumulated in the perivascular and leptomeningeal endfeet. This observation favours the view of a local release of the content of these granules, since there is no evidence for a reverse transport of these granules all the way back from the distal termination to the apical pole, to be finally released into the ventricle.     

The roles of mast cells in anticancer immunity

The tumor microenvironment (TME), which is composed of stromal cells such as endothelial cells, fibroblasts, and immune cells, provides a supportive niche promoting the growth and invasion of tumors. The TME also raises an immunosuppressive barrier to effective antitumor immune responses and is therefore emerging as a target for cancer immunotherapies. Mast cells (MCs) accumulate in the TME at early stages, and their presence in the TME is associated with poor prognosis in many aggressive human cancers. Some well-established roles of MCs in cancer are promoting angiogenesis and tumor invasion into surrounding tissues. Several mouse models of inducible and spontaneous cancer show that MCs are among the first immune cells to accumulate within and shape the TME. Although MCs and other suppressive myeloid cells are associated with poor prognosis in human cancers, high densities of intratumoral T effector (T(eff)) cells are associated with a favorable prognosis. The latter finding has stimulated interest in developing therapies to increase intratumoral T cell density. However, cellular and molecular mechanisms promoting high densities of intratumoral T(eff) cells within the TME are poorly understood. New evidence suggests that MCs are essential for shaping the immune-suppressive TME and impairing both antitumor T(eff) cell responses and intratumoral T cell accumulation. These roles for MCs warrant further elucidation in order to improve antitumor immunity. Here, we will summarize clinical studies of the prognostic significance of MCs within the TME in human cancers, as well as studies in mouse models of cancer that reveal how MCs are recruited to the TME and how MCs facilitate tumor growth. Also, we will summarize our recent studies indicating that MCs impair generation of protective antitumor T cell responses and accumulation of intratumoral T(eff) cells. We will also highlight some approaches to target MCs in the TME in order to unleash antitumor cytotoxicity.     

Ancient origin of mast cells

The sentinel roles of mammalian mast cells (MCs) in varied infections raised the question of their evolutionary origin. We discovered that the test cells in the sea squirt Ciona intestinalis morphologically and histochemically resembled cutaneous human MCs. Like the latter, C. intestinalis test cells stored histamine and varied heparin·serine protease complexes in their granules. Moreover, they exocytosed these preformed mediators when exposed to compound 48/80. In support of the histamine data, a C. intestinalis-derived cDNA was isolated that resembled that which encodes histidine decarboxylase in human MCs. Like heparin-expressing mammalian MCs, activated test cells produced prostaglandin D₂ and contained cDNAs that encode a protein that resembles the synthase needed for its biosynthesis in human MCs. The accumulated morphological, histochemical, biochemical, and molecular biology data suggest that the test cells in C. intestinalis are the counterparts of mammalian MCs that reside in varied connective tissues. The accumulated data point to an ancient origin of MCs that predates the emergence of the chordates >500 million years ago, well before the development of adaptive immunity. The remarkable conservation of MCs throughout evolution is consistent with their importance in innate immunity.     

T cell proliferation by direct cross-talk between OX40 ligand on human mast cells and OX40 on human T cells: comparison of gene expression profiles between human tonsillar and lung-cultured mast cells

Mast cells (MCs) are the primary effector cells in allergic reactions and have also been found to activate T cells and to reside in close physical proximity to T cells. However, the molecular mechanisms involved in the MC-T cell interaction remain unclear. We hypothesized that human tonsillar MCs, which locate in the interfollicular areas, might interact with T cells. Thus, we first established a culture system of human tonsillar MCs and then compared gene expression profiles of tonsillar MCs with that of lung MCs before and after aggregation of FcepsilonRI by using high-density oligonucleotide probe arrays. Here we show that resting tonsillar MCs, when compared with lung MCs, revealed significantly higher expression levels for CC chemokines (CCL3 and 4), which recruit T cells, and for TNFR superfamilies (OX40 ligand and 4-1BB ligand), which induce proliferation of T cells. After aggregation of FcepsilonRI, not only tonsillar MCs but also lung MCs up-regulated the expression of these molecules. We confirmed that T cell proliferation is induced in direct cross-talk by the MC surface molecule OX40 ligand. These results suggest that human MCs may play important roles in adaptive immunity through the T cell responses.     

Mesothelin expression in the leptomeninges and meningiomas.

The identity and functions of surface proteins on human leptomeningeal and meningioma cells are incompletely characterized. Some structural and functional similarities between the leptomeninges and pleura suggest that proteins important to pleural function and tumorigenesis might also be relevant to leptomeningeal disease. Mesothelin is a recently described, 40-kDa membrane protein expressed in pleura. Its functions in this tissue are under investigation. Sections of 20 normal adult brains with leptomeninges and 49 World Health Organization (WHO) grade I, 21 grade II, and 2 grade III meningiomas were analyzed using an extensively characterized monoclonal antibody to mesothelin and streptavidin-biotin complex immunohistochemistry. Five meningiomas were also evaluated by Western blot. Mesothelin immunoreactivity was detected in the arachnoid in 6 of 20 cases and in 23 of 49 WHO grade I meningiomas. It was also detected in 7 of 21 WHO II tumors and 1 of the 2 anaplastic meningiomas. By Western blot, all five meningiomas exhibited mesothelin precursor protein, including one where notable immunoreactivity was not identified in a formalin-fixed tissue section. These findings suggest that mesothelin is expressed in at least some arachnoid and meningioma cells. Future studies may clarify its role in the development of meningiomas, meningeal seeding of gliomas, and metastases to the leptomeninges.     

A sharp increase in the density of pulmonary and pericardial mast cells under monocrotaline-induced pulmonary hypertension in rats

Multifunctional granular mast cells (MCs) are involved in various pathological processes. The response of MC populations of myocardium, pericardium and lung to pulmonary hypertension (PH) has been studies 8 weeks after injection of monocrotaline. Five intact and five experimental rats were used. The density of MCs of different maturity was estimated on paraffin sections stained with Alcian blue and Safranin. Expressiveness of PH was estimated by functional parameters with the help of echocardiograms and by morphological markers. The MC density in myocardium of the intact and experimental rats was relatively low: 2 to 4 cells/mm2. MC density in the pericardium of intact rats was 14 times higher than in myocardium and increased 3 times for PH. The mature Safranin-positive cells predominated (70-80%) in myocardium and pericardium of intact and experimental rats. The MC density in the lungs of intact rats was about 30 cells/mm2; 98% of these cells were immature Alcian-positive cells. The mean density of MCs in the lungs of rats with PH increased 5.6 times. The mature Safranin-positive cells appeared in the lungs of rats with severe pathology. The greatest number of MCs in lungs was in the rats with the most pronounced disorders of myocardium function and marked histological damages (injuries) of myocardium and lungs. The finding show active response of MC population to monocrotaline-induced PH that stimulates migration of immature MCs into pericardium and lungs from the outside. Our data indicate the important role of MCs in the pathogenesis of PH.     

Fatty acid-binding protein regulates LPS-induced TNF-alpha production in mast cells

There has been increasing evidence for the involvement of fatty acid-binding proteins (FABPs) in the cytokine production of macrophages and dendritic cells probably through the control of cellular lipid metabolism and signal transduction. Since mast cells (MCs) are recently shown to be involved in immune response through modification of cytokine production, it is possible that some FABPs could also be involved in the immune response of MCs. In this study, we found that epidermal-type FABP (E-FABP) was expressed in murine bone marrow-derived MCs (BMMCs). Using BMMCs from genetically E-FABP-null mutated mice, we demonstrated that E-FABP in BMMCs plays a key role in the production of TNF-alpha following lipopolysaccharide (LPS) stimulation. In the in vivo septic peritonitis model (cecal ligation and puncture model), E-FABP-null mice showed a significantly increased mortality compared to wild-type mice. However, no significant difference in antigen-induced cytokine production was observed between wild-type and E-FABP-null BMMCs, and systemic anaphylaxis was equally induced in vivo in both wild-type and E-FABP-null mice. These results suggest that E-FABP is specifically involved in the LPS-induced cytokine production of MCs, and could play a role in the host-defense against bacterial infection, possibly through regulation of TNF-alpha production.     

Resident and circulating mast cells in propulsative organs of frog <Emphasis Type="Italic">Rana temporaria</Emphasis>

A histochemical and ultrastructural examination of mast cells (MCs) in “blood” and lymph hearts of the adult frog Rana temporaria showed that they are represented by two populations, i.e., resident and circulating MCs. Resident cardiac MCs have an oval or elongated shape and are located in the atrial and ventricular myocardium, as well as in connective tissue of the epicardium. Circulating MCs were identified in heart lumen lacunas and in narrow clefts produced by ventricular trabecular myocardium, as well as in blood-filled atrial and ventricular central cavities. The small round shape circulating MCs resemble lymphocytes, but their cytoplasm is filled with granules that are ultrastucturally similar to granules of cardiac resident MCs. In the lymph heart, elongated resident MCs are located in the interstitial space between the cross-striated muscle fibers and smooth muscle cells of afferent and efferent heart valves. Round circulating MCs are occasionally visible in the cavity of the lymph heart. More commonly, circulating MCs are found in the lymphatic sinus cavity located adjacent to lymph hearts. In certain parts of the lymphatic sinus walls, MCs form clusters that are in tight contact with the mesothelial cells that line the lymphatic cavity. Our histochemical investigation revealed that both resident and circulating MCs of the propulsative organs are strongly alcian blue positive, but are weakly red after safranin staining and weakly metachromatic with toluidine blue. The presence of populations of circulating MCs in adult frogs suggests that there are differences in MC biology in lower and higher vertebrates.     

Differentiation of mononuclear blood cells into macrophages, fibroblasts and endothelial cells in thrombus organization

The organization of thrombi and emboli may be performed exclusively by mononuclear blood cells which represent precursors of various mesenchymal cell types. Between the 10th and 20th day after the onset of blood clotting, mononuclear cells within the fibrinous matrix differentiate into (1) macrophages responsible for hematoclasia and hematophagocytosis, (2) endothelial cells lining autolytic slits in the fibrinous matrix and forming new capillaries, and (3) fibroblasts and even smooth muscle cells building up a young mesenchymal connective tissue.     

The mast cell: an evolutionary perspective

This review article is an attempt to trace the evolution of mast cells (MCs). These immune cells have been identified in all vertebrate classes as single‐lobed cells containing variable amounts of membrane‐bound secretory granules which store a large series of mediators, namely histamine, proteases, cytokines and growth factors. Other MC features, at least in mammals, are the c‐kit receptor for the stem cell factor and the high‐affinity receptor, FcεRI, for immunoglobulin E (IgE). The c‐kit receptor also has been identified in fish MCs. The FcεRI receptor seems to be a more recent acquisition in MC phylogenesis given that IgE originated in mammalian species. Tryptase and histamine have also been recognized in MCs of teleost fish. Thus, a cell population with the overall characteristics of higher vertebrate MCs is identifiable in the most evolutionarily advanced fish species. Two potential MC progenitors have been identified in ascidians (urochordates which appeared approximately 500 million years ago): the basophil/MC‐like granular haemocyte and the test cell. Both contain histamine and heparin, and provide defensive functions. Some granular haemocytes in Arthropoda also closely approximate the ultrastructure of modern MCs. The origin of MCs is probably to be found in a leukocyte ancestor operating in the context of a primitive local innate immunity and involved in phagocytic and killing activity against pathogens. From this type of defensive cell, the MC phylogenetic progenitor evolved into a tissue regulatory and remodelling cell, which was incorporated into the networks of recombinase activating genes (RAG)‐mediated adaptive immunity in the Cambrian era, some 550 million years ago. Early MCs probably appeared in the last common ancestor we shared with hagfish, lamprey and sharks about 450‐500 million years ago.     

Selective activation of human intestinal mast cells by Escherichia coli hemolysin

Mast cells (MCs) are recognized to play an important role in bacterial host defense in the murine system. In this study, we studied the interaction of human MCs, isolated from the intestine and purified to homogeneity, with different Escherichia coli and Shigella flexneri strains. We show that alpha-hemolysin (Hly)-producing E. coli strains induce the release of histamine, leukotrienes, and proinflammatory cytokines in intestinal MCs. In contrast, MCs were virtually unresponsive to S. flexneri and several Hly-negative E. coli strains, including the isogenic Hly-deficient mutants of Hly(+) strains. Hly(+) E. coli but not Hly(-) E. coli caused an increase in intracellular Ca(2+) levels. Blocking of extracellular Ca(2+) and of the calmodulin/calcineurin pathway by cyclosporin A inhibited the response to Hly(+) E. coli. Furthermore, inhibition of MAPKs p38 and ERK reduces activation of MCs by Hly(+) E. coli. In addition, using an ex vivo system, we directly record the histamine release by MCs located in the lamina propria after infection with Hly(+) E. coli. Our data indicate that human intestinal mast cells interact with selected Gram-negative bacteria, establish E. coli Hly as a factor regulating MC effector functions, and argue further for a role of human MCs in innate immunity.     

Sharp increase in density of pulmonary and pericardial mast cells in monocrotaline-induced pulmonary hypertension in rats

Multifunctional granular mast cells (MCs) are involved in various pathological processes. The response of the MC population in the myocardium, pericardium, and lungs to pulmonary hypertension (PH) has been studied 8 weeks after the injection of monocrotaline. Five intact and five experimental rats were used. The density of MCs of different degrees of maturity was estimated in paraffin sections stained with Alcian blue and Safranin. The expression of PH was estimated by functional parameters using an echocardiogram and morphological markers. The MC density in the myocardium of intact and experimental rats was relatively low, i.e., 2–4 cells/mm². In the pericardia of intact rats, the MC density was 14 times higher than in the myocardia and increased by a factor of three in PH. In the myocardia and pericardia of intact and experimental rats, mature, Safranin-positive cells predominated (70–80%). In the lungs of intact rats, the MC density was about 30 cells/mm² and 98% of the cells were immature Alcian-positive cells. In lungs of rats with PH the mean density of MCs increased 5.6 times. In lungs of rats with severe pathologies, mature Safranin-positive cells appeared. The highest number of MCs in lungs was found in rats with distinctly pronounced disorders of myocardial function and marked histolological damages of myocardium and lung. The findings show the active reaction of the MC population to monocrotaline-induced PH, which stimulates the migration of immature MCs to the pericardium and lungs from the outside. The connection of cellular mechanisms of the development of PH with the function of MCs is not yet clear; however, the results of the present work indicate the important role of MCs in the pathogenesis of PH.     

Lipid body formation during maturation of human mast cells

Lipid droplets, also called lipid bodies (LB) in inflammatory cells, are important cytoplasmic organelles. However, little is known about the molecular characteristics and functions of LBs in human mast cells (MC). Here, we have analyzed the genesis and components of LBs during differentiation of human peripheral blood-derived CD34(+) progenitors into connective tissue-type MCs. In our serum-free culture system, the maturing MCs, derived from 18 different donors, invariably developed triacylglycerol (TG)-rich LBs. Not known heretofore, the MCs transcribe the genes for perilipins (PLIN)1-4, but not PLIN5, and PLIN2 and PLIN3 display different degrees of LB association. Upon MC activation and ensuing degranulation, the LBs were not cosecreted with the cytoplasmic secretory granules. Exogenous arachidonic acid (AA) enhanced LB genesis in Triacsin C-sensitive fashion, and it was found to be preferentially incorporated into the TGs of LBs. The large TG-associated pool of AA in LBs likely is a major precursor for eicosanoid production by MCs. In summary, we demonstrate that cultured human MCs derived from CD34(+) progenitors in peripheral blood provide a new tool to study regulatory mechanisms involving LB functions, with particular emphasis on AA metabolism, eicosanoid biosynthesis, and subsequent release of proinflammatory lipid mediators from these cells.     

Meningeal cells stimulate and direct the migration of cerebellar external granule cells in vitro

The external granular layer is a secondary proliferative zone that arises from the caudolateral margin of the cerebellar ventricular zone and then spreads beneath the pial surface, eventually covering the entire cerebellar anlage. Here, both a part of the Bergmann glia and granule cells are generated. Selective destruction of the leptomeningeal cell layer during development in vivo disrupts the subpial extension of the external granular layer and the laminar deposition of its descendant cells. The mechanisms by which meningeal fibroblasts exert their controlling influence on cortical development have remained unclear but could involve diffusible factors and/or interactions mediated by direct cellular contacts. In order to test these assumptions, we have co-cultivated cerebellar slice explants with meningeal cells with and without interposition of a microfilter barrier. In this setup, meningeal cells by a diffusible factor stimulated the emigration of immature neurons exclusively from the external granular layer. This effect could also be elicited by fibroblasts from other tissues but not by nonfibroblastic cells such as, e.g., astroglia. In the Boyden chamber assay, the migration of undifferentiated neurons isolated from the external granular layer was chemotactically oriented towards the source of meningeal cell-conditioned media. In comparison, neurons from the internal granular layer did not respond to this stimulus. The attraction of immature neurons towards the pial surface could (1) represent a mechanism for the establishment of (subpial) secondary proliferative zones and (2) hypothetically also play a role in the outward-directed migration of postmitotic cells, e.g., in the isocortical anlage.