Mast cells of the lungs in experimental hyperergic pleurisy

Reaction of mast cells, the content of free and cell histamine and serotonin in the lung tissue at early stage of inflammation were studied on the model of hyperergic pleurisy in albino rats. Intrapleural antigen injection to sensitized rats was followed by progressive degranulation of mast cells of pleural and subpleural lung tissue with release of histamine and serotonin. The maximal increase in the content of free amines was found after 15 min. The level of free amines did not differ significantly from the initial one by the first hour. The early activation of amines synthesis and their storage recovery were observed as well as reactions of the late phase of immunological activation in the mast cells as a leukocytic tissue infiltration by subsequently polymorphonuclear leukocytes and macrophages.     

The role of mast cells in virus-induced inflammation in the murine central nervous system

The mononuclear inflammatory response to Sindbis virus infection of the central nervous system is analogous to the cutaneous delayed-type hypersensitivity reaction. It is dependent on sensitized T cells for initiation, but many of the cells present are nonsensitized bone marrow-derived cells. Tissue mast cells have been shown to be important for the development of the delayed-type hypersensitivity reaction in the skin where capillary endothelial cells are joined by tight junctions. To determine whether mast cells are also important for the development of an immune-mediated inflammatory response across the endothelial tight junctions of the blood-brain barrier, the development of mononuclear inflammation in the central nervous system of reserpine-treated mice and mast cell-deficient mice (WBB6F1-W/Wv) was studied after infection with Sindbis virus. Three central nervous system compartments, the cerebrospinal fluid, the meninges, and the brain parenchyma, were evaluated for inflammation by counting the number of cells present, by grading the histopathologic lesions, and by labeling infiltrating cells with 125IUDR. By all parameters inflammation was reduced when mice were treated with reserpine or were deficient in mast cells. Antigen-specific humoral and cellular immune responses were depressed and virus clearance delayed in reserpine-treated mice, but not in mast cell deficient mice. It is concluded that the vasoactive amines released by mast cells in the central nervous system play a facilitating role in the development of the inflammatory response to Sindbis virus.     

Changes in the combined activity of the thyroid and the fascicular zone of the adrenal cortical substance in the development of subcutaneous connective tissue inflammation during prolactin administration

As demonstrate the experiments performed in white male rats, during development of an inflammatory reaction, some essential fluctuations take place in nicotinamide dinucleotide. H2 (HAD.H2), nicotinamide dinucleotide phosphate. H2 (NADPh.H2), glucose-6-phosphate-dehydrogenase (G-6-PhDH), monoaminoxydase (MAO) activities and in content of ascorbic acid in the fascicular zone of the adrenals and the same enzymes in the thyroid follicular cells. There is a reverse connection between the adrenal fascicular zone and the thyroid gland activity. At inflammation, prolactin increases MAO and G-6-PhDH activity in thyrocytes and adrenocorticocytes of the adrenal fascicular zone, changes correlation between NAD.H2-DG and NADPh.H2-DG activities. At an acute inflammation, prolactin activates the thyroid gland function, and during the reparative period--decreases it. During the inflammation period, prolactin administration decreases contingency of the indices in the thyroid gland-adrenals systems, that is to say produces a dissociative effect; it is, perhaps, connected with certain changes in balance and a mediatory role of biogenic amines.     

Mast cells in inflammatory arthritis

Mast cells are present in limited numbers in normal human synovium, but in rheumatoid arthritis and other inflammatory joint diseases this population can expand to constitute 5% or more of all synovial cells. Recent investigations in a murine model have demonstrated that mast cells can have a critical role in the generation of inflammation within the joint. This finding highlights the results of more than 20 years of research indicating that mast cells are frequent participants in non-allergic immune responses as well as in allergy. Equipped with a diversity of surface receptors and effector capabilities, mast cells are sentinels of the immune system, detecting and delivering a first response to invading bacteria and other insults. Accumulating within inflamed tissues, mast cells produce cytokines and other mediators that may contribute vitally to ongoing inflammation. Here we review some of the non-allergic functions of mast cells and focus on the potential role of these cells in murine and human inflammatory arthritis.     

Increase in mast cell number and altered vascular permeability in thirsty rats.

The intravenous administration of 2M NaCl causes marked swelling, vacuolization and degranulation of rat mesenteric mast cells. 72 h of water deprivation (with food available) doubled the number of mast cells in the rat mesentery. Both experimental conditions induced venular labeling. $\text{In vitro}$, up to 300 mM NaCl did not elicit the release of amines from the mast cell. These results led us to infer the existence of some intermediary between hyperosmolarity and mast cell activation. Increased venular permeability, mast cell degranulation and proliferation are common features in inflammatory processes. Sodium salicylate, a non steroidal anti-inflammatory drug, was found to inhibit specifically cell dehydration thirst. A connection between inflammation and the peripheral mechanisms which trigger the central elaboration of the sensation of thirst is suggested.     

Immunoglobulin E-independent activation of mast cell is mediated by Mrg receptors

Mast cells play a central role in inflammatory and allergic reactions by releasing inflammatory mediators through two main pathways, immunoglobulin E-dependent and -independent activation. In the latter, mast cells are activated by a diverse range of basic molecules, including peptides and amines such as substance P, neuropeptide Y, and compound 48/80. These secretagogues are thought to activate the G proteins in mast cells through a receptor-independent mechanism. Here, we report that the basic molecules activate G proteins through the Mas-related gene (Mrg) receptors on mast cells, leading to mast cell degranulation. We suggest that one of the Mrg receptors, MrgX2, has an important role in regulating inflammatory responses to non-immunological activation of human mast cells.     

P2 receptor-mediated signaling in mast cell biology

Mast cells are widely recognized as effector cells of allergic inflammatory reactions. They contribute to the pathogenesis of different chronic inflammatory diseases, wound healing, fibrosis, thrombosis/fibrinolysis, and anti-tumor immune responses. In this paper, we summarized the role of P2X and P2Y receptors in mast cell activation and effector functions. Mast cells are an abundant source of ATP which is stored in their granules and secreted upon activation. We discuss the contribution of mast cells to the extracellular ATP release and to the maintenance of extracellular nucleotides pool. Recent publications highlight the importance of purinergic signaling for the pathogenesis of chronic airway inflammation. Therefore, the role of ATP and P2 receptors in allergic inflammation with focus on mast cells was analyzed. Finally, ATP functions as mast cell autocrine/paracrine factor and as messenger in intercellular communication between mast cells, nerves, and glia in the central nervous system.     

Changes in the catecholamine metabolism in the adrenal medulla of male hamsters with experimental hyperprolactinemia

1. Prolactin (PRL) can play a role as a physiological modulator of adrenal medulla function in several rodents. 2. We have examined the effects of hyperprolactinemia induced by ectopic pituitary grafts in Syrian hamsters on the adrenal medulla contents of catecholamines (CA) and their metabolites, as well as on the activities of several enzymes involved in the metabolism of these amines. 3. Increases in the peripheral levels of PRL in these animals were associated with decreases in adrenal medulla weight and increases in adrenal medulla contents of norepinephrine, epinephrine and vanilmandelic acid, the main degradative metabolite of CA, while adrenal medulla contents of the O-methylated derivatives of CA, normetanephrine and metanephrine, were unaltered. 4. These changes were correlated with increases in the adrenal medulla activity of monoamine oxidase, while the activities of tyrosine hydroxylase, phenylethanolamine-N-methyl transferase and catechol-O-methyl transferase were unaltered. 5. These results indicate that PRL is able to act on the adrenal medulla of hamsters by increasing the ability of these cells to metabolize CA via oxidative deamination.     

Mast cells in inflammatory arthritis

Mast cells are present in limited numbers in normal human synovium, but in rheumatoid arthritis and other inflammatory joint diseases this population can expand to constitute 5% or more of all synovial cells. Recent investigations in a murine model have demonstrated that mast cells can have a critical role in the generation of inflammation within the joint. This finding highlights the results of more than 20 years of research indicating that mast cells are frequent participants in non-allergic immune responses as well as in allergy. Equipped with a diversity of surface receptors and effector capabilities, mast cells are sentinels of the immune system, detecting and delivering a first response to invading bacteria and other insults. Accumulating within inflamed tissues, mast cells produce cytokines and other mediators that may contribute vitally to ongoing inflammation. Here we review some of the non-allergic functions of mast cells and focus on the potential role of these cells in murine and human inflammatory arthritis.     

The contribution of the nervous system to inflammation and inflammatory disease

Recent studies have identified a major contribution of the nervous system to inflammation and to inflammatory disease. In particular, substances released from the peripheral terminals of small diameter primary afferent fibers and from sympathetic postganglionic nerve (SPGN) terminals have been implicated in several of the major components of acute inflammation (e.g., vasodilatation and plasma extravasation) as well as in the regulation of tissue injury in an inflammatory disease model, experimental arthritis in the rat. Although the release of peptides from primary afferent terminals has received the most attention, our studies have established an important contribution of mast cells and the SPGN terminals to acute inflammation. We describe studies which indicate that plasma extravasation provoked by activation of small diameter primary afferents in the knee joint of the rat involves a cascade of events in which the mast cell and then the sympathetic terminal are sequentially activated. Our studies indicate that release of prostaglandins, but neither norepinephrine nor neuropeptide Y, from the SPGN terminal contributes to increased plasma extravasation. Although activation of the SPGN terminal (via the mast cell) or more directly, via injection of bradykinin, increased plasma extravasation, surgical or pharmacological sympathectomy decreased the severity of experimental arthritis. In related studies we demonstrated that adrenal medullary-derived epinephrine can exacerbate arthritis through a beta-receptor-mediated regulation of the release of an as yet unidentified substance(s) from the SPGN terminal. Our results raise important questions as to whether acute inflammation contributes to tissue repair or to further injury in the setting of disease.     

The relationship between adrenal vascular events and steroid secretion: the role of mast cells and endothelin.

The actions of ACTH on the adrenal cortex are known to be 2-fold. In addition to increased steroidogenesis, ACTH also causes marked vasodilation, reflected by an increased rate of blood flow through the gland. Our studies, using the in situ isolated perfused rat adrenal preparation, have shown that zona fasciculata function and corticosterone secretion are closely related to vascular events, with an increase in perfusion medium flow rate causing an increase in corticosterone secretion, in the absence of any known stimulant. These observations give rise to two important questions: how does ACTH stimulate blood flow; and how does increased blood (or perfusion medium) flow stimulate steroidogenesis? Addressing the first question, we have recently identified mast cells in the adrenal capsule, and shown that Compound 48/80, a mast cell degranulator, mimics the actions of ACTH on adrenal blood flow and corticosterone secretion. We have also demonstrated an inhibition of the adrenal vascular response to ACTH in the presence of disodium cromoglycate, which prevents mast cell degranulation. We conclude, therefore, that ACTH stimulates adrenal blood flow by its actions on mast cells in the adrenal capsule. Addressing the second question, we looked at the role of endothelin in the rat adrenal cortex. Endothelin 1, 2 and 3 caused significant stimulation of steroid secretion by collagenase dispersed cells from both the zona glomerulosa and the zona fasciculata. A sensitive response was seen, with significant stimulation at an endothelin concentration of 10(-13) mol/l or lower. Endothelin secretion by the in situ isolated perfused rat adrenal gland was measured using the Amersham assay kit. Administration of ACTH (300 fmol) caused an increase in the rate of immunoreactive endothelin secretion, from an average of 28.7 +/- 2.6 to 52.6 +/- 6 fmol/10 min (P less than 0.01, n = 5). An increase in immunoreactive endothelin secretion was also seen in response to histamine, an adrenal vasodilator, which stimulates corticosterone secretion in the intact gland, but has no effect on collagenase-dispersed cells. From these data we conclude that endothelin may mediate the effects of vasodilation on corticosterone secretion, and this mechanism may explain some of the differences in response characteristics between the intact gland and dispersed cells.     

Chemical neuroanatomy of the vesicular amine transporters.

Acetylcholine, catecholamines, serotonin, and histamine are classical neurotransmitters. These small molecules also play important roles in the endocrine and immune/inflammatory systems. Serotonin secreted from enterochromaffin cells of the gut epithelium regulates gut motility; histamine secreted from basophils and mast cells is a major regulator of vascular permeability and skin inflammatory responses; epinephrine is a classical hormone released from the adrenal medulla. Each of these molecules is released from neural, endocrine, or immune/inflammatory cells only in response to specific physiological stimuli. Regulated secretion is possible because amines are stored in secretory vesicles and released via a stimulus-dependent exocytotic event. Amine storage-at concentrations orders of magnitude higher than in the cytoplasm-is accomplished in turn by specific secretory vesicle transporters that recognize the amines and move them from the cytosol into the vesicle. Immunohistochemical visualization of specific vesicular amine transporters (VATs) in neuronal, endocrine, and inflammatory cells provides important new information about how amine-handling cell phenotypes arise during development and how vesicular transport is regulated during homeostatic response events. Comparison of the chemical neuroanatomy of VATs and amine biosynthetic enzymes has also revealed cell groups that express vesicular transporters but not enzymes for monoamine synthesis, and vice versa: their function and regulation is a new topic of investigation in mammalian neurobiology. The chemical neuroanatomy of the vesicular amine transporters is reviewed here. These and similar data emerging from the study of the localization of the recently characterized vesicular inhibitory and excitatory amino acid transporters will contribute to understanding chemically coded synaptic circuitry in the brain, and amine-handling neuroendocrine and immune/inflammatory cell regulation.     

Histaminylation of fibrinogen by tissue transglutaminase-2 (TGM-2): potential role in modulating inflammation

Plasma fibrinogen plays an important role in hemostasis and inflammation. Fibrinogen is converted to fibrin to impede blood loss and serves as the provisional matrix that aids wound healing. Fibrinogen also binds to cytokine activated endothelial cells and promotes the binding and migration of leukocytes into tissues during inflammation. Tissue transglutaminase (TGM-2) released from injured cells could cross-link fibrinogen to form multivalent complexes that could promote adhesion of platelets and vascular cells to endothelium. Histamine released by mast cells is a potent biogenic amine that promotes inflammation. The covalent attachment of histamine to proteins (histaminylation) by TGM-2 could modify local inflammatory reactions. We investigated TGM-2 crosslinking of several biogenic amines (serotonin, histamine, dopamine and noradrenaline) to fibrinogen. We identified histaminylation of fibrinogen by TGM-2 as a preferred reaction in solid and solution phase transglutaminase assays. Histamine caused a concentration-dependent inhibition of fibrinogen cross-linking by TGM-2. Fibrinogen that was not TGM-2 crosslinked bound to un-activated endothelial cells with low affinity. However, the binding was increased by sevenfold when fibrinogen was cross-linked by TGM-2. Histaminylation of fibrinogen also inhibited TGM-2 crosslinking of fibrinogen and the binding to un-activated HUVEC cells by 75–90 %. In summary, the histaminylation of fibrinogen by TGM-2 could play a role in modifying inflammation by sequestering free histamine and by inhibiting TGM-2 crosslinking of fibrinogen.     

Mast cells in the focus of an acute infectious inflammation]

On the model of E. coli-induced acute infectious peritonitis in rats it is established that the mast cell reaction and histamine level increase in exudate and inflamed mesentery tissue are biphase and are observed predominantly following the inflammatory agent action, in the period corresponding to the immediate phase of peritoneal cavity vessel permeability increases. The preliminary elimination of mast cells significantly inhibits a rise in the vascular permeability in the immediate phase and slightly affects the delayed phase, thus prolonging exudation. At the same time the dynamics of free histamine indicates its direct involvement in mediation and/or modulation as well as in subsequent inflammatory events. The common rules of mast cell involvement and vascular permeability increase in infectious and aseptic inflammation have been shown.     

A histochemical analysis of adrenal lipids in Ox and Sheep

Summary The adrenals of Ox and Sheep were analysed by various histochemical methods available for lipids. The cortex was found to be rich in choline containing phospholipids, unsaturated phospholipids and masked lipids compared with the medulla. Unsaturated lipids and free fatty acids were more abundant in the cortex. There was slightly more cholesterol and plasmalogen in the medulla than the cortex. Formaldehyde fixation apparently increased the relative number of carboxyl groups in the adrenaline storing cells. Osmium tetroxide reacted with catechol amines and differentiated between the adrenaline and noradrenaline storing cells in the ox medulla. The histochemical results are compared with previous biochemical findings on the nature and distribution of adrenal lipids.     

Mast cell-dependent amplification of an immunologically nonspecific inflammatory response. Mast cells are required for the full expression of cutaneous acute inflammation induced by phorbol 12-myristate 13-acetate

Mast cells clearly are critical for the expression of some IgE-dependent responses, but their roles in other forms of inflammation are uncertain. We previously described a new model system for defining the unique contribution of mast cells to biologic responses in vivo, genetically mast cell-deficient WBB6F1-W/Wv mice that have undergone selective local repair of their mast cell deficiency by the injection of IL-3-dependent cultured mast cells derived from the congenic normal (WBB6F1-+/+) mice. Using this approach, we analyzed the contribution of mast cells to the acute inflammation induced by the epicutaneous application of PMA. Even though PMA can activate a wide variety of cell types that may contribute to acute inflammation, we found that mast cells were required for the full expression of the tissue swelling and leukocyte infiltration associated with the response to the agent in vivo. Thus, in WBB6F1-W/Wv mice selectively reconstituted with dermal mast cells by intradermal injection of cultured WBB6F1-+/+ mast cells into the left ear only, PMA induced approximately twice the tissue swelling and neutrophil infiltration in the mast cell-reconstituted left ears as in the contralateral control ears. This represents the first use of W/Wv mice locally reconstituted with mast cells to confirm the hypothesis that mast cells can represent an important amplification mechanism in acute inflammatory responses of nonimmunologic origin. It also defines a model system that may be generally useful for investigating mast cell-dependent and -independent aspects of acute inflammatory responses.     

Role of mast cells in health: daily rhythmic variations in their number, exocytotic activity, histamine and serotonin content in the rat thyroid gland.

A chronobiologic transverse study on rat thyroid has been carried out to investigate whether mast cells and their content in biogenic amines normally undergo daily variations and whether these are related to circadian activity of the gland. The mean number of mast cells per microscopic field presents daily variations ranging from 10.9 +/- 3 to 14.6 +/- 3.8 in males and from 8.4 +/- 1.9 to 14.8 +/- 3 in females: these variations show a circadian trend in both sexes, with a 12 hrs period and two peaks at about 11:10/23:10. The mean percentage of degranulated mast cells per microscopic fields shows daily variations ranging from 51 +/- 11 to 60.4 +/- 14.2 in males and from 49.8 +/- 12.5 to 58.3 +/- 13.6 in females; these variations present a circadian rhythm with a 24 hrs period and a mean peak at 02:00. The histamine content of the gland varies in 24 hrs from 20.93 +/- 1.19 micrograms/g w w to 38.08 +/- 1.7 micrograms/g w w, without any sex-related difference: these variations show a rhythmic trend with a 12 hrs period and two peaks at 09:10/21:10. Serotonin content of thyroid presents circadian variations from 15.98 +/- 0.83 to 23.23 +/- 0.61 micrograms/g w w, with a 12 hrs period and two peaks at 04:20/16:20. Whereas the variations of mast cell exocytosis and of serotonin content seem to be chronobiologically linked to circadian variations of gland activity, evaluated on the basis of free and total tetraiodothyronine serum levels, the variations of mast cell number appear to be related to those of thyroid and blood histamine. The present data support the hypothesis that mast cell activity should not be considered as only linked to inflammation or allergic responses.     

Role of 5-HT in the regulation of the brain-pituitary-adrenal axis: effects of 5-HT on adrenocortical cells

Serotonin (5-HT) plays a pivotal role in the regulation of the brain-pituitary-adrenal axis. In particular, 5-HT has been shown to control the activity of hypothalamic CRF neurons and pituitary corticotrope cells through activation of 5-HT1A and (or) 5-HT(2A/2C) receptor subtypes. 5-HT, acting through 5-HT2 receptors, can also trigger the renin-angiotensin system by stimulating renin secretion and consequently can enhance aldosterone production. At the adrenal level, 5-HT produced locally stimulates the secretory activity of adrenocortical cells through a paracrine mode of communication. The presence of 5-HT in the adrenal gland has been demonstrated immunohistochemically and biochemically in various species. In the frog, rat, and pig adrenal gland, 5-HT is synthesized by chromaffin cells, while in the mouse adrenal cortex, 5-HT is contained in nerve fibers. In man, 5-HT is present in perivascular mast cells. In vivo and in vitro studies have shown that 5-HT stimulates corticosteroid secretion in various species (including human). The type of receptor involved in the mechanism of action of 5-HT differs between the various species. In frogs and humans, the stimulatory effect of 5-HT on adrenocortical cells is mediated through a 5-HT4 receptor subtype positively coupled to adenylyl cyclase and calcium influx. In the rat, the effect of 5-HT on aldosterone secretion is mediated via activation of 5-HT7 receptors. Clinical studies indicate that 5-HT4 receptor agonists stimulate aldosterone secretion in healthy volunteers and in patients with corticotropic insufficiency and primary hyperaldosteronism. Local serotonergic control of corticosteroid production may be involved in the physiological control of the activity of the adrenal cortex as well as in the pathophysiology of cortisol and aldosterone disorders.     

Human mast cell-derived gelatinase B (matrix metalloproteinase-9) is regulated by inflammatory cytokines: role in cell migration

Mast cells are key effectors in the pathogenesis of inflammatory and tissue destructive diseases such as rheumatoid arthritis (RA). These cells contain specialized secretory granules loaded with bioactive molecules including cytokines, growth factors, and proteases that are released upon activation. This study investigated the regulation of matrix metalloproteinase MMP-9 (gelatinase B) in human mast cells by cytokines that are known to be involved in the pathogenesis of RA. Immunohistochemical staining of synovial tissue showed abundant expression of MMP-9 by synovial tissue mast cells in patients with RA but not in normal controls. The expression, activity, and production of MMP-9 in mast cells was confirmed by RT-PCR, zymography, and Western blotting using cord blood-derived human mast cells (CB-HMC). Treatment of CB-HMC with TNF-alpha significantly increased the expression of MMP-9 mRNA and up-regulated the activity of MMP-9 in a time- and dose-dependent manner. By contrast, IFN-gamma inhibited MMP-9 mRNA and protein expression. The cytokine-mediated regulation of MMP-9 was also apparent in the human mast cell line (HMC-1) and in mouse bone marrow-derived mast cells. Furthermore, TNF-alpha significantly increased the invasiveness of CB-HMC across Matrigel-coated membranes while the addition of IFN-gamma, rTIMP-1, or pharmacological MMP inhibitors significantly reduced this process. These observations suggest that MMP-9 is not a stored product in mast cells but these cells are capable of producing this enzyme under inflammatory conditions that may facilitate the migration of mast cell progenitors to sites of inflammation and may also contribute to local tissue damage.     

An overview of the effects of annexin 1 on cells involved in the inflammatory process

The concept of anti-inflammation is currently evolving with the definition of several endogenous inhibitory circuits that are important in the control of the host inflammatory response. Here we focus on one of these pathways, the annexin 1 (ANXA1) system. Originally identified as a 37 kDa glucocorticoid-inducible protein, ANXA1 has emerged over the last decade as an important endogenous modulator of inflammation. We review the pharmacological effects of ANXA1 on cell types involved in inflammation, from blood-borne leukocytes to resident cells. This review reveals that there is scope for more research, since most of the studies have so far focused on the effects of the protein and its peptido-mimetics on neutrophil recruitment and activation. However, many other cells central to inflammation, e.g. endothelial cells or mast cells, also express ANXA1: it is foreseen that a better definition of the role(s) of the endogenous protein in these cells will open the way to further pharmacological studies. We propose that a more systematic analysis of ANXA1 physio-pharmacology in cells involved in the host inflammatory reaction could aid in the design of novel anti-inflammatory therapeutics based on this endogenous mediator.