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Query: UNIPROT:P15088 (
mast cell
)
14,925
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Mast cells are involved in allergic reactions where they release numerous vasoactive and other mediators in response to IgE and antigen. They are also activated by neuropeptides and are found in close contact with neurons. Mast cell heterogeneity has now been documented for mucosal mast cells and connective tissue mast cells. Rat brain mast cells were studied in a perfusion system and were shown to release serotonin in response to the
mast cell
secretagogue compound 48/80 (C48/80). High-potassium neuronal depolarization also released serotonin, but this was calcium dependent, not associated with beta-hexosaminidase, and was unaffected by prior treatment with C48/80.
Neuronal
depolarization, however, was associated with somatostatin secretion and substantially reduced subsequent C48/80 stimulation, an effect abolished by neonatal treatment of the animals with capsaicin. Perfusion with somatostatin and substance P also induced brain
mast cell
serotonin release. C48/80 stimulation of combined thalamic and hypothalamic slices after neuronal depolarization substantially reduced the C48/80 effect, suggesting the possible presence of endogenous inhibitors released from the hypothalamus. Finally, the alpha 2-receptor agonist clonidine had a slight stimulatory effect. These results indicate that brain
mast cell
serotonin release may be regulated by endogenous neurotransmitters and/or neuromodulators.
...
PMID:Endogenous regulation of rat brain mast cell serotonin release. 172 Apr 23
Allergic rhinitis involves an early phase, largely mediated through mast cells, and a late phase which involves cellular infiltration and mediator release. In the early phase, mast cells release mediators as a result of antigen cross-linking adjacent immunoglobulin E molecules bound to
mast cell
surfaces. This results in an accumulation of histamine which gives rise to the characteristic symptoms of rhinitis--sneezing, itching, rhinorrhoea and congestion. The late phase of the allergic response (hours after challenge) involves infiltration of the nasal epithelium by eosinophils, basophils, monocytes and T-lymphocytes, which release leukotrienes, kinins, histamine and a host of other mediators. The most important part of the late-phase response is probably mediated via the production of cytokines (IL-4, IL-5, IL-6, IL-8, GM-CSF and RANTES) by mast cells, TH2 lymphocytes or epithelial cells. The infiltration of tissues by cells normally present only in the blood is brought about by the production of adhesion molecules, such as VCAM-1 and E-selectin, which cause circulating eosinophils, basophils and T-lymphocytes to adhere to endothelial cells before moving through the endothelium into the tissue (diapedesis).
Neuronal
reflexes also play a role in the allergic response, both by mediating local responses to mediators and possibly playing a part in the activation of T-lymphocytes. The allergic response has also been shown to be less intense in a hot, humid environment, and more marked in a cold, dry environment, possibly due to changes in osmolality of the nasal surface fluid. Similar factors may play a role in the aetiology of non-allergic rhinitis.
...
PMID:Pathophysiology of perennial allergic rhinitis. 921 57
Neuronal
and non-neuronal tissues show distinctly different intracellular localization of synaptotagmin (Syt) homologues. Therefore, cell type-specific mechanisms are likely to direct Syt homologues to their final cellular destinations. Syt IX localizes to dense core vesicles in PC12 cells. However, in the rat basophilic leukemia (RBL-2H3)
mast cell
line, as well as in CHO cells, Syt IX is localized at the endocytic recycling compartment (ERC). We show that targeting of Syt IX to the ERC involves constitutive trafficking to the plasma membrane followed by internalization and transport to the ERC. We further show that internalization from the plasma membrane and delivery to the ERC are dependent on phosphorylation by Ca(2+)-dependent protein kinase Calpha or beta. As such, correct targeting of Syt IX is facilitated by the phorbol ester TPA but prevented by the cPKC inhibitor Go 6976.
...
PMID:Classical protein kinase C(s) regulates targeting of synaptotagmin IX to the endocytic recycling compartment. 1578 85
Pain intensity in chronic venous disease varies with the stage in the clinical-etiologic-anatomic-pathophysiologic (CEAP) classification but also with patient perception, pain being by definition subjective. The venous hypertension responsible for the varicose veins and trophic changes in CVD has a variety of algogenic repercussions in which leukocytes play a particular role, notably through their ability to roll along the vessel wall. Shear stress, hypoxia and stasis activate the marginated leukocytes to shed L-selectin from their surface and express integrins, matrix metalloproteinase 9, elastase, lactoferrin and free radicals. Meanwhile the endothelium expresses adhesion molecules that permit slow rolling on E-selectin followed by adhesion and tissue transmigration. Vein wall and valve areas in particular attract mast cells, monocyte-macrophages and T lymphocytes, and undergo remodeling. Sympathetic sensory C and Adelta fibers, which wrap around cutaneous venules and are also present in the venous intima and media, are nociceptors sensitive to the pain mediators concentrated within leukocytes, such as
mast cell
bradykinin, responsible for visceral pain.
Neuronal
inflammation combined with wall remodeling intensifies symptoms. Yet no direct link has so far been shown between pain and
mast cell
mediator levels. Leukocyte adhesion is also associated with the increased capillary permeability that leads to edema. Antileukocyte therapies include postural rest and venotonics which alone or in combination with compression have been shown to unstick and inhibit leukocytes. The micronized purified flavonoid fraction (MPFF) protects vascular endothelium against hypoxia and reduces adhesion molecule expression. Unlike other antileukocyte therapies, venotonics do not cause neutropenia.
...
PMID:Leukocyte involvement in the signs and symptoms of chronic venous disease. Perspectives for therapy. 1772 58
Mast cell-nerve interactions play a key role in intestinal inflammation and irritable bowel disease. Loss of enteric neurons has been reported in inflammatory conditions but the contribution of mast cells in this event is unknown. To study neuronal survival and plasticity of myenteric neurons in contact with mast cells a co-culture system using myenteric neurons from rat small intestine and peritoneal mast cells was set up. Dissociated myenteric neurons were cultured for 4 days before addition of mast cells isolated by peritoneal lavage.
Neuronal
survival and expression of vasoactive intestinal peptide (VIP) and nitric oxide synthase (NOS) were studied by immunocytochemistry and neuronal cell counting. Myenteric neurons cultured without mast cells were used to study the rate of neuronal survival after the addition of various
mast cell
mediators, proteinase-activated receptor(2) (PAR(2)) agonist, VIP or corticosteroid. A striking
mast cell
-induced neuronal cell death was found after co-culturing. It was counteracted by the addition of
mast cell
stabiliser doxantrazole, protease inhibitors, PAR(2) antagonist FSLLRY-amide, corticosteroid or VIP. In myenteric neurons cultured without mast cells the PAR(2) agonist SLIGRL-amide, prostaglandin D(2) and interleukin (IL) 6 reduced neuronal survival while histamine, serotonin, heparin, IL1beta and tumour necrosis factor alpha had no effect; corticosteroid and VIP enhanced neuronal survival. The relative numbers of VIP-, but not NOS-expressing myenteric neurons increased after co-culturing. Mast cell-induced neuronal cell death is suggested to be mediated via PAR(2) activation, IL6 and prostaglandin D(2). Corticosteroid and VIP are neuroprotective and able to prevent cell death of myenteric neurons in co-culture.
...
PMID:Mast cells reduce survival of myenteric neurons in culture. 1901 85
Different tendons are designed to withstand different mechanical loads in their individual environments. Variable physiologic loading ranges and correspondingly different injury thresholds lead to tendon heterogeneity. Also, tendon heterogeneity is evident when examining how different tendons regulate their response to changes in mechanical loading (over- and under-loading). The response of tendons to changes in mechanical loading plays an important role in the induction and progression of tendinosis which is tendon degeneration without inflammation. Tendon overuse injury is likely related to abnormal mechanical loading that deviates from normal mechanical loading in magnitude, frequency, duration and/or direction. Mechanical loading that results in tendon overuse injury can initiate a repair process but, after failed initial repair, non-resolving chronic attempted repair appears to lead to a "smoldering" fibrogenesis. Contributions of regulatory components, including minor components in the "nerve-
mast cell
-myofibroblast axis", are key features in the development and progression of tendinosis. Hormonal and genetic factors may also influence risk for tendinosis. Further understanding of how tendinosis induction is related to mechanical use/overuse, how tendinosis progression is related to abnormal regulation of attempted repair, and how induction and/or progression are modulated by other risk factors may lead to interventions that mitigate risk and enhance functional repair.
J Musculoskelet
Neuronal
Interact 2011 Jun
PMID:The interface of mechanical loading and biological variables as they pertain to the development of tendinosis. 2162 46
