Mast cells are classically viewed as effector cells of IgE-mediated allergic diseases. However, over the last decade our understanding has been enriched about their roles in host defense, innate and adaptive immune responses, and in homeostatic responses, angiogenesis, wound healing, tissue remodeling, and immunoregulation. Despite impressive progress, there are large gaps in our understanding of their phenotypic heterogeneity, regulatory mechanisms involved, and functional significance. This review summarizes our knowledge of mast cells in innate and acquired immunity, allergic inflammation and tissue homeostasis, as well as some of the regulatory mechanisms that control mast cell development, phenotypic determination, and function, particularly in the context of mucosal surfaces.
Lipid Phosphate Phosphatase-2 Activity Regulates S-phase Entry of the Cell Cycle in Rat2 Fibroblasts
Lipid phosphates are potent mediators of cell signaling and control processes including development, cell migration and division, blood vessel formation, wound repair, and tumor progression. Lipid phosphate phosphatases (LPPs) regulate the dephosphorylation of lipid phosphates, thus modulating their signals and producing new bioactive compounds both at the cell surface and in intracellular compartments. Knock-down of endogenous LPP2 in fibroblasts delayed cyclin A accumulation and entry into S-phase of the cell cycle. Conversely, overexpression of LPP2, but not a catalytically inactive mutant, caused premature S-phase entry, accompanied by premature cyclin A accumulation. At high passage, many LPP2 overexpressing cells arrested in G 2 /M and the rate of proliferation declined severely. This was accompanied by changes in proteins and lipids characteristic of senescence. Additionally, arrested LPP2 cells contained decreased lysophosphatidate concentrations and increased ceramide. These effects of LPP2 activity were not reproduced by overexpression or knock-down of LPP1 or LPP3. This work identifies a novel and specific role for LPP2 activity and bioactive lipids in regulating cell cycle progression.The lipid phosphates, lysophosphatidate (LPA) 4 and sphingosine 1-phosphate (S1P) are present in biological fluids and activate cells through families of four G-protein-coupled receptors for LPA and five receptors for S1P (1). These receptors are coupled through G␣ i that decreases cAMP concentrations; G 12/13 that stimulates phospholipase D and Rho leading to stress fiber formation; and G q that activates phospholipase C, Ca 2ϩ transients, and protein kinase C isoforms (1). LPA and S1P receptors also transactivate epidermal growth factor and platelet-derived growth factor receptors (2, 3).Intracellular lipid phosphates also act as signaling molecules. For example, PA stimulates NADPH oxidase, protein kinase C-, phosphatidylinositol 4-kinase, phospholipase C-␥, and sphingosine kinase-1, increases Ras-GTP and inhibits protein phosphatase-1 (4 -6). PA can increase proliferation through the mammalian target of rapamycin (7) and PA stimulates stress fiber formation (8). The relative concentrations of LPA and PA in biological membranes control their curvature and vesicle budding (9). C1P is the sphingolipid analogue of PA and is thought to be involved in synaptic vesicle movement and transport (10). It is formed during neutrophil phagocytosis and it is involved in liposome fusion (11). C1P binds to and activates cytosolic phospholipase A 2 , thereby increasing arachidonate and prostaglandin E 2 production (12). C1P also blocks activation of apoptosis in macrophages by inhibiting acidic sphingomyelinase activity (13).Intracellular LPA can signal through the peroxisome proliferatoractivated receptor-␥ receptor (14) and a nuclear receptor, LPA 1 , that regulates proinflammatory gene expression (15). Intracellular S1P stimulates ERK giving a mitogenic or anti-apoptotic response, it mobilizes intracellular Ca 2ϩ and increases act...
Autonomic nervous system regulates secretion of anti-inflammatory prohormone SMR1 from rat salivary glands
The autonomic nervous system regulates the secretion of bioactive proteins and peptides from salivary glands that can be important in systemic physiological responses. The prohormone submandibular rat-1, which is highly expressed in rat submandibular glands, can be cleaved to produce polypeptides with analgesic and anti-inflammatory activities. Human genes related to submandibular rat-1 have conserved biological functions and are potentially important in pain suppression, erectile function, and inflammation. In this study we describe the differential expression and posttranslational modification of submandibular rat-1 protein in salivary glands, the urogenital tract, lung, blood, and saliva in male Sprague-Dawley and Brown Norway rats. Submandibular rat-1 protein is secreted into saliva after the administration of beta-adrenergic or cholinergic agonists. Removal of the sympathetic ganglion that innervates the salivary glands results in increased levels of submandibular rat-1 protein in salivary glands. The secretion of submandibular rat-1 in response to physiological stress may provide a large pool of submandibular rat-1-derived peptide products that can promote analgesia and decrease inflammation locally and systemically. This pathway may be conserved among mammals and may constitute an important anti-inflammatory and analgesic response to stress.
The recently emerged Vcsa1 gene is one member of the variable coding sequence (VCS) multigene family of Rattus norvegicus. This gene encodes the precursor prohormone SMR1 (submandibular rat-1), which on enzymatic processing gives rise to several 5 to 11 amino acid peptides that modulate a variety of physiological functions. The analgesic pentapeptide sialorphin and anti-inflammatory heptapeptide submandibular gland peptide-T (TDIFEGG) are the most intensively studied. Although the Vcsa1 gene and its protein product are unique to rats, TDIFEGG or a derivative acts on all species examined to date, including human cells, in functions related to allergic reactions and inflammation. In this review, the patent and academic literature on SMR1 and its natural peptides and their derivatives are reviewed for consideration of biological targets and relevance to the development of novel therapeutic agents. The VCS gene family is discussed and we speculate on possible human homologs of these potent anti-inflammatory rat-derived peptides. The biologically active peptide products of SMR1 are considered and the mechanism of action and structure-activity relationships of the anti-inflammatory submandibular gland peptide-T and its derivatives are discussed.
Respiratory syncytial virus (RSV) is associated with bronchiolitis in infancy and the later development of asthma. Research on RSV in vitro requires preparation of a purified RSV stock. The objective for this work was to develop best methods for RSV purification, while monitoring the samples for potential contaminating proinflammatory mediators. Using polyethylene glycol concentration, and sucrose‐gradient ultracentrifugation, we collected samples at each step of purification and measured the values of RSV titer, total protein (µg/mL), and proinflammatory cytokines (ELISA). We analyzed the efficacy of each step in the purification procedure. In so doing, we also determined that despite optimal purification methods, a well‐known chemokine in the field of allergic disease, CCL5 (RANTES), persisted within the virus preparations, whereas other cytokines did not. We suggest that researchers should be aware that CCL5 appears to co‐purify with RSV. Despite reasonable purification methods, a significant level of CCL5 (RANTES) persists in the virus preparation. This is relevant to the study of RSV‐induced allergic disease.
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