Infection of Nippostrongylus brasiliensis induces development of mucosal-type but not connective tissue-type mast cells in genetically mast cell-deficient Ws/Ws rats

Ws/Ws rats have a small deletion at the tyrosine kinase domain of the c- kit gene and are deficient in both mucosal mast cells (MMC) and connective tissue-type mast cells (CTMC). The role of the c-kit receptor in the development of MMC and CTMC was investigated by infecting Ws/Ws and control +/+ rats with Nippostrongylus brasiliensis (NB), which induces T-cell-dependent mast cell proliferation. Although mast cells did not develop in the skin of Ws/Ws rats, a significant number of mast cells developed in the jejunum after NB infection. These mast cells had the MMC protease phenotype (rat mast cell protease [RMCP] I-/II+) and lacked heparin because they were not stained with berberine sulfate. Globule leukocytes were also detected in the mucosal epithelium of these rats. However, the number of MMC and the serum concentration of RMCP II in NB-infected Ws/Ws rats were only 13% and 7% of those of NB-infected +/+ rats, respectively. A small number of mast cells also developed in the lung, liver, and mesenteric lymph nodes of Ws/Ws rats after NB infection. Although mast cells in these tissues had the MMC phenotype throughout the observation period, the increased mast cells in the lung and liver of +/+ rats acquired a CTMC-like phenotype and were RMCP I+/II+, berberine sulfate+, and formalin resistant. These results indicate that the need for the stimulus through the c-kit receptor appears to be greater in the development of CTMC in the skin as well as for CTMC-like mast cells in the lung and liver than for the development of MMC.     

Characterization of cultured mast cells derived from Ws/Ws mast cell- deficient rats with a small deletion at tyrosine kinase domain of c-kit

The Ws mutant allele of rats represents a 12-base deletion at the tyrosine kinase domain of the c-kit gene. Although homozygous Ws/Ws rats were deficient in both connective tissue-type mast cells (CTMC) and mucosal-type mast cells (MMC), mast cells did develop when bone marrow cells of Ws/Ws rats were cultured in the presence of concanavalin A-stimulated spleen cell conditioned medium (ConA-SCM). Although the proliferative response of rat cultured mast cells (RCMC) derived from Ws/Ws rats to ConA-SCM was comparable to that of RCMC derived from control normal (+/+) rats, the proliferative response of Ws/Ws RCMC to rat recombinant stem cell factor (rrSCF; a ligand for the c-kit receptor tyrosine kinase) was much lower than that of +/+ RCMC. However, a slight c-kit kinase activity was detectable in Ws/Ws RCMC, and the proliferation of Ws/Ws RCMC was accelerated when rrSCF was added to ConA-SCM. Because CTMC contain rat mast cell protease-I (RMCP- I) and MMC contain RMCP-II, the phenotype of +/+ and Ws/Ws RCMC in various culture conditions was evaluated by immunohistochemistry of RMCPs. Both +/+ and Ws/Ws RCMC showed the MMC-like phenotype (RMCP-I- /II+) when they were cultured with ConA-SCM alone. Most +/+ RCMC and about half of Ws/Ws RCMC acquired a novel protease (RMCP-I+/II+) phenotype when they were cultured with rrSCF alone. However, because the number of Ws/Ws RCMC dropped to one-tenth in the medium containing rrSCF alone, the absolute number of Ws/Ws RCMC with the RMCP-I+/II+ phenotype did not increase significantly. The effect of rrSCF in inducing the novel phenotype was suppressed when ConA-SCM was added to rrSCF. In contrast, +/+ and Ws/Ws RCMC cocultured with +/+ fibroblasts showed the RMCP-I+/II+ phenotype even in the presence of ConA-SCM. Moreover, a fibroblast cell line derived from SI/SI mouse embryos that did not produce SCF did not support the survival of both +/+ and Ws/Ws RCMC but did induce the RMCP-I+/II+ phenotype in about half of +/+ and Ws/Ws RCMC when their survival was supported by the addition of ConA- SCM. The normal signal transduction through the c-kit receptor did not appear to be prerequisite for the acquisition of the RMCP-I+/II+ phenotype.     

Anemia and mast cell depletion in mutant rats that are homozygous at "white spotting (Ws)" locus

Mice possessing two mutant alleles at the W or Sl locus are anemic and deficient in mast cells. These mouse mutants have black eyes and white hair. Because homozygous mutant rats at the newly found white spotting (Ws) locus were also black-eyed whites, the numbers of erythrocytes and mast cells were examined. Suckling Ws/Ws rats showed a severe macrocytic anemia and were deficient in mast cells. When bone marrow cells of normal (+/+) control or Ws/Ws rats were injected into C3H/He mice that had received cyclophosphamide injection and whole-body irradiation, remarkable erythropoiesis occurred in the spleen of +/+ marrow recipients but not in the spleen of Ws/Ws marrow recipients. When skin pieces of Ws/Ws embryos were grafted under the kidney capsule of nude athymic rats, mast cells did develop in the grafted skin tissues. Therefore, the anemia and mast cell deficiency of Ws/Ws rats were attributed to a defect of precursors of erythrocytes and mast cells. Because the magnitude of the anemia decreased and that of the mast cell deficiency increased in adult Ws/Ws rats, this mutant is potentially useful for investigations about differentiation and function of mast cells.     

Age-dependent amelioration of hypoplastic anemia in Ws/Ws rats with a small deletion at the kinase domain of c-kit

The white-spotting (Ws) locus of rats represents a 12-base deletion of the c-kit receptor tyrosine kinase. Homozygous Ws/Ws rats are deficient in melanocytes, mast cells, and erythrocytes. Although mice possessing two mutant alleles at the c-kit (W) locus, such as mice of W/Wv genotype, show severe anemia even in adult age, the anemia of Ws/Ws rats remarkably ameliorated with age. We investigated the mechanism of the age-dependent amelioration. Bone marrow cells of Ws/Ws rats did not form macroscopic colonies in the spleen of irradiated rats, and the concentration of burst-forming unit-erythroid in the marrow of Ws/Ws rats was comparable with that of +/+ rats. Therefore, the increase in morphologically identifiable erythroid precursors in the marrow of Ws/Ws rats was attributed to the increased concentration of colony- forming unit-erythroid (CFU-E). Furthermore, the increase in CFU-E appeared to result from the increased concentration of erythropoietin (EPO). Because injections of relatively low doses of EPO cured the slight anemia that remained in adult Ws/Ws rats, CFU-E and/or its immediate precursors of Ws/Ws rats appeared to be more sensitive to EPO than those of W/Wv mice, in which a huge dose of EPO was necessary to cure the anemia.     

Infection with Nippostrongylus brasiliensis induces invasion of mast cell precursors from peripheral blood to small intestine

Precursors of mast cells were defined as cells that formed mast-cell colonies in methylcellulose culture (CFU-mast). Mononuclear cells (MNC) were obtained from the bone marrow, peripheral blood, and small intestine of Ws/Ws rats with a small deletion at the tyrosine kinase domain of c-kit and of control normal (+/+) rats. In the culture containing concanavalin A-stimulated spleen cell conditioned medium (ConA-SCM) alone, the numbers of mast-cell colonies produced by Ws/Ws MNC were comparable with those of +/+ MNC. In the culture containing both ConA-SCM and stem cell factor (a ligand of c-kit), however, the numbers of mast-cell colonies produced by +/+ blood MNC were 107 times as great as that of Ws/Ws blood MNC. Using this culture condition, we investigated changes in concentration of CFU-mast in the marrow, blood, and intestine of +/+ rats after infection with Nippostrongylus brasiliensis (NB), which induced marked mast-cell accumulation in the small intestine. The concentration of CFU-mast in blood dropped to 21% of preinfection levels 1 week after the NB infection. In contrast, a sevenfold increase of CFU-mast occurred in the small intestine. The proportion of CFU-mast in S phase of the cell cycle remained at low levels in the marrow and blood after NB infection, but it increased significantly in the small intestine. The present result suggests that NB infection induces the invasion of CFU-mast into the intestine from blood and their subsequent proliferation in the tissue site.     

Role of c-kit receptor tyrosine kinase-mediated signal transduction in proliferation of bile epithelial cells in young rats after ligation of bile duct: a study using Ws/Ws c-kit mutant rats

BACKGROUND/AIMS: Recently, it has been shown that the c-kit receptor tyrosine kinase (KIT) is expressed in the liver of young rats, and its expression is up-regulated in bile epithelial cells (BEC) after ligation of the common bile duct (BDL). To clarify a role of KIT in BEC, we examined whether BEC of Ws/Ws rats, whose KIT kinase activity was severely impaired, could proliferate in response to bile stasis after BDL. METHODS/RESULTS: When 2-week-old control normal (+/+) and Ws/Ws mutant rats underwent BDL, only a few BEC were found in the portal field of livers of Ws/Ws rats, whereas many BEC were found in that of +/+ rats. Furthermore, Ki-67 immunostaining showed that the proliferative activity of BEC in 2-week-old Ws/Ws rats was much lower than that in +/+ rats of the same age. In contrast, when 6-week-old +/+ and Ws/Ws rats underwent BDL, BEC similarly proliferated in the livers of +/+ and Ws/Ws rats, and the proliferative activity of BEC was comparable. CONCLUSIONS: The mechanism whereby BEC proliferate in response to bile stasis after BDL may be different between 2- and 6-week-old rats, and KIT mediated-signal transduction plays a crucial role in the proliferation of immature BEC in young rats.     

Role of c-kit receptor tyrosine kinase in development of oval cells in the rat 2-acetylaminofluorene/partial hepatectomy model

Oval cells that develop in the rat 2-acetylaminofluorene/partial hepatectomy (AAF/PH) model express the c-kit receptor tyrosine kinase (KIT) and its ligand, stem cell factor (SCF). We investigated the role of the SCF/KIT system in the development of oval cells using Ws/Ws rats, whose c-kit kinase activity was severely impaired owing to a small deletion in the kinase domain. On days 7, 9, and 13 after PH in the AAF/PH model, the development of oval cells was remarkably suppressed in Ws/Ws rats when compared with that of the control normal (+/+) rats. However, oval cells that developed in Ws/Ws rats expressed marker proteins of oval cells, such as alpha-fetoprotein (AFP), cytokeratin-19 (CK-19), and flt-3 receptor tyrosine kinase, similar to those of +/+ rats. Furthermore, labeling with [3H]-thymidine and immunostaining of Ki-67 showed that the proliferative activity of oval cells that developed in Ws/Ws rats was comparable with that of +/+ rats. The present results indicate that the signal transduction of the SCF/KIT system plays a crucial role in the development of oval cells, at least, in the rat AAF/PH model, and suggest that KIT-mediated signal transduction plays only a small role in determining the phenotype and in the proliferative activity of oval cells.     

Role of mast cells in chronic stress induced colonic epithelial barrier dysfunction in the rat

BACKGROUND AND AIMS: Stress may be an important factor in exacerbating inflammatory bowel disease but the underlying mechanism is unclear. Defective epithelial barrier function may allow uptake of luminal antigens that stimulate an immune/inflammatory response. Here, we examined the effect of chronic stress on colonic permeability and the participation of mast cells in this response. METHODS: Mast cell deficient Ws/Ws rats and +/+ littermate controls were submitted to water avoidance stress or sham stress (one hour/day) for five days. Colonic epithelial permeability to a model macromolecular antigen, horseradish peroxidase, was measured in Ussing chambers. Epithelial and mast cell morphology was studied by light and electron microscopy. RESULTS: Chronic stress significantly increased macromolecular flux and caused epithelial mitochondrial swelling in +/+ rats, but not in Ws/Ws rats, compared with non-stressed controls. Stress increased the number of mucosal mast cells and the proportion of cells showing signs of activation in +/+ rats. No mast cells or ultrastructural abnormalities of the epithelium were present in Ws/Ws rats. Increased permeability in +/+ rats persisted for 72 hours after stress cessation. CONCLUSIONS: Chronic stress causes an epithelial barrier defect and epithelial mitochondrial damage, in parallel with mucosal mast cell hyperplasia and activation. The study provides further support for an important role for mast cells in stress induced colonic mucosal pathophysiology.     

Evaluation of role of mast cells in the development of liver fibrosis using mast cell-deficient rats and mice.

BACKGROUND/AIMS: Several studies have suggested that mast cells participate in the development of liver fibrosis in rodent models. In this study mast cell-deficient mutant Ws/Ws rats and W/Wv mice were used to examine whether mast cells are involved in the development of liver fibrosis. METHODS: Liver fibrosis was induced in rats by bile duct resection (BDR), and by intraperitoneal injections of carbon tetrachloride (CCl4) or porcine serum, and in mice by intragastric administrations of CCl4, and BDR. The degree of fibrosis was evaluated by measuring the hydroxyproline content (microg/mg tissue) of the liver as an index of the collagen content. The density of mast cells (number/cm2 liver section) was determined by counting mast cells in liver sections stained with alcian blue. RESULTS: In the liver of control non-mutant (+/+) rats, mast cells were found principally in portal areas, and their average density was 200-300/cm2 liver section. BDR, and treatments with CCl4 and porcine serum increased the density of mast cells in the liver of +/+ rats several-fold, and induced liver fibrosis, increasing the liver hydroxyproline content markedly. BDR, and treatments with CCl4 and porcine serum also induced liver fibrosis in Ws/Ws rats, increasing the liver hydroxyproline content to a similar or higher level than that in +/+ rats. However, the average densities of mast cells in the liver of Ws/Ws rats after BDR and treatment with CCl4 and porcine serum were at most 10.2/cm2 liver section. The density of mast cells in the liver of control +/+ mice was extremely low (average, less than 2), and neither BDR nor treatment with CCl4 caused any significant increase in their density, whereas these treatments induced liver fibrosis and markedly increased the liver hydroxyproline content. Furthermore, treatment with CCl4 induced fibrosis in the liver of W/Wv mice similarly to that in +/+ mice, but the density of mast cells in the liver of W/Wv mice was very low (average, less than 1), and was not increased by treatment with CCl4. CONCLUSIONS: The present results indicate that mast cells play no role in the development of liver fibrosis in rats and mice.     

Role of complement activation and mast cell degranulation in the pathogenesis of rapid intestinal ischemia/reperfusion injury in rats

The aim of this study is to define the putative role of complement activation and mucosal mast cell (MMC) degranulation in the pathogenesis of rapid ischemia-reperfusion (I/R) injury. We prepared complement activity-depleted rats by the administration of the anti-complementary agent K-76COONa. To assess the role of MMC degranulation, we used the MMC stabilizer MAR-99 and genetically mast cell-deficient Ws/Ws rats. Autoperfused segments of the jejunum were exposed to 60 min of ischemia, followed by 60 min reperfusion. The epithelial permeability was assessed by (51)Cr-EDTA clearance rate, and the number of MMC was immunohistochemically assessed. I/R treatment induced a marked increase in mucosal permeability and MMC degranulation. The treatment with K-76COONa and MAR-99 significantly attenuated these changes. Furthermore, in Ws/Ws rats the increase in mucosal permeability and MMC degranulation was significantly attenuated. These findings indicate the role of complement activation and MMC activation in the pathogenesis of rapid intestinal I/R injury. A regulation of the complement activation and MMC degranulation may be one of the clinical strategies for prevention of I/R-induced mucosal injury.     

Mast cells may not play a crucial role in the pathogenesis of experimental closed duodenal loop-induced pancreatitis in rats

INTRODUCTION: Ws/Ws rats have a small deletion of the c-kit gene and are deficient in both mucosal-type mast cells and connective tissue-type mast cells. AIM: To investigate the role of pancreatic mast cells in the development of experimental closed duodenal loop (CDL)-induced pancreatitis using Ws/Ws rats. METHODOLOGY: Pancreatitis was induced by the CDL technique for 5 and 12 hours, and the subsequent ascites volume, wet pancreatic weight, pancreatic myeloperoxidase activities, and serum amylase levels were evaluated. The pancreatic tissue damage was also evaluated histologically. RESULTS: The CDL technique induced equally severe ascites, pancreatic edema and hyperemia, and hyperamylasemia in the Ws/Ws versus the control (+/+) rats. The microscopic mucosal damage score was also equivalent in the Ws/Ws and control (+/+) rats, and there were no significant differences in mucosal myeloperoxidase activity between the Ws/Ws and control (+/+) rats. CONCLUSION: These results indicate that mast cells may not be crucial for the development of CDL-induced pancreatitis.     

Differences in irradiation susceptibility and turnover between mucosal and connective tissue-type mast cells of mice

Although precursors of mast cells are derived from the bone marrow, phenotypes of mast cells are influenced by the tissues in which final differentiation occurs. Connective tissue-type mast cells (CTMC) and mucosal mast cells (MMC) are different in morphological, biochemical, immunological, and functional criteria. The purpose of the present study was to obtain information about the differentiation process of MMC. First, we compared changes in irradiation susceptibility in mice during the differentiation process of CTMC and MMC. The decrease in irradiation susceptibility was remarkable in the CTMC differentiation process, but it was moderate in that of MMC. Some morphologically identifiable CTMC in the peritoneal cavity had proliferative potential and were highly radioresistant, whereas such a radioresistant population of MMC was not detectable in the gastric mucosa. Second, we estimated the turnover of CTMC and MMC by determining the proportion of mast cells that were labeled with continuously administered bromodeoxyuridine. The turnover of MMC was significantly faster than that of CTMC. The absence of the radioresistant mast cell population in the gastric mucosa appeared to be related to the short life span of MMC.     

Steel factor and c-kit regulate cell-matrix adhesion

Steel (SI) and white spotting (W) loci encode steel factor (c-kit ligand) and the c-kit tyrosine kinase receptor, respectively. Mutations at these loci affect migration and differentiation of primordial germ cells, neural crest-derived melanoblasts, and hematopoietic cells. In these processes, cell adhesion molecules are hypothesized to be crucial. We have examined the role of steel factor and c-kit in cell- extracellular matrix adhesion using bone marrow-derived mast cells as a model system. Steel factor stimulates mast cells to bind to fibronectin and, to a lesser extent, to vitronectin, whereas interleukin-3 and interleukin-4, which are also mast cell growth factors, do not. Activation of adhesiveness is transient, occurs at concentrations of steel factor 100-fold lower than required for growth stimulation, and requires the integrin VLA-5. Mast cells from c-kit mutant mice adhere to fibronectin on stimulation with phorbol 12-myristate 13-acetate (PMA), but not on stimulation with steel factor, indicating that stimulation of integrin adhesiveness requires activation of the c-kit protein tyrosine kinase. By contrast, c-kit mutant and wild-type mast cells adhere equally well to COS cells expressing membrane-anchored steel factor, showing that the kinase activity of c-kit is not required for adhesion directly mediated by c-kit. Our findings suggest that regulation of adhesion is an important biologic function of steel factor.     

Adventitial mast cells contribute to pathogenesis in the progression of abdominal aortic aneurysm

Abdominal aortic aneurysm (AAA) is histologically characterized by medial degeneration and various degrees of chronic adventitial inflammation, although the mechanisms for progression of aneurysm are poorly understood. In the present study, we carried out histological study of AAA tissues of patients, and interventional animal and cell culture experiments to investigate a role of mast cells in the pathogenesis of AAA. The number of mast cells was found to increase in the outer media or adventitia of human AAA, showing a positive correlation between the cell number and the AAA diameter. Aneurysmal dilatation of the aorta was seen in the control (+/+) rats following periaortic application of calcium chloride (CaCl2) treatment but not in the mast cell-deficient mutant Ws/Ws rats. The AAA formation was accompanied by accumulation of mast cells, T lymphocytes and by activated matrix metalloproteinase 9, reduced elastin levels and augmented angiogenesis in the aortic tissue, but these changes were much less in the Ws/Ws rats than in the controls. Similarly, mast cells were accumulated and activated at the adventitia of aneurysmal aorta in the apolipoprotein E-deficient mice. The pharmacological intervention with the tranilast, an inhibitor of mast cell degranulation, attenuated AAA development in these rodent models. In the cell culture experiment, a mast cell directly augmented matrix metalloproteinase 9 activity produced by the monocyte/macrophage. Collectively, these data suggest that adventitial mast cells play a critical role in the progression of AAA.     

Histological evaluation of mast cells in rat gastric mucosal lesions induced by compound 48/80

Repeated intraperitoneal administration of compound 48/80 to rats produced gastric lesions, a decrease in connective tissue mast cells (CTMCs) and an increase in gastric mucosal mast cells (MMCs). The ratio of MMC to CTMC was significantly correlated with lesion formation. A mast cell stabilizer, MAR-99 (50 mg/kg), prevented lesion formation and changes in the mast cells. Omeprazole (20 or 60 mg/kg) significantly reduced the gastric lesions, but mast cell changes persisted. Cimetidine (50 mg/kg) could not inhibit compound 48/80-induced lesions nor a decrease in CTMCs, but did prevent an increase in MMCs. These facts suggest that in compound 48/80-induced gastric lesions chemical mediators released from CTMCs might be trigger factors, while intraluminal gastric acid might be an aggravating factor. Furthermore, the increase in MMCs might be regulated by histamine released from the CTMCs via H2 receptors and have no causal relation to lesions formation.     

Multiple bidirectional alterations of phenotype and changes in proliferative potential during the in vitro and in vivo passage of clonal mast cell populations derived from mouse peritoneal mast cells

Mouse peritoneal mast cells (PMC) express a connective tissue-type mast cell (CTMC) phenotype, including reactivity with the heparin-binding fluorescent dye berberine sulfate and incorporation of [35S] sulfate predominantly into heparin proteoglycans. When PMC purified to greater than 99% purity were cultured in methylcellulose with IL-3 and IL-4, approximately 25% of the PMC formed colonies, all of which contained both berberine sulfate-positive and berberine sulfate-negative mast cells. When these mast cells were transferred to suspension culture, they generated populations that were 100% berberine sulfate-negative, a characteristic similar to that of mucosal mast cells (MMC), and that synthesized predominantly chondroitin sulfate [35S] proteoglycans. When "MMC-like" cultured mast cells derived from WBB6F1-+/+ PMC were injected into the peritoneal cavities of mast cell-deficient WBB6F1- W/Wv mice, the adoptively transferred mast cell population became 100% berberine sulfate-positive. In methylcellulose culture, these "second generation PMC" formed clonal colonies containing both berberine sulfate-positive and berberine sulfate-negative cells, but exhibited significantly less proliferative ability than did normal +/+ PMC. Thus, clonal mast cell populations initially derived from single PMC exhibited multiple and bidirectional alterations between CTMC-like and MMC-like phenotypes. However, this process was associated with a progressive diminution of the mast cells' proliferative ability.     

Effects of stem cell factor (kit-ligand) and interleukin-3 on the growth and serine proteinase expression of rat bone-marrow-derived or serosal mast cells

The effects of rat stem-cell factor (SCF) and interleukin-3 (IL-3), alone or in combination, on the in vitro growth and serine proteinase expression of rat serosal/connective-tissue mast cells (CTMC) or bone marrow-derived mast cells (BMMC) were examined. Rat SCF stimulated the growth of both CTMC and BMMC. IL-3 stimulated BMMC growth to a lesser extent than did SCF, whereas CTMC numbers did not increase in IL-3. However, SCF and IL-3 had synergistic effects on the growth of both BMMC and CTMC. SCF favoured the maintenance of rat mast cell proteinase- I (RMCP-I) in CTMC, but did not induce detectable production of RMCP-I in BMMC. In contrast, when IL-3 or lymph node-conditioned medium (LNCM) was added to SCF, a subpopulation of CTMC expressed and stored the soluble proteinase RMCP-II. In BMMC, the RMCP-II content of cells maintained in SCF was significantly less than that of cells maintained in IL-3 or LNCM. RMCP-II also appeared in the supernatants of BMMC, especially when BMMC numbers were increasing rapidly in SCF with or without IL-3 or LNCM. Thus, SCF and IL-3 can regulate the growth of rat BMMC and CTMC, as well as influence their production and release of proteinases.