A role for serglycin proteoglycan in granular retention and processing of mast cell secretory granule components

In the absence of serglycin proteoglycans, connective tissue-type mast cells fail to assemble mature metachromatic secretory granules, and this is accompanied by a markedly reduced ability to store neutral proteases. However, the mechanisms behind these phenomena are not known. In this study, we addressed these issues by studying the functionality and morphology of secretory granules as well as the fate of the secretory granule proteases in bone marrow-derived mast cells from serglycin(+/+) and serglycin(-/-) mice. We show that functional secretory vesicles are formed in both the presence and absence of serglycin, but that dense core formation is defective in serglycin(-/-) mast cell granules. The low levels of mast cell proteases present in serglycin(-/-) cells had a granular location, as judged by immunohistochemistry, and were released following exposure to calcium ionophore, indicating that they were correctly targeted into secretory granules even in the absence of serglycin. In the absence of serglycin, the fates of the serglycin-dependent proteases differed, including preferential degradation, exocytosis or defective intracellular processing. In contrast, beta-hexosaminidase storage and release was not dependent on serglycin. Together, these findings indicate that the reduced amounts of neutral proteases in the absence of serglycin is not caused by missorting into the constitutive pathway of secretion, but rather that serglycin may be involved in the retention of the proteases after their entry into secretory vesicles.     

Mast cell proteoglycans modulate the secretagogue, proteoglycanase, and amidolytic activities of dog mast cell chymase.

Chymase, a potent secretagogue for airway gland serous cells, is stored in secretory granules and released from mast cells together with proteoglycans. To investigate the hypothesis tha tproteoglycans modulate chymase-induced effects, we studied the influence of proteoglycans purified from dog mastocytoma cells on chymase-induced secretion from cultured bovine airway gland serous cells. Heparin proteoglycans reduced the chymase-induced secretory response, whereas glycosaminoglycans and chondroitin sulfate proteoglycans had less of an effect. Chymase released together with proteoglycans from activated mast cells caused secretion comparable to that caused by purified chymase reconstituted with purified proteoglycans. Despite partial inhibition by exocytosed proteoglycans, the secretagogue activity of chymase remains substantial compared to that of histamine. However, proteoglycans virtually abolished chymase-induced degradation of the products of serous cell secretion. Although the secretagogue and proteoglycanase activities of chymase are inhibited by most classes of mast cell granule-associated glycans, the amidolytic activity of chymase toward tripeptide 4-nitroanilide substrates is augmented. These findings suggest that mast cell proteoglycans modulate the secretagogue, proteoglycanase, and peptidase activity of chymase, and the results predict that the extent of this modulation in vivo depends on the nature of the proteoglycans with which chymase is released from mast cells.     

Proteoglycans in haemopoietic cells

Proteoglycans are produced by all types of haemopoietic cells including mature cells and the undifferentiated stem cells. The proteinase-resistant secretory granule proteoglycan (serglycin; Ref. 14), is the most prevalent and best characterised of these proteoglycans. Although its complete pattern of distribution in the haemopoietic system is unknown, serglycin has been identified in the mast cells, basophils and NK cells, in which secretion is regulated, and in HL-60 cells and a monocytoid cell line (Kolset, S.O., unpublished data) in which secretion is constitutive. Proteinase-resistant proteoglycans have been detected in human T-lymphocytes and murine stem cells (FDCP-mix) and the core proteins may be closely related to serglycin. A variety of glycosaminoglycan chains are assembled on the serglycin protein and it is likely that this class of proteoglycan can carry out a wide variety of functions in haemopoietic cells including the regulation of immune responses, inflammatory reactions and blood coagulation. There is strong evidence that in mast cells, NK cells and platelets, the proteoglycans are complexed to basic proteins (including enzymes and cytolytic agents) and amines in secretory granules and such complexes may dissociate following secretion from the cell. The stability of the complexes may be regulated by the ambient pH which may be acidic in the granules and neutral or above in the external medium. However, proteinase-proteoglycan complexes in mast cell granules seem to remain stable after secretion and it has been proposed that the proteoglycan regulates activity of proteinases released into the pericellular domain. The functions of proteoglycans which are constitutively secreted from cells are less clear. If cells have no requirement for storage of basic proteins why do they utilise the same design of proteoglycan as cells which accumulate secretory material prior to regulated release? We should stress that the so-called constitutive secretory pathway has been identified in haemopoietic cells in culture, which are usually maintained and grown in the presence of mitogenic factors (e.g., IL-2, IL-3). the cells are therefore activated and it has not been established that continuous proteoglycan secretion occurs in quiescent cells circulating in the peripheral blood. It is possible that lymphocytes, monocytes and macrophages, in which the constitutive secretion pathway operates in vitro, may store proteoglycan in vivo unless stimulated by mitogens or other activating agents.(ABSTRACT TRUNCATED AT 400 WORDS)     

A role for serglycin proteoglycan in mast cell apoptosis induced by a secretory granule-mediated pathway

Mast cell secretory granules (secretory lysosomes) contain large amounts of fully active proteases bound to serglycin proteoglycan. Damage to the granule membrane will thus lead to the release of serglycin and serglycin-bound proteases into the cytosol, which potentially could lead to proteolytic activation of cytosolic pro-apoptotic compounds. We therefore hypothesized that mast cells are susceptible to apoptosis induced by permeabilization of the granule membrane and that this process is serglycin-dependent. Indeed, we show that wild-type mast cells are highly sensitive to apoptosis induced by granule permeabilization, whereas serglycin-deficient cells are largely resistant. The reduced sensitivity of serglycin(-/-) cells to apoptosis was accompanied by reduced granule damage, reduced release of proteases into the cytosol, and defective caspase-3 activation. Mechanistically, the apoptosis-promoting effect of serglycin involved serglycin-dependent proteases, as indicated by reduced sensitivity to apoptosis and reduced caspase-3 activation in cells lacking individual mast cell-specific proteases. Together, these findings implicate serglycin proteoglycan as a novel player in mast cell apoptosis.     

Immortalization of murine connective tissue-type mast cells at multiple stages of their differentiation by coculture of splenocytes with fibroblasts that produce Kirsten sarcoma virus

Mature connective tissue mast cells (CTMC) have not been previously available as a cell line from any species. Here we describe 15 novel mast cell lines (KiSV-MC) that were derived by coculturing murine splenocytes with fibroblasts that produce a Ki-ras-containing murine sarcoma virus. Some of the KiSV-MC lines are similar to CTMC in that they synthesize predominantly heparin proteoglycans, and contain up to 35 micrograms of histamine and 2.2 units of carboxypeptidase A/10(6) cells in secretory granules which stain red with Safranin. Other cell lines display phenotypic characteristics intermediate to CTMC and mucosal-like mast cells in being predominantly Safranin-, having lower amounts of histamine and carboxypeptidase A, and in synthesizing chondroitin sulfate E proteoglycans in preference to heparin proteoglycans. When the individual KiSV-MC lines were compared, a linear relationship was found between the number of Safranin+ granules, the cellular contents of histamine and carboxypeptidase A, and the biosynthesis of heparin relative to chondroitin sulfate E proteoglycans. Upon sensitization with monoclonal IgE and exposure to hapten-specific antigen, the cells exocytose the contents of their secretory granules. Thus, these immortalized cells provide the first source of CTMC-like lines for chemical and functional analysis and illustrate that murine mast cells can express a continuum of phenotypes.     

Cloning of the cDNA and gene of mouse mast cell protease-6. Transcription by progenitor mast cells and mast cells of the connective tissue subclass

The cDNA and gene for mouse mast cell protease-6 (MMCP-6) have been sequenced and show MMCP-6 to be translated as a prepro-enzyme with a 21-amino acid hydrophobic leader peptide, a 10-amino acid activation peptide, and a 245-amino acid mature enzyme. The mature form of the enzyme has 73% amino acid sequence identity with human and dog mast cell tryptases. The MMCP-6 gene includes 6 exons, with a total span of 1.8 kilobases. A 208-base pair intron was defined which separates the 5'-untranslated sequence of MMCP-6 from the translation initiation codon, thereby presenting a gene organization which distinguishes tryptic serine proteases from chymotryptic serine proteases of the mast cell secretory granule. By RNA blot analysis with a gene-specific probe, MMCP-6 has a unique subclass distribution in being transcribed in mouse connective tissue mast cells but undetectable in mucosal mast cells. MMCP-6 is the first serine protease of any class to be shown to be significantly transcribed in progenitor, bone marrow-derived mast cells, which can reconstitute both mucosal mast cell and connective tissue mast cell populations in mast cell-deficient mice.     

Serglycin is the major secreted proteoglycan in macrophages and has a role in the regulation of macrophage tumor necrosis factor-alpha secretion in response to lipopolysaccharide

It has recently been shown that serglycin is essential for maturation of mast cell secretory granules. However, serglycin is expressed also by other cell types, and in this study we addressed the role of serglycin in macrophages. Adherent cells were prepared from murine peritoneal cell populations and from spleens, and analyzed for proteoglycan synthesis by biosynthetic labeling with [35S]sulfate. Conditioned media from serglycin-/- peritoneal macrophages and adherent spleen cells displayed a 65-80% reduction of 35S-labeled proteoglycans, compared with corresponding material from serglycin+/+ cells, indicating that serglycin is the dominant secretory proteoglycan in macrophages of these origins. In contrast, the levels of intracellular proteoglycans were similar in serglycin+/+ and serglycin-/- cells, suggesting that serglycin is not stored intracellularly to a major extent in macrophages. This is in contrast to mast cells, in which serglycin is predominantly stored intracellularly. Transmission electron microscopy revealed that the absence of serglycin did not cause any major morphological effects on peritoneal macrophages, in contrast to dramatic defects in intracellular storage vesicles in peritoneal mast cells. Several secretory products were not found to be affected by the lack of serglycin. However, the secretion of tumor necrosis factor-alpha in response to lipopolysaccharide stimulation was markedly higher in serglycin-/- cultures than in those of serglycin+/+. The present report thus demonstrates that serglycin is the major proteoglycan secreted by peritoneal macrophages and suggests that the macrophage serglycin may have a role in regulating secretion of tumor necrosis factor-alpha.     

Co-sedimentation of chondroitin sulfate A glycosaminoglycans and proteoglycans with the cytolytic secretory granules of rat large granular lymphocyte (LGL) tumor cells, and identification of a mRNA in normal and transformed LGL that encodes proteoglycans

Rat large granular lymphocyte (LGL) tumor cell lines were analyzed for the presence of proteoglycans and glycosaminoglycans in their cytolytic secretory granules. When isolated rat LGL tumor cells were incubated in vitro for 1 to 3 hr with [35S]sulfate, and the 35S-labeled macromolecules were purified by density-gradient centrifugation, they filtered on Sepharose CL-4B columns predominantly as approximately 500,000 m.w. macromolecules. After 19 hr of incubation with [35S]sulfate, however, an 85,000 m.w. species predominated. Pulse-chase experiments revealed that the larger macromolecules were proteoglycans that with time were processed to glycosaminoglycan-sized macromolecules. As assessed by their susceptibility to chemical and enzymatic degradation and by high pressure liquid chromatography of the chondroitinase ABC-generated unsaturated disaccharides, the cell-associated rat LGL tumor cell proteoglycans bore almost exclusively chondroitin sulfate A glycosaminoglycans. Northern blot analysis using a gene-specific probe revealed that both normal peripheral blood and transformed rat LGL expressed the same approximately 1.3-kb mRNA that encodes the peptide core of the proteoglycans in the secretory granules of rat and mouse mast cells. In vivo radiolabeling of rat LGL tumor cells and isolation of their intact granules after nitrogen cavitation and density sedimentation established that glycosaminoglycans compartmentalized with cytolytic activity. Thus these negatively charged macromolecules may play a role in the regulation of the packaging and delivery of the cytolysins and basically charged serine proteases that have been identified in the cytolytic secretory granules of LGL.     

Serglycin proteoglycan promotes apoptotic versus necrotic cell death in mast cells

The mechanisms that govern whether a cell dies by apoptosis or necrosis are not fully understood. Here we show that serglycin, a secretory granule proteoglycan of hematopoietic cells, can have a major impact on this decision. Wild type and serglycin(-/-) mast cells were equally sensitive to a range of cell death-inducing regimens. However, whereas wild type mast cells underwent apoptotic cell death, serglycin(-/-) cells died predominantly by necrosis. Investigations of the underlying mechanism revealed that cell death was accompanied by leakage of secretory granule compounds into the cytosol and that the necrotic phenotype of serglycin(-/-) mast cells was linked to defective degradation of poly(ADP-ribose) polymerase-1. Cells lacking mouse mast cell protease 6, a major serglycin-associated protease, exhibited similar defects in apoptosis as observed in serglycin(-/-) cells, indicating that the pro-apoptotic function of serglycin is due to downstream effects of proteases that are complex-bound to serglycin. Together, these findings implicate serglycin in promoting apoptotic versus necrotic cell death.     

Mast cell exocytosis: evidence that granule proteoglycan processing is not coupled to degranulation

It has been hypothesized that the dissolution of mast cell granules at the time of degranulation results from proteoglycan cleavage coupled to exocytosis. To address this hypothesis, we studied granule proteoglycan before and after exocytosis in dog mastocytoma cells, which solubilize granule contents during exocytosis. 35S-labeled proteoglycans were extracted from unstimulated whole cells and cell degranulation supernatant. Sequential anion-exchange and gel filtration chromatography, followed by specific glycosaminoglycan digestion, identified chondroitin sulfate and heparin glycosaminoglycan and proteoglycan in unstimulated cells and degranulated material alike. Glycosaminoglycan type and charge density in degranulation supernatant were unchanged compared with unstimulated cells. There was no decrease in proteoglycan size with cell activation and exocytosis. Thus, granule release and solubilization does not appear to require exocytosis-coupled degradation of granule proteoglycans. Release in association with high-m.w. proteoglycans may serve to limit rates of diffusion and activity of proteases and other mast cell mediators.     

Proteolytic Histone Modification by Mast Cell Tryptase,a Serglycin Proteoglycan-dependent Secretory Granule Protease

A hallmark feature of mast cells is their high content of cytoplasmic secretory granules filled with various preformed compounds, including proteases of tryptase-, chymase-, and carboxypeptidase A3 type that are electrostatically bound to serglycin proteoglycan. Apart from participating in extracellular processes, serglycin proteoglycan and one of its associated proteases, tryptase, are known to regulate cell death by promoting apoptosis over necrosis. Here we sought to outline the underlying mechanism and identify core histones as primary proteolytic targets for the serglycin-tryptase axis. During the cell death process, tryptase was found to relocalize from granules into the cytosol and nucleus, and it was found that the absence of tryptase was associated with a pronounced accumulation of core histones both in the cytosol and in the nucleus. Intriguingly, tryptase deficiency resulted in defective proteolytic modification of core histones even at baseline conditions, i.e. in the absence of cytotoxic agent, suggesting that tryptase has a homeostatic impact on nuclear events. Indeed, tryptase was found in the nucleus of viable cells and was shown to cleave core histones in their N-terminal tail. Moreover, it was shown that the absence of the serglycin-tryptase axis resulted in altered chromatin composition. Together, these findings implicate histone proteolysis through a secretory granule-derived serglycin-tryptase axis as a novel principle for histone modification, during both cell homeostasis and cell death.     

Rat mast cell protease 4 is a beta-chymase with unusually stringent substrate recognition profile

Activated mast cells release a variety of potent inflammatory mediators including histamine, cytokines, proteoglycans, and serine proteases. The serine proteases belong to either the chymase (chymotrypsin-like substrate specificity) or tryptase (trypsin-like specificity) family. In this report we have investigated the substrate specificity of a recently identified mast cell protease, rat mast cell protease-4 (rMCP-4). Based on structural homology, rMCP-4 is predicted to belong to the chymase family, although rMCP-4 has previously not been characterized at the protein level. rMCP-4 was expressed with an N-terminal His tag followed by an enterokinase site substituting for the native activation peptide. The enterokinase-cleaved fusion protein was labeled by diisopropyl fluorophosphate, demonstrating that it is an active serine protease. Moreover, rMCP-4 hydrolyzed MeO-Suc-Arg-Ala-Tyr-pNA, thus verifying that this protease belongs to the chymase family. rMCP-4 bound to heparin, and the enzymatic activity toward MeO-Suc-Arg-Ala-Tyr-pNA was strongly enhanced in the presence of heparin. Detailed analysis of the substrate specificity was performed using peptide phage display technique. After six rounds of amplification a consensus sequence, Leu-Val-Trp-Phe-Arg-Gly, was obtained. The corresponding peptide was synthesized, and rMCP-4 was shown to cleave only the Phe-Arg bond in this peptide. This demonstrates that rMCP-4 displays a striking preference for bulky/aromatic amino acid residues in both the P1 and P2 positions.     

Serglycin is essential for maturation of mast cell secretory granule

To address the biological function of the scarcely studied intracellular proteoglycans, we targeted the gene for serglycin (SG), the only known committed intracellular proteoglycan. SG-/- mice developed normally and were fertile, but their mast cells (MCs) were severely affected. In peritoneum there was a complete absence of normal granulated MCs. Furthermore, peritoneal cells and ear tissue from SG-/- animals were devoid of the various MC-specific proteases. However, mRNA for the proteases was present in SG+/+, SG+/-, and SG-/- tissues, indicating that SG is essential for the storage, but not expression, of the MC proteases. Experiments, in which the differentiation of bone marrow stem cells into mature MCs was followed, showed that secretory granule maturation was compromised in SG-/- cells. Moreover, SG+/+ and SG+/- cells, but not SG-/- cells, synthesized proteoglycans of high anionic charge density. Taken together, we demonstrate a key role for SG proteoglycan in MC function.     

Mast Cells Produce a Unique Chondroitin Sulfate Epitope

The granules of mast cells contain a myriad of mediators that are stored and protected by the sulfated glycosaminoglycan (GAG) chains that decorate proteoglycans. Whereas heparin is the GAG predominantly associated with mast cells, mast cell proteoglycans are also decorated with heparan sulfate and chondroitin sulfate (CS). This study investigated a unique CS structure produced by mast cells that was detected with the antibody clone 2B6 in the absence of chondroitinase ABC digestion. Mast cells in rodent tissue sections were characterized using toluidine blue, Leder stain and the presence of mast cell tryptase. The novel CS epitope was identified in rodent tissue sections and localized to cells that were morphologically similar to cells chemically identified as mast cells. The rodent mast cell-like line RBL-2H3 was also shown to express the novel CS epitope. This epitope co-localized with multiple CS proteoglycans in both rodent tissue and RBL-2H3 cultured cells. These findings suggest that the novel CS epitope that decorates mast cell proteoglycans may play a role in the way these chains are structured in mast cells.     

High degree of conservation of the multigene tryptase locus over the past 150–200 million years of mammalian evolution

Activated mast cells release a number of potent inflammatory mediators including histamine, proteoglycans, cytokines, and serine proteases. The proteases constitute the majority of the mast cell granule proteins, and they belong to either the chymase or the tryptase family. In mammals, these enzymes are encoded by two different loci, the mast cell chymase and the multigene tryptase loci. In mice and humans, a relatively large number of tryptic enzymes are encoded from the latter locus. These enzymes can be grouped into two subfamilies, the group 1 tryptases, with primarily membrane-anchored enzymes, and the group 2 tryptases, consisting of the soluble mast cell tryptases. In order to study the appearance of these enzymes during vertebrate evolution, we have analyzed the dog, cattle, opossum, and platypus genomes and sought orthologues in the genomes of several bird, frog, and fish species as well. Our results show that the overall structure and the number of genes within this locus have been well conserved from marsupial to placental mammals. In addition, two relatively distantly related group 2 tryptase genes and several direct homologues of some of the group 1 genes are present in the genome of the platypus, a monotreme. However, no direct homologues of the individual genes of either group 1 or 2 enzymes were identified in bird, amphibian, or fish genomes. Our results indicate that the individual genes within the multigene tryptase locus, in their present form, are essentially mammal-specific.     

Stem cell factor is localized in, released from, and cleaved by human mast cells.

Stem cell factor (SCF) is the most important cytokine regulating human mast cell growth and functions. The immunogold technique showed SCF in the secretory granules of skin mast cells and in lung parenchymal mast cells (HLMC). Immunoreactive SCF (iSCF) was detected in cell lysates of HLMC, but not in basophils; iSCF and histamine were detected in supernatants of HLMC 3 min after challenge with anti-FcepsilonRI or anti-IgE, and iSCF in supernatants rapidly declined after 30 min, whereas histamine remained unchanged for 120 min. HPLC and electrospray mass spectrometry (ES/MS) analysis of recombinant human SCF1-166 (18,656. 9 +/- 0.9 Da) treated with chymase showed a polypeptide of 17,977.1 +/- 0.6 Da and a minor component of 697.4 +/- 0.1 Da generated by specific cleavage at Phe159. SCF1-166 and SCF1-159 similarly activated HLMC, potentiated anti-IgE-induced activation of these cells, and stimulated HLMC chemotaxis. SCF159-166 had no effect on mast cells. Western blot analysis of supernatants of anti-IgE-activated HLMC incubated with recombinant human SCF1-166 showed that SCF1-166 was rapidly cleaved to SCF1-159 and SCF1-144. Experiments with supernatants of anti-IgE-activated HLMC incubated with SCF1-166 yielded similar results. In conclusion, SCF is stored in mast cell secretory granules and is immunologically released by human mast cells. SCF1-166 is rapidly and specifically cleaved to SCF1-159 by chymase, which retains its biological effect on mast cells. SCF is also cleaved by other proteases to several SCF species whose possible biological activities remain to be established.     

Xylose-linked proteoglycan synthesis does not have a primary role in the control of secretory cell differentiation in salivary glands

Xylose-linked proteoglycans, particularly chondroitin sulfate proteoglycan, have been shown to play a significant role in the regulation of salivary gland morphogenesis. The purpose of this study was to determine if xylose-linked proteoglycans are involved in the regulation of differentiation of salivary gland secretory cells. Embryonic rat submandibular salivary gland rudiments were cultured for 120 hr in the presence or absence of 0.75 to 1.0 mM p-nitrophenyl-beta-D-xylopyranoside (beta-D-xyloside), an inhibitor of xylose-linked proteoglycan assembly. beta-D-Xyloside has been shown to block submandibular gland morphogenesis (Thompson and Spooner, 1982). In the present study glandular morphogenesis was blocked in 93.3% of the rudiments cultured in the presence of beta-D-xyloside. However, secretory cell differentiation was observed in 71.4% of those rudiments in which morphogenesis had been inhibited. Biochemical evaluation confirmed that xylose-linked proteoglycan assembly had been inhibited by xyloside. These results indicate that while xylose-linked proteoglycans play a significant role in the control of salivary gland morphogenesis these molecules are not primary regulators for secretory cell differentiation within developing salivary glands.