Guang W. Wong

Heparin is essential for the storage of specific granule proteases in mast cells

All mammals produce heparin, a negatively charged glycosaminoglycan that is a major constituent of the secretory granules of mast cells which are found in the peritoneal cavity and most connective tissues. Although heparin is one of the most studied molecules in the body, its physiological function has yet to be determined. Here we describe transgenic mice, generated by disrupting the N -deacetylase/N -sulphotransferase-2 gene,, that cannot express fully sulphated heparin. The mast cells in the skeletal muscle that normally contain heparin lacked metachromatic granules and failed to store appreciable amounts of mouse mast-cell protease (mMCP)-4, mMCP-5 and carboxypeptidase A (mMC-CPA), even though they contained substantial amounts of mMCP-7. We developed mast cells from the bone marrow of the transgenic mice. Although these cultured cells contained high levels of various protease transcripts and had substantial amounts of mMCP-6 protein in their granules, they also failed to express mMCP-5 and mMC-CPA. Our data show that heparin controls, through a post-translational mechanism, the levels of specific cassettes of positively charged proteases inside mast cells.

The Tryptase, Mouse Mast Cell Protease 7, Exhibits Anticoagulant Activity in Vivo and in Vitro Due to Its Ability to Degrade Fibrinogen in the Presence of the Diverse Array of Protease Inhibitors in Plasma*

Mouse mast cell protease (mMCP) 7 is a tryptase of unknown function expressed by a subpopulation of mast cells that reside in numerous connective tissue sites. Because enzymatically active mMCP-7 is selectively released into the plasma of V3 mastocytosis mice undergoing passive systemic anaphylaxis, we used thisin vivo model system to identify a physiologic substrate of the tryptase. Plasma samples taken from V3 mastocytosis mice that had been sensitized with immunoglobulin (Ig) E and challenged with antigen were found to contain substantial amounts of four 34–55-kDa peptides, all of which were derived from fibrinogen. To confirm the substrate specificity of mMCP-7, a pseudozymogen form of the recombinant tryptase was generated that could be activated after its purification. The resulting recombinant mMCP-7 exhibited potent anticoagulant activity in the presence of normal plasma and selectively cleaved the α-chain of fibrinogen to fragments of similar size as that seen in the plasma of the IgE/antigen-treated V3 mastocytosis mouse. Subsequent analysis of a tryptase-specific, phage display peptide library revealed that recombinant mMCP-7 preferentially cleaves an amino acid sequence that is nearly identical to that in the middle of the α-chain of rat fibrinogen. Because fibrinogen is a physiologic substrate of mMCP-7, this tryptase can regulate clot formation and fibrinogen/integrin-dependent cellular responses during mast cell-mediated inflammatory reactions.

Identification of a new member of the tryptase family of mouse and human mast cell proteases which possesses a novel COOH-terminal hydrophobic extension.

Mapping of the tryptase locus on chromosome 17 revealed a novel gene 2.3 kilobase 3′ of the mouse mast cell protease (mMCP) 6 gene. This 3.7-kilobase gene encodes the first example of a protease in the tryptase family that contains a membrane-spanning segment located at its COOH terminus. Comparative structural studies indicated that the putative transmembrane tryptase (TMT) possesses a unique substrate-binding cleft. As assessed by RNA blot analyses, mTMT is expressed in mice in both strain- and tissue-dependent manners. Thus, different transcriptional and/or post-transcriptional mechanisms are used to control the expression of mTMT in vivo. Analysis of the corresponding tryptase locus in the human genome resulted in the isolation and characterization of the hTMT gene. ThehTMT transcript is expressed in numerous tissues and is also translated. Analysis of the tryptase family of genes in mice and humans now indicates that a primordial serine protease gene duplicated early and often during the evolution of mammals to generate a panel of homologous tryptases in each species that differ in their tissue expression, substrate specificities, and physical properties.

Mouse Chromosome 17A3.3 Contains 13 Genes That Encode Functional Tryptic-like Serine Proteases with Distinct Tissue and Cell Expression Patterns

Probing of the mouse EST data base at GenBank™ with known tryptase cDNAs resulted in the identification of undiscovered serine protease transcripts whose genes reside at a 1.5-Mb complex on mouse chromosome 17A3.3. Mouse tryptase-5 (mT5), tryptase-6 (mT6), and mast cell protease-11 (mMCP-11) are new members of this serine protease superfamily whose amino acid sequences are 36–54% identical to each other and to their other 10 family members. The 13 functional mouse proteases can be subdivided into two subgroups based on conserved features in their propeptides. Of the three new serine proteases, mT6 is most widely expressed in tissues. mT5 is preferentially expressed in smooth muscle, whereas mMCP-11 is preferentially expressed in the spleen and bone marrow. In contrast to mT5 and mT6, mMCP-11 is also expressed in mast cells. Although mT6 and mMCP-11 are constitutively secreted when expressed in mammalian and insect cells, mT5 remains membrane-associated. The fact that recombinant mT5, mT6, and mMCP-11 possess non-identical expression patterns and substrate specificities suggests that each protease has a unique function in vivo. Of the 13 functional mouse tryptase genes identified at the complex, 12 have orthologs that reside in the syntenic region of human chromosome 16p13.3. The establishment of these ortholog pairs helps clarify the evolutionary relationship of the serine protease locus in the two species. This information provides a useful framework for the functional analysis of each protease using gene targeting and other molecular approaches.

Tryptase 4, a new member of the chromosome 17 family of mouse serine proteases.

Genomic blot analysis raised the possibility that uncharacterized tryptase genes reside on chromosome 17 at the complex containing the three genes that encode mouse mast cell protease (mMCP) 6, mMCP-7, and transmembrane tryptase (mTMT). Probing of GenBanks expressed sequence tag data base with these three tryptase cDNAs resulted in the identification of an expressed sequence tag that encodes a portion of a novel mouse serine protease (now designated mouse tryptase 4 (mT4) because it is the fourth member of this family). 5′- and 3′-rapid amplification of cDNA ends approaches were carried out to deduce the nucleotide sequence of the full-length mT4 transcript. This information was then used to clone its ∼5.0-kilobase pair gene. Chromosome mapping analysis of its gene, sequence analysis of its transcript, and comparative protein structure modeling of its translated product revealed that mT4 is a new member of the chromosome 17 family of mouse tryptases. mT4 is 40–44% identical to mMCP-6, mMCP-7, and mTMT, and this new serine protease has all of the structural features of a functional tryptase. Moreover, mT4 is enzymatically active when expressed in insect cells. Due to its 17-mer hydrophobic domain at its C terminus, mT4 is a membrane-anchored tryptase more analogous to mTMT than the other members of its family. As assessed by RNA blot, reverse transcriptase-polymerase chain reaction, and/or in situ hybridization analysis, mT4 is expressed in interleukin-5-dependent mouse eosinophils, as well as in ovaries and testes. The observation that recombinant mT4 is preferentially retained in the endoplasmic reticulum of transiently transfected COS-7 cells suggests a convertase-like role for this integral membrane serine protease.

Mast Cells in Airway Hyporesponsive C3H/HeJ Mice Express a Unique Isoform of the Signaling Protein Ras Guanine Nucleotide Releasing Protein 4 That Is Unresponsive to Diacylglycerol and Phorbol Esters

cDNAs were recently isolated from BALB/c mouse mast cells (MCs) that encode the new signaling protein mouse Ras guanine nucleotide releasing protein 4 (mRasGRP4). The present study evaluates the expression pattern and biological activity of mRasGRP4 in a variety of mouse strains. As assessed immunohistochemically and by RNA analysis, mRasGRP4 is not coordinately expressed with any of its family members. Normally, mRasGRP4 is an MC-restricted protein in tissues, and kinetic studies revealed that mRasGRP4 is expressed relatively early in developing MCs. The expression of mRasGRP4 in the fetus before granulated MCs become abundant supports the conclusion that RasGRP4 participates in MC-specific differentiation pathways. Functional studies conducted with recombinant material revealed that mRasGRP4 is a cation-dependent, diacylglycerol (DAG)-regulated, guanine nucleotide exchange factor. Immunoelectron microscopic studies revealed that mRasGRP4 resides in either the cytosol or inner leaflet of the plasma membrane of the MC, implying that DAG controls the intracellular movement of this signaling protein in c-kit-stimulated MCs. The mRasGRP4 gene resides on chromosome 7B1 within a site that is prominently linked to baseline airway reactivity in backcrossed C3H/HeJ and A/J mice. A truncated isoform of mRasGRP4 that lacks its DAG-regulatory domain was isolated from C3H/HeJ mouse MCs. Sequence analysis showed that this isoform is the result of defective splicing of the precursor transcript. MCs play a central role in allergic inflammation. The discovery of a novel isoform of mRasGRP4 in hyporesponsive mice suggests that airway reactivity is influenced by RasGRP4-dependent signaling events in pulmonary MCs.

Cloning of the human homolog of mouse transmembrane tryptase.

Background: Three functionally distinct tryptases have been identified in the mouse, one of which encodes an unusual protease that possesses a membrane–spanning domain located in its C terminus. Methods and Results: Using the deduced nucleotide sequence of this mouse transmembrane tryptase (mTMT) gene in a polymerase chain reaction approach, cDNAs were isolated from a number of tissues which encode its human homolog. The amino acid sequences of hTMT and mTMT are 74% identical, and the human tryptase also has the novel membrane–spanning domain. Conclusion: The discovery that the human genome contains a large number of homologous, but distinct, tryptase genes suggests that the individual members of this family of proteases evolved to carry out discrete functions in mast cell–mediated allergic reactions.

Biochemical and functional characterization of human transmembrane tryptase (TMT)/tryptase γ. TMT is an exocytosed mast cell protease that induces airway hyperresponsiveness in vivo via an IL-13/IL-4Rα/STAT6-dependent pathway

Transmembrane tryptase (TMT)/tryptase γ is a membrane-bound serine protease stored in the secretory granules of human and mouse lung mast cells (MCs). We now show that TMT reaches the external face of the plasma membrane when MCs are induced to degranulate. Analysis of purified recombinant TMT revealed that it is a two-chain neutral protease. Thus, TMT is the only MC protease identified so far which retains its 18-residue propeptide when proteolytically activated. The genes that encode TMT and tryptase βI reside on human chromosome 16p13.3. However, substrate specificity studies revealed that TMT and tryptase βI are functionally distinct even though they are ∼50% identical. Although TMT is rapidly inactivated by the human plasma serpin α1-antitrypsin in vitro, administration of recombinant TMT (but not recombinant tryptase βI) into the trachea of mice leads to airway hyperresponsiveness (AHR) and increased expression of interleukin (IL) 13. T cells also increase their expression of IL-13 mRNA when exposed to TMT in vitro. TMT is therefore a novel exocytosed surface mediator that can stimulate those cell types that are in close proximity. TMT induces AHR in normal mice but not in transgenic mice that lack signal transducer and activator of transcription (STAT) 6 or the α-chain of the cytokine receptor that recognizes both IL-4 and IL-13. Based on these data, we conclude that TMT is an exocytosed MC neutral protease that induces AHR in lungs primarily by activating an IL-13/IL-4Rα/STAT6-dependent pathway.

Mouse and Rat Models of Mast Cell Development

Based on histochemical and morphological properties, Enerback concluded in 1966 that the mast cells (MC) residing in the jejunal mucosa of rats at the height of helminth infection are phenotypically different from the MC residing in the skin of uninfected animals.1 The biochemical basis for these variations was subsequently shown to be the different neutral proteases2–4 and proteoglycans5,6 stored in the secretory granules of the MC. Because hybrid MC with different stainable granules are not routinely seen in vivo, it was originally thought that mucosal and cutaneous MC are develop-mentally distinct.

Mouse mast cells express the tryptic protease neuropsin/Prss19☆

The only tryptic enzymes identified so far in mouse mast cells (MCs) are three members of the chromosome 17A3.3 family of neutral proteases. Sequence analysis of a cDNA library revealed that BALB/c mouse bone marrow-derived MCs express neuropsin, a member of the chromosome 7B2 family of tryptic kallikreins. Kinetic studies revealed that neuropsin is expressed relatively early in MC development. As assessed immunohistochemically, the MCs residing in numerous connective tissues store neuropsin in their secretory granules. The finding that the neuropsin transcript is maximally expressed in the intestine at the height of a helminth infection indicates that MC-committed progenitors selectively increase their expression of neuropsin as they develop into mature mucosal MCs. This is the first report documenting the expression of neuropsin in an immune cell. Thus, it is now apparent that mouse MCs store at least two distinct families of tryptic-like proteases in their secretory granules.