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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Cleavage Specificity of Mast Cell Chymases

Andersson, Mattias K. January 2008 (has links)
<p>Mast cells (MC) are potent inflammatory cells that are known primarily for their prominent role in IgE mediated allergies. However, they also provide beneficial functions to the host, e.g. in bacterial and parasitic defence. MCs react rapidly upon stimulation by releasing potent granule-stored mediators, and serine proteases of the chymase or tryptase families are such major granule constituents. </p><p>As a first step towards a better understanding of the biological function of these proteases, we have determined the extended cleavage specificities of four mammalian mast cell chymases, by utilizing a substrate phage display approach. The specificities of these enzymes have then been used to compare their functional characteristics.</p><p>The major mucosal MC chymase in mice, mMCP-1, was found to possess a strict preference in four amino acid positions of the peptide substrate. Using this sequence to search the mouse proteome for potential <i>in vivo</i> substrates led to the identification of several very interesting potential novel substrates. Some of them may explain the increased epithelial permeability provided by this enzyme.</p><p>Human MCs, express only one single α-chymase, and the rodent α-chymases have secondarily gained elastase-like primary cleavage specificity. However, rodents express additional chymases, the β-chymases, and rodent β-chymases may have adopted the function of the α-chymases. The cleavage specificities of the human chymase and two rodent β-chymases were therefore determined (rat rMCP-1 and mouse mMCP-4). N-terminal of the cleaved bond the three chymases showed similar preferences, but C-terminal the human chymase and mMCP-4 shared a high preference for acidic amino acids in the P2´ position and therefore seem to be functional homologues. The molecular interactions mediating the preference for acidic amino acids in position P2´ were further investigated. By site-directed mutagenesis of the human chymase, amino acids Arg143 and Lys192 were concluded to synergistically mediate this preference.</p><p>Our data show that chymases, of different MC subpopulations, display quite different extended cleavage specificities. However mouse do possess a MC chymase with almost identical cleavage specificity as the human MC chymase indicating a strong evolutionary pressure to maintain this enzyme specificity.</p>
2

Cleavage Specificity of Mast Cell Chymases

Andersson, Mattias K. January 2008 (has links)
Mast cells (MC) are potent inflammatory cells that are known primarily for their prominent role in IgE mediated allergies. However, they also provide beneficial functions to the host, e.g. in bacterial and parasitic defence. MCs react rapidly upon stimulation by releasing potent granule-stored mediators, and serine proteases of the chymase or tryptase families are such major granule constituents. As a first step towards a better understanding of the biological function of these proteases, we have determined the extended cleavage specificities of four mammalian mast cell chymases, by utilizing a substrate phage display approach. The specificities of these enzymes have then been used to compare their functional characteristics. The major mucosal MC chymase in mice, mMCP-1, was found to possess a strict preference in four amino acid positions of the peptide substrate. Using this sequence to search the mouse proteome for potential in vivo substrates led to the identification of several very interesting potential novel substrates. Some of them may explain the increased epithelial permeability provided by this enzyme. Human MCs, express only one single α-chymase, and the rodent α-chymases have secondarily gained elastase-like primary cleavage specificity. However, rodents express additional chymases, the β-chymases, and rodent β-chymases may have adopted the function of the α-chymases. The cleavage specificities of the human chymase and two rodent β-chymases were therefore determined (rat rMCP-1 and mouse mMCP-4). N-terminal of the cleaved bond the three chymases showed similar preferences, but C-terminal the human chymase and mMCP-4 shared a high preference for acidic amino acids in the P2´ position and therefore seem to be functional homologues. The molecular interactions mediating the preference for acidic amino acids in position P2´ were further investigated. By site-directed mutagenesis of the human chymase, amino acids Arg143 and Lys192 were concluded to synergistically mediate this preference. Our data show that chymases, of different MC subpopulations, display quite different extended cleavage specificities. However mouse do possess a MC chymase with almost identical cleavage specificity as the human MC chymase indicating a strong evolutionary pressure to maintain this enzyme specificity.
3

Haematopoietic Serine Proteases : A Cleavage Specificity Analysis

Thorpe, Michael January 2014 (has links)
Mast cells are innate immune cells, historically involved in allergy responses involving IgE. Through this, they have earned a reputation as a fairly detrimental cell type. Their beneficial roles remain somewhat enigmatic although they clearly have the ability to modulate the immune system. This is due to their ability to synthesise many cytokines and chemokines as well as immediately release potent granule-stored mediators. One such mediator is a serine protease, chymase, which has been targeted by pharmaceutical companies developing inhibitors for use in inflammatory conditions. In order to address roles of the proteases, information regarding their cleavage specificity using substrate phage display can help find potential in vivo substrates.  The human chymase cleaves substrates with aromatic amino acids in the P1 position and has a preference for negatively charged amino acids in the P2’ position. The molecular interactions mediating this P2’ preference was investigated by site-directed mutagenesis, where Arg143 and Lys192 had a clear effect in this selectivity. As humans express one chymase and rodents express multiple chymases, extrapolating data between species is difficult. Here, the crab-eating macaque was characterised, which showed many similarities to the human chymase including a near identical extended cleavage specificity and effects of human chymase inhibitors.  Appropriate models are needed when developing human inhibitors for therapeutic use in inflammatory conditions. The effects of five specific chymase inhibitors in development were also tested. The selectivity of inhibitors was dependent on both Arg143 and Lys192, with a greater effect of Lys192. Identification of residues involved in specific inhibitor interactions is important for selective inhibitor development. Another innate cell type, the NK cell, is important in virus and tumour defence. In the channel catfish, a serine protease from an NK-like cell, granzyme-like I, was characterised. A strict preference for Met in the P1 position was seen, and caspase 6 was identified as a potential in vivo target. This may highlight a novel apoptosis-inducing mechanism from a similar cell type has been conserved for approximately 400 myr. Here, important residues mediating chymases’ specificity and interactions with inhibitors has been addressed, as well as finding a new animal model for providing ways to combat their roles in pathological settings.

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