A theoretical approach towards the identification of cleavage-determining amino acid motifs of the 20s proteasome
Identifieur interne : 003972 ( Main/Exploration ); précédent : 003971; suivant : 003973A theoretical approach towards the identification of cleavage-determining amino acid motifs of the 20s proteasome
Auteurs : Hermann-Georg Holzhütter [Hongrie, Allemagne] ; Cornelius Frömmel [Allemagne] ; Peter-Michael Kloetzel [Allemagne]Source :
- Journal of Molecular Biology [ 0022-2836 ] ; 1999.
English descriptors
- KwdEn :
- Teeft :
- Academic press, Acid motifs, Acid residues, Active site, Active sites, Amino, Amino acid, Amino acid motifs, Amino acid residues, Amino acids, Anchor locations, Anchor position, Anchor positions, Anchor residues, Anking, Anking region, Anking regions, Antigen presentation, Antigenic peptides, Appropriate binding conformations, Binding epitope, Bold bars, Bold frames, Carboxyl, Carboxyl site, Cardinal properties, Certain length, Classical protease, Cleavage, Cleavage frequencies, Cleavage frequency, Cleavage mechanism, Cleavage preference, Cleavage preferences, Cleavage probability, Cleavage products, Cleavage rate, Cleavage rates, Cleavage site, Cleavage sites, Conformation, Continuous line, Corresponding property term, Degradation, Degradation pattern, Degradation products, Effective substrate binding, Epitope, Eukaryotic proteasomes, False positives, Febs letters, Fragment, Globular proteins, Grey cells, Hydrophobic residue, Hydrophobic residues, Independent observations, Larger sequence region, Larger weight, Lmp2, Lmp2 subunits, Lmp7 subunits, Major histocompatibility, Molecular ruler, Niedermann, Normalised, Optimal properties, Other cleavage sites, Other hand, Overall cleavage probability, Pattern recognition, Peptide, Peptide bond, Peptide bond cleavage, Peptide bonds, Peptide fragments, Peptide substrate, Peptide substrates, Pituitary multicatalytic proteinase, Possible epitopes, Possible shapes, Potential cleavage site, Predictive capacity, Processive degradation, Properties volume, Property term, Property terms, Property volume, Protease, Proteasome, Proteasome figure, Proteasome table, Proteasomes, Protein substrate, Protein substrates, Proteolytic, Proteolytic fragments, Relative frequencies, Relative orientation, Residual squares, Residue, Residue types, Same residue, Scatter plot, Scissile, Scissile bond, Scissile peptide bond, Selective cleavage, Sequence length, Sequence positions, Sequence window, Short peptides, Shorter fragments, Size distribution, Small number, Subunit, Subunits lmp2, Theoretical approach, Total number, Transfer energy, Tting, Tting round, Tting strategy, Uorgenic peptides, Vertebrate proteasomes, Window method, Yeast proteasome subunit.
Abstract
Abstract: Hitherto the mechanisms controlling the selective cleavage of peptide bonds by the 20 S proteasome have been poorly understood. The observation that peptide bond cleavage may eventually occur at the carboxyl site of either amino acid residue rules out a simple control of cleavage preferences by the P1 residue alone. Here, we follow the rationale that the presence of specific cleavage-determining amino acids motifs (CDAAMs) around the scissile peptide bond are required for the attainment of substrate conformations susceptible to cleavage. We present an exploratory search for these putative motifs based on empirical regression functions relating the cleavage probability for a given peptide bond to some selected side-chain properties of the flanking amino acid residues. Identification of the sequence locations of cleavage-determining residues relative to the scissile bond and of their optimal side-chain properties was carried out by fitting the cleavage probability to (binary) experimental observations on peptide bond cleavage gathered among a set of seven different peptide substrates with known patterns of proteolytic degradation products. In this analysis, all peptide bonds containing the same residue in the P1 position were assumed to be cleaved by the same active sites of the proteasome, and thus to be under control of the same CDAAMs. We arrived at a final set of ten different CDAAMs, accounting for the cleavage of one to five different groups of peptide bonds with an overall predictive correctness of 93%. The CDAAM is composed of two to four “anchor” positions preferentially located between P5 and P5′ around the scissile bond. This implies a length constraint for the usage of cleavage sites, which could considerably suppress the excision of shorter fragments and thus partially explain for the observed preponderance of medium-size cleavage products.
Url:
DOI: 10.1006/jmbi.1998.2530
Affiliations:
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strategy</term><term>Uorgenic peptides</term><term>Vertebrate proteasomes</term><term>Window method</term><term>Yeast proteasome subunit</term></keywords></textClass><langUsage><language ident="en">en</language></langUsage></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Abstract: Hitherto the mechanisms controlling the selective cleavage of peptide bonds by the 20 S proteasome have been poorly understood. The observation that peptide bond cleavage may eventually occur at the carboxyl site of either amino acid residue rules out a simple control of cleavage preferences by the P1 residue alone. Here, we follow the rationale that the presence of specific cleavage-determining amino acids motifs (CDAAMs) around the scissile peptide bond are required for the attainment of substrate conformations susceptible to cleavage. We present an exploratory search for these putative motifs based on empirical regression functions relating the cleavage probability for a given peptide bond to some selected side-chain properties of the flanking amino acid residues. Identification of the sequence locations of cleavage-determining residues relative to the scissile bond and of their optimal side-chain properties was carried out by fitting the cleavage probability to (binary) experimental observations on peptide bond cleavage gathered among a set of seven different peptide substrates with known patterns of proteolytic degradation products. In this analysis, all peptide bonds containing the same residue in the P1 position were assumed to be cleaved by the same active sites of the proteasome, and thus to be under control of the same CDAAMs. We arrived at a final set of ten different CDAAMs, accounting for the cleavage of one to five different groups of peptide bonds with an overall predictive correctness of 93%. The CDAAM is composed of two to four “anchor” positions preferentially located between P5 and P5′ around the scissile bond. This implies a length constraint for the usage of cleavage sites, which could considerably suppress the excision of shorter fragments and thus partially explain for the observed preponderance of medium-size cleavage products.</div></front></TEI><affiliations><list><country><li>Allemagne</li><li>Hongrie</li></country><region><li>Berlin</li></region><settlement><li>Berlin</li></settlement></list><tree><country name="Hongrie"><noRegion><name sortKey="Holzhutter, Hermann Georg" sort="Holzhutter, Hermann Georg" uniqKey="Holzhutter H" first="Hermann-Georg" last="Holzhütter">Hermann-Georg Holzhütter</name></noRegion></country><country name="Allemagne"><region name="Berlin"><name sortKey="Holzhutter, Hermann Georg" sort="Holzhutter, Hermann Georg" uniqKey="Holzhutter H" first="Hermann-Georg" last="Holzhütter">Hermann-Georg Holzhütter</name></region><name sortKey="Frommel, Cornelius" sort="Frommel, Cornelius" uniqKey="Frommel C" first="Cornelius" last="Frömmel">Cornelius Frömmel</name><name sortKey="Kloetzel, Peter Michael" sort="Kloetzel, Peter Michael" uniqKey="Kloetzel P" first="Peter-Michael" last="Kloetzel">Peter-Michael Kloetzel</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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