Specific amino acid substitutions in human collagenase cause decreased autoproteolysis and reveal a requirement for a second zinc atom for catalytic activity

Williams, D. H.; Murray, Edward J.

doi:10.1016/0014-5793(94)01136-2

Cited by 7 publications

(6 citation statements)

References 19 publications

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“…Similar mutagenesis in fibroblast collagenase has been demonstrated recently and the conversion of He 251 -> Ser and/or He 241 -> Leu leads to resistance to autoproteolysis when the active enzymes were stored at 4°C [30,31]-In contrast, mutagenesis of the Pi position of the peptide bonds cleaved by autoproteolysis has no effect on stability (mutant V), or leads to increased autoproteolysis (mutant IV).…”

Section: Effect Of the Hinge Mutations On Stability Of Active Neutropsupporting

confidence: 64%

Analysis of the contribution of the hinge region of human neutrophil collagenase (HNC, MMP‐8) to stability and collagenolytic activity by alanine scanning mutagenesis

Knäuper¹,

Docherty²,

Smith³

et al. 1997

FEBS Letters

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Analysis of the hinge region of neutrophil collagenase by alanine scanning mutagenesis revealed that this sequence motif has a pronounced effect on the stability and collagenolytic activity of the active enzyme. The mutagenesis of the amino acid residues in the P^ ' position of the two autoproteolytically cleaved peptide bonds (Leu 43 and He 248 ) to Ala showed that the mutant enzymes were more resistant to autoproteolysis. However, these mutants were not completely stable and autoproteolysis occurred mainly at the Ala 239 -Ile 240 peptide bond and the half-life of the active enzyme was increased by 50%. In contrast, mutagenesis of Pro 247 -> Ala (P, of the minor cleavage site Pro 247 -Ile 248 ) lead to increased susceptibility of the enzyme to autoproteolysis. However, when the other Pi position Gly 242 was altered to Ala no effect on stability was observed. The analysis of the ability of the mutant active enzymes to hydrolyse 14 C-type I collagen was assessed and our results demonstrate that the hinge sequence motif of neutrophil collagenase is important for collagenolytic activity. The alteration of the Gly 24 -Leu-Ser-Ser-Asn-ProIle-Gln-Pro 247 sequence motif to Gly 242 -Ala-Ala-Ala-AlaPro-Ala-Ala-Pro showed that the collagenolytic activity was reduced by 68.4%. In addition, mutagenesis of the downstream sequence motif Pro 7 -Thr-Gly-Pro-Ser-Thr-Pro-Lys-Pro s to Pro 247 -AIa-Ala-Pro-Ala-Ala-Pro-Ala-Pro 258 had an even more marked effect on the collagenolytic activity, which was reduced by 87.4%. When the Pro residues in the hinge motif (Pro 247 , Pro 250 , Pro 253 and Pro 256 ) were altered to Ala the collagenolytic activity dropped to 1.5% of the value observed for wild-type enzyme.

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Section: Effect Of the Hinge Mutations On Stability Of Active Neutropsupporting

confidence: 64%

Analysis of the contribution of the hinge region of human neutrophil collagenase (HNC, MMP‐8) to stability and collagenolytic activity by alanine scanning mutagenesis

Knäuper¹,

Docherty²,

Smith³

et al. 1997

FEBS Letters

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“…In addition, Kly18 possesses most of the structural details characteristic of MMP CDs that distinguish them from other metzincins: (i) the residue downstream of the third zinc‐binding histidine is always a serine, and it hydrogen bonds the aspartate residue in helix αC that binds the N‐terminus in physiologically relevant ‘superactive’ MMP variants (Reinemer et al ., 1994; Tallant et al ., 2010b), (ii) after this conserved serine, the downstream chain trace, which leads to the Met‐turn and is characteristic for MMPs, and the latter turn itself, are perfectly superimposable, (iii) the Met‐turn is stabilized through hydrogen bonds of its main‐chain with a conserved aspartate residue immediately downstream of the aforementioned one within helix αC, (iv) the characteristic loop structures found in Kly18, the S‐loop, the bulge‐edge segment, the S 1 ′‐wall forming segment – which includes the sequence Pro175–Tyr–Tyr177 – and the specificity loop, are essential hallmarks of mammalian MMP CDs (Tallant et al ., 2010b), (v) the S 1 ′ pocket is hydrophobic and designed to accommodate bulky hydrophobic side‐chains, (vi) in addition, Kly18 accomplishes with the structural requirements of another characteristic feature of the active‐site cleft of MMPs, i.e. the selectivity for proline in position P 3 of a substrate, through an S 3 pocket framed by His117 and Phe119 of strand βIV and Tyr106 of the S‐loop, (vii) the first part of the S‐loop includes an essential structural zinc site (Williams and Murray, 1994) formed by residues contained in conserved sequence stretches equivalent to Pro107–His–Asp–Gly–(Xxx) 3 –Phe–Asp–Gly110 of Kly18 (Fig. 2C), and finally (viii) the sequences found in Kly18 within the upper‐rim strand βIV, Leu115–Ala–His–Ala–Phe–Xxx–Pro121, and within strand βV, His133–Phe–Asp135, are likewise conserved among MMPs.…”

Section: Resultsmentioning

confidence: 99%

The structure of the catalytic domain of Tannerella forsythia karilysin reveals it is a bacterial xenologue of animal matrix metalloproteinases

Cerdà-Costa

Guevara

Karim

et al. 2010

Molecular Microbiology

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SummaryMetallopeptidases (MPs) are among virulence factors secreted by pathogenic bacteria at the site of infection. One such pathogen is Tannerella forsythia, a member of the microbial consortium that causes peridontitis, arguably the most prevalent infective chronic inflammatory disease known to mankind. The only reported MP secreted by T. forsythia is karilysin, a 52 kDa multidomain protein comprising a central 18 kDa catalytic domain (CD), termed Kly18, flanked by domains unrelated to any known protein. We analysed the 3D structure of Kly18 in the absence and presence of Mg 2+ or Ca 2+ , which are required for function and stability, and found that it evidences most of the structural features characteristic of the CDs of mammalian matrix metalloproteinases (MMPs). Unexpectedly, a peptide was bound to the active-site cleft of Kly18 mimicking a left-behind cleavage product, which revealed that the specificity pocket accommodates bulky hydrophobic side-chains of substrates as in mammalian MMPs. In addition, Kly18 displayed a unique Mg 2+ or Ca 2+ binding site and two flexible segments that could play a role in substrate binding. Phylogenetic and sequence similarity studies revealed that Kly18 is evolutionarily much closer to winged-insect and mammalian MMPs than to potential bacterial counterparts found by genomic sequencing projects. Therefore, we conclude that this first structurally characterized non-mammalian MMP is a xenologue co-opted through horizontal gene transfer during the intimate coexistence between T. forsythia and humans or other animals, in a very rare case of gene shuffling from eukaryotes to prokaryotes. Subsequently, this protein would have evolved in a bacterial environment to give rise to full-length karilysin that is furnished with unique flanking domains that do not conform to the general multidomain architecture of animal MMPs.

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“…There may be subtle structural differences between the truncated forms of the MMPs and the mature full-length enzymes in relation to the role of the second “structural” zinc(II) ion. To overcome problems of autoproteolysis when attempting to crystallize full-length active HFC (domains II and III), mutation of two amino acids which chelate the “structural” zinc(II) ion was found to result in a loss of catalytic activity . However, while analysis of the zinc contents of truncated forms of prostromelysin-1 and progelatinase-A indicates the presence of two zinc(II) ions, only one zinc(II) ion is detected in the corresponding full-length enzymes, and it has been suggested that the C-terminal domain performs the role proposed for the “structural” zinc(II) ion in maintaining the structure of the enzyme catalytic domain …”

Section: Mmp Structural Studiesmentioning

confidence: 99%

“…To overcome problems of autoproteolysis when attempting to crystallize full-length active HFC (domains II and III), mutation of two amino acids which chelate the "structural" zinc(II) ion was found to result in a loss of catalytic activity. 93 However, while analysis of the zinc contents of truncated forms of prostromelysin-1 and progelatinase-A indicates the presence of two zinc-(II) ions, only one zinc(II) ion is detected in the corresponding full-length enzymes, and it has been suggested that the C-terminal domain performs the role proposed for the "structural" zinc(II) ion in maintaining the structure of the enzyme catalytic domain. 94 However, a recent structure of full-length porcine synovial collagenase (MMP-1), which includes the haemopexin-like domain III, reveals the presence of both "catalytic" and "structural" zinc(II) ions in the crystalline form.…”

Section: Mmp Structural Studiesmentioning

confidence: 99%

Design and Therapeutic Application of Matrix Metalloproteinase Inhibitors

Whittaker¹,

Floyd²,

Brown³

et al. 1999

Chem. Rev.

950

999

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Specific amino acid substitutions in human collagenase cause decreased autoproteolysis and reveal a requirement for a second zinc atom for catalytic activity

Cited by 7 publications

References 19 publications

Analysis of the contribution of the hinge region of human neutrophil collagenase (HNC, MMP‐8) to stability and collagenolytic activity by alanine scanning mutagenesis

Analysis of the contribution of the hinge region of human neutrophil collagenase (HNC, MMP‐8) to stability and collagenolytic activity by alanine scanning mutagenesis

The structure of the catalytic domain of Tannerella forsythia karilysin reveals it is a bacterial xenologue of animal matrix metalloproteinases

Design and Therapeutic Application of Matrix Metalloproteinase Inhibitors

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