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PDBsum entry 4jrw
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Cell adhesion
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PDB id
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4jrw
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Enzyme class:
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E.C.3.4.24.3
- microbial collagenase.
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Reaction:
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Digestion of native collagen in the triple helical region at Xaa-|-Gly bonds. With synthetic peptides, a preference is shown for Gly at P3 and P1'; Pro and Ala at P2 and P2'; and hydroxyproline, Ala or Arg at P3'.
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Cofactor:
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Zn(2+)
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DOI no:
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Acta Crystallogr D Biol Crystallogr
71:565-577
(2015)
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PubMed id:
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Structures of three polycystic kidney disease-like domains from Clostridium histolyticum collagenases ColG and ColH.
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R.Bauer,
K.Janowska,
K.Taylor,
B.Jordan,
S.Gann,
T.Janowski,
E.C.Latimer,
O.Matsushita,
J.Sakon.
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ABSTRACT
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Clostridium histolyticum collagenases ColG and ColH are segmental enzymes that
are thought to be activated by Ca(2+)-triggered domain reorientation to cause
extensive tissue destruction. The collagenases consist of a collagenase module
(s1), a variable number of polycystic kidney disease-like (PKD-like) domains
(s2a and s2b in ColH and s2 in ColG) and a variable number of collagen-binding
domains (s3 in ColH and s3a and s3b in ColG). The X-ray crystal structures of
Ca(2+)-bound holo s2b (1.4 Å resolution, R = 15.0%, Rfree = 19.1%) and holo
s2a (1.9 Å resolution, R = 16.3%, Rfree = 20.7%), as well as of Ca(2+)-free
apo s2a (1.8 Å resolution, R = 20.7%, Rfree = 27.2%) and two new forms of
N-terminally truncated apo s2 (1.4 Å resolution, R = 16.9%, Rfree = 21.2%;
1.6 Å resolution, R = 16.2%, Rfree = 19.2%), are reported. The structurally
similar PKD-like domains resemble the V-set Ig fold. In addition to a conserved
β-bulge, the PKD-like domains feature a second bulge that also changes the
allegiance of the subsequent β-strand. This β-bulge and the genesis of a
Ca(2+) pocket in the archaeal PKD-like domain suggest a close kinship between
bacterial and archaeal PKD-like domains. Different surface properties and
indications of different dynamics suggest unique roles for the PKD-like domains
in ColG and in ColH. Surface aromatic residues found on ColH s2a-s2b, but not on
ColG s2, may provide the weak interaction in the biphasic collagen-binding mode
previously found in s2b-s3. B-factor analyses suggest that in the presence of
Ca(2+) the midsection of s2 becomes more flexible but the midsections of s2a and
s2b stay rigid. The different surface properties and dynamics of the domains
suggest that the PKD-like domains of M9B bacterial collagenase can be grouped
into either a ColG subset or a ColH subset. The conserved properties of PKD-like
domains in ColG and in ColH include Ca(2+) binding. Conserved residues not only
interact with Ca(2+), but also position the Ca(2+)-interacting water molecule.
Ca(2+) aligns the N-terminal linker approximately parallel to the major axis of
the domain. Ca(2+) binding also increases stability against heat and guanidine
hydrochloride, and may improve the longevity in the extracellular matrix. The
results of this study will further assist in developing collagen-targeting
vehicles for various signal molecules.
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