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PDBsum entry 3da7
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Protein binding
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PDB id
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3da7
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Contents |
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109 a.a.
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101 a.a.
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90 a.a.
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102 a.a.
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References listed in PDB file
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Key reference
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Title
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Structural and thermodynamic analysis of a conformationally strained circular permutant of barnase.
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Authors
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J.S.Butler,
D.M.Mitrea,
G.Mitrousis,
G.Cingolani,
S.N.Loh.
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Ref.
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Biochemistry, 2009,
48,
3497-3507.
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PubMed id
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Abstract
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Circular permutation of a protein covalently links its original termini and
creates new ends at another location. To maintain the stability of the permuted
structure, the termini are typically bridged by a peptide long enough to span
the original distance between them. Here, we take the opposite approach and
employ a very short linker to introduce conformational strain into a protein by
forcing its termini together. We join the N- and C-termini of the small
ribonuclease barnase (normally 27.2 A distant) with a single Cys residue and
introduce new termini at a surface loop, to create pBn. Compared to a similar
variant permuted with an 18-residue linker, permutation with a single amino acid
dramatically destabilizes barnase. Surprisingly, pBn is folded at 10 degrees C
and possesses near wild-type ribonuclease activity. The 2.25 A X-ray crystal
structure of pBn reveals how the barnase fold is able to adapt to permutation,
partially defuse conformational strain, and preserve enzymatic function. We
demonstrate that strain in pBn can be relieved by cleaving the linker with a
chemical reagent. Catalytic activity of both uncleaved (strained) pBn and
cleaved (relaxed) pBn is proportional to their thermodynamic stabilities, i.e.,
the fraction of folded molecules. The stability and activity of cleaved pBn are
dependent on protein concentration. At concentrations above approximately 2
microM, cleaving pBn is predicted to increase the fraction of folded molecules
and thus enhance ribonuclease activity at 37 degrees C. This study suggests that
introducing conformational strain by permutation, and releasing strain by
cleavage, is a potential mechanism for engineering an artificial zymogen.
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