ISDA

Entry Detail

PDB ID:

1L24

Keywords:

HYDROLASE (O-GLYCOSYL)

Title:

ENHANCED PROTEIN THERMOSTABILITY FROM SITE-DIRECTED MUTATIONS THAT DECREASE THE ENTROPY OF UNFOLDING

Biological Source:

Source Organism:

Enterobacteria phage T4

PDB Version:

Deposition Date:

1989-05-01

Release Date:

1990-01-15

Method Details:

Experimental Method:

X-RAY DIFFRACTION

Resolution:

1.70 Å

R-Value Observed:

0.15

Space Group:

P 32 2 1

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Macromolecular Entities

Protein Blast

Polymer Type:polypeptide(L)
Description:T4 LYSOZYME
Chain IDs:A
Chain Length:164
Number of Molecules:1
Biological Source:Enterobacteria phage T4

UniProt ID:P00720 Pfam ID:PF00959 EC:3.2.1.17

Primary Citation

Enhanced protein thermostability from site-directed mutations that decrease the entropy of unfolding.

Matthews, B.W, Nicholson, H, Becktel, W.J, Matsumura, M, Wozniak, J.A, Dao-Pin, S, Matthews, B.W, Weaver, L.H, Gray, T.M, Gruetter, M.G, Anderson, D.E, Wozniak, J.A, Dahlquist, F.W, Matthews, B.W, Nicholson, H, Soderlind, E, Tronrud, D.E, Matthews, B.W, Matsumura, M, Becktel, W.J, Matthews, B.W, Nicholson, H, Becktel, W.J, Matthews, B.W, Alber, T, Bell, J.A, Dao-Pin, S, Nicholson, H, Wozniak, J.A, Cook, S, Matthews, B.W, Gray, T.M, Matthews, B.W, Alber, T, Dao-Pin, S, Wilson, K, Wozniak, J.A, Cook, S.P, Matthews, B.W, Gruetter, M.G, Gray, T.M, Weaver, L.H, Alber, T, Wilson, K, Matthews, B.W, Weaver, L.H, Matthews, B.W, Alber, T, Dao-Pin, S, Nye, J.A, Muchmore, D.C, Matthews, B.W, Matthews, B.W, Gruetter, M.G, Anderson, W.F, Remington, S.J, Anderson, W.F, Gruetter, M.G, Remington, S.J, Weaver, L.H, Matthews, B.W, Matthews, B.W, Remington, S.J, Gruetter, M.G, Anderson, W.F, Remington, S.J, Anderson, W.F, Owen, J, Teneyck, L.F, Grainger, C.T, Matthews, B.W, Remington, S.J, Teneyck, L.F, Matthews, B.W, Matthews, B.W, Matthews, B.W, Remington, S.J, Matthews, B.W, Dahlquist, F.W, Maynard, A.Y.Show

Proc.Natl.Acad.Sci.USA 84 6663 6667 (1987)

PMID: 3477797 DOI: 10.1073/pnas.84.19.6663

Abstact

It is proposed that the stability of a protein can be increased by selected amino acid substitutions that decrease the configurational entropy of unfolding. Two such substitutions, one of the form Xaa----Pro and the other of the form Gly----Xaa, were constructed in bacteriophage T4 lysozyme at sites consistent with the known three-dimensional structure. Both substitutions stabilize the protein toward reversible and irreversible thermal denaturation at physiological pH. The substitutions have no effect on enzymatic activity. High-resolution crystallographic analysis of the proline-containing mutant protein (Ala-82----Pro) shows that its three-dimensional structure is essentially identical with the wild-type enzyme. The overall structure of the other mutant enzyme (Gly-77----Ala) is also very similar to wild-type lysozyme, although there are localized conformational adjustments in the vicinity of the altered amino acid. The combination of a number of such amino acid replacements, each of which is expected to contribute approximately 1 kcal/mol (1 cal = 4.184 J) to the free energy of folding, may provide a general strategy for substantial improvement in the stability of a protein.

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Primary Citation of related structures