1l44

CUMULATIVE SITE-DIRECTED CHARGE-CHANGE REPLACEMENTS IN BACTERIOPHAGE T4 LYSOZYME SUGGEST THAT LONG-RANGE ELECTROSTATIC INTERACTIONS CONTRIBUTE LITTLE TO PROTEIN STABILITY

OverviewOverview

Bacteriophage T4 lysozyme is a basic molecule with an isoelectric point, above 9.0, and an excess of nine positive charges at neutral pH. It might, be expected that it would be energetically costly to bring these, out-of-balance charges from the extended, unfolded, form of the protein, into the compact folded state. To determine the contribution of such, long-range electrostatic interactions to the stability of the protein, five positively charged surface residues, Lys16, Arg119, Lys135, Lys147, and Arg154, were individually replaced with glutamic acid. Eight selected, double, triple and quadruple mutants were also constructed so as to, sequentially reduce the out-of-balance formal charge on the molecule from, +9 to +1 units. Each of the five single variant proteins was crystallized, and high-resolution X-ray analysis confirmed that each mutant structure, was, in general, very similar to the wild-type. In the case of R154E, however, the Arg154 to Glu replacement caused a rearrangement in which, Asp127 replaced Glu128 as the capping residue of a nearby alpha-helix. The, thermal stabilities of all 13 variant proteins were found to be fairly, similar, ranging from 0.5 kcal/mol more stable than wild-type to 1.7, kcal/mol less stable than wild-type. In the case of the five single, charge-change variants, for which the structures were determined, the, changes in stability can be rationalized in terms of changes in local, interactions at the site of the replacement. There is no evidence that the, reduction in the out-of-balance charge on the molecule increases the, stability of the folded relative to the unfolded form, either at pH 2.8 or, at pH 5.3. This indicates that long-range electrostatic interactions, between the substituted amino acid residues and other charged groups on, the surface of the molecule are weak or non-existent. Furthermore, the, relative stabilities of the multiple charge replacement mutant proteins, were found to be almost exactly equal to the sums of the relative, stabilities of the constituent single mutant proteins. This also clearly, indicates that the electrostatic interactions between the replaced charges, are negligibly small. The activities of the charge-change mutant, lysozymes, as measured by the rate of hydrolysis of cell wall suspensions, are essentially equal to that of the wild-type lysozyme, but on a, lysoplate assay the mutant enzymes appear to have higher, activity.(ABSTRACT TRUNCATED AT 400 WORDS)

About this StructureAbout this Structure

1L44 is a Single protein structure of sequence from Bacteriophage t4. Active as Lysozyme, with EC number 3.2.1.17 Full crystallographic information is available from OCA.

ReferenceReference

Cumulative site-directed charge-change replacements in bacteriophage T4 lysozyme suggest that long-range electrostatic interactions contribute little to protein stability., Sun DP, Soderlind E, Baase WA, Wozniak JA, Sauer U, Matthews BW, J Mol Biol. 1991 Oct 5;221(3):873-87. PMID:1942034

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