J. Biol. Chem., Vol. 261, Issue 21, 9576-9578, 07, 1986
Protein engineering of homodimeric tyrosyl-tRNA synthetase to produce active heterodimers
WH Ward, DH Jones and AR Fersht
Heterodimers of tyrosyl-tRNA synthetase from Bacillus stearothermophilus
have been produced by mutagenesis at the subunit interface. Oppositely
charged groups have been engineered into the subunits so that they can form
a complementary pair. Wild-type tyrosyl- tRNA synthetase is a symmetrical
dimer in which the side chains of the 2 Phe-164 residues interact at the
subunit interface. Phe-164 was mutated to Asp in tyrosyl-tRNA synthetase
and to Lys in a truncated enzyme (des-(321-419)tyrosyl-tRNA synthetase)
which lacks the two tRNA- binding sites, but which can catalyze
pyrophosphate exchange. The size difference allows subunit association to
be studied by gel filtration chromatography. These changes induce
reversible dissociation from active dimers into inactive monomers at pH
values which favor ionization at position 164. A mixture of the two mutants
near neutral pH is apparently fully active in pyrophosphate exchange and
consists of a heterodimer of [Asp164]tyrosyl-tRNA synthetase and
[Lys164]des-(321- 419)tyrosyl-tRNA synthetase. Despite having only one
binding site for tRNA, heterodimer has full aminoacylation activity at high
concentrations of tyrosine. We have therefore produced a family of dimers
that differ in stability near neutral pH. This novel approach using protein
engineering allows specific dimerization of subunits of the same size that
have different defined mutations, each subunit being tagged by the charge.
Such hybrid proteins can be used to study subunit interaction.
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