Replacement of all tryptophan residues in T4 bacteriophage lysozyme by tyrosine residues

Nucleotide sequence of the lysozyme gene of bacteriophage T4. Analysis of mutations involving repeated sequences

The nucleotide sequence of the lysozyme (e) gene of bacteriophage T4 and approximately 130 additional nucleotides on each side has been determined. The 5'-end of the gene for internal protein III appears to be located about 70 base-pairs from the 3'-end of the lysozyme gene. Nucleotide sequence analysis of mutant e genes confirmed that three identified hotspots of frameshift mutations are runs of five A nucleotides in the wild-type gene. The endpoints of two deletions are direct repeats of eight base-pairs in the wild-type gene. Two frameshift mutations with high reversion frequencies are duplications of five or seven base-pairs. The cloning and nucleotide sequence determination of the lysozyme gene will facilitate further study of the molecular biology of T4 lysozyme.

Stability of phage T4 lysozymes. I. Native properties and thermal stability of wild type and two mutant lysozymes

Two mutants of phage T4 lysozyme were prepared and characterized. One mutation substituted a tyrosine residue for tryptophan at position 138. The other substituted tyrosines at all three tryptophan positions of the wild type molecule (126, 138, 158). Comparative studies of the physical properties (absorption, fluorescence, circular dichroism) of the three enzymes were performed as a function of pH. Also, the proteins were reversibly melted as a function of pH. Since the unfolding reaction appeared to be a two-state process for all these proteins, the data were analyzed by the van 't Hoff procedure. The changes in stability and activity produced by substitution of Trp 138 were especially significant. The other substitutions were neutral. See the end of the paper for a summary of conclusions. In the appendix the appropriate thermodynamic relations are developed for a constant deltaCp transition.

Effect of neighboring nucleotide sequences on suppression efficiency in amber mutants of T4 phage lysozyme

Variations in suppression efficiency were observed among nonsense mutations at different locations within the lysozyme gene (e) of T4 phage. The present experiments using three amber mutants in lysozyme gene indicate such variations presumably depend upon the base sequences neighboring to the nonsense mutations.

Intragenic mutational spectra and hot spots

In this review we outline the various factors which may contribute to the non-randomness of intragenic mutational spectra and the occurrence of hot spots. These factors include sample size limitation, particularly for sites of low mutability, and possible regions of low recombination potential. In addition, the nature of the gene product places great restraint on the detectability of either frameshift and premature chain-terminating mutations on one hand, or of the majority of missense mutations on the other. The nature of the Genetic Code itself also limits the mutational spectrum in so far as specific base pair substitutions lead only to a limited number of detectable amino acid replacements. Mutational hot spots may be a special example of the influence of neighbouring base pairs in the mutability of any given base pair. This is apparently true for frameshift mutations which tend to occur in runs of repeated base pairs or base pair doublets. Neighbouring base effects could operate not only at the level of initial reactivity with a mutagen, but also subsequently at the levels of DNA repair, recombination or replication. In some cases rare or modified bases may be responsible for neighbour effects. We suggest specific experimental approaches which seem likely to aid in the elucidation of these problems.