SEGREGATION OF INDUCED FRAMESHIFT MUTATIONS AND THE SEQUENCE OF GENE REPLICATION IN ESCHERICHIA COLI K12

We have constructed a strain of E. coli K12 carrying six mutations induced by the acridine half-mustard ICR-191. The mutations are widely spaced on the E. coli linkage map and are all easily reverted by ICR-191. Mapping of ten independent revertants for each of five markers indicated that the reversions induced by ICR-191 occurred near the original mutations. Exponentially and nonsynchronously growing cultures of this strain were exposed to ICR-191 for 0.85 generation, quickly washed free of mutagen, and resuspended in the original medium minus mutagen. Total viable cell number maintained its exponential increase both during and immediately after exposure to mutagen, whereas the number of revertants of any particular type remained constant for a characteristic period after removal of mutagen before finally assuming an exponential increase. Theoretically, the length of such a segregation lag should depend on the position of the particular reverted gene in the sequence of gene replication: the earlier a gene is replicated in the chromosome replication cycle, the longer its segregation lag should be. Our results are consistent with this prediction and fit a unidirectional, clockwise replication scheme with an origin between 55 and 74 min on the E. coli linkage map. The results also fit a very asymmetric bidirectional replication scheme.