Injection defect in alkylated and depurinated T7 bacteriophage: analysis by DNA ejection.

Using DNA ejection in vitro as a model, we have studied the DNA injection defect caused by alkylation and depurination of T7 bacteriophage. Phage was alkylated with 0.02 M methyl methanesulfonate for 2 h at 37 degrees C; alkylated phage was then incubated 24 h at 30 degrees C to induce depurination. These samples were treated with formamide to cause DNA ejection without dissociation of the phage capsid. After ejection, the phage preparations were analyzed by electron microscopy. DNA lengths in capsid-DNA complexes were measured; relative numbers of full, empty, and partially empty phage heads were determined. To establish the direction of DNA ejection, E. coli RNA polymerase was bound to capsid-DNA complexes. The results showed that DNA was partially ejected from both alkylated and depurinated phages. In the alkylated sample, RNA polymerase was bound to the DNA end distal to the capsid; this showed that ejection started from the genetic left end. We interpret these results to show, in confirmation of earlier results obtained by marker rescue, that alkylation causes T7 phage to partially inject its DNA, starting from the genetic left end. For depurinated phage, our results suggest that partial DNA injection is responsible, in this case as well, for the already documented injection defect.