Killing of Haemophilus influenzae cells by integrated ultraviolet-induced lesions from transforming deoxyribonucleic acid.

Abstract

Highly competent cultures of Haemophilus influenzae are inactivated by exposure to transforming deoxyribonucleic acid (DNA) irradiated with ultraviolet light (UV). As a function of UV dose to the DNA, the killing goes to a maximum and then decreases. The killing of H. influenzae by unirradiated H. parainfluenzae DNA, reported by other workers, is enhanced by low doses of UV, but drops off at high doses. Since there are no such lethal effects in a strain of H. influenzae that takes up DNA normally but does not integrate it, it is concluded that the killing is associated with integrated UV lesions. All the killing of wild-type cells due to irradiated DNA is eliminated by photoreactivation of the DNA. The killing of an excisionless strain of H. influenzae, however, is not eliminated by maximal photoreactivation of the irradiated transforming DNA. The nonphotoreactivable fraction of killing in the excisionless strain increases with increasing dose. The kinetics of the killing-dose curves may be explained only partially in terms of UV-induced loss of integration. It is postulated that the number of pyrimidine dimers relative to other DNA components integrated decreases at higher UV doses.