PENICILLIN RESISTANCE OF COMPETENT CELLS IN DEOXYRIBONUCLEIC ACID TRANSFORMATION OF BACILLUS SUBTILIS
AUTOR(ES)
Nester, E. W.
RESUMO
Nester, E. W. (University of Washington, Seattle). Penicillin resistance of competent cells in deoxyribonucleic acid transformation of Bacillus subtilis. J. Bacteriol. 87:867–875. 1964.—Transformants are resistant to penicillin killing for several hours after deoxyribonucleic acid (DNA) addition. The present study indicates that this resistance is a consequence of such cells still remaining competent and is not the result of any interaction of donor DNA with the recipient cell. The following data support this conclusion: (i) the frequency of transformation can be increased five- to tenfold if penicillin acts on a competent culture prior to DNA addition; (ii) the percentage of competent cells in such a penicillin-treated culture calculated on the basis of a random coincidence of DNA molecules entering the same cell increases some 25-fold over that of a penicillin-nontreated population; (iii) the kinetics of penicillin killing of a recipient culture are identical whether or not transforming DNA has been added; (iv) the extent of killing by penicillin is related to the level of competence of the recipient culture; and (v) the kinetics of appearance and disappearance of competence in a population as well as in individual cells indicate that a cell may remain competent for 3 to 4 hr.
ACESSO AO ARTIGO
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