The genetics of low-level resistance to penicillin and other antibiotics in a clinical isolate and a multistep laboratory mutant of Neisseria gonorrhoeae was studied by transformation. Mutations at three loci affected sensitivity to penicillin. Mutation atpenA resulted in an eightfold increase in resistance to penicillin without affecting response to other antimicrobial agents. Mutation at ery resulted in a twoto fourfold increase in resistance to penicillin and similar increases in resistance to many other antibiotics, dyes, and detergents. Mutation at penB resulted in a fourfold increase in resistance to penicillin and tetracycline, the phenotypic expression of which was dependent on the presence of mutation at ery. The cumulative effect of mutations at penA, ery, and penB was an approximate 128-fold increase in penicillin resistance, to a minimum inhibitory concentration of 1.0 ,ug/ml. Low-level resistance to tetracycline or chloramphenicol was due to similar additive effects between mutations at the nonspecific ery and penB loci and a locus specific for resistance to each drug (tet and chl, respectively). No evidence was found for penicillinases or other druginactivating enzymes.We previously presented evidence that lowlevel resistance ofNeisseria gonorrhoeae to penicillin (Pen), tetracycline (Tet), chloramphenicol (Chl), and erythromycin (Ery) was determined by separate loci, designated penA, tet, chl, and ery, respectively (29). Introduction of these loci by transforming deoxyribonucleic acid (DNA) individually into a wild-type (sensitive) recipient resulted in phenotypic levels of resistance considerably less than exhibited by the multiply antibiotic-resistant donor strains, however (29). In contrast, introduction of loci for high-level resistance to rifampin (Rif), streptomycin (Str), or spectinomycin resulted in phenotypic resistance in the transformants equal to the donor's (29). These observations suggested that the genetic control of low-level resistance to Pen and other drugs was complex, either due to additive effects between the known loci or existence of other undescribed loci.In this communication, we have utilized genetic transformation to show that low-level resistance to each of Pen, Tet, and Chl is acquired in small increments as the result of additive effects between mutations at several previously described loci and a new locus, designated penB. Both ery and penB are shown to result in low-level cross-resistance between unrelated drugs. Evidence is also presented that pheno-74C typic expression of mutation at penB depends on the presence of mutation at ery.MATERIALS AND METHODS Bacterial strains. Bacterial strains are listed in Table 1. Several have been described previously (16,17,29). Strain FA19 is strain Ceylon 3 from the collection of A. Reyn. Strain FA48 is a two-step mutant from FA19, initially selected for high-level Str resistance, and subsequently for Pen resistance, as described (17). Strain FA5 was a clinical isolate from a patient in Los Angeles, obtained as strain P955 from th...
