Intracellular production of Brucella L forms . II. Induction and survival of Brucella abortus L forms in tissue culture

Hatten, Betty A. (The University of Texas Southwestern Medical School, Dallas), and S. Edward Sulkin. Intracellular production of Brucella L forms. II. Induction and survival of Brucella abortus L forms in tissue culture. J. Bacteriol. 91:14-20. 1966.-Intracellular survival of altered brucellae, possibly L forms, was not greatly affected by penicillin or streptomycin in concentrations ranging from 5.0 to 40 mug/ml, but a combination of these two antibiotics (2.5 to 20 mug/ml each) reduced the number of positive L-form cultures. Tetracycline (2.0 mug/ml) decreased the number of positive L-form cultures at about the same rate as combinations of the higher concentrations of penicillin and streptomycin. Various concentrations of tetracycline (0.1 to 2.0 mug/ml) with 5.0 mug/ml of penicillin or streptomycin significantly reduced the number of positive L-form cultures. L forms were recovered for several days after elimination of bacteria from the cultures by all of the antibiotics tested. L-form production was not dependent upon the presence of antibiotics in the culture medium, but they were recovered in greater numbers when bacteria were still present in the hamster kidney cells. Addition of thallium acetate to infected cells (at varying intervals of time after infection) to control bacterial growth and conversion to the L phase during cellular disintegration decreased the number of positive L-form cultures obtained over a 10-day period. Comparison of the antibiotic sensitivity of bacteria recovered from infected tissue culture cells with the stock strain of Brucella abortus indicated that some resistance to penicillin and tetracycline had developed. A marked resistance to streptomycin was observed in those bacteria recovered from cells maintained in the presence of this antibiotic.     

In Vitro Effect of Rifampin on Mycobacteria

Rifampin inhibited 20 strains of Mycobacterium tuberculosis in concentrations of 0.005 to 0.02 mug/ml in 7H-9 broth with Tween 80 and killed all or nearly all of the inoculum in four to eight times greater concentrations. In the same medium without Tween 80, as well as on 7H-10 agar, about 16 to 64 times these amounts were required to produce the same effect. Rifampin was also active against M. kansasii and some of the nonchromogenic mycobacteria. The incidence of mycobacterial cells resistant to rifampin within the cultures studied was in the range of one to four per 10(8) to 10(9) colony-forming units with concentrations of 4 to 125 mug of rifampin per ml. Only one of the Battey cultures and that of M. fortuitum yielded cells resistant to rifampin at 125 mug/ml but not at 500 mug/ml. The same strains yielded more than double that number of organisms resistant to streptomycin and up to 100 times more organisms resistant to isoniazid. All three drugs stopped the growth or reduced the mycobacterial population in growing cultures after contact for 24 to 48 hr. Complete inhibition of growth was produced by rifampin at 1.0 mug/ml in an average of 6 days and by streptomycin at 5.0 mug/ml in 3 days. After an average contact of 10.7 days with rifampin, five of seven strains resumed growth and all strains began regrowth after exposure to streptomycin for 9.4 days. The marked susceptibility of M. tuberculosis and of atypical mycobacteria to rifampin in vitro and the relatively low incidence of resistant mutants suggests that this agent may have clinical usefulness in the treatment of tuberculosis and some other mycobacterioses.     

THE ADAPTATION OF FUNGI TO FUNGICIDES: ADAPTATION TO COPPER AND MERCURY SALTS

The susceptibility of Botrytis cinerea to copper sulphate in liquid media increased when the volume, and therefore the depth, of the medium in culture bottles exceeded certain values; when the volume was 40 ml. the maximum concentration allowing growth was 300 p.p.m.
By growing mycelium in media containing progressively higher concentrations of copper sulphate a strain was produced which grew at a concentration of 750 p.p.m.
In high concentrations of copper sulphate growth always started at the edge of the liquid, and inocula grew only if they were placed in this position.
In germination tests spores from the resistant strain were more resistant to copper sulphate than were spores of the parent strain.
The resistance of mycelium, and to a lesser extent of spores, was retained after growth of the resistant strain for six months in fungicide-free media.
Spore and mycelial inocula grew in much higher concentrations of copper sulphate when nutrient media were solidified with agar.
The strain resistant in liquid media was no more resistant than the parent strain on agar media.
The resistance of the fungus was not increased after growth for long periods on agar containing high concentrations of copper sulphate. The resistance of the strain resistant in liquid media was not lost after growth on agar media for 3 months.
Attempts to produce strains more resistant than the parent to mercuric chloride were unsuccessful.
The results obtained with phenyl-mercuric acetate were essentially similar to those obtained with copper sulphate, but relatively much more resistant strains were produced.     

Vibrion variability under the action of antibiotics]

Tetracycline, streptomycin and monomycin resistant variants of the cholera and NAG-vibrios were obtained by means of repeated passages on nutrient media with increasing concentrations of the antibiotics (114 variants V. cholerae asiaticae, 1337 variants of V. cholerae eltor and 299 variants of NAG-vibrios of the 1st Heiberg group). The highest number of the antibiotic resistant variants was obtained under the effect of streptomycin and the resistance level to it was much higher (up to 8000 gamma/ml) than that to tetracycline or monomycin (160 or 320 gamma/ml respectively). The study of the differential-diagnostic properties of the above vibrios showed that 14.8 per cent of the strains of V. cholerae asiaticae and 4.6 per cent of the strains of V. cholerae eltor became non-typical with respect to the colony morphology and fermentative properties. Their agglutinability with the species or type specific cholera sera partially decreased. Nine per cent out of 299 antibiotic resistant NAG-vibrios had changes only in the colony structure. None of them changed their fermentative properties or acquired even minor capacity for agglutination with cholera sera or lysing with specific bacteriophages. The described changes in the properties of the antibiotic resistant cholera and NAG-vibrios were not stable and disappeared after 2- or 3-fold passages on media containing no antibiotics.     

Rsistance to streptomycin in a producing strain of Streptomyces griseus.

Streptomyces griseus S 104 was sensitive to streptomycin during exponential growth in a medium which, in the subsequent stationary phase, supported production of the antibiotic in yields above 200 mug/ml. When antibiotic production began cultures developed a tolerance toward their lethal metabolite. This was not due to an increase in pH associated with antibiotic production, since pH effects on streptomycin sensitivity in S. griseus were in the reverse direction. However, the degree of tolerance was directly related to the amount of cell material present. Streptomycin production caused no change in the proportion of resistant variants in the population, nor did it cause the severe inhibition of protein synthesis observed in non-producing cultures exposed to the antibiotic. The lack of an effect on protein synthesis is attributed to the absence of streptomycin with in the cytoplasm since soluble extracts from mycelium harvested in the production phase were inactive when bioassayed immediately after cell disruption. However, they developed antibacterial activity rapidly when heated, and more slowly when incubated at 25 degrees C. The addition of phosphatase inhibitors during incubation prevented the appearance of antibiotic activity, and it was concluded that a small amount of streptomycin phosphate is present in the mycelium during antibiotic production. Differences in (14C) streptomycin uptake suggested that the mycelium was appreciably less permeable to the antibiotic in the production phase than during exponential growth. However, a small amount was taken up and much of it was in the soluble fraction of disrupted cells. Bioassays showed that this 14C-labeled antibiotic within the cells had been partially inactivated, suggesting that conversion of streptomycin to an inactive derivative is involved in the mechanism which protects the organism from its metabolite.     

Nitrosomethylurea induced streptomycin resistance in Lycopersicon esculentum Mill

High frequency of streptomycin resistant variants of Lycopersicon esculentum were isolated on selective shoot regeneration medium supplemented with IAA (0.5 mg/L), zeatin (1.5 mg/L) and streptomycin sulphate (500 mg/L). Nonmutagenized (controls) and NMU treated cotyledons were placed on shoot regeneration medium supplemented with antibiotic streptomycin. Resistant shoots appeared at a high frequency in mutagenized cotyledons, whereas in controls morphogenesis was suppressed, accompanied by bleaching. Shoot regeneration occurred from the nodular tissues developed at the cut ends of cotyledons. Resistant shoots developed into complete plantlets on rooting medium containing selective concentration of antibiotic. Stability of streptomycin resistance was confirmed by leaf assay and reciprocal crosses between streptomycin-resistant and sensitive plants.     

Characterization of a respiratory mutant of Escherichia coli with reduced uptake of aminoglycoside antibiotics

A strain of Escherichia coli (NSW77) which is partially resistant to streptomycin was isolated by selecting for growth on plates supplemented with 12.5 μg/ml streptomycin, a concentration which completely inhibits growth of wild-type strains. The low-level resistance of the mutant appears to result from a reduced ability to accumulate streptomycin intracellularly. In addition, the mutant strain is unable to use succinate for growth because of a defective respiratory chain. Thus, membranes of the mutant strain were found to have approximately half the NADH and D-lactate oxidase activity of the parent strain. Succinate oxidase activity was reduced more drastically, to a level of 7% that of the parent strain. Moreover, membranes of the mutant were found to contain demethyl-menaquinone and, in place of ubiquinone, a structural analogue, 2-octaprenyl-3-methyl-6-methoxy-1,4 benzoquinone. The mutation responsible for both the Suc⁻ phenotype and partial resistance to streptomycin was found to be located near minute 15 on the bacterial chromosome. Both the biochemical and genetic evidence suggests that the mutation in strain NSW77 resides in the ubi F gene. Another previously characterized ubi F strain was also found to have a reduced capacity to take up an aminoglycoside antibiotic (gentamicin). These results suggest that the respiratory defects in ubi F strains are responsible for the reduced capacity of such strains to accumulate aminoglycosides.     

[3H] dihydrostreptomycin accumulation and binding to ribosomes in Rhizobium mutants with different levels of streptomycin resistance.

Rhizobium trifolii B1, a symbiotic nitrogen fixer, is sensitive to streptomycin (10 microgram/ml) and spontaneously produces spheroplast-like forms during cultivation. Streptomycin-resistant mutants selected with high doses of antibiotic (1,000 microgram/ml) showed pleiotropic changes, including loss of spheroplast formation and infectivity to plants, whereas mutants selected with low doses of streptomycin (10 to 100 microgram/ml) retained properties of parent strain B1 (I. Zelazna-Kowalska, Acta Microbiol. Pol., in press). The present studies revealed that strain B1 and its mutant with a high level of streptomycin resistance, B1 strH, accumulated the antibiotic at similar rates. Mutant B1 strL, with a low level of streptomycin resistance (up to 100 microgram/ml), accumulated the antibiotic at a lower rate. Ribosomes isolated from strains B1 and B2 strL bound [3H]dihydrostreptomycin, whereas those from strain B1 strH did not. These observations indicate that, in R. trifolii B1, mutation to a high level of streptomycin resistance affects ribosomal structure, whereas low-level resistance involves a change in membrane permeability.     

Transformability of Streptomycin-resistant Group H Streptococci

Several resistant mutants of a transformable group H streptococcus, strain Challis, were isolated from media containing high concentrations of streptomycin. Mutants SR5a and SR5 exhibited high and low transformability, respectively, when exposed to deoxyribonucleic acid (DNA) from a novobiocin-resistant Challis strain. With similar exposure, mutant SR30 exhibited loss of transformability. The mutants further differed from the parent strain in time of appearance of optimal competence, and, in the case of SR5 and SR30, total growth was somewhat less than that of the parent. The rapidity with which transformants appeared upon initial exposure to DNA was approximately the same in the mutants and the parent strain. The decrease or loss of transformability of mutants SR5 and SR30 was found to be due to an alteration in capacity to take up DNA. Mutant SR5a (highly transformable) was further differentiated from mutants SR5 and SR30 in that it was somewhat more sensitive to high concentrations of streptomycin. Transformants obtained by treating strain Challis with the three types of mutant DNA, on the other hand, exhibited similar degrees of resistance to increasing concentrations of streptomycin. The additional decrease in transforming ability of mutant SR5a and the loss of transforming ability of mutant SR5 after a second exposure to streptomycin may indicate a stepwise process in the change from transformability to nontransformability. Although streptomycin resistance may not be directly related to inability to transform, results indicate that streptomycin greatly increases the chances of selecting these mutants and also can be of value in serving as a marker in studies of this nature.     

Suppressive Activity of Streptomycin on the Growth of Mycobacterium lepraemurium in Macrophage Cultures

The effect of streptomycin on the growth of an obligate intracellular bacterium was studied in a new host-parasite cell system. The system consisted of Mycobacterium lepraemurium grown in cultures of mouse peritoneal macrophages. Since these organisms do not grow in bacteriological media, the influence of extracellular bacterial growth can be ruled out. The suppressive activity of streptomycin was observed in a total of five experiments. At the end of 4 weeks, the average number of organisms per macrophage for the controls was 65.7; for cultures with streptomycin at concentrations of 0.5, 1, 5, 10, 50, and 100 mug/ml of medium, it was 45.4, 38.3, 28.7, 22.7, 13.4, and 8.2, respectively. A good dose-response relationship was evident. M. lepraemurium which had been treated in macrophage cultures with various concentrations of the antibiotic for 6 to 8 weeks was used to infect fresh macrophages. These cultures were in turn treated with streptomycin. Resistance of the organisms to streptomycin did not occur.     

Nuclear-Transfer Studies on Induced Increases in Streptomycin Resistance of Amoeba proteus

SYNOPSIS. The responses of a strain of Amoeba proteus to conditions which could give rise to induced increases in resistance to streptomycin have been investigated. An indirect selection method, based on survival time in high concentrations of streptomycin, was devised. All attempts to obtain substrains with enhanced sensitivity or enhanced resistance by indirect methods were unsuccessful. It was therefore concluded that increases in resistance observed as a result of other treatments were likely to be the result of adaptation of a majority of individuals, rather than selection of pre-existing resistant variants. Direct treatment with regularly increased concentrations of streptomycin led to a 10-fold increase in resistance of large cultures. Nuclear transfers were made by the de Fonbrune technique to produce resistant nucleus/normal cytoplasm, and normal cytoplasm/resistant nucleus combinations. Examination of the descendants of these 'crosses' showed that the resistance was nuclear dependent and not influenced by the cytoplasm. The resistance proved transitory, disappearing slowly during continued culture without further contact with streptomycin.
These results are discussed with reference to possible mechanisms responsible for the increase in streptomycin resistance and its mode of origin.     

Resistance of Pseudomonas to Quaternary Ammonium Compounds: II. Cross-Resistance Characteristics of a Mutant of Pseudomonas aeruginosa

Tube dilution experiments showed that benzalkonium chloride (BC)-resistant mutants of Pseudomonas aeruginosa grown in the presence of 1,000 mug of BC per ml were at least 20 times more sensitive to polymyxin B and colistin sulfate than the BC-sensitive (BCS) parent strain. BCS cells selected for resistance to 500 mug of polymyxin B per ml remained sensitive to BC. There was little difference in the amount of carbenicillin, gentamicin sulfate, or rifampin needed to prevent growth of either the BCS or BC-resistant (BCR) strains. Growth of BCR cells was inhibited by ethylenediaminetetraacetate at a concentration of 400 mug/ml or less, whereas the BCS strain grew at ethylenediaminetetraacetate levels of 10,000 mug/ml. Phenylmercuric acetate and thimerosal inhibited growth of BCR and BCS cells at concentrations of 10 mug/ml or less. BCR cells were cross-resistant to >1,000 mug/ml concentrations of five other quaternary ammonium compounds, including three with C(16) alkyls and two with alkyl groups of shorter length. The BCS strain was also resistant to >1,000 mug/ml concentrations of the three quaternary ammonium compounds with C(16) alkyl groups but, in addition to BC, was inhibited by 200 mug/ml levels or less of the two quaternary ammonium compounds containing alkyl groups of less than 16 carbon atoms.     

The effects of bovine serum albumin, bovine uterine fluid, and heat-treated bovine serum on in vitro mouse embryo development

Two-cell mouse embryos were cultured in Whitten's medium with one of three supplements: bovine serum albumin (WM + BSA), heat-treated bovine serum (WM + HTBS) or bovine uterine fluid (WM + BUF). Protein concentrations for cultures of WM + BSA were 50.2, 100.5, 251.2, 502.5, and 1005.0 mug/ml and for WM + HTBS were 70.4, 105.1, 269.0, 524.5 and 1193.9 mug/ml. Protein concentrations ranged from 56.9 to 739.1 mug/ml for 22 WM + BUF samples. Embryo development in all media was significantly correlated with the log total protein concentration. When compared to WM + BSA, development was not significantly inhibited or stimulated in any WM + BUF cultures or in WM with 70.4, 524.5 and 1193.9 mug/ml HTBS. Development was enhanced in WM with 105.1 and 269.0 mug/ml HTBS (P<0.05). The results suggest that at the protein concentrations used, culture media supplemented with BUF and BSA support similar mouse embryo development. Culture medium supplemented with HTBS supported embryo development more than medium with BSA. Uterine factors in the bovine capable of enhancing or inhibiting early embryo development were not detected.     

Diverse responses of Staphylococcus aureus NCTC 10442 and some of its variants to methicillin.

The methicillin resistant strain of Staphylococcus aureus NCTC 10442 when aged in a broth culture at 42 degrees C yielded variants showing responses of sensitivity, dependence and indifference to the antibiotic. These responses and that of resistance in the parent cells were displayed in agar dilution and agar diffusion experiments at 30 degrees C. At 42 degrees C, all four organisms were sensitive to methicillin.     

Susceptibility of Salmonellae to Cephalosporins and to Nine Other Antimicrobial Agents

Three cephalosporin-related antibiotics and nine other antimicrobial agents were studied for in vitro effectiveness against 54 recently isolated strains of Salmonella. Minimal inhibitory concentrations determined by the plate dilution method demonstrated the following percentages of resistance: ampicillin, 6%; tetracycline, 13%; streptomycin, 52%; sulfadiazine, 94%; cephaloglycin, 96%; and lincomycin, 100%. No strains were resistant to cephalothin, cephaloridine, chloramphenicol, colistimethate, kanamycin, and polymyxin B. The commonest serotype studied, S. typhimurium, showed the greatest antibiotic resistance, with 21% resistant to ampicillin, 36% resistant to tetracycline, and 71% resistant to streptomycin. Cephalothin and cephaloridine were highly effective in vitro but inhibitory concentrations of 20 to 40 mug of cephaloglycin per ml were required for the majority of Salmonella strains.     

Strategies for adaptation to antibiotics in wild type <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> and in the strains with small colony phenotype

Emergence of ciprofloxacin stress-induced mutants in the cultures of a collection strain Pseudomonas aeruginosa ATCC 27853 and of two strains with a small colony phenotype, which were isolated from a swimming pool biofilm, was studied. In biofilm cultures of the small colony phenotype strains, which were already resistant to hypochlorite, prolonged incubation (up to 16 days) with sublethal ciprofloxacin concentrations was shown to result in emergence of the cells, which are resistant to the antibiotic and form colonies on media with rifampicin (100 μg/mL) and streptomycin (50 μg/mL). Under the same conditions, the mechanisms of temporary adaptation are switched on in the cells of strain ATCC 27853, which enabled its shortterm survival at an average level in liquid media and provided for colony formation on solid medium with ciprofloxacin (0.2 μg/mL). Only 20% of these colonies remained viable when transferred to a higher antibiotic concentration (2 μg/mL).     

Resistance system of Mycobacterium bovis B.C.B. to aminoglycoside- and peptide-antibiotics. Comparison of resistant phenotypes between Mycobacterium tuberculosis and Mycobacterium bovis

The resistance system of Mycobacterium bovis (B.C.G.) to aminoglycoside-and peptide-antibiotics has been studied. The phenotype of mutants isolated from the parent B.C.G. strain by a single-step selection with an antibiotic were classified into the following three types: (1) resistant only to a low concentration (200 μg/ml) of kanamycin in Ogawa egg medium (k1R); (2) resistant to a low concentration (200 μg/ml) of viomycin and of capreomycin (2R); and (3) resistant to a high concentration (1,000 μg/ml or more) of kanamycin and low concentrations (100 to 200 μg/ml) of lividomycin and of paromomycin (KR). The mutants showing these phenotypes, k1R, 2R, and KR, were isolated from the parent strain by inoculating the strain into media containing 100 μg/ml of kanamycin, and 100 μ/g/ml of viomycin or capreomycin, and 1,000 μg/ml of kanamycin, respectively, at rates of 10^?5-10^?6, 10^?5-10^?6, and 10^?6-10^?7, respectively, in a total viable population of the parent strain. Unlike in the case of M. tuberculosis, no mutant could be isolated from the parent strain by use of enviomycin, lividomycin, and/or paromomycin. In contrast to the fact that quadruply resistant mutants were isolated directly from the parent H37Rv strain of M. tuberculosis, such mutants could be isolated only by two-step selections. Furthermore, the phenotypes of the quadruply resistant mutants were those showing a higher resistance or a broader spectrum than expected by the addition of phenotypes of individual mutations. In addition, it was shown that, in contrast to the fact that hextuply resistant mutants could be isolated directly from the parent strain of M. tuberculosis, such mutants were not isolated directly from the parent B.C.G. strain, but could be isolated only after pre-incubation of the strain on a medium containing Tween 80.     

Corrected Version Distribution of Heterogeneous and Homologous Plasmids in Bacillus spp

A total of 75 strains (including 5 reference strains) of Bacillus amyloliquefaciens, B. cereus, B. circulans, B. licheniformis, B. megaterium, B. pumilus, B. sphaericus, B. subtilis, and B. thuringiensis and 36 species-unidentified Bacillus strains were surveyed for plasmids by cesium chloride-ethidium bromide equilibrium centrifugation of cell lysates in a study of antibiotic resistance in host cells. Of the 111 strains, 13 (including 3 reference strains) were found to harbor plasmids, and 5 of the 13 showed antibiotic resistance. This antibiotic resistance appeared not to be due to the plasmids, however, because the trait was not cured by cultivation of cells in nutrient medium containing ethidium bromide (1 mug/ml), sodium dodecyl sulfate (0.2 mug/ml), or novobiocin (1 mug/ml), except in one strain, in which kanamycin and streptomycin resistances were cured by novobiocin. One strain of B. amyloliquefaciens, S294, was found to harbor a plasmid, pFTB14, which differed from the plasmid species of classes 1 to 6 in B. subtilis and B. amyloliquefaciens, as determined by restriction analysis and DNA contour length determination. However, in DNA-DNA hybridization on a filter after Southern blotting from an agarose gel, the pFTB14 DNA hybridized with plasmids of classes 1 to 5. Three strains of B. thuringiensis each carried at least 4 to 11 plasmid species, whereas no plasmids were detected in four strains of B. cereus, which, in relation to B. thuringiensis, is closely related taxonomically and has highly homologous DNA sequences. The plasmid DNAs prepared from species other than B. subtilis and B. amyloliquefaciens did not hybridize with that of pFTB14.     

THE ADAPTATION OF FUNGI TO FUNGICIDES: ADAPTATION TO THIRAM, ZIRAM, FERBAM, NABAM AND ZINEB

The concentrations of thiram preventing germination of spores of Botrytis cinerea in drops of a 1% solution of sucrose, and on the surface of a sucrose-nitrate agar have been determined. Thiram had much less effect on germination in the agar medium, even when a purified agar was used. There was no growth on sucrose-nitrate agar if the concentration of thiram exceeded 31 p.p.m. Attempts to obtain strains able to grow at higher concentrations were unsuccessful.
Similar results were obtained with ziram, nabam and zineb.
Ferbam also was more effective in preventing spore germination in spore drops than on agar media; this effect was obtained with ordinary and with purified agar.
On a sucrose-nitrate agar generally there was no growth if the concentration of ferbam exceeded 125 p.p.m., but in one of forty-eight plates containing 250 p.p.m. ferbam, five slowly growing colonies were produced, and from these colonies arose mycelium which grew and sporulated rapidly on 500 p.p.m. ferbam agar. Agar disk inocula were transferred from these cultures to agar containing higher concentrations of ferbam and in this way, and by repeating the process, a strain was obtained which grew slowly but continuously, and sporulated on agar containing 5000 p.p.m. ferbam. However, the poor solubility of this fungicide made it difficult to assess quantitatively the degree of adaptation.
A proportion of the spores from this strain germinated in drops containing about twice the concentration of ferbam which prevented germination of parent spores.
The resistance of the mycelium of the resistant strain was not lost after repeated subculture on fungicide-free agar. The resistant strain was as susceptible as the parent strain to thiram, ziram, nabam and zineb.
Attempts to obtain strains of Venturia inaequalis resistant to thiram, ferbam, ziram and zineb were unsuccessful.     

Induction of Cycloheximide-Resistant Mutants in Saccharomyces cerevisiae with N-Methyl-N′-Nitro-N-Nitrosoguanidine and ICR-170

N-Methyl-N'-nitro-N-nitrosoguanidine (MNNG) induces cycloheximide-resistant mutations in Saccharomyces cerevisiae, but few, if any, resistant mutants are induced by the acridine mustard ICR-170. Cycloheximide sensitivity in yeast is associated with the ribosome, and treatment with the antibiotic at concentrations of 2 mug/ml results in complete inhibition of protein synthesis. Missense mutations induced by MNNG probably lead to the loss of cycloheximide binding sites on the ribosome, resulting in resistance to the antibiotic without altering the activity of the organelle in protein synthesis. ICR-170, however, induced primarily frameshift mutations that would alter ribosome structural integrity, resulting in cell death rather than resistance. ICR-170 and MNNG are both mutagenic in a system in which base-pair substitution and frameshift mutations can be detected. These results indicate that cycloheximide resistance in S. cerevisiae, like streptomycin and spectinomycin resistance in Escherichia coli, can be induced by base-pair substitution mutagens but not by frameshift mutagens such as ICR-170.