Inactivation and mutagenesis of lambda phage by O-methylhydroxylamine and O-delta-aminooxybutylhydroxylamine

The inactivation and the mutagenesis of lambda phage Cl 857 virR by O-methylhydroxylamine (OMHA) and O-delta-aminooxybuthylhydroxylamine (delta-HA) were studied. The inactivation of OMHA-treated phage was shown to be stronger in E. coli polA cells defective in DNA-polymerase I as compared to wild-type host E. coli W3350. In contrast delta-HA caused similar phage inactivation in these two strains. Wave-type kinetics of the inactivation and the mutagenesis of phage by OMHA and delta-HA was observed. delta-HA appeared to be a more effective mutagen than OMHA: it induced higher mutant yield at a given level of inactivation.     

Mutagenic action of O-methlhydroxylamide on transforming DNA

The mutagenic effect of O-methylhydroxylamine (OMHA) on transforming DNA of Bacillus subtilis was studied. In accordance with the earlier reported chemical and functional data, the mutagenic effect was observed at 4.5 and 6.0 pH. An increase in pH caused a decrease in the rate of mutagenesis, though the maximal level of mutagenesis was equal at both values of pH. The results obtained with recipients defective in the system of UV-repair revealed that both products of reaction of OMHA with the cytosine-base of DNA, N4-metoxycytidine and N4-metoxy-6-metoxyamino-5,6-dihydrocytidine, are effectively eliminated through the system of UV repair.     

The mechanism of the mutagenic action of hydroxylamine XIII. Reversion of phage MS2 amber mutants in the presence of hydroxylamines.

The replication of the phage MS2 in the presence of either hydroxylamine (HA) or O-methylhydroxylamine (OMHA) (mutagenesis in vivo) results in an increase in the reversion frequency of two amber mutations in the maturation protein. When acting on the extracellular phage (mutagenesis in vitro) the mutagens do not affect the reversion frequency. The most probable mode of mutagenic action of the hydroxylamines on the vegetative MS2 phage involves the enzymic formation of modified precursors and their incorporation into RNA.     

The secondary structure of bacteriophage DNA in situ. VIII. The reaction of sodium bisulphite with intraphage cytosine as a probe for studying the DNA-protein interaction

To obtain data on the viral nucleoprotein a study has been made of the reaction of sodium bisulphite with cytosine in the intraphage DNA of the phage Sd. The CHlO4 hydrolysates of the bisulphite-modified phage Sd have demonstrated a decrease of 18% in the cytosine content and the presence of the products with the properties of cytosyl-amino acids (the main amino acid responsible for the DNA-protein interaction involving cytosine is lysine). But when prior to hydrolysis the modified phage was disintegrated under mild conditions in 0.1--1 M NaCl solution or Tris-HCl buffer (pH 7), neither the decrease in the cytosine content nor cytosyl-amino acids have been found. An exception is the heating of the phage at 70 degrees C in a medium containing 0.05 M phosphate buffer (pH 7.9--8.5), when an 18% decrease in the cytosine content and subsequent appearance of cytosyl-amino acids have also been observed. The presence of cytosyl-amino acids which are the nucleotide-protein cross-links is confirmed by the results of viscometry, equilibrium centrifugation in cesium sulphate gradient and determinations of the survival percentage. It is suggested that the reaction between bisulphite and cytosine in the phage Sd stops at the stage of the intermediate product C5-C6-dihydro-C6-sulphopyrimidine whose amino group is shielded by interaction with protein (product VII). This product can exist only under in situ conditions: with disintegration of nucleoprotein (destruction of phage particles or ejection of the DNA) in phosphate-free media the product VII reverts into the initial cytosine. Under the conditions of acid hydrolysis or destruction of phage in the presence of phosphate ions product VII undergoes transamination with cleavage of SO3 and restoration of the C5-C6 double bond producing cytosyl-amino acids. The factors determining the stability of the product VII are discussed.     

Mutagenic effect of o-methylhydroxylamine on the prophage and extracellular phage lambda

Induction of c-mutations in extracellular bacteriophage and prophage lambda cI857 ind-treated with 1 M O-methylhydroxylamine (OMHA) at 32 degrees and pH 5.6 has been studied. The frequency of c-mutations increases proportionally to the time of treatment of extracellular phage and does not depend on cellular recA+ or polA+ functions and on induction of SOS-repair system caused by UV-irradiation of host cells. Prophage is inactivated and mutagenized approximately 10-fold faster than extracellular phage immediately after treatment of lysogenic cells during prophage induction. Thus, prophage survival does not depend on repair functions of the host cells, and the frequency of c-mutations in recA and, especially, in polA lysogens is significantly lower, than in the wild-type cells.Delayed thermoinduction (90 min) of prophage causes significant enhancement of survival and decreases the frequency of c-mutations in all strains studied. Preliminary treatment of non-lysogens with OMHA does not increase the frequency of c-mutations in undamaged phage or in phage treated with OMHA in vitro.     

The action of mutagens on MS2 phage and on its infective RNA. V. Kinetics of the chemical and functional changes of the genome under hydroxylamine treatment

The kinetics of chemical and functional changes induced in the genome of bacteriophage MS2 by hydroxylamine under the conditions of predominant modification of either cytidine (pH 5.0) or uridine (pH 8.0) have been studied.Comparison of the kinetics of chemical modifications of monomeric nucleotides with those of bacteriophage inactivation at pH 8.0 and 5.0 made it possible to estimate the effective number of exposed cytidine and uridine residues in the intra-phage RNA (B_eff^c and B_eff^u). The B_eff^u was close to that expected and increased from 70 to 130 as the temperature rose from 0 to 30°. The B_eff^c was much greater than that expected on the basis of the results with the monomer, suggesting that side reactions are involved in the inactivation of the phage at pH 5.0.A significant increase of the frequency of mutation occurs only under the conditions of predominant modification of cytidine (pH 5.0) at 0°. No such effect was observed at 30°. This was probably due to the increased contribution of inactivating side reactions. The effect of hydroxylamine on the phage under the conditions of predominant uridine modification (pH 8.0) did not lead to an increase in frequency of mutants.Incubation of the intact phage in acetate buffer resulted in considerable inactivation and mutations. Inactivation was inhibited by magnesium ions. Incubation at pH 5.5, of the phage inactivated by hydroxylamine treatment at pH 8.0, resulted in a considerable increase of the inefectivity with no effect on the frequency of mutants. The infectivity and the mutation frequency of the phage treated with hydroxylamine at pH 5.0 did not change as a result of incubation at pH 4.0 after the removal of the reagent.     

Co-operative mutagenic actions of bisulfite and nitrogen nucleophiles.

The combined effect of bisulfite and a nitrogen nucleophile, i.e. semicarbazide, methoxyamine or hydroxylamine, to chemically modify cytosine and to cause mutation and inactivation of bacteriophage lambda was investigated. A rapid transamination of cytidine with each of the amines took place in the presence of bisulfite, and the reaction product was solely the N(4)-transaminated 5,6-dihydrocytidine-6-sulfonate. Modifications of cytidine with bisulfite alone and with the nitrogen nucleophile alone were much slower reactions than those using a combination of bisulfite and the nucleophile. Whereas the product of the modification with the bisulfite/semicarbazide, 5,6-dihydro-4-semicarbazido-2-ketopyrimidine ribofuranoside-6-sulfonate, is convertible to 4-semicarbazido-2-ketopyrimidine ribofuranoside by treatment with a phosphate buffer, the products of the modification with the bisulfite/methoxyamine and with the bisulfite/hydroxylamine, i.e. 4-methoxy-5,6-dihydrocytidine-6-sulfonate and 4-hydroxy-5,6-dihydrocytidine-6-sulfonate, were stable in phosphate buffer.Inactivation and the “clear” mutation of bacteriophage lambda were observed when the phage was treated with sodium bisulfite in the presence of semicarbazide, methoxyamine or hydroxylamine. Under the conditions used, only very small increases in the mutation frequency were obtained by treatment of the phage with bisulfite alone or with the base alone. It was concluded that the residues, 5,6-dihydro-4-semicarbazido-2-ketopyrimidine-6-sulfonate, 4-methoxy-5, 6-dihydrocytosine-6-sulfonate and 4-hydroxy-5,6-dihydrocytosine-6-sulfonate in DNA are the causes of the mutation.When phage that had been inactivated by the semicarbazide/bisulfite reagent was subsequently treated with a phosphate buffer, a reactivation took place. The rate of the reactivation increased as the concentration of phosphate in the buffer increased. This reactivation was not accompanied by change in the mutation frequency. No reactivation was observed after a similar incubation when the prior inactivation had been induced by either methoxyamine/bisulfite or hydroxylamine/bisulfite. These results indicate that the 4-semicarbazido-2-ketopyrimidine residue is also mutagenic but is less lethal than the corresponding 5,6-dihydro-6-sulfonate structure.These results offer the first clear example of the co-operative mutagenic action of two different reagents.     

Chemical induction of streptomycin-resistant mutations in Escherichia coli. Dose and mutagenic effects of dichlorvos and methyl methanesulfonate

A procedure for the quantitative determination of induced streptomycin-resistant mutants in E. coli was applied to study and compare mutation induction by the organophosphate dichlorvos and by methyl methanesulfonate (MMS). Both compounds increased the frequency of mutants even under conditions where no inactivation of cell was observed. Mutation induction by these agents as a function of both concentration and exposure time was measured. The dose-response curves found with both mutagens were non-linear; atp higher doses more mutants were induced per unit dose than at lower doses. Possible relationships between dose-effect curves and the chemical nature of alkylating mutagenic agents are discussed.     

The mechanism of the mutagenic action of hydroxylamine XII. Phenotypic suppression of amber mutants of phage T7 by hydroxylamine and O-methylhydroxylamine.

The reproduction of phage T7 in the presence of hydroxylamine (HA) (mutagenesis in vivo) results in the phenotypic suppression of some amber mutants. The presence of O-methylhydroxylamine (OMHA) results in a similar effect, indicating a similar mechanism for the action of the two compounds. Since the rate of reaction of mutagen with nucleoside residues under these conditions in negligibly low, one of the most plausible explanations of this effect is the enzymic formation of modified precursors and their incorporation into bacterial tRNAs or phage-induced RNA.     

Charged-particle mutagenesis. 1. Cytotoxic and mutagenic effects of high-LET charged iron particles on human skin fibroblasts.

Cytotoxic and mutagenic effects of high-LET charged iron (56Fe) particles were measured quantitatively using primary cultures of human skin fibroblasts. Argon and lanthanum particles and gamma rays were used in comparative studies. The span of LETs selected was from 150 keV/microns (330 MeV/u) to 920 keV/microns (600 MeV/u). Mutations were scored at the hypoxanthine guanine phosphoribosyl transferase (HPRT) locus using 6-thio-guanine (6-TG) for selection. Exposure to these high-LET charged particles resulted in exponential survival curves. Mutation induction, however, was fitted by the linear model. The relative biological effectiveness (RBE) for cell killing ranged from 3.7 to 1.3, while that for mutation induction ranged from 5.7 to 0.5. Both the RBE for cell killing and the RBE for mutagenesis decreased with increasing LET over the range of 1.50 to 920 keV/microns. The inactivation cross section (sigma i) and the action cross section for mutation induction (sigma m) ranged from 32.9 to 92.0 microns2 and 1.45 to 5.56 X 10(-3) microns2; the maximum values were obtained by 56Fe with an LET of 200 keV/microns. The mutagenicity (sigma m/sigma i) ranged from 2.05 to 7.99 X 10(-5) with an inverse relationship to LET.     

Mutagenic effect of 1.1'-hexamethylene-bis-[(5-p-chlorophenyl)-biguanide].

The strongly effective bactericidal compound 1.1'-hexamethylene-bis-[(5-p-chlorophenyl)-biguanide] (HCG) induces mutations with a slight inactivation rate in the auxotrophic strains Salmonella typhimurium TA 1535 and TA 1538 in 0.4 microM solution. The mutagenic effect could be confirmed by using the plate incorporation test and the repair test. As phenylethylbiguanide at different inactivation rates does not show any mutagenic effect, the biguanide structure does not seem to be responsible for chemical mutagenesis. A hypothetic mutation mechanism is proposed and compared with the corresponding reaction mechanism of N-methyl-N'-nitro-N-nitro-soguanidine (MNNG).     

Some peculiarities of phage DDVI-specific methylases]

The types of methylases are found in the cellular extract of Escherichia coli B, infected with phage DDVI. One of them is a cellular enzyme, which methylates adenine to form 6-methylaminopurine (6-MAP) and is repressed in the infected cell in vivo. The second type, which is not found in the non-infected cells, is specific for phage DDVI and induces the formation of 7-methylguanine (7-MG). Both enzymes recognize various sites, which accounts for the ratio 6-MAP/7-MG to vary in heterological DNAs between 2.07 in phage Sd DNA and 0.40 in phage DDII DNA. During in vitro incubation with homologous methylases phage DDVI DNA and especially phage T2 DNA are subjected to further methylation, which is probably indicative of their "undermethylation" in vivo. The DDVI-specific enzyme, similar to B-specific type, methylates DNA with a normal set of nitrogenous bases (phages Sd and DDII), as well as DNAs containing 5-oxymethylcytosine and glucose (phages T2 and DDVI). Both methylases under study use only native double-helical DNA as substrate and are strongly inhibited by S-adenosylhomocysteine. Phage DDVI Methylase is characterized by low stability.     

Inactivation and mutation of coliphage T4 by aliphatic nitrosamides and methanesulphonates: in vitro recovery of infectivity of T4 inactivated by isopropyl methanesulphonate.

The inactivation and mutation (to r phenotype) of extracellular coliphage T4 wild-type by the monofunctional alkylating agents N-methyl- and N-ethyl-N-nitrosourea and isopropyl methanesulphonate were investigated. The rate and extent of change in phage infectivity observed during the post-treatment period were found to correlate with what is known of the mechanisms by which these agents react in vitro. Loss of phage infectivity was found to occur during the period following treatment with these agents, but that resulting from treatment with isopropyl methanesulphonate was preceded, in the first 24 to 48 h, by a recovery of infectivity. This suggested that changes in phage infectivity occurring after treatment with monofunctional alkylating agents are resultant of various processes which diversely promote loss and recovery of infectivity. The mutagenicity of N-methyl-N-nitrosourea was similar to that of its ethyl homologue at a level of phage survival of 4 x 10-3, but less than that of isopropyl methanesulphonate. At a level of survival of 3 x 10-2 ethyl methanesulphonate was a mutagenic as its isopropyl homologue, but methyl methanesulphonate was only slightly if at all mutagenic. These results could not be correlated with the compounds' reaction mechanisms. The efficiency of isopropyl methanesulphonate (compared with its toxicity to phage) was found to decrease as the severity of the dose was increased.     

Comparison of the inactivation of IgM and IgG complement fixation sites by acid and base.

Rabbit IgM antibodies to denatured mammalian or T6 bacteriophage DNA or poly(A)-poly(U) irreversibly lost complement-(C) fixation reactivity on exposure to low pH and reneutralization, with a halving of the complement-fixation titer occurring after treatment at about pH 3. The titers of IgG antibodies to denatured phage DNA, to poly(A)-poly(U), or to hemocyanin were halved only after exposure to pH 2. Inactivation by acid was enhanced by low protein concentrations, incubation at higher temperatures, and by slow reneutralization; under all these conditions it was more extensive with IgM than with IgG. Inactivation of IgM C-fixation activity at pH 2.5 and room temperature was a first order reaction, with a half-time of about 20 min. Both classes retained antigen-binding activity after exposure to pH 2. In the alkaline range, full C-fixation reactivity was retained by both classes after reneutralization from pH 11.5, some loss occurred at pH 12, and total irreversible inactivation occurred by pH 12.5. In the latter case, antigen-binding activity was also lost. The C-fixation inactivation curves in the alkaline range were similar for IgG and IgM antibodies.     

Metal-induced lethality and mutagenesis: possible role of apurinic intermediates

The possible mechanisms by which various metals exert their mutagenic effects were investigated using both chemical and biochemical techniques. Ions of Cu, Ni and Cr enhanced the release of either adenine [Cu(II) and Ni(II)] or guanine [Cr(VI)] from DNA as measured in a chromatography assay, suggesting the possible importance of depurination in metal-induced mutagenesis. Transfection experiments with single-stranded bacteriophage phi X174 DNA indicated that micromolar levels of Cu(II), Cr(III), Cr(VI) and Pt(IV) are capable of causing extensive lethal damage to the phage DNA. In case of Cu(II) and Pt(IV) this damage proved mutagenic for phi X174 am3 after transfection of DNA into SOS-induced spheroplasts. For Cu(II) mutagenesis is likely due to the release of adenine residues from the phage DNA based on the abolishment of mutagenesis by alkali and the observed specificity of the phage revertants. The enhancement of the adenine depurination rate by Cu(II) was estimated to be as high as 10,000-fold.     

Lethal and mutagenic action of incorporated 5-3H-cytosine on extracellular phage lambda

A study was made of the lethal and mutagenic effects on extracellular phage gamma of 5-3H-cytosine incorporated into DNA. The efficiencies of inactivation by incorporated 3H were equal for 5-3H-cytosine and [3H-methyl]-thymidine, but the yield of c-mutations for the former was 14 times higher. The lethal and mutagenic effects of incorporated 5-3H-cytosine did not depend on ung mutation of host cells which caused a deficiency in uracil-DNA-glycosylase. The mutagenic effect was not enhanced when SOS-repair system was induced by UV-radiation. The mutagenic effect of 5-3H-cytosine was associated with the modified mispairing bases but not with uracil residues.     

Inactivation and reactivation of B. megatherium phage

Preparation of Reversibly Inactivated (R.I.) Phage.- If B. megatherium phage (of any type, or in any stage of purification) is suspended in dilute salt solutions at pH 5-6, it is completely inactivated; i.e., it does not form plaques, or give rise to more phage when mixed with a sensitive organism (Northrop, 1954). The inactivation occurs when the phage is added to the dilute salt solution. If a suspension of the inactive phage in pH 7 peptone is titrated to pH 5 and allowed to stand, the activity gradually returns. The inactivation is therefore reversible. Properties of R.I. Phage.- The R.I. phage is adsorbed by sensitive cells at about the same rate as the active phage. It kills the cells, but no active phage is produced. The R.I. phage therefore has the properties of phage "ghosts" (Herriott, 1951) or of colicines (Gratia, 1925), or phage inactivated by ultraviolet light (Luria, 1947). The R.I. phage is sedimented in the centrifuge at the same rate as active phage. It is therefore about the same size as the active phage. The R.I. phage is most stable in pH 7, 5 per cent peptone, and may be kept in this solution for weeks at 0 degrees C. The rate of digestion of R.I. phage by trypsin, chymotrypsin, or desoxyribonuclease is about the same as that of active phage (Northrop, 1955 a). Effect of Various Substances on the Formation of R.I. Phage.- There is an equilibrium between R.I. phage and active phage. The R.I. form is the stable one in dilute salt solution, pH 5 to 6.5 and at low temperature (<20 degrees C.). At pH >6.5, in dilute salt solution, the R.I. phage changes to the active form. The cycle, active right harpoon over left harpoon inactive phage, may be repeated many times at 0 degrees C. by changing the pH of the solution back and forth between pH 7 and pH 6. Irreversible inactivation is caused by distilled water, some heavy metals, concentrated urea or quanidine solutions, and by l-arginine. Reversible inactivation is prevented by all salts tested (except those causing irreversible inactivation, above). The concentration required to prevent R.I. is lower, the higher the valency of either the anion or cation. There are great differences, however, between salts of the same valency, so that the chemical nature as well as the valency is important. Peptone, urea, and the amino acids, tryptophan, leucine, isoleucine, methionine, asparagine, dl-cystine, valine, and phenylalanine, stabilize the system at pH 7, so that no change occurs if a mixture of R.I. and active phage is added to such solutions. The active phage remains active and the R.I. phage remains inactive. The R.I. phage in pH 7 peptone becomes active if the pH is changed to 5.0. This does not occur in solutions of urea or the amino acids which stabilize at pH 7.0. Kinetics of Reversible Inactivation.- The inactivation is too rapid, even at 0 degrees to allow the determination of an accurate time-inactivation curve. The rate is independent of the phage concentration and is complete in a few seconds, even in very dilute suspensions containing <1 x 10(4) particles/ml. This result rules out any type of bimolecular reaction, or any precipitation or agglutination mechanism, since the minimum theoretical time for precipitation (or agglutination) of a suspension of particles in a concentration of only 1 x 10(4) per ml. would be about 300 days even though every collision were effective. Mechanism of Salt Reactivation.- Addition of varying concentrations of MgSO(4) (or many other salts) to a suspension of either active or R.I. phage in 0.01 M, pH 6 acetate buffer results in the establishment of an equilibrium ratio for active/R.I. phage. The higher the concentration of salt, the larger proportion of the phage is active. The results, with MgSO(4), are in quantitative agreement with the following reaction: See PDF for Equation Effect of Temperature.- The rate of inactivation is too rapid to be measured with any accuracy, even at 0 degrees C. The rate of reactivation in pH 5 peptone, at 0 and 10 degrees , was measured and found to have a temperature coefficient Q(10) = 1.5 corresponding to a value of E (Arrhenius' constant) of 6500 cal. mole(-1). This agrees very well with the temperature coefficient for the reactivation of denatured soy bean trypsin inhibitor (Kunitz, 1948). The equilibrium between R.I. and active phage is shifted toward the active side by lowering the temperature. The ratio R.I.P./AP is 4.7 at 15 degrees and 2.8 at 2 degrees . This corresponds to a change in free energy of -600 cal. mole(-1) and a heat of reaction of 11,000. These values are much lower than the comparative one for trypsin (Anson and Mirsky, 1934 a) or soy bean trypsin inhibitor (Kunitz, 1948). Neither the inactivation nor the reactivation reactions are affected by light. The results in general indicate that there is an equilibrium between active and R.I. phage. The R.I. phage is probably an intermediate step in the formation of inactive phage. The equilibrium is shifted to the active side by lowering the temperature, adjusting the pH to 7-8 (except in the presence of high concentrations of peptone), raising the salt concentration, or increasing the valency of the ions present. The reaction may be represented by the following: See PDF for Equation The assumption that the active/R.I. phage equilibrium represents an example of native/denatured protein equilibrium predicts all the results qualitatively. Quantitatively, however, it fails to predict the relative rate of digestion of the two forms by trypsin or chymotrypsin, and also the effect of temperature on the equilibrium.     

Mutation of Haemophilus influenzae transforming DNA in vitro with near-ultraviolet radiation: action spectrum

Mutations were produced in purified transforming DNA from Haemophilus influenzae by near-UV radiation and were assayed as mutants among cells transformed with irradiated DNA. The maximum efficiency of mutation induction was at around 334 nm, and the efficiency dropped off steeply at lower and higher wavelengths. The difference between the action spectrum for mutation and that for the oxygen-independent inactivation of transforming DNA, which had a shoulder at 365 nm, indicates that there are different lesions involved in the inactivating and mutagenic effects of near-UV. The presence of histidine during irradiation enhanced the mutagenic effect at 334 and 365 nm, although it protected against inactivation at 365 nm. The effective near-UV wavelengths for in vitro mutation are to some extent the same as the effective wavelengths for mutation in vivo reported previously. These findings indicate that mutations are produced in vivo by near-UV with DNA as the primary target molecule rather than by a secondary non-photochemical reaction between DNA and some other cell component.     

Base substitution mutations induced in the cI gene of lambda phage by neocarzinostatin chromophore: correlation with depyrimidination hotspots at the sequence AGC.

Treatment of intact lambda phage with the nonprotein chromophore of neocarzinostatin resulted in efficient phage inactivation and generation of clear-plaque mutants. Both effects required a preincubation at low pH to allow diffusion of chromophore into the phage head. Chromophore activation was then effected by addition of a sulfhydryl cofactor, followed by a shift to neutral pH. Sequence analysis of mutations mapped to the DNA-binding region of the cI gene revealed that nearly all were single base substitutions. Significant numbers of all possible base changes were found, with A:T to G:C transitions being the most frequent events. Of 11 G:C to A:T transitions, 7 were found at C residues in the trinucleotide sequence AGC, which has previously been shown to be a hotspot for chromophore-induced depyrimidination. This result, as well as the SOS dependence of mutagenesis and the overall distribution of various types of base substitutions, is consistent with the hypothesis that apurinic/apyrimidinic sites are important mutagenic lesions.