Assays for phosphotriester formation in the reaction of bacteriophage R17 with a group of alkylating agents.

The interaction of bacteriophage R17 with 8 compounds has been studied, comparing the contribution of degradation of ribonucleic acid to the total toxicity. Breaks in the RNA chain result from the hydrolysis of phosphotriesters and thus are a measure of the extent of O-alkylation and of the SN1-type mechanism of the reaction. With many alkylating agents mutagenicity and carcinogenicity increase with increasing SN1 character of the reaction. In experiments with methyl methanesulphonate no evidence of degradation was observed at up to 19 times the mean lethal dose (620 methylations/RNA molecule). Breaks in the RNA chain accounted for 1 in 10 of the lethal lesions with beta-hydroxyethyl methanesulphonate, 1 in 60 with bis-(2-chloromethyl)methylamine (nitrogen mustard, HN2), less than 1 in 125 with 2,2-dichlorvinyl dimethyl phosphate (dichlorovos, DDVP), and 1 in 200 with propylene oxide. The hydrolysis rate of bis-(2 chloroethyl)ether was too slow for any reaction to be detected. In reactions with the carcinogen bis-(2-chloromethyl)ether the toxicity observed could be accounted for by the formaldehyde produced on hydrolysis. Cross-linking of the bacteriophage components by formaldehyde reduced the survival range over which the physical state of the RNA could be studied. No evidence of RNA degradation was observed. Reaction of the formaldehyde led to a progressive loss of biological activity over 24 h, a loss which was partially reversed by dialysis.     

The reaction of alkylating agents with bacteriophage R17. Biological effects of phosphotriester formation

The extent of biological inactivation and of the degradation of the RNA after reaction of bacteriophage R17 with ethyl methanesulphonate, isopropyl methanesulphonate and N-ethyl-N-nitrosourea was studied. Formation of breaks in the RNA chain probably results from hydrolysis of phosphotriesters formed in the alkylation reactions. Near neutral pH the ethyl and isopropyl phosphotriesters are sufficiently stable for the kinetics of the hydrolysis reaction to be followed. Results indicate that the rate of hydrolysis increases rapidly as the pH is raised. The evidence shows that a phosphotriester group does not itself constitute a lethal lesion. The extent of phosphotriester formation by the different agents is discussed in terms of reaction mechanism.     

Hydroxylamine-O-sulfonic acid: in vitro and possible in vivo reaction with DNA

Exposure of DNA solutions to low levels (2 · 10^?3M) of hydroxylamine-O-sulfonic acid (HOS) resulted in limited degradation accompanied by increases in the buoyant density of the DNA. The thermal helix-coil profile of the DNA was not changed significantly following exposure to HOS. Upon thermal denaturation, the treated DNA specimens exhibited buoyant density values similar to those of heated control DNA. This is taken to mean that an added function or a modified DNA base is removed upon heating. Exposure of DNA to elevated levels of HOS (>0.2 M) resulted in extensive degradation which was accompanied by spectral changes: a hyperchromic shift and an increase in the wavelength of maximum absorbance.Exposure of individual deoxynucleosides to HOS also resulted in spectral changes and in the detection of new reaction products by paper Chromatographic means.HOS preferentially inhibited the growth of a bacterial strain deficient in DNA polymerase. This is a property also exhibited by known mutagens and carcinogens. This is taken to mean that HOS is capable of reacting with the DNA of living cells as well.     

Liver-microsome-mediated formation of alkylating agents from vinyl bromide and vinyl chloride.

When a mixture of vinyl chloride/oxygen or vinyl bromide/air was passed through a mouse-liver microsomal system, volatile alkylating metabolites were trapped by reaction with excess 4-(4-nitrobenzyl)pyridine. The absorption spectra of the adducts, either from vinyl bromide or vinyl chloride, were identical with that obtained by reaction of chloroethylene oxide with 4-(4-nitrobenzyl) pyridine. Chloroethylene oxide decomposes in aqueous solution with a half-life of 1.6 minutes. After reaction of chloroethylene oxide and 2-chloroacetaldehyde with adenosine and Sephadex chromatography the binding products were compared with those formed in the presence of vinyl chloride, mouse-liver microsomes and adenosine. A common product of these reactions was tentatively characterized as 3-β-ribofuranosyl-imidazo-[2,1-i]purine.     

Adaptive response to alkylating agents in the Drosophila sex-linked recessive lethal assay

The adaptive response to alkylating agents was studied in Drosophila assays under various treatment procedures. Pre-treatment of males as well as treatment of females with low doses of EMS (0.05-0.1 mM) did not affect sex-linked recessive lethal (SLRL) rates induced by high doses of this mutagen (10 mM, various feeding duration) in mature sperm cells. Pre-treatment of males with a low dose of MMS (0.1 mM) enhanced mutagenesis induced by the high dose of EMS (10 mM) at different stages of spermatogenesis, the observed effects exceeding the additive action of both mutagens. On the contrary, larval pre-treatment with the adaptive dose of EMS (0.05 mM) resulted in resistance of their germ cells to higher doses of EMS (1 mM). Specifically, offspring production increased while dominant lethality in F(1) as well SLRL frequency in F(2) was significantly reduced as compared with the effects of larval exposure to the challenge dose. Under the conditions tested, the adaptive response of germ cells to alkylating agents was demonstrated in larvae, but not in adult flies.     

The action of tuftsin on the reaction of macrophage-suppressor formation in vitro and in vivo

A cell suspension consisting of nonadhering and adhering spleen cells in the ratio 30:1 was incubated in a 10(-4) M tuftsin's solution during 15-30 min. The addition of 10(7) cells incubated in tuftsin syngeneic recipients resulted in the suppression of the immune response of the latter to sheep red blood cells. It was noted that this effect may be induced by using adhering cells only of intact donors and only when incubated together with nonadhering cells. The addition of tuftsin one hour after transplantation of the nonadhering spleen cells resulted in the suppression of the immune response. It was proposed, that suppression effect released through generation of the macrophage-suppressors.     

An unexpected side reaction in the guaiacol assay for peroxidase.

In routine guaiacol assays for thyroid peroxidase and lactoperoxidase employing a newly purchased bottle of guaiacol from Aldrich Chemical Co., we were surprised to find the formation of a blue color instead of the expected amber color classically associated with this assay. This was observed also with horseradish, myelo-, and cytochrome c peroxidase. The blue color (Amax approximately 650 nm) was not formed with guaiacol reagents obtained from two other chemical companies, nor was it seen with a bottle of old Aldrich guaiacol that had been in use in the laboratory for more than 10 years. In the present investigation we provide evidence that formation of the blue color is closely associated with the presence of a low concentration of catechol (approximately 0.5 mol%) in the new Aldrich guaiacol reagent. Catechol itself, even in much higher concentration, is a very weak donor for peroxidase, forming a light pink color. The blue color in Aldrich new guaiacol is not formed to the exclusion of 470-nm-absorbing product(s). Formation of the latter is, however, inhibited, and use of Aldrich new guaiacol for assay leads to low values for peroxidase activity. Other dihydroxyphenols (resorcinol and hydroquinone) do not mimic the action of catechol in formation of the blue color. Resorcinol is a very potent inhibitor of peroxidation of guaiacol. Possible schemes are proposed for formation of the products that may be associated with the amber and blue colors.     

The reaction of alkylating agents with cyclic 3',5'-nucleotide phosphodiesterase

The reaction of anti-tumour alkylating agents with beef heart cyclic nucleotide phosphodiesterase (adenosine 3',5'-monophosphate phosphohydrolase, EC 3.1.4.c) has been investigated. This enzyme exists in two forms differing in their Michaelis-Menten K_m values. Chlorambucil [p-(di-2-chloroethylamino)-phenyl-butyric acid] inhibits the form of the enzyme with a low K_m value with a velocity constant for inactivation three times that for inhibition of the high K_m form. While the monofunctional N-ethyl analogue of chlorambucil is ineffective as an inhibitor of either form of the enzyme, iodoacetate inhibits both forms, though the velocity constant for inactivation of each form is much less than that for chlorambucil. Also the rate of inactivation of each form does not significantly differ. A cross-linking mechanism for the inactivation of regulatory enzymes is proposed.     

Development of an in vitro colony formation assay for the evaluation of in vivo chemotherapy of a rat brain tumor.

An in vitro colony formation assay for the evaluation of in vivo brain tumor therapy has been developed. When plated, disaggregated cells derived from solid tumors proliferated to form relatively homogeneous colonies after a latency period of 2 to 6 days. Increasing concentrations of fetal calf serum enhanced colony-forming efficiency (CFE) with a plateau between 7 and 16%. Supplementation with either irradiated feeder cells (10(3) to 10(5) cells per dish), or medium conditioned by 1 to 3 days of in vitro incubation with the same cell line, doubled the CFE. The density of tumor cells (untreated or previously treated with chemotherapeutic agents) did not affect the CFE when a minimum of 10(4) total cells (tumor plus feeder) were plated. Therefore, in this system the optimal experimental conditions for evaluating chemotherapy and radiotherapy require incubation of disaggregated tumor cells for 12 days in medium containing 10% of fetal calf serum and enough feeder cells to provide a minimum of 10(4) cells per dish. The CFE for untreated tumors was 18 +/- 10% (+/-S.D.), demonstrating that there is significant biological variation. The assay appeared sensitive, with reproducible results, when applied to individual chemically treated tumors. An estimate of the percentage of clonogenic cells affected by in vivo chemotherapy may be obtained by comparing the CFE of cells from treated and untreated tumors. This assay can measure up to a 5 log(10) cell kill, and it should prove to be valuable in developing more effective regimens for the treatment of solid tumors in animals and man.     

The influence of some alkylating agents on the structure of DNA in vitro

The influence of the industrially used mutagenic agents β-propiolactone (BPL), propylene oxide (PO) and butylene oxide (BO) on the structure of DNA in vitro was studied. The heat denaturation of DNA and its reversibility were used as a criterion of the structural change in the DNA molecule. The rate constants for the reaction of the different compounds with DNA were determined. The effects were correlated with the degree of alkylation. Butylene oxide and propylene oxide caused a decrease of the reversibility of the heat denaturation at a degree of alkylation at which the melting temperature was only slightly decreased. β-propiolactone had no influence on the reversibility, but decreased the melting temperature of DNA as a function of the degree of alkylation.     

Alkylating esters X. The reaction of some aziridine alkylating agents with methionine and S-methyl cysteine

Two biologically active aziridine ring-containing compounds, N,N-ethylene urethane (I) and N,N-ethylene urea (II), have been shown to react with methionine in dilute phosphate buffer (pH 7.4) at 37°C. Degradative procedures indicate that the aziridine ring effectively alkylates the thio ether group of methionine and other thio ether-containing amino acids to produce sulphonium salts (V). By using [³⁵S]methionine, the sulphonium salts have been shown to be quite stable under physiological conditions ($\text{t}{}_{\mathrm{<mtext>built1</mtext><mtext>2</mtext>}}$ 7–9 days) hydrolysing to convert the methionine residue to homoserine.It is proposed that similar alkylations of methionyl residues in vivo by aziridine-alkylating agents may explain the complex, and as yet unknown, metabolic fate of the aziridine ring and could also be a factor contributing to the diverse effects that these agents have on living cells.     

Increased urinary excretion of nucleic acid and nicotinamide derivatives by rats after treatment with alkylating agents.

Rats treated with di(2-chloroethyl)methylamine (HN2), N-methyl-N-nitrosourea (MNUA) and N-ethyl-N-nitrosourea (ENUA) excrete significantly larger amounts of deoxycytidine (dC) and thymidine in their urine 0-24 h after treatment. Ethyl methanesulphonate (EMS) and dimethylnitrosamine (DMN) gave negative results in this respect but all five alkylating agents increased the excretion of 1-methyl-nicotinamide (1-meNmd). In addition, a larger quantity of 7-methylguanine (7MG) and uric acid was excreted after DMN treatment. 1,4-Dimethanesulphonoxybutane (myleran), 2,2-dichlorovinyl dimethyl phosphate (dichlorvos), 5-fluorouracil (5FU), cytosine arabinoside (araC), 2-acetylaminofluorene (AAF) and 7-bromomethylbenz-[a]anthracene (7-BrMBA) gave negative results.     

Unscheduled DNA synthesis in spermatogenic cells of mice treated in vivo with the indirect alkylating agents cyclophosphamide and mitomen

Cyclophosphamide (CPA) and mitomen (DMO) are chemical mutagens that require metabolic activation to produce their biological effect. We have used an in vivo UDS assay in various meiotic and postmeiotic germ-cell stages of male mice to study DNA repair after treatment with these chemicals. EMS, a compound requiring no metabolic activation, was also used for comparative purposes.CPA and DMO induced UDS in meiotic through early-to-midspermatid stages, but no UDS was detected in late spermatids and mature sperm. While EMS produced a maximum UDS response in the germ cells immediately after treatment, CPA and DMO did not produce a maximum response until ～0.5 to 1 h after injection. This delay is attributed to the time required for CPA and DMO to be enzymatically vonverted active alkylating metabolites.Unlike the results found with EMS, mutation frequencies (dominant lethals, translocations, specific-locus mutations) following CPA treatment are not noticeably reduced in germ-cell stages in which UDS occurred. In the case of DMO, mutations are induced only in mature spermatozoa, and these germ-cell stages represent only a fraction of those in which no UDS is detected. The results with CPA and DMO thus still leave unclear the relationship between DNA repair and the differential spermatogenic response of mice to genetic damage.