Biological responses of Habrobracon to spaceflight

Since the interaction of the parasitic wasp Habrobracon with the space environment could not be prejudged, we decided to test approximately 30 different parameters of a genetic, mutational, biochemical, behavioral, and physiological character in the one spaceflight we had at our disposal. These parameters were examined at six different exposures of gamma-radiation (including 0 dose) in flight, resulting in about 180 different endpoints in all. The most profound effects of spaceflight in conjunction with radiation were decreased hatchability and enhanced fecundity of eggs exposed to spaceflight at different stages of oogenesis. The interpretation we favor is that these two endpoints are reflections of chromosomal non-disjunction in the former case and inhibition of cell division in the latter. Our most comprehensive study of mutagenesis was on sperm, where dominant lethality, recessive lethality, translocations, and visible mutations were assayed; the only effect found was a threefold enhancement of the recessive lethal mutation frequency in the non-irradiated sperm in the orbited Habrobracon males. Behavioral and biochemical differences were found. Mating activity of orbited males was severely disrupted and xanthine dehydrogenase activity was sharply decreased in the irradiated flight animals, an unexpected observation. Postflight experiments were like the ground-based control experiments in all aspects but one. Under conditions of vibration similar to those encountered during the launch and re-entry, the mutation frequency in the sperm increased by a factor of three over that of the non-vibrated control.

Mutational responses of insects in the Biosatellite II experiment

Genetic effects associated with space flight include mutation induction by the space flight itself, and enhancements or antagonisms of radiation-induced mutations. The conditions of space flight vary in mutagenic effectiveness from no response at all to responses nine times that found in ground-based controls. The test systems follow the sensitivity pattern: spermatogonial translocations > oogonial and oocyte nondisjunction > recessive lethality of stages in spermatogenesis > dominant lethality of stages in spermatogenesis. Large enhancing and antagonistic effects of space flight in conjunction with radiation were observed in the Biosatellite II experiment. The most surprising one was the elimination of the effect of 2500 R by space flight in Habrobracon oogonia where the effects of 500 R normally can be easily observed. Two sets of parameters are considered in attempts to explain the responses: (1) the nature of the biological targets, and (2) the particular conditions of space flight that are responsible for the effects.

A rapid assay for mitochondrial DNA damage and respiratory chain inhibition in the yeast Saccharomyces cerevisiae

There is a need for a rapid assay to identify agents that damage mitochondria because the mitochondrion may be an important target for numerous environmental mitotoxins. Certainly at least one chemotherapeutic regimen (CHOP therapy) that includes doxorubicin can induce cardiomyopathy through mitochondrial genotoxicity in cardiac muscle cells. Yeast cells (1.5 x 10(6)-10(7)) in water are spread on a YEPD plate, and, when the suspension of cells has dried, a small well (12 mm diameter) is cut into the agar; 200-400 microl of a solution of the presumptive mitochondrial genotoxin is placed in the well, and the plates are incubated for 2 days. The genotoxin forms a concentration gradient through the agar and affects the growing cells. An overlay containing tetrazolium chloride is added, and the plates are incubated for 6-24 hr. Respiring cells turn red, and nonrespiring cells, with damaged DNA or inhibited respiratory chains, that are adjacent to the well, are white. A white ring, or a more lightly colored red ring, around the well indicates the presence of cells with lowered respiratory activity which may be fully reversible when the mitochondrial genotoxin is removed. In preliminary experiments, doxorubicin (= adriamycin) shows strong activity with this assay; cyclophosphamide is negative, and 4-hydroxycyclophosphamide, a metabolite of cyclophosphamide, is weakly positive. Ethidium bromide, methotrexate, 5-fluorouracil, and 5-fluorocytosine also are mitochondrial genotoxins. Antifungal agents similar to 5-fluorocytosine and anthelmintic compounds such as pyrvinium iodide can be powerful mitochondrial genotoxins.

An experimental solution for the Luria-Delbrück fluctuation problem in measuring hypermutation rates

A cell line harboring all trans-acting elements necessary for hypermutation was transfected with a plasmid harboring the major cis-acting elements plus a green fluorescent protein gene containing a premature chain-termination codon. Transfected cells do not fluoresce unless the stop codon reverts. When a sizable cell population is purged of revertants by sorting, the frequency of mutants increases linearly with time, and there is no Luria-Delbrück fluctuation effect. Moreover, as mutant frequencies seemed to vary less than cell numbers in replicate cultures, it is suggested that hypermutation might not be coupled closely to cell division.

Janus carcinogens and mutagens

Janus carcinogens are carcinogenic agents that, under differing conditions of cell type or dose, can instead act as anticarcinogens. Studies by Haseman and Johnson [J.K. Haseman, F.M. Johnson, Analysis of rodent NTP bioassay data for anticarcinogenic effects, Mutat. Res. , 350 (1996) 131-142], have demonstrated that many chemicals that are carcinogenic for one tissue type can have anticarcinogenic action on another tissue type. As Magni et al. [G.E. Magni, R.C. von Borstel, S. Sora, Mutagenic action during meiosis and antimutagenic action during mitosis by 5-aminoacridine in yeast, Mutat. Res., 1 (1964) 227-230] have shown in 1964, this principle holds true for chemical mutagens as well, that is 9-aminoacridine is an antimutagen in the vegetative cell and a mutagen in the sporulating cell. The conclusion can be drawn that two established carcinogens, tobacco and ionizing radiation, are indeed Janus carcinogens. In their review of 'ambiguous carcinogens' (their name), Weinberg and Storer [A.M. Weinberg, J.B. Storer, Ambiguous carcinogens and their regulation, Risk Anal., 5 (1985) 151-156], pointed out that tobacco can be classified as an ambiguous carcinogen. The strong carcinogenicity and anticarcinogenicity of tobacco smoke and/or tobacco itself (i.e., chewing tobacco) may be due to components in the mixture, not that of a single carcinogenic chemical that also may be anticarcinogenic. Kondo [S. Kondo, Health Effects of Low-Level Radiation, Kinki Univ. Press, Osaka, Japan and Medical Physics Publishing, Madison, WI, 1995, 213 pp.] has compiled data that demonstrate that human populations who survive exposures to ionizing radiation generally live longer and have less cancer than unirradiated human populations, and this Janus phenomenon goes beyond the more trivial concept of increased sensitivity to radiation of rapidly dividing tumor cells. Thiabendazole is an interesting compound in that it is both aneugenic and antimutagenic, and yet it does not appear to be a carcinogen or a mutagen. It is discussed here because aneugenesis and antimutagenesis are at extremes of the mutagenic spectrum. In general, mutagenic or carcinogenic actions usually are at least partially understood at a molecular level, whereas antimutagenic and anticarcinogenic actions usually are not. It is possible there may be numerous specific mechanisms underlying the Janus activity of different chemicals.

Topical reversion at the HIS1 locus of Saccharomyces cerevisiae. A tale of three mutants

Mutants of the HIS1 locus of the yeast Saccharomyces cerevisiae are suitable reporters for spontaneous reversion events because most reversions are topical, that is, within the locus itself. Thirteen mutations of his1-1 now have been identified with respect to base sequence. Revertants of three mutants and their spontaneous reversion rates are presented: (1) a chain termination mutation (his1-208, née his1-1) that does not revert by mutations of tRNA loci and reverts only by intracodonic suppression; (2) a missense mutation (his1-798, née his1-7) that can revert by intragenic suppression by base substitutions of any sort, including a back mutation as well as one three-base deletion; and (3) a -1 frameshift mutation (his1-434, née his1-19) that only reverts topically by +1 back mutation, +1 intragenic suppression, or a -2 deletion. Often the +1 insertion is accompanied by base substitution events at one or both ends of a run of A's. Missense suppressors of his1-798 are either feeders or nonfeeders, and at four different locations within the locus, a single base substitution encoding an amino acid alteration will suffice to turn the nonfeeder phenotype into a feeder phenotype. Late-appearing revertants of his1-798 were found to be slowly growing leaky mutants rather than a manifestation of adaptive mutagenesis. Spontaneous revertants of his1-208 and his1-434 produced no late-arising colonies.

Protection and repair of gamma-radiation-induced lesions in mice with DNA or deoxyribonucleoside treatments

Mice can survive lethal doses of ionizing radiation if deoxyribonucleosides or 'highly polymerized' salmon sperm DNA (Sigma) are administered 30 min to 24 h post-irradiation. DNA is more effective than deoxyribonucleosides in increasing the survival frequency. At supralethal exposures of gamma-irradiation, Deoxyribonucleosides and DNA are equally effective in reversing radiation damage which otherwise leads to chromosome breakage. The micronucleus frequencies in the polychromatic erythrocytes of bone marrow cells from DNA- or deoxyribonucleoside-treated mice were near the unirradiated control values. This reduction in chromosome breakage was approximately 4-fold when compared with the irradiated, saline-treated control. 'Highly polymerized' DNA protects against mortality if administered 48 and 24 h prior to irradiation. This is somewhat comparable to the effectiveness of the growth factors Interleukin-1 alpha (IL-1 alpha) or tumor necrosis factor-alpha (TNFalpha) administered prior to irradiation. With survival as criterion, the sensitivity of 4 lines of mice to gamma-irradiation is BALB/c > C3H/OuJ > or = C3H/HeJ > C57B1/6.

Origins of spontaneous base substitutions

Although simple to understand, satisfying to the imagination, and compelling as a teaching aid for beginning students, the evidence is mounting that the tautomeric shift is neither a common nor a likely origin for spontaneous base substitutions. Indeed, other sources, such as ionized base mispairings with nonionized bases, wobble of a bases in the DNA, and transient misalignment of bases causing dislocations at pairing sites, have been shown to induce spontaneous base substitutions. On the other hand, among the 4 common bases in DNA, no experimental evidence exists that tautomeric shifts can induce mutations.

The mutator mut7-1 of Saccharomyces cerevisiae

The mut7-1 mutant of Saccharomyces cerevisiae is a cell-division-cycle mutant, exhibiting temperature-sensitive lethality and enhancement of mutator activity with increases in temperature. The base-sequence alterations in mutants arising in a mut7-1 background differed from the control by there being a higher transversion/transition ratio and by the much increased production of multi-base deletions. The deletions were, in every instance, associated with repeated oligonucleotide sequences (3-8 bases in length), where one of the two sequences was removed during the deletion process. The mutant mut7-1 failed to complement with cdc2, the temperature-sensitive mutant of the locus which encodes DNA polymerase III (delta).

The phenotype of a dihydrofolate reductase mutant of Saccharomyces cerevisiae

We have constructed a dihydrofolate reductase mutant (dfr1) of Saccharomyces cerevisiae. The mutant has auxotrophic growth requirements for the C1 metabolites dTMP, adenine, histidine and methionine, similar to those of wild-type (wt) strains grown in the presence of methotrexate (MTX). However, unlike wt strains treated with MTX, the growth requirements of the dfr1 mutant are not satisfied by exogenous 5-formyltetrahydrofolic acid (FA; folinic acid) in complex (YEPD) medium. This result is surprising, as yeast cells treated with MTX are expected to be phenocopies of dfr1 mutants. The inability of the mutants to metabolize FA suggests that the DFR1 gene product may have a role in folate metabolism in addition to its well-characterized function in the reduction of dihydrofolate. From dfr1 strains, we have isolated secondary mutants whose growth can be supported by FA in YEPD medium. This FA-utilizing phenotype is attributable to recessive mutations which we have designated fou. In addition to their inability to metabolize FA, the dfr1 strains are unable to grow on medium containing the non-fermentable carbon source glycerol, suggesting that the DFR1 gene product is also required for mitochondrial function. In order to overcome this lack of respiratory activity in the dfr1 mutants, we isolated strains containing a dominant mutation, DIR, which allows growth on glycerol in the presence of antifolate drugs. When crossed into dfr1 strains, the DIR mutation conferred respiratory competence. These strains should be useful in a variety of studies on the genetics and biochemistry of folate metabolism in this simple eukaryote.

Base alterations in yeast induced by alkylating agents with differing Swain-Scott substrate constants

The base alterations induced by four alkylating agents, methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), N-nitroso-N-methylurea (MNU), and N-nitroso-N-ethylurea (ENU), have been determined at the URA3 locus in the yeast Saccharomyces cerevisiae. The mutagen treatment was carried out on yeast cells in the logarithmic phase of growth. The mutants were selected by their resistance to 7.3 mM-5-fluoroorotic acid at pH 3.8. DNA sequence analysis was carried out by the dideoxy chain termination method. The alkylating agents were selected for their widely differing Swain-Scott substrate constants (s values), which are as follows: MMS, s = 0.83; EMS, s = 0.67; MNU, s = 0.42; ENU, s = 0.26. A higher s value is correlated with a higher ratio of 7-alkylguanine to O6-alkylguanine in native DNA in vitro. 125 forward mutations from URA3----ura3 were sequenced with marked differences in the mutational spectra being observed as the s value changed. Five hotspots were recorded for the four alkylating agents. They were all G.C----A.T transition mutations. There was one common hotspot for all of them; there were two additional ones for the two ethylating agents (ENU and EMS) and two different ones for MNU. Four of the five hotspots have the 5'-GG-3' sequence with the 3'-guanine mutated. It was seen that MMS, which has the highest Swain-Scott substrate constant, yielded the widest array of mutational types. As the substrate constants decreased, the types of mutations became more and more restricted to the G.C----A.T transitions and the A.T----T.A transversions. The transitions are consistent with the concept that mutations arise from O6-alkylation of guanine and alkylation of thymine. The transversions are consistent with the notion of N1-alkylation of adenosine or adenylic acid.

Sequence and localization of the gene encoding yeast phosphoglycerate mutase

In this study we report on the complete nucleotide sequence of the yeast phosphoglycerate mutase gene (GPM1) and its essential 5' and 3' non-coding regions. The transcriptional start points were determined by S1-mapping and sequencing of a cDNA clone. Several sequences identified as important for transcriptional regulation in yeast promoters are present upstream of the transcription start point. 3' to the coding region we sequenced a composite repetitive element which, apparently, originated from a recombination between a delta- and a tau-element. Finally, we mapped the GPM1 gene 13 cM distal to fas1 on chromosome XI.

Antimutagenesis in yeast by sodium chloride, potassium chloride, and sodium saccharin

Aqueous salt solutions containing NaCl, KCl, MgCl2, Na2SO4, CaCl2, NH4Cl, or sodium saccharin are mutagenic in yeast when logarithmic growth of cells is interrupted by exposure to a 0.5-2.0 M salt solution. Stationary-phase cells are not mutated by this treatment. When placed in an enriched medium with the salt, the stationary-phase cells grow after a prolonged lag period. The compounds tested (NaCl, KCl, and sodium saccharin), under conditions in which growth in medium can take place, exhibit an antimutagenic response as measured by the compartmentalization test. The antimutagenic action of salt solutions in yeast is concentration-dependent. Unlike the mutagenic action of these compounds, which approximates an osmolality-dependent response, the antimutagenic action seems to be correlated with toxicity as measured by growth rate reduction at increasing concentrations of the compounds. For example, sodium saccharin and NaCl exhibit almost identical osmolalities; however, 0.3 M sodium saccharin reduces the growth rate much more than does 0.3 M NaCl. At these same molar concentrations, the spontaneous mutation rate for histidine prototrophy is, for the control, 6.2 x 10(-8) mutations/cell/-generation, 3.5 x 10(-8) with 0.3 M NaCl, and 1.7 x 10(-8) with 0.3 M sodium saccharin.

The phosphofructokinase genes of yeast evolved from two duplication events

Yeast phosphofructokinase (PFK) is an octameric enzyme composed of four alpha-subunits and four beta-subunits, encoded by the genes PFK1 and PFK2, respectively. PFK1 was mapped 23 cM distal to ADE3 on chromosome VII, and PFK2 30 cM proximal to RNA1 on chromosome XIII. The entire nucleotide sequences for the two genes were obtained by sequencing both DNA strands. Only one major open reading frame was found for each gene. They encode 987 aa for PFK1 (Mr 107,984) and 959 aa for PFK2 (Mr 104,589). Both genes show a biased codon usage. The deduced amino acid sequences showed: (i) 20% homology between the N- and the C-terminal halves of each subunit, (ii) 55% homology between the two subunits, and (iii) significant homologies to the PFK sequences from human and rabbit muscle (42%), Escherichia coli (34%), and Bacillus (36%). These data support the view that two gene duplication events occurred in the evolution of the yeast PFK genes. The first duplication event took place soon after the separation of prokaryotic and eukaryotic lineage and the second in Saccharomyces later in the phylogeny. Functional domains in the yeast subunits were deduced by comparison to the rabbit muscle enzyme.

Scope of action of the immunoglobulin mutator system

The authors have developed a method to measure the rate of spontaneous mutations taking place in IgH, the gene encoding the immunoglobulin heavy chain. When an amber chain-termination codon mutates to a sense codon, translation of the polypeptide chain will be completed, and mutant cells producing the heavy chain can be detected with a fluorescent labelled antibody. The protocol used is the compartmentalization test which minimizes any effect of selection. In subclones of the pre-B lymphocyte line 18-81, the spontaneous mutation rate in the part of IgH encoding the variable region is somewhat greater than 10(-5) mutations per base pair per generation. This supports the hypothesis that hypermutation is not dependent on cell stimulation by an antigen. In a hybrid between a cell of this line and a myeloma (which represents the terminal stage of the B-cell lineage), the mutation rate was too low to be determined by this test, less than 10(-9). When the same loss to gain procedure system was used with an opal chain-terminating codon in the part of IgH encoding the constant region (C mu), a high rate of reversion by deletion was found. Long (more than one exon) and short (less than one exon) deletions occurred at rates of 1.7 x 10(-5) and 1.4 x 10(-7) per generation, respectively. It is thought that the high rate of deletion is not related to somatic hypermutation but rather to DNA rearrangement during the heavy-chain class switch, which is occurring in these pre-B cell lines. The point mutation rate was too low to be detected above the background of deletion mutants, less than 5 x 10(-8). The immunoglobulin mutator system works weakly, if at all, on two other, nonimmunoglobulin, genes tested: B2m (beta 2 microglobulin) and the gene for ouabain resistance.

The base-alteration spectrum of spontaneous and ultraviolet radiation-induced forward mutations in the URA3 locus of Saccharomyces cerevisiae

A forward mutation system has been developed to obtain rapidly clonable mutants at the URA3 locus in yeast by means of selection for 5-fluoroorotic acid resistance. We have used this system to determine base changes in 35 spontaneous and 34 ultraviolet radiation-induced ura3 base substitution mutants. Other mutants (frameshift, deletion, duplication, replacement) were detected as well. Evidence is reported which suggests cyclobutane dimers are the principal mutagenic lesions induced by UV radiation in stationary phase cells of the yeast Saccharomyces cerevisiae. Since most of the induced lesions are at 5'-TT-3' sites, the results suggest that the "A-rule", preferential insertion of adenine residues opposite poorly pairing sites in DNA, does not apply for yeast cells irradiated in stationary phase, whereas the spontaneous mutation data indicate that the A-rule applies for cells in logarithmic phase. Most of the spontaneous mutations are transversions. UV-induced transitions and transversions occur at approximately equal frequencies.

Internalization of the human immunodeficiency virus does not require the cytoplasmic domain of CD4

Binding of the human immunodeficiency virus (HIV) to infectable host cells, such as B and T lymphocytes, monocytes and colorectal cells, is mediated by a high-affinity interaction between the gp120 component of the viral envelope glycoprotein and the CD4 receptor. Upon binding, it is thought that the second component of the envelope, gp41, mediates fusion between the viral envelope and host cell membranes. However, the early steps of HIV infection have not yet been thoroughly elucidated. Viral entry was first reported to be mediated by pH-dependent receptor-mediated endocytosis; subsequent studies have shown entry to be pH-independent. Although direct fusion of virus to plasma membranes of infected cells has been observed by electron microscopy, it is still formally possible that the infectious path of the virus involves receptor-mediated endocytosis. To gain a better understanding of receptor function in viral entry, we have analysed the ability of several altered or truncated forms of CD4 to serve as effective viral receptors. Our results indicate that domains beyond the HIV-binding region of CD4 are not required for viral infection. Some of the altered forms of CD4 that serve as effective HIV receptors are severely impaired in their ability to be endocytosed. These experiments therefore support the notion that viral fusion to the plasma membrane is sufficient for infection.

Base-substitution and frameshift mutagenesis by sodium chloride and potassium chloride in Saccharomyces cerevisiae

Sodium chloride (NaCl) and potassium chloride (KCl) are both capable of inducing lethality and mutations when each is administered at a molarity of two for different lengths of time to logarithmic phase cells of the yeast Saccharomyces cerevisiae. Analysis of the revertants indicates that the reversions can be base substitutions, of both the transition and the transversion type, as well as frameshift mutations. At equal molarity, with the frequency of mutations as the criterion, KCl and NaCl are equally efficient in inducing all types of mutations.

The detection of chemical impurities by high pressure liquid chromatography and the genetic activity of medical grades of pyrvinium pamoate in Saccharomyces cerevisiae and Salmonella typhimurium

The genetic activity of several medical grades of the anthelmintic drug pyrvinium pamoate, which is a dipyrvinium salt, was studied in a diploid mitotic recombination and gene conversion assay (strain D5 of Saccharomyces cerevisiae), and in several haploid yeast reversion assays (strains XV185-14C, XY718-1A, and 7854-1A). All of the samples were recombinogenic in strain D5 and mutagenic in the haploid strains, however, the degree of genetic activity varied considerably among the medical grades of pyrvinium pamoate that were tested. Similarly, these samples varied in degree of mutagenicity when they were tested in strains TA97, TA98, TA100, and TA102 of Salmonella typhimurium, but some of the medical grades of pyrvinium pamoate were mutagenic both in the presence and in the absence of the metabolic transformation system, whereas other medical grades of the drug required such activation to be mutagenic. In addition, the medical grades and dosage forms of several brands of pyrvinium pamoate were examined for purity by fluorescence high pressure liquid chromatography (HPLC) using a methanol:water (90:10) solvent system. The HPLC data indicate that monopyrvinium salts are the major contaminants in these pharmaceuticals. In general, there is a correlation between the degree of genetic activity and toxicity, and the number and relative quantity of impurities found in each sample.

Measurements of mutation rates in B lymphocytes

It is established that somatic mutation is an important source of antibody diversity in vivo. It is also established that Igh-V gene segments are hypermutable in vitro. This is not a completely satisfactory situation. While there is no reason to believe that Igh-V genes are not hypermutable in vivo as well, direct experimental evidence is lacking. Perhaps experiments with transgenic mice will soon fill this gap. It is not so clear how much higher than normal the rate of hypermutation is. As far as we are aware, there are no direct measurements of mutation rates per base pair per cell generation in mammals, certainly not for lymphocyte cell lines. For a variety of reasons, it is difficult to measure very low mutation rates. The general consensus is that the normal rate should be somewhere between 10(-10) and 10(-12) mutations per base pair per cell generation. Therefore, an experiment designed to directly determine a rate using the compartmentalization test would involve hundreds of cultures, each containing at least 10(9) cells. It is not a trivial problem to find one or a few mutants among so many cells. It is simple to study mutation to resistance to a drug, for example, ouabain or azaguanine, but, as we discussed, there are technical and conceptual pitfalls. The vast excess of dead cells influences the growth of a few mutant cells, particularly in lymphocyte cell lines. Even if this problem could be solved, the mutation rate so obtained would be "per gene(s)" and not "per base pair". The problems associated with cytotoxic agents can be avoided by immunofluorescence methods in conjunction with selective cloning or cell sorting. Using these techniques, we have carried out extensive experiments to determine whether the immunoglobulin mutator system acts, at least partially, on genetic elements other than those in or near the heavy chain variable region gene segment. For an opal termination codon in a heavy chain constant region gene segment, the rate of reversion was less than 10(-7) per base pair per cell generation. This upper limit was fixed by the high rate of small deletions at the heavy chain locus. For an allotype mutation at B2m, the gene encoding beta 2 microglobulin, the rate of mutation was less than 10(-8). This upper limit could be lowered by at least two orders of magnitude by using a high-speed cell sorter.

A comparison of the genetic activity of pyrvinium pamoate with that of several other anthelmintic drugs in Saccharomyces cerevisiae

Several anthelmintic drugs that are used routinely in oxyuriasis therapy were analyzed for genotoxicity in a diploid mitotic recombination and gene conversion assay (strain D5 of Saccharomyces cerevisiae), and in a haploid yeast reversion assay (strain XV185-14C). Piperazine citrate, piperazine adipate, mebendazole and thiabendazole did not appear to be genotoxic in either yeast strain. Pyrvinium pamoate induced the reversion of the missense, nonsense and frameshift alleles in strain XV185-14C, whereas pyrantel pamoate induced only the reversion of the frameshift allele. Pyrvinium pamoate was recombinogenic in strain D5, and there is an indication that pyrantel pamoate, at the lowest dose that was tested, might induce gene conversion or aneuploidy.

The binding of the anthelmintic pyrvinium cation to deoxyribonucleic acid in vitro

Pyrvinium pamoate, an anthelmintic drug with mutagenic activity, binds to duplex DNA in vitro. Binding markedly enhances the intrinsic fluorescence of the drug, permitting a characterization of the binding reaction to be performed directly through fluorimetric analysis. The monopyrvinium salt, pyrvinium iodide, binds cooperatively to native calf thymus DNA with an intrinsic binding constant of 1.1 X 10(4) M-1 as determined fluorimetrically and 1.4 X 10(4) M-1 as determined by equilibrium dialysis. The respective binding site was estimated to be 2.5 base pairs. A change in the absorption of bound drug as a function of the binding ratio identifies secondary, nonfluorescent binding which is essentially ionic in character. The binding of pyrvinium removes negative supercoils from PM2-ccc-DNA with an experimental efficiency greater than that observed for the intercalating drug chloroquine. Electron microscopy shows that molecules of pBR322 DNA treated with pyrvinium increase in length by as much as 18% over controls, consistent with an increase in DNA base pair separation upon binding. The evidence indicates that the primary interaction of pyrvinium with DNA involves intercalation.

Modulation in cytochrome P-420 and P-450 content in Saccharomyces cerevisiae according to physiological conditions and genetic background

The diploid strain D5 of Saccharomyces cerevisiae, relative to other strains of yeast, has a large amount of cytochrome P-450 present during the logarithmic phase of growth and a low amount of cytochrome P-420. As the stationary phase of growth is approached, an increasing intensity of absorbance is observed at 420 nm. If the cells are suspended in buffer during mid-logarithmic growth, the absorbance at 450 nm disappears and absorbance at 420 nm is increased after the cells have been held in buffer for 24 h. At late logarithmic growth, the absorbance at 450 nm is still retained after the cells have been held in buffer for 24 h. Within 44 h of the time of harvest, the absorbance at 450 nm disappears completely and the absorbance at 420 nm is intense. Cytoplasmic petite variants of strain D5 have less of both cytochromes P-450 and P-420 than does the grande D5 strain; the absorbances at 450 and 420 nm are retained up to 96 h when the cells are held in buffer. Haploid spores of strain D5 exhibit absorbances at 450 and 420 nm during the logarithmic phase of growth, and these absorbances are retained after the cells are held in buffer for 24 h. An hypothesis is proposed which states that cytochrome P-450 is the membrane-bound form and cytochrome P-420 is free in the cytosol; the cytochromes interconvert and are active in either state until the associated enzymes disassociate.

Situation-dependent repair of DNA damage in yeast

The concept of channelling of lesions in DNA into defined repair systems has been used to explain many aspects of induced and spontaneous mutation. The channelling hypothesis states that lesions excluded from one repair process will be taken up by another repair process. This is a simplification. The three known modes of repair of damage induced by radiation are not equivalent modes of repair; they are, instead, different solutions to the problem of replacement of damaged molecules with new molecules which have the same informational content as those that were damaged. The mode of repair that is used is the result of the response to the situation in which the damage takes place. Thus, when the most likely mode of repair does not take place, then the situation changes with respect to the repair of the lesion; the lesion may enter the replication fork and be reparable by another route.

Mutagen testing of agricultural chemicals with yeast

The microorganism Saccharomyces cerevisiae is frequently used to test chemical agents in short-term mutagenicity tests. Advantages of yeast are its eukaryotic character and the numerous genetic endpoints which can be tested. A disadvantage is the lower sensitivity towards compounds which, when compared with the Salmonella Ames test, need to be metabolized in order to be active. However, the sensitivity of yeast tests can be improved by using cells from the logarithmic phase and by growing them under conditions which increase the activity of metabolizing enzymes, such as the cytochrome P-448/P-450 complexes. Furthermore, we discuss which information can be drawn from the shape of the survival and mutation frequency curves, and which parameters from the mutant yield curves can be used to compare the mutagenic efficiencies of various agents or the mutabilities of various test systems. Also, the qualitative yeast assay results are compiled for insecticides and herbicides in agricultural usage in Third World countries (Pakistan, for example).

Testing of chemicals for genetic activity with Saccharomyces cerevisiae: a report of the U.S. Environmental Protection Agency Gene-Tox Program

The yeast Saccharomyces cerevisiae is a unicellular fungus that can be cultured as a stable haploid or a stable diploid . Diploid cultures can be induced to undergo meiosis in a synchronous fashion under well-defined conditions. Consequently, yeasts can be used to study genetic effects both in mitotic and in meiotic cells. Haploid strains have been used to study the induction of point mutations. In addition to point mutation induction, diploid strains have been used for studying mitotic recombination, which is the expression of the cellular repair activities induced by inflicted damage. Chromosomal malsegregation in mitotic and meiotic cells can also be studied in appropriately marked strains. Yeast has a considerable potential for endogenous activation, provided the tests are performed with appropriate cells. Exogenous activation has been achieved with S9 rodent liver in test tubes as well as in the host-mediated assay, where cells are injected into rodents. Yeast cells can be recovered from various organs and tested for induced genetic effects. The most commonly used genetic end point has been mitotic recombination either as mitotic crossing-over or mitotic gene conversion. A number of different strains are used by different authors. This also applies to haploid strains used for monitoring induction of point mutations. Mitotic chromosome malsegregation has been studied mainly with strain D6 and meiotic malsegregation with strain DIS13 . Data were available on tests with 492 chemicals, of which 249 were positive, as reported in 173 articles or reports. The genetic test/carcinogenicity accuracy was 0.74, based on the carcinogen listing established in the Gene-Tox Program. The yeast tests supplement the bacterial tests for detecting agents that act via radical formation, antibacterial drugs, and other chemicals interfering with chromosome segregation and recombination processes.

Tolerance induction during ontogeny. III. Carrier recognition by the immature and adult immune system determines tolerogenicity of hapten-carrier conjugates

Hapten-specific B-cell tolerance may be induced by nonimmunogenic hapten derivatives of carboxylmethylcellulose or methylcellulose (MC) in adult, neonatal, or irradiated fetal liver reconstituted mice. Such tolerance was shown to occur independent of T cells, and a receptor blockade has been ruled out as a causative mechanism. Oxidation and subsequent reduction of the vicinal hydroxyl groups of both carriers significantly reduces their tolerogenic potential in adult mice, yet their hapten derivatives remain nonimmunogenic. Such chemical modification of the carrier does not affect the molecular weight and not only does not reduce the binding avidity but increases it for either free antibody- or antigen-binding cells. We have examined the ability of the immature immune system to functionally discriminate between the nominal and the chemically modified hapten conjugate. Like adult mice, the immunologically immature animals were invariably capable of distinguishing between the tolerogenic and the nontolerogenic carrier. Mice treated during ontogenic development with 2,4-dinitrophenyl (DNP)-MC were found to be hapten specifically tolerant when challenged at 4 weeks of age with the TI-2 antigen DNP-Ficoll (F) but not when challenged with the polyclonal activator lipopolysaccharide (LPS) or the TI-1 antigen DNP-Brucella. Moreover, neonatal mice treated for 8 weeks with 2,4,6-trinitrophenyl-ovalbumin (TNP-OVA) were hapten specifically tolerant when challenged with TNP-OVA or the TI-1 antigen TNP-LPS but responded to a challenge with the TI-2 antigen TNP-F. These data suggest that B-cell tolerance in adult as well as in immunologically immature mice is not only carrier dependent but, in addition, that the carrier selects the B subpopulation to be rendered unresponsive. The most popular version of the clonal abortion hypothesis puts no constraints upon the nature of the antigen as long as the B cell is ontogenically "predisposed" toward being rendered unresponsive upon contact with a ligand of sufficiently high binding avidity. Our data are at variance with this prediction.

Testing of chemicals for mutagenic activity with Schizosaccharomyces pombe

Two genetic end-points are used for testing mutagens in Schizosaccharomyces pombe: forward mutations of the loci which encode steps early in the adenine synthetic pathway and reversion of certain selected mutants. 54 chemicals have been tested for at least one of the genetic end-points. The relevant literature has been reviewed through 1979.

Repair of gamma-ray induced DNA strand breaks in the radiation-sensitive mutant rad18-2 of Saccharomyces cerevisiae

The repair of gamma-ray induced DNA single and double-strand breaks was looked at in wild type and rad18-2 strains of the yeast Saccharomyces cerevisiae using sucrose gradient centrifugation. It was found that rad18-2 diploid cells could repair single and double-strand breaks induced by gamma-rays. It was also found that rad18-2 cells experienced a breakup of their DNA during post-irradiation incubation to a size smaller than seen in cells just receiving irradiation. This breakup of DNA in rad18-2 cells is not degradation due to cell death since wild type cells irradiated to similar low survival levels do not show this breakup of DNA with 8 h incubation. The breakup of DNA in rad18-2 cells is not due to replication gaps being formed by synthesis on a damaged template since treatment of rad18-2 a mating type cells with alpha factor, to prevent initiation of DNA synthesis, does not prevent breakup of the DNA.

Can experimental B cell tolerance serve as a model for self tolerance?

We have examined the abilities of the mature and immature immune systems to discriminate between tolerogenic and nontolerogenic forms of a hapten-carrier conjugate; both forms are multivalent nonimmunogenic polymers of the same molecular weight, and have the same avidity for free, hapten-specific antibody and hapten-binding B cells. Hapten-specific tolerance was induced in adult B cells by nonimmunogenic dinitrophenylated carboxymethyl cellulose or methyl cellulose. Oxidation and subsequent reduction of the vicinal hydroxyl groups of both carriers aborgated tolerogenicity, although they remained nonimmunogenic. This chemical modification did not affect the carrier's molecular weight, and it did not reduce the binding avidity of their hapten derivatives to hapten-specific antibody or to antigen-binding B cells. The same experiments, when carried out in either neonatal mice or mice that had been lethally irradiated and given the above compounds during treatment with 13-day-old fetal liver cells, invariably yielded the same results. Like adult mice, these immunologically immature animals were capable of distinguishing between the tolerogenic and the nontolerogenic form of each antigen. It has also been shown (C. A. Waters et al., in preparation) that neonatally induced tolerance to TNP-HGG is irreversible, whereas tolerance to TNP-BSA is reversible by challenge with TNP-LPS. These results are in conflict with the clonal abortion hypothesis.

Genetic activity in Saccharomyces cerevisiae and thin-layer chromatographic comparisons of medical grades of pyrvinium pamoate and monopyrvinium salts

The pamoate, chloride, and iodide salts of pyrvinium, a cyanine dye with anthelmintic properties, were studied in a diploid mitotic recombination and gene conversion assay system (strain D5 of Saccharomyces cerevisiae) and a haploid yeast reversion assay (strain XV185-14C). With the use of a thin-layer chromatographic (TLC) detection technique, samples of pyrvinium pamoate from several sources were found to contain different numbers and quantities of impurities. All samples of pyrvinium pamoate and the monopyrvinium salts were recombinogenic in strain D5 and mutagenic in strain XV185-14C; the degree of genetic activity varied among the tested medical grades of pyrvinium pamoate. Monopotassium pamoate was found to be genetically inactive in both strains. Light-catalyzed degradation did not enhance the genetic activity of pyrvinium in either of the yeast strains; the degraded samples were not mutagenic.

Genetic activity of diethylstilbestrol in Saccharomyces cerevisiae: enhancement of mutagenicity by oxidizing agents

Diethylstilbestrol (DES), a synthetic estrogen, is known to cause cancer in humans and experimental animals. Although it has been established that DES can induce unscheduled DNA synthesis, sister-chromatid exchange, and cell transformation in various short-term tests, the efforts to demonstrate its mutagenic activity in bacterial and mammalian systems have largely failed. It has been shown that DES can covalently bind to DNA after being oxidized either chemically, in the presence of iodine and hydrogen peroxide, or metabolically, by mammalian cells in tissue culture and also in the presence of rat-liver microsomes. We studied genetic activity of DES in growing cultures of the strains XV185-14C and D5 of S. cerevisiae in the presence and absence of oxidizing agents, namely, iodine and hydrogen peroxide. We demonstrated that DES alone exhibits a weak mutagenic response in the strain XV185-14C. On the other hand, the treatment of cells with DES in the presence of iodine or hydrogen peroxide plus ferrous sulfate induced a large increase in the frequency of induced mutations in strain XV185-14C and mitotic recombination and gene conversion in strain D5. This enhancement in the genetic activity of DES in our test assays in the presence of chemical oxidative systems indicates that DES undergoes oxidation to produce a genetically active metabolite.

Repair of interstrand cross-links in DNA of Saccharomyces cerevisiae requires two systems for DNA repair: the RAD3 system and the RAD51 system

We have studied the role of the excision-repair system and the recombination-repair system in the removal of cross-links and monoadducts caused by furocoumarins plus 360 nm radiation in yeast DNA by neutral and alkaline sucrose gradients and by a fluorometric procedure which detects cross-linked DNA molecules. We found that the excision-repair system, represented by the rad3 mutations, is required both for the removal of monoadducts, causing single-strand break formation, and for the removal of cross-links, causing double-strand break formation. The recombination-repair system, represented by the rad51 mutation, is necessary for double-strand break repair following cross-link removal, but it has no role in the repair of monoadducts. It can be concluded, that at least some of the same enzymes are used in yeast for both the excision of pyrimidine dimers and the excision of cross-links or monoadducts caused by furocoumarins plus light. The RAD3 and RAD51 repair systems, which act independently in the repair of UV-induced lesions, are part of a single system for the repair of cross-links.

The origin of spontaneous mutation in Saccharomyces cerevisiae

Characterization of two antimutator loci in yeast shows that both are members of the same mutagenic repair system known to be responsible for almost all induced mutation (LAWRENCE and CHRISTENSEN 1976, 1979a,b; PRAKASH 1976). One of the these newly isolated antimutator mutations is an allele of rev3 (LEMONTT 1971b). Two other alleles of rev3 were tested and were also found to be antimutators. Double mutants carrying rev3 and mutator mutations of rad3, rad51 or rad18 are like rev3 single mutants with respect to spontaneous mutation rate, supporting the hypothesis (HASTINGS, QUAH and VON BORSTEL, 1976) that many mutators in yeast act by channelling spontaneous lesions from accurate to mutagenic repair. However, the enhanced mutation rate seen in a radiation-resistant mutator mutant mut1 is not dependent on REV3, but is dependent on another gene designated ANT1. An additive effect on the reduction in spontaneous mutation, seen in the ant1 rev3 double-mutant strain, leads to the conclusion that at least 90% of spontaneous mutations seen in the wild type are caused by mutagenic repair of spontaneous lesions.

Enhanced mitotic recombination in a ligase-defective mutant of the yeast Saccharomyces cerevisiae

The temperature-sensitive Saccharomyces cerevisiae cell cycle mutant cdc9 is defective in DNA ligase, and the DNA synthesized at the restrictive temperature contains many single-strand breaks. We find that holding a diploid homozygous for cdc9 at the restrictive temperature and then plating cells at the permissive temperature gives rise to increased intragenic and intergenic recombination. In the latter case, recombinants signaled by the ade2 locus rise to about 4% of the survivors after 6 hr of incubation at the restrictive temperature. We propose that the single-strand breaks left in DNA synthesized at the restrictive temperature may lead to recombination.

Genetic effects of formaldehyde in yeast. III. Nuclear and cytoplasmic mutagenic effects

Low concentrations of formaldehyde induce nuclear mutations when yeast cells are allowed to grow in the presence of this compound. The induction of reversions is a linear function of the concentration and depends upon the repair capacities of the treated cells. A strain defective in excision-repair (rad3-12) is more mutable by formaldehyde than the isogenic wild-type whereas a strain blocked in the mutagenic pathway (rad6-1) is not mutable after the same treatment. Allele specificities were found. In particular the lys1-1 mutation is not reversible by formaldehyde. Higher concentrations of formaldehyde induce efficiently the cytoplasmic "petite" mutation in non-growing conditions when a lethal effect is noticeable. The growth phase as well as the physiological state influence this mutagenic effect. The mutagenic effect of formaldehyde in yeast is discussed in relation with the repair processes involved.

Mutagenicity of cross-links and monoadducts of furocoumarins (psoralen and angelicin) induced by 360-nm radiation in excision-repair-defective and radiation-insensitive strains of Saccharomyces cerevisiae

The furocoumarin psoralen can form both monoadducts and cross-links with DNA when combined with 360-nm radiation, whereas the analog angelicin can form monoadducts only. Psoralen plus 360-nm radiation causes mutation induction with a slope of 2 (log-log plot) for a radiation-insensitive strain, whereas angelicin action with 360-nm radiation displays a slope of unity. For a radiation-sensitive mutant defective in the excision-repair pathway, the actions of both angelicin and psoralen plus 360-nm radiation exhibit one-target kinetics, but at higher exposures psoralen plus 360-nm radiation assumes a slope of 2. The excision-repair-defective strain is considerably more sensitive to the furocoumarins plus 360-nm radiation than is the radiation-insensitive strain, both for killing and mutation induction. The simplest explanation for the data is that both cross-links and monoadducts, formed by furocoumarins with DNA when exposed to 360-nm radiation, are capable of inducing mutations, and that monoadducts are repaired 20 times more efficiently than cross-links by the excision-repair pathway.

Spontaneous mutation by mutagenic repair of spontaneous lesions in DNA

Strains of yeast carrying mutations in many of the steps in pathways repairing radiation-induced damage to DNA have enhanced spontaneous mutation rates. Most strains isolated because they have enhanced spontaneous mutation carry mutations in DNA repair systems. This suggests that much spontaneous mutation arises by mutagenic repair of spontaneous lesions.

Mutator activity of petite strains of Saccharomyces cerevisiae

Petite strains in Saccharomyces exhibit enhanced spontaneous mutation rates of nuclear genes regardless of whether they are cytoplasmically or nuclearly inherited, or whether or not the cytoplasmic petite strains have mitochondrial DNA. In petite strains, the mutation rate for the nonsense allele lys1-1 is enhanced by a factor of 3-6 and for the missense allele his1-7 by a factor of 2 as compared with their grande counterparts. The reversion of a third allele, the putative frameshift mutation, hom3-10, is not enhanced in a petite background. The results indicate that the spontaneous mutation rate of an organism can be altered by indirect intracellular influences.

Mutators in Saccharomyces cerevisiae: MUT1-1, MUT1-2 and MUT2-1

The purpose of this study was to characterize two mutator stocks of yeast which were induced and selected on the basis of high spontaneous reversion rates of the suppressible "ochre" nonsense allele lys1-1. In the mutator stock VA-3, a single mutation, designated mut1-1, is responsible for the increase in the reversion rate of the ochre alleles lys1-1 and arg4-17. In stock VA-105, there are two separate mutator mutations. Tetrad analysis data showed these two loci are loosely linked. Based on complementation data, one of these mutations is at the same locus as mut1-1 and designated mut1-2. The second mutator of stock VA-105 was designated mut2-1. All three mutators are recessive. Both mut1-1 and mut1-2 give a high mutation rate for ochre nonsense suppressor (SUP) loci, but not for the ochre nonsense alleles. On the contrary, the mutation rates of the ochre alleles are greatly reduced. With the mutant mut2-1 there were mutations at both the lys1-1 site and its suppressors; mut2-1 is as effective as mut1-2 but not as effective as mut1-1 in inducing reversions of a missense mutant, his1-7. Neither mut1-1, mut1-2 nor mut2-1 were effective in inducing reversions of a putative frameshift mutation, hom3-10, or in inducing forward mutations to canavanine resistance.

Genetic activity of the antimicrobial food additives AF-2 and H-193 in Saccharomyces cerevisiae

The genetic activity of the antimicrobial food additives AF-2 and H-193 has been investigated in Saccharomyces cerevisiae. The strains chosen for the present studies were D5 for the induction of mitotic recombinational events and XV185-14C for the induction of reversion of the mutants lys1-1, his1-7 and homs3-7. When three concentrations (25, 50 and 100 mug/ml) of AF-2 were used in the reversion system of strain XV185-14C, there was an increase in the frequency of hom+ and his+ revertants as a function of incubation time, while the lysine mutant exhibited a very low frequency of induced reversion. When AF-2 and H-193 were compared at the same concentration and exposure time, AF-2 exhibited a higher genetic activity in both systems than H-193. However, H-193 was genetically more active in inducing revertants than AF-2, when the comparison was made at the same survival level. Cells of both haploid and diploid strains were found to be more sensitive to inactivation by AF-2 than by H-193 It should be pointed out that the solubility of H-193 was lower (about 4 mug/ml saturation) than the solubility of AF-2 (120 mug/ml saturation). The haploid strain was more sensitive to both compounds than the diploid strain.