Obtaining mutations with cytoplasmic male sterility (CMS) in Dactylis glomerata L. under the influence of chemical mutagens]

When treating seeds of orchard grass with definite concentrations of nitrosoethylurea (NEU), dimethyl sulphate (DMS) and ethylene imine (EI) in M1 and M2 the plants with CMS as well as sterility fixators to them are obtained. Proportionality of mutagenic action and stimulation effect of these substances are found. The greatest amount of sterility fixators is found in M1 among plants the seeds of which were treated with NEU and EI; in M2 the fixators are found among plants obtained after treating seeds with DMS. Sterility fixators were found among plants of the VIK-61 and Asta and VIK-61XAsta hybrid population.     

Comutagenic effects exerted by N-nitroso compounds.

Mutagenesis induced by dimethylnitrosamine (DMN) and N-methyl-N-nitrosourea (NMU) in Salmonella typhimurium TA100 and TA1530 is characterized by biphasic dose and time response curves. At low doses or short incubation times mutagenic response is minimal, but increases rapidly when an apparent threshold dose or threshold incubation time is exceeded. Bacteria pretreated with subthreshold doses of DMN or NMU were many times more sensitive to the mutagenic effects of methylating and ethylating N-nitroso compounds than were untreated bacteria. The growth phase of the bacteria had little effect on the percentage enhancement of mutagenesis caused by pretreatment with NMU although exponentially growing cells were more sensitive to mutagenesis induced by NMU or diethylnitrosamine. Mutagenesis induced by methylmethanesulfonate and N-propyl-N'-nitro-N-nitrosoguanidine was not significantly enhanced by pretreatment of bacteria with NMU or NEU suggesting that the former mutagens act by different mechanisms than NMU or NEU.     

家蚕化学诱变剂及诱导突变体的筛选

在家蚕Bombyx mori基因组计划完成之后,其功能基因组研究成为该领域的最重要课题。突变体是功能基因组学研究的重要材料,因此,通过人为诱导获取大量的突变系统是及其重要的手段。本研究用化学诱变剂ENU、MNU、DES、5-BU、EMS诱导处理家蚕标准品种C108,筛选获得了非滞育红卵,长圆筒茧、小茧、丝胶茧及绵茧突变体,致死突变体及无鳞毛蛾翅突变体。结果还表明： MNU、DES诱变家蚕的突变效率高,注射翅原基比腹部更方便且效果好,化学诱导雄体比雌体的效果好; 在时期上,注射蛹和蛾都有诱导效果。上述突变体大多为致死性突变,推测其可能与致死性基因突变有关。同时,本研究为应用TILLING技术鉴定家蚕更多目的基因突变体提供了有效的材料。     

The chemical mutagen dimethyl sulphate induces homologous recombination of plasmid DNA by increasing the binding of RecA protein to duplex DNA.

The role of different DNA damages in the stimulation of homologous recombination was studied by using an in vivo plasmid recombination assay. Dimethyl sulphate (DMS) treatment of plasmid DNA induced a 20-50-fold increase in the frequency of recombinational events. DMS treatment also stimulated RecA protein binding to double-stranded DNA. In contrast, plasmid DNA containing uracil, which, like DMS, is also subject to repair, was less effective in stimulation of recombination. The ability of purified RecA protein to bind DMS-treated or uracil-containing DNA was tested by measuring its ATPase activity. The result indicates that DMS treatment, but not uracil incorporation, stimulates RecA protein binding to DNA. We conclude, that the main reason (or the first step) for stimulation of recombination by mutagens is activation of RecA binding to damaged DNA.     

Effect of nitrosourea in small doses on the frequency of mutation in Salmonella typhimurium

The effect of N-nitroso-N-methylurea (NMU), N-nitroso-N,N'-dimethylurea (NDMU) and N-nitroso-N-ethylurea (NEU) at doses less than 100 mkg/ml on mutability of Salmonella typhimurium strains of Ames' system (G-46, TA-1950, TA-1535, TA-100, TA-1538) has been studied. NMU and NEU at doses of 5-10 mkg/ml have been found to increase the survival and decrease the number of reversions from auxotrophity in histidine to prototrophity. The effect of given doses of NMU and NEU on bacteria repair activity has been shown. The role of pk M101 plasmide in this process is being discussed. NDMU in contrast to NMU and NEU induces read frome shift mutations and exhibits high mutagenous activity at all doses examined.     

Novel pH-dependent regulation of human cytosolic sialidase 2 (NEU2) activities by siastatin B and structural prediction of NEU2/siastatin B complex

Human cytosolic sialidase (Neuraminidase 2, NEU2) catalyzes the removal of terminal sialic acid residues from glycoconjugates. The effect of siastatin B, known as a sialidase inhibitor, has not been evaluated toward human NEU2 yet. We studied the regulation of NEU2 activity by siastatin B in vitro and predicted the interaction in silico. Inhibitory and stabilizing effects of siastatin B were analyzed in comparison with DANA (2-deoxy-2,3-dehydro-N-acetylneuraminic acid) toward 4-umbelliferyl N-acetylneuraminic acid (4-MU-NANA)- and α2,3-sialyllactose-degrading activities of recombinant NEU2 produced by E. coli GST-fusion gene expression. Siastatin B exhibited to have higher competitive inhibitory activity toward NEU2 than DANA at pH 4.0. We also revealed the stabilizing effect of siastatin B toward NEU2 activity at acidic pH. Docking model was constructed on the basis of the crystal structure of NEU2/DANA complex (PDB code: 1VCU). Molecular docking predicted that electrostatic neutralization of E111 and E218 residues of the active pocket should not prevent siastatin B from binding at pH 4.0. The imino group (¹NH) of siastatin B can also interact with D46, neutralized at pH 4.0. Siastatin B was suggested to have higher affinity to the active pocket of NEU2 than DANA, although it has no C7–9 fragment corresponding to that of DANA. We demonstrated here the pH-dependent affinity of siastatin B toward NEU2 to exhibit potent inhibitory and stabilizing activities. Molecular interaction between siastatin B and NEU2 will be utilized to develop specific inhibitors and stabilizers (chemical chaperones) not only for NEU2 but also the other human sialidases, including NEU1, NEU3 and NEU4, based on homology modeling.     

Protective protein/cathepsin A rescues N-glycosylation defects in neuraminidase-1

Background

Neuraminidase-1 (NEU1) catabolizes the hydrolysis of sialic acids from sialo-glycoconjugates. NEU1 depends on its interaction with the protective protein/cathepsin A (PPCA) for lysosomal compartmentalization and catalytic activation. Murine NEU1 contains 4 N-glycosylation sites, 3 of which are conserved in the human enzyme. The expression of NEU1 gives rise to differentially glycosylated proteins.

Methods

We generated single-point mutations in mouse NEU1 at each of the 4 N-glycosylation sites. Mutant enzymes were expressed in NEU1-deficient cells in the presence and absence of PPCA.

Results

All 4 N-glycosylation variants were targeted to the lysosomal/endosomal compartment. All N-glycans, with the exception of the most C-terminal glycan, were important for maintaining stability or catalytic activity. The loss of catalytic activity caused by the deletion of the second N-glycan was rescued by increasing PPCA expression. Similar results were obtained with a human NEU1 N-glycosylation mutant identified in a sialidosis patient. The N-terminal N-glycan of NEU1 is indispensable for its function, whereas the C-terminal N-glycan appears to be non-essential. The omission of the second N-glycan can be compensated for by upregulating the expression of PPCA.

General significance

These findings could be relevant for the design of target therapies for patients carrying specific NEU1 mutations.     

Isolation of Serratia marcescens mutants superproducers of endonuclease by exposure to nitrosomethylurea in a synchronized culture

The work was aimed at studying the capability of chemical mutagens, such as hydroxylamine (HA), dimethyl sulfate (DMS) and nitrosomethylurea (NMU), to produce mutants of Serratia marcescens with an elevated synthesis of endonuclease. HA and DMS did not induce these mutations at tested concentrations. NMU caused such mutations resulting in a sharp rise of endonuclease production. The mutagen was added to the medium at different periods of synchronized DNA replication to generate a selective effect on certain genes located in the replication sites. A 15-minute period 40 min after the beginning of the lag-phase was shown to be most sensitive to NMU treatment for producing mutants with a high yield of endonuclease. A mutant of S. marcescens was obtained, which synthesized endonuclease 40-100 times as effective as the parent strain did. The ability of S. marcescens endonuclease to hydrolyze RNA and DNA and to inhibit the reproduction of RNA- and DNA-containing viruses is of practical importance.     

The chiral mutagens: cytogenetic effects on higher plants

The paper covers investigation of cytogenetic activity of chiral mutagens and their specific effects on the plant cells chromosomes of soft winter wheat (Triticum aestivum L.). Comparative analysis of cytogenetic activity of chiral NEU: S(+)1-N-nitroso- 1-N-methyl-3-N-sec-buthylureas (S(+)NMsBU) and R(-)1-N-nitroso- 1N-methyl-3-Nsec-buthylureas (R(-)NMsBU) on winter wheat was performed. As it was shown by the frequency of chromosomal aberrations the S(+) stereoisomer was twice more active than R(-). In addition to typical anaphase aberrations (fragments, bridges, lagging chromosomes) the numerous mitosis pathologies were revealed - K-mitoses, hyperspiralization and despiralization of chromosomes, unequal allocation of chromosomes between the daughter nuclei, mass fragmentation, nondisjunction and chromosome adhesion, three-pole mitoses, etc. Neither of the mentioned pathologies was observed under the action of NEU and gamma-rays.     

Analysis of a case of mutagen specificity in Neurospora crassa. IV. Interactions between UV and three chemical mutagens

Summary In the strain ad 3A 38701 inos 37401, UV usually produces about twice as many inositol-as adenine-reversions. We have shown previously that this inositol-specificity of UV can be reversed into adenine-specificity by pre- or post-treatment with low doses of the adenine-specific DEB. We now have tested two more adenine-specific mutagens, nitrous acid (NA) and a mixture of hydrogen peroxide and formaldehyde (HF) and one inositolspecific mutagen nitrosoethylurethane (NEU) for interaction with UV. The former two substances behaved like DEB in reversing the inositol-specificity of UV when given as pre-or post-treatment. Pre-treatment with NEU always enhanced the frequency of inositol-reversions beyond additivity. At low doses, it also enhanced the frequency of adenine-reversions. The results are discussed in relation to mutagen specificity. They indicate that specificity may arise from the effects of treatment on cellular events in any one of the three major parts of the mutational pathway: repair, expression, growth of completed mutants into clones.     

Influence of mutagenic factors on the epidermis of tomatillo,currant tomato and tomato

Epidermal features of control, 16 treated and 7 mutants ofPhysalis ixocarpa BROT. (tomatillo),Lycopersicon esculentum MILL. (tomato) andL. pimpinellifolium MILL. (currant tomato) are studied. Although the distribution, ontogenesis and mature structure of stomata in control as well as in treated and mutant plants were similar, the mutagens reduced the stomatal abnormalities which were abundant (60%) inP. ixocarpa. Maximum rectification was found after combined treatment of gamma radiation (5.16 C kg^-1 [= 20 kR]) + 1 % dimethyl sulphate. Methyl ethane sulfonate, gamma radiation and gamma radiation + DMS caused an increase in epidermal cell size irrespective of the leaf size but in DMS and diethyl sulphate treated plants, a close negative correlation between leaf size and epidermal coll size was observed. The size and frequency of stomata were also affected, the large leaf usually showed high frequency and small size stomata. The data reveal that mutagens affect the epidermal structures differently.     

一种特异性识别小细胞肺癌细胞的小分子肽

应用“一个珠子一个化合物”的组合化学肽库技术,筛选得到特异性识别小细胞肺癌细胞(DMS53)的小分子肽.初次筛选共得到32个与DMS53阳性结合的珠子,经氨基酸序列分析后发现,含有cNGRXXXc或cXNGRXXc肽链结构的序列共有10个.再次合成三种有代表性的小分子肽,发现cFNGRQQc与DMS53的结合率明显高于其他小分子肽.选择cFNGRQQc作进一步的细胞特异性研究,发现cFNGRQQc与DMS53的粘附特异性明显高于其他细胞系,对cFNGRQQc的结构分析显示,-NGR-及六肽长度对小分子肽与DMS53细胞的粘附非常重要.用抗整合素、E-cadherin、NCAM及ICAM的抗体或多肽阻断小分子肽与DMS53细胞表面的相应受体结合,未见明显的阻断效应.小分子肽与DMS53细胞表面的结合位点有待于进一步证实.     

Comparative effectiveness in the induction of sister chromatid exchanges and chromosome aberrations

The dose curves for 5 chemicals were studied to compare the efficiency of induction of SCEs and chromosomal aberrations by "polycentric" mutagens. The number of SCEs was found to increase linearly with the dose while that of chromosomal aberrations--nonlinearly. The efficiency of SCEs induction by these mutagens was found to be 25-50 times as high as in the induction of chromosomal aberrations. Division of alkylating mutagens into "monocentric" and "polycentric" is shown to be useful. It reflects their different efficiency in damaging one or simultaneously two DNA strands. The correlation between SCEs and formation of aberrations of the chromatid type is stated.     

Heterodimerization of the Sialidase NEU1 with the Chaperone Protective Protein/Cathepsin A Prevents Its Premature Oligomerization

Lysosomal neuraminidase-1 (NEU1) forms a multienzyme complex with β-galactosidase and protective protein/cathepsin A (PPCA). Because of its association with PPCA, which acts as a molecular chaperone, NEU1 is transported to the lysosomal compartment, catalytically activated, and stabilized. However, the mode(s) of association between these two proteins both en route to the lysosome and in the multienzyme complex has remained elusive. Here, we have analyzed the hydrodynamic properties of PPCA, NEU1, and a complex of the two proteins and identified multiple binding sites on both proteins. One of these sites on NEU1 that is involved in binding to PPCA can also bind to other NEU1 molecules, albeit with lower affinity. Therefore, in the absence of PPCA, as in the lysosomal storage disease galactosialidosis, NEU1 self-associates into chain-like oligomers. Binding of PPCA can reverse self-association of NEU1 by causing the disassembly of NEU1-oligomers and the formation of a PPCA-NEU1 heterodimeric complex. The identification of binding sites between the two proteins allowed us to create innovative structural models of the NEU1 oligomer and the PPCA-NEU1 heterodimeric complex. The proposed mechanism of interaction between NEU1 and its accessory protein PPCA provides a rationale for the secondary deficiency of NEU1 in galactosialidosis.Mammalian neuraminidases have been classified as lysosomal (NEU1),⁴ cytosolic (NEU2), plasma membrane (NEU3), and mitochondria/lysosomal (NEU4) based on their subcellular distributions, pH optimum, kinetic properties, responses to ions and detergents, and substrate specificities (1–3). Of the four sialidases, only NEU1 is ubiquitously expressed at different levels in various tissues and cell types (4–7). The importance of these proteins in normal cellular physiology is illustrated by the numerous metabolic processes that they control, including cell proliferation and differentiation, cell adhesion, membrane fusion and fluidity, immunocyte function, and receptor modification (8–21).NEU1 initiates the intralysosomal hydrolysis of sialo-oligosaccharides, -glycolipids, and -glycoproteins by removing their terminal sialic acid residues. In human and murine tissues, NEU1 forms a complex with at least two other proteins, β-galactosidase and the protective protein/cathepsin A (PPCA) (22). By virtue of their association with PPCA, NEU1 and β-galactosidase acquire their active and stable conformation in lysosomes. However, PPCA appears to function as a crucial chaperone/transport protein for NEU1. Because NEU1 is poorly mannose 6-phosphorylated, it depends on PPCA for correct compartmentalization and catalytic activation in lysosomes (23–25). Only a small amount of PPCA and β-galactosidase activities is found in the NEU1-PPCA-β-galactosidase complex, which instead contains all of the NEU1 catalytic activity (24–27). By understanding how and when NEU1 and PPCA interact, how they regulate each other in different cell types, and what determinants control their association, we may gain important insight into their significance in physiologic and pathologic conditions.The absence of NEU1 is associated with two neurodegenerative diseases that involve glycoprotein metabolism; sialidosis, which is caused by structural lesions in the lysosomal NEU1 locus (28), and galactosialidosis (GS), a combined deficiency of NEU1 and β-galactosidase which is caused by the absence of PPCA (22). Patients with sialidosis and those with GS have similar clinical and biochemical features, and both diseases are characterized by multiple phenotypes that are classified according to the age of onset and severity of the symptoms.Previously, we generated two animal models of primary or secondary NEU1 deficiency, Neu1^−/− mice and Ppca^−/− mice. Both mouse models have a profound loss of Neu1 activity in multiple tissues and develop clinical, biochemical, and pathologic manifestations resembling those seen in patients with severe sialidosis and GS (29–31). Neu1^−/− mice are phenotypically similar but not identical to Ppca^−/− mice and, like children with the disease, exhibit a time-dependent splenomegaly associated with extramedullary hematopoiesis (30, 31). We found that the cause of these phenotypic abnormalities is the gradual loss of retention of hematopoietic progenitors within the bone niche due to exacerbated lysosomal exocytosis of bone marrow cells. The latter process is negatively regulated by NEU1 activity (31).The mode of interaction between PPCA and NEU1 and the mechanism of catalytic activation are not well understood. Here we present biochemical, analytical, and structural analyses of NEU1, PPCA, and the PPCA-NEU1 complex by using purified baculovirus (BV)-expressed wild-type and mutagenized recombinant enzymes and synthetic peptides.     

Growth Kinetics of Hyphomicrobium and Thiobacillus spp. in Mixed Cultures Degrading Dimethyl Sulfide and Methanol

The growth kinetics of Hyphomicrobium spp. and Thiobacillus spp. on dimethyl sulfide (DMS) and methanol (in the case of Hyphomicrobium spp.) in an enrichment culture created from a biofilter cotreating DMS and methanol were studied. Specific growth rates of 0.099 h⁻¹ and 0.11 h⁻¹ were determined for Hyphomicrobium spp. and Thiobacillus spp., respectively, growing on DMS at pH 7. These specific growth rates are double the highest maximum specific growth rate for bacterial growth on DMS reported to date in the literature. When the pH of the medium was decreased from pH 7 to pH 5, the specific growth rate of Hyphomicrobium spp. decreased by 85%, with a near 100-fold decline in the yield of Hyphomicrobium 16S rRNA gene copies in the mixed culture. Through the same pH shift, the specific growth rate and 16S rRNA gene yield of Thiobacillus spp. remained similar. When methanol was used as a substrate, the specific growth rate of Hyphomicrobium spp. declined much less over the same pH range (up to 30%) while the yield of 16S rRNA gene copies declined by only 50%. Switching from an NH₄⁺-N-based source to a NO₃⁻-N-based source resulted in the same trends for the specific growth rate of these microorganisms with respect to pH. This suggests that pH has far more impact on the growth kinetics of these microorganisms than the nitrogen source. The results of these mixed-culture batch experiments indicate that the increased DMS removal rates observed in previous studies of biofilters cotreating DMS and methanol are due to the proliferation of DMS-degrading Hyphomicrobium spp. on methanol at pH levels not conducive to high growth rates on DMS alone.Dimethyl sulfide (DMS) is a reduced sulfur compound that is emitted from both natural and anthropogenic sources. Natural DMS emissions are largely the result of the cleavage of dimethylsulfoniopropionate (9), the breakdown of the sulfur-containing amino acids methionine and cysteine (9, 11), and the degradation of methoxylated aromatic compounds (3, 9). Anthropogenic DMS emissions tend to be the result of high-temperature industrial processes and are problematic due to the foul smell of DMS and its low odor threshold (34). Industries that are sources of anthropogenic DMS emissions include wastewater treatment (14), aerobic composting (40), animal rendering (23), and kraft pulping (35).In the environment, microbial degradation can be a significant sink for DMS. In seawater, approximately 90% of the DMS produced is removed biologically before it reaches the atmosphere (21). Removal of DMS in the environment can be carried out by a variety of pathways. Aerobic bacteria, such as Hyphomicrobium spp. (7, 27, 36, 45), Thiobacillus spp. (6, 19, 42), or Methylophaga spp. (10), convert DMS to oxidized inorganic sulfur products such as sulfate and thiosulfate. There are also a wide variety of microorganisms, such as Pseudomonas spp. (46), capable of oxidizing DMS to dimethyl sulfoxide (DMSO) (11, 18). Finally, DMS can be eliminated through several anaerobic pathways, with a variety of methanogens (13, 22), sulfate-reducing bacteria (39), phototrophic bacteria (41, 44), and denitrifiers (42) capable of growth on DMS being reported in the literature.The prevalence of bacteria in the environment capable of growth on DMS has created interest in developing low-cost biotechnological methods to remove DMS from industrial waste gas streams. One possible technology is biofiltration which involves passing waste air through a packed bed of microorganisms. Removal of DMS in these systems, however, has proved to be difficult. This is believed to be due to the acidification of the biofilter bed brought about by the conversion of DMS to sulfate (32).Previous research by our group investigated the effect of the presence of methanol on DMS removal rates in inorganic biofilters treating DMS inoculated with sludge since industrial biofilters often treat mixtures of waste gases with biofilms composed of mixed microbial communities. It was demonstrated that the DMS degradation rate in biofilters where the pH of the biofilter bed was allowed to acidify naturally over time to pH 5 before the pH was neutralized back to pH 7 could be increased by up to 11-fold with methanol cotreatment (47). The increase in the DMS removal rates was shown to be the result of an order of magnitude increase in the concentration of Hyphomicrobium spp., which were also capable of growth on methanol (16). Methanol addition also resulted in a decrease in the full conversion of DMS to sulfate (increase in S⁰) and nitrification in biofilters cotreating DMS and methanol compared to the biofilter treating DMS alone, resulting in a decrease in the rate of acidification in these biofilters (48). Finally, it was shown that the DMS removal rate in these biofilters could be optimized by adopting step-feeding (49) and pulse-feeding (50) strategies.This paper focuses on the mechanism behind increased DMS removal rates in biofilters cotreating DMS and methanol. The behavior of an enrichment culture created from a biofilter cotreating DMS and methanol under different conditions relevant to biofilter operations as reported previously was investigated. Batch studies coupled with quantitative PCR (qPCR) methods were conducted to determine the effect of pH and nitrogen source on the kinetics of Hyphomicrobium spp., Thiobacillus spp., and a group of bacteria closely related to Chitinophaga spp. present in the enrichment culture grown on DMS and methanol.     

Interaction between chemical mutagens with a delayed effect and metabolites of seeds

Summary A study was made of chromosome aberrations in Crepis capillaris seedlings, induced by the reaction products of chemical mutagens with seed metabolites. Interaction between ethylenimine and seed metabolites of some plants of the family Compositae (C. capillaris, Taraxacum officinale, Pyrethrum carneum, Helianthus annuus) has been found to lead to the formation of highly active secondary mutagens whose action remains similar to that of ethylenimine, although the effect of ethylenimine is enhanced dozens of times. The substances responsible for this enhancement effect are contained in the fruit coating of the seed. The metabolites of seeds of other plants studied (Triticum vulgare, Hordeum vulgare, Fagopyrum esculentum) enhanced the effect of ethylenimine only 1.5–2.0 times. Unlike ethylenimine, the effect of its derivatives (thioTEP and phosphazine) and of ethyl methanesulphonate, HN2 and maleic hydrazide is not enhanced after their interaction with metabolites of compositae plant seeds. Experiments with HN2 revealed an almost complete inactivation of the mutagenic action of NH2 by metabolites of C. capillaris seeds. The observed modification of the mutagenic action of ethylenimine and NH2 after successive treatment of seedlings with mutagens and metabolites of seeds points to the preservation of the mutagen in the cell. It is concluded that when chemical mutagens act on the cells, chromosome aberrations are induced not only by the chemical agent itself, but also by its reaction with cell metabolites.     

NEU3 sialidase strictly modulates GM3 levels in skeletal myoblasts C2C12 thus favoring their differentiation and protecting them from apoptosis

Membrane-bound sialidase NEU3, often referred to as the "ganglioside sialidase," has a critical regulatory function on the sialoglycosphingolipid pattern of the cell membrane, with an anti-apoptotic function, especially in cancer cells. Although other sialidases have been shown to be involved in skeletal muscle differentiation, the role of NEU3 had yet to be disclosed. Herein we report that NEU3 plays a key role in skeletal muscle differentiation by strictly modulating the ganglioside content of adjacent cells, with special regard to GM3. Induced down-regulation of NEU3 in murine C2C12 myoblasts, even when partial, totally inhibits their capability to differentiate by increasing the GM3 level above a critical point, which causes epidermal growth factor receptor inhibition (and ultimately its down-regulation) and an higher responsiveness of myoblasts to the apoptotic stimuli.     

Lack of Chemically Induced Mutation in Repair-Deficient Mutants of Yeast

Two genes, rad6 and rad9, that confer radiation sensitivity in the yeast Saccharomyces cerevisiae also greatly reduce the frequency of chemically-induced reversions of a tester mutant cyc1-131, which is a chain initiation mutant in the structural gene determining iso-1-cytochrome c. Mutations induced by ethyl methanesulfonate (EMS), diethyl sulfate (DES), methyl methanesulfonate (MMS), dimethyl sulfate (DMS), nitroquinoline oxide (NQO), nitrosoguanidine (NTG), nitrogen mustard (HN2), beta-propiolactone, and tritiated uridine, as well as mutations induced by ultraviolet light (UV) and ionizing radiation were greatly diminished in strains homozygous for either the rad6 or rad9 gene. Nitrous acid and nitrosoimidazolidone (NIL), on the other hand, were highly mutagenic in these repair-deficient mutants, and at low doses, these mutagens acted with about the same efficiency as in the normal RAD strain. At high doses of either nitrous acid or NIL, however, reversion frequencies were significantly reduced in the two rad mutants compared to normal strains. Although both rad mutants are immutable to about the same extent, the rad9 strains tend to be less sensitive to the lethal effect of chemical mutagens than rad6 strains. It is concluded that yeast requires a functional repair system for mutation induction by chemical agents.     

The Effect of Heterosis and Inheritance of Quantitative Traits in Silkworm Exposed to Electromagnetic Irradiation

The effect of heterosis was studied in several quantitative traits of clone breed and interbreed silkworm hybrids exposed to electromagnetic irradiation ( = 1.6 cm, power density 700 W/cm²) during postdiapause embryonic development. The influence of the type of reproduction on the manifestation of irradiation effects in the next generation was also examined. In hybrids, the resistance to low-intensity high-frequency irradiation was higher than in the parental forms. Unlike the latter, the hybrids showed no significant modification of the traits after the exposure to electromagnetic irradiation. In the second generation, the modifying effect of irradiation is retained in the case of parthenogenetic silkworm development but not after mating.