Effect of the yellow locus on sensitivity of drosophila sex cells to chemical mutagens

The effect of the yellow (y) locus on germ cell sensitivity to the alkylating agent ethyl methanesulfonate (EMS) has been studied in Drosophila. Since DNA repair is one of the most important factors that control cell sensitivity to mutagens, the approaches used in our experiments aimed at evaluating the relationship between germ-cell mutability and activity of DNA repair. Germ-cell mutability and repair activity were assessed using several parameters, the most important of which was the frequency of the recessive sex-linked lethal mutations (RSLLM). In one series of experiments, the adult males of various genotypes (Berlin wild; y; y ct v; y mei-9a) were treated by mutagenic agents and then crossed to Basc females. Comparative analysis of germ-cell mutability as dependent on genotype and the stage of spermatogenesis showed that the yellow mutation significantly enhanced the premeiotic cell sensitivity to EMS, presumably, due to the effect on DNA repair. In the second series of experiments, the effect of the maternal DNA repair was studied and, accordingly, mutagen-treated Basc males were crossed to females of various genotypes including y and y mei-9a ones. The crosses involving y females yielded F1 progeny with high spontaneous lethality, whereas in F2, the frequency of spontaneous mutations was twice higher. The germ cell response to EMS depended also on female genotype: the effect of yellow resulted in increased embryonic and postembryonic lethality, whereas the RSLLM frequency decreased insignificantly. The latter result may be explained by elimination of some mutations due to 50% mortality of the progeny. The results obtained using the above two approaches suggest that the yellow locus has a pleiotropic effect on the DNA repair systems in both males and females of Drosophila.     

Effects of caffeine on chromosomal loss and nondisjunction in Drosophila melanogaster

Three types of male larvae, normal X males and two types with structurally abnormal X chromosomes (ring X and short X sc ⁴ sc ³, y) were treated during the third instar with 0.5 per cent caffeine in nutrient medium. Upon eclosion, these males were mated to yellow and Oregon-R wild type females. The F₁ generation of each cross was scored for normal (XX and XY) and abnormal (XO and XXY) progeny. Statistical analyses of data demonstrate that caffeine increases chromosomal loss for all genotypes tested. The effect of caffeine on nondisjunction, however, is not clear. There are at least marginal increases in all cases when Oregon-R females are used. Slight increase and decreases noted for offspring of yellow females appear to be dependent upon the genotype of the inseminating male.     

Genetic damage induced by X-rays or neutrons in spermatozoa of Drosophila melanogaster; differential processing in the oocytes of females carrying the DNA-repair-deficient mutants mei-9a and mus-101d1

Radiation-induced premutational lesions on the chromosomes of irradiated mature spertozoa of Drosphila are processed when the sperm nucleus the egg cytoplasm at fertilization. This processing depends on enzymatic repair systems, which are built up in ocytes under the control of the maternal genotype. The present study is concerned with 2 repair-deficient mutants, mei-9^a and mus-101^D1. Irradiated Basc males were crossed to homozygous mei-9^a or mus-101^D1 females, or to repair-proficient control females. The frequencies of recovered sex-link recessive lethal mutations and of II–III translocations were used to assess the effects of impaired maternal repair. Neutrons, as a densely ionizing radiation, and X-rays as a sparsely ionizing one, were used to induce the premutational lesions.The question being asked was whether different radiation qualities cause specific types of lesion that are processed differentially under conditions of impaired maternal repair. The results indicate that this may be so. In comparison with the control, with repair-proficient females, all major effects caused by impaired maternal repair led to frequency reductions in the recovery of lethals and translocations. These reductions in yield were pronounced in all neutron experiments, whereby mus-101^D1 had a stronger effect than mei-9^a. Two possible explanations are considered. The first is based on the idea that specific lesions are processed in a specific way, resulting in a specific mutational end-product, which may not be recovered when repair is impaired. The second is based on the notion that energy deposition in cells exposed to neutrons is not uniform, which leads to clustered damage. Impaired repair may select againts multiply damaged cells much more powerfully than normal repair. Consequently, the surviving fraction of cells is likely to have received less than the average dose. With X-rays, no or only spurious effects of the repair-defective mutants were detected, except in the following case: recovery of translocations (but not of lethals) was strongly reduced when irradiated males were crossed to mus-101^D1 females. It is assumed that mus-101^D1 is defective in repair of DNA double-strand damage, and that the formation of translocations may depend particularly on this repair function.     

The relationship between reaction kinetics and mutagenic action of monofunctional alkylating agents in higher eukaryotic systems. IV. The effects of the excision-defective mei-9L1 and mus(2)201D1 mutants on alkylation-induced genetic damage in Drosophila

Repair-defective mutants of Drosophila melanogaster which identify two major DNA excision repair loci have been examined for their effects on alkylation-induced mutagenesis using the sex-linked recessive lethal assay as a measure of genotoxic endpoint. The alkylating agents (AAs) chosen for comparative analysis were selected on the basis of their reaction kinetics with DNA and included MMS, EMS, MNU, DMN, ENU, DEN and ENNG. Repair-proficient males were treated with the AAs and mated with either excision-defective mei-9L1 or mus(2)201D1 females or appropriate excision-proficient control females. The results of the present work suggest that a qualitative and quantitative relationship exists between the nature and the extent of chemical modification of DNA and the induction of of genetic alterations. The presence of either excision-defective mutant can enhance the frequency of mutation (hypermutability) and this hypermutability can be correlated with the Swain-Scott constant S of specific AAs such that as the SN1 character of the DNA alkylation reaction increases, the difference in response between repair-deficient and repair-proficient females decreases. The order of hypermutability of AAs with mei-9L1 relative to mei-9+ is MMS greater than MNU greater than DMN = EMS greater than iPMS = ENU = DEN = ENNG. When the percentage of lethal mutations induced in mei-9L1 females are plotted against those determined for control females, straight lines of different slopes are obtained. These mei-9L1/mei-9+ indices are: MMS = 7.6, MNU = 5.4, DMN = 2.4, EMS = 2.4 and iPMS = ENU = DEN = ENNG = 1. An identical order of hypermutability with similar indices is obtained for the mus(2)201 mutants: MMS(7.3) greater than MNU (5.4) greater than EMS(2.0) greater than ENU(1.1). Thus, absence of excision repair function has a significant effect on mutation production by AAs efficient in alkylating N-atoms in DNA but no measurable influence on mutation production by AAs most efficient in alkylating O-atoms in DNA. The possible nature of these DNA adducts has been discussed in relation to repair of alkylated DNA. In another series of experiments, the effect on alkylation mutagenesis of mei-9L1 was studied in males, by comparing mutation induction in mei-9L1 males vs. activity in Berlin K (control). Although these experiments suggested the existence of DNA repair in postmeiotic cells during spermatogenesis, no quantitative comparisons could be made.(ABSTRACT TRUNCATED AT 400 WORDS)     

The suppressor of Hairy-wing binding region is required for gypsy mutagenesis

Summary We undertook a deletional analysis of the gypsy retrotransposon in order to determine which sequences of the element are required for its mutagenic effect. We show that a phenotype indistinguishable from that ofy ² flies can be generated by transformingy ^– flies with a construct containing theyellow gene and a gypsy element located at the same insertion site inyellow as found iny ² flies. When flies are transformed with similar constructs in which increasing amounts of the 5 transcribed untranslated region of gypsy have been removed, either a partialy ² revertant or a completely revertant phenotype is obtained. These results yield direct proof that the region of gypsy to which thesu(Hw) protein binds is required for the generation of mutant phenotypes by this retrotransposon.     

Oxygen-effect as an inhibition of repair: Radiation studies on excision repair deficient mei-9L1-embryos of drosophila

Summary The excision repair deficient mei-9^L1-embryos of Drosophila melanogaster are up to four times more radiosensitive than normal +/+ embryos. The lack of oxygen-effect in the repair deficient 4-h-embryos and the reduced O₂-effect in the 1 3/4-h-embryos suggest an interpretation of the oxygen effect as a modification of the ability to repair. The conversion of the early death (heavy damage) to late death (slight damage) by irradiation of normal embryos in N₂ supports this interpretation. This theory can also explain the dependence of O₂-effect on LET. The spontaneous lethality and the increase in radiosensitivity depend in heterozygous mei-9^L1-embryos strictly upon the genotype of the mother, thus representing a maternal effect.     

Identification of multiple quantitative trait loci affecting the size and shape of the mandible in mice

A quantitative trait locus (QTL) analysis was performed on the size and shape of the mandible in F₂ mice between KK-A ^y and C57BL/6 J strains and the effect of the A ^y allele on the morphology of the mandible was analyzed. A total of 13 measurements were taken on each right mandible. By means of discriminant and canonical discriminant analyses, KK-A ^y males and KK males were exactly discriminated from each other. In contrast to its known effects on body weight, the A ^y allele reduced the overall size of the mandible. QTL analysis of the 13 measurements and on three principal components extracted from these measurements identified multiple QTLs. When F₂ a/a and F₂ A ^y /a were analyzed separately, 11 significant main-effect QTLs were identified in F₂ a/a, whereas only two QTLs were identified in F₂ A ^y /a. Although four significant interactions were identified, all were in F₂ a/a. The A ^y allele thus made the difference in the size and shape of the mandible between strains obscure. Among mandible QTLs, those on Chrs 5 (Mssq6 and Mssq7) and 15 (Mssq14) were important. Mssq6 had an effect on the height of the posterior mandible. Mssq7 had an effect on mandible length. Mssq14 had an effect on the height of the anterior and posterior mandible. Mssq7 and Mssq14 also had an effect on the overall size. Thus, mandible QTLs have distinct and characteristic sites of action. Therefore, mandible morphology will be determined largely by the combination of these QTLs.     

A high level of hybrid dysgenesis in Drosophila: High thermosensitivity, dependence on DNA repair, and incomplete cytotype regulation

Summary An unusually high level of P-M hybrid dysgenesis in Drosophila melanogaster is characteristic of hybrid offspring originating from both, A (M × ) and B (P × M) crosses of a subline of the Harwich P strain, termed H ^s . The novel properties induced by mobility of P elements carried by H ^s paternal chromosomes include: very high (over 95%) gonadal dysgenesis (GD) in both sexes at the low restrictive temperature of 21°C, and highly premature sterility when males are reared at 18°C and aged at 21°C. Although all three major chromosomes of the H ^s subline contributed to this atypical pattern of gonadal dysgenesis, chromosome 3 had the largest effect. Gonadal dysgenesis showed a temperature- and sex-dependent repression pattern by the defective P elements of Muller-5 Birmingham chromosomes; at 21°C there was virtually no repression of male sterility, but most effective repression of GD in females. At 29°C repression was effective in males, but declined in females. The high thermosensitive sterility, low fecundity, and premature aging of the male germ line were greatly exacerbated when males derived from either A or B crosses were deficient either in excision repair (mei-9 mutation) or in post-replication repair (mei-41 mutation). These findings demonstrate that both DNA repair pathways are essential for the repair of lesions induced by P element transposition and support the hypothesis that P element-induced chromosome breaks are responsible for the virtual abolition of the germ line. The relatively high premature sterility of cross B DNA repair-deficient males, reared at 18°C and aged at 21°C, indicates that there is incomplete cytotype regulation in H ^s subline hybrids.     

O-alkylation in DNA does not correlate with the formation of chromosome breakage events in D. melanogaster

Postmeiotic cell stages of repair-proficient ring-X (RX) males were treated with methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), diethylnitrosamine (DEN) or ethylnitrosourea (ENU) and then mated to either repair-defective (mei-9L1) or to repair-competent females (mei-9+). Absence of the mei-9+ function resulted in a hypermutability effect to all alkylating agents (AAs) when they were assayed for their ability to induce chromosomal aberrations (chromosome loss; CL), irrespective of marked differences in distribution of DNA adducts brought about by these AAs. This picture is different from that described previously for the induction of point mutations (Vogel et al., 1985a). There, evidence was presented indicating that reduction in DNA excision repair does not affect point mutation induction (recessive lethals) by those AAs most efficient in ring-oxygen alkylation such as ENU, DEN, N-ethyl-N'-nitro-N-nitrosoguanidine (ENNG), and isopropyl methanesulfonate (iPMS): the order of hypermutability of AAs with mei-9L relative to mei-9+ was MMS greater than MNU greater than DMN = EMS greater than iPMS = ENU = DEN = ENNG. When the percentage of lethal mutations induced in mei-9L1 females were plotted against those determined for mei-9+ females, straight lines of following slopes were obtained: MMS = 7.6, MNU = 5.4, DMN = 2.4, EMS = 2.4, and iPMS = ENU = DEN = ENNG = 1. Those findings, together with the recent observation that AAs do not split into two groups when assayed for their ability to cause CL, point to the involvement of different DNA alkylation products in ENU- and DEN-induced chromosome loss vs. that of point mutations. It is concluded that with ENU and DEN chromosomal loss results from N-alkylation products whereas point mutations (SLRL) are the consequence of interactions with oxygen-sites in DNA. Thus, as a consequence of a very dominating role of O-ethylguanine (and possibly O4-alkylation of thymine), N-alkylation in DNA does not contribute measurably to mutation induction in the case of ENU-type mutagens while O-alkylation, very clearly, does not show a positive correlation with the formation of chromosome breakage events in Drosophila. Conversely, it appeared that with MMS-type mutagens (MMS; dimethyl sulfate, DMS; trimethyl phosphate, TMP), alkylation products such as 7-methylguanine and 3-methyladenine, if unrepaired or misrepaired, are potentially mutagenic lesions causing both mutations and chromosomal aberrations.     

Ethylation pf DNA and protamine by ethyl methanesulfonate in the germ cells of male mice and the relevancy of these molecular targets to the induction of dominant lethals

The molecular dosimetry of ethyl methanesulfonate (EMS) in the germ cells of male mice has been investigated. The mice were injected i.p. with 200 mg/kg of [³H]EMS and the ethylations per sperm head, per deoxynucleotide, and per unit of protamine were then determined over a 2-week period. The ethylations per sperm head closely paralleled the dominant-lethal frequency curve for EMS, reaching a maximum of 5 to 6.5 million ethylations per vas sperm head at 8 to 10 days after treatment. Ethylation of sperm DNA was greatest at 4 h after treatment, with 5.7 ethylations/10⁵ deoxynucleotides, and gradually decreased to 2.2 ethylations/10⁵ deoxynucleotides at 15 days after treatment. The ethylation of sperm DNA did not increase in the germ-cell stages most sensitive to EMS, ans was not correlated with the dominant-lethal frequency curve for EMS. However, ethylation of sperm protamine did increase in the germ-cell stages most sensitive to EMS, and showed an excellent correlation with the incidence of dominant lethals produced by EMS in the germ cells.A model is presented to explain, at a molecular level, how dominant lethals may be induced in mouse germ cells by EMS. Ethylation by cysteine sulfhydryl groups contained in mouse-sperm protamine could block normal disulfidebond formation, preventing proper chromatin condensation in the sperm nucleus. Stresses in the chromatin structure could then eventually lead to chromosome breakage, with resultant dominant lethality.     

The mei-9a Mutant of DROSOPHILA MELANOGASTER Increases Mutagen Sensitivity and Decreases Excision Repair

The mei-9^a mutant of Drosophila melanogaster , which reduces meiotic recombination in females (Baker and Carpenter 1972), is deficient in the excision of UV-induced pyrimidine dimers in both sexes. Assays were performed in primary cultures and established cell lines derived from embryos. An endonuclease preparation from M. luteus , which is specific for pyrimidine dimers, was employed to monitor UV-induced dimers in cellular DNA. The rate of disappearance of endonuclease-sensitive sites from DNA of control cells is 10–20 times faster than that from mei-9^a cells. The mutant mei-218, which is also deficient in meiotic recombination, removes nuclease-sensitive sites at control rates. The mei-9^a cells exhibit control levels of photorepair, postreplication repair and repair of single strand breaks. In mei-9 cells DNA synthesis and possibly postreplication repair are weakly sensitive to caffeine. Larvae which are hemizygous for either of the two mutants that define the mei-9 locus are hypersensitive to killing by the mutagens methyl methanesulfonate, nitrogen mustard and 2-acetylaminofluorene. Larvae hemizygous for the mei-218 mutant are insensitive to each of these reagents. These data demonstrate that the mei-9 locus is active in DNA repair of somatic cells. Thus functions involved in meiotic recombination are also active in DNA repair in this higher eukaryote. The results are consistent with the earlier suggestions (Baker and Carpenter 1972; Carpenter and Sandler 1974) that the mei-9 locus functions in the exchange events of meiosis. The mei-218 mutation behaves differently in genetic tests and our data suggest its function may be restricted to meiosis. These studies demonstrate that currently recognized modes of DNA repair can be efficiently detected in primary cell cultures derived from Drosophila embryos.     

Novel genes influencing the expression of the yellow locus and mdg4 (gypsy) in Drosophila melanogaster

Summary We used a system with a mobilized Stalker transposable element, sometimes in combination with P-M hybrid dysgenesis, in the search for new mutations interfering with the y ² mutation induced by mdg4 (gypsy) insertion into the yellow locus. A novel gene, modifier of mdg4, was detected in chromosome 3. The mutation mod(mdg4) either enhanced or suppressed phenotypic changes in different mutations induced by mdg4 insertions. Thus, mod(mdg4) seems to be involved in the control of mdg4 expression. Six other loci designated as enhancers of yellow were also detected. The e(y) ⁿ (with n from 1–6) mutations enhanced the expression of several y mutations induced by different insertions into the yellow locus. The major change is a damage of bristle and hair pigmentation which is not suppressed by su(Hw) mutations. On the other hand, e(y) ⁿ alleles do not interact with mdg4 induced mutations in other loci. All e(y) ⁿ genes are located in different regions of the X chromosome. One may speculate that e(y) ⁿ genes are involved in trans-regulation of the yellow locus and possibly of some other loci.     

Mutagenesis in Oocytes of DROSOPHILA MELANOGASTER. I. Scheduled Synthesis of Nuclear and Mitochondrial DNA and Unscheduled DNA Synthesis

As a model system for studying mutagenesis, the oocyte of Drosophila melanogaster has exhibited considerable complexity. Very few experiments have been conducted on the effect of exposing oocytes to chemical mutagens, presumably due to their lower mutational response relative to sperm and spermatids. This lower response may be due either to a change in probability of mutation induction per adduct due to a change in the type of DNA repair or to a lower dose of the mutagen to the female germ line. To study molecular dosimetry and DNA repair in the oocyte, the large number of intracellular constituents (mtDNA, RNA, nucleic acid precursors and large quantities of proteins and lipids) must be separated from nuclear DNA. In this paper we present results showing reliable separation of such molecules enabling us to detect scheduled nuclear and mitochondrial DNA synthesis. We also, by understanding the precise timing of such events, can detect unscheduled DNA synthesis (UDS) as a measure of DNA repair. Furthermore, by comparing the UDS results in a repair competent (Ore-R) vs. a repair deficient (mei-9^L1 ) strain, we have shown the oocyte capable of DNA repair after treatment with ethyl methanesulfonate (EMS). We conclude that the important determinant of mutation induction in oocytes after treatment with EMS is the time interval between DNA alkylation and DNA synthesis after fertilization, i.e., the interruption of continuous DNA repair.     

Molecular cloning of mei-41, a gene that influences both somatic and germline chromosome metabolism of Drosophila melanogaster

The mei-41 gene of Drosophila melanogaster plays an essential role in meiosis, in the maintenance of somatic chromosome stability, in postreplication repair and in DNA double-strand break repair. This gene has been cytogenetically localized to polytene chromosome bands 14C4-6 using available chromosomal aberrations. About 60 kb of DNA sequence has been isolated following a bidirectional chromosomal walk that extends over the cytogenetic interval 14C1-6. The breakpoints of chromosomal aberrations identified within that walk establish that the entire mei-41 gene has been cloned. Two independently derived mei-41 mutants have been shown to carry P insertions within a single 2.2 kb fragment of the walk. Since revertants of those mutants have lost the P element sequences, an essential region of the mei-41 gene is present in that fragment. A 10.5 kb genomic fragment that spans the P insertion sites has been found to restore methyl methanesulfonate resistance and female fertility of the mei-41 ^D3 mutants. The results demonstrate that all the sequences required for the proper expression of the mei-41 gene are present on this genomic fragment. This study provides the foundation for molecular analysis of a function that is essential for chromosome stability in both the germline and somatic cells.This Paper is dedicated to the memory of Professor James B. Boyd     

Genetic characterization of the mei-41 locus in Drosophila melanogaster

Summary The mutagen-sensitive mutant mus(1)104 ^D1 of Drosophila melanogaster maps to a position on the X chromosome very close to the meiotic mutant mei-41 ^D5 . Both mutants have been characterized as mutagen-sensitive and defective in post-replication repair. In the present report we show by complementation studies that mus(1)104 and mus(1)103 are allelic with mei-41. In addition, two reported alleles of mus(1)104 lie between the mei-41 alleles A10 and D5. The size of the mei-41 locus is estimated to be about 0.1 centimorgans (cM). Because several alleles of mei-41 have been shown to reduce recombination and increase meiotic chromosome loss and nondisjunction, mus(1)104 ^D1 females were examined for defects in meiosis. Although there was no evidence for reduced recombination on the second chromosome in homozygous mus(1)104 ^D1 females, heterozygous mus(1)104 ^D1 /mei-41 ^>D5 and mus(1)104 ^D1 /deficiency females showed reduced levels of recombination. However, there was no evidence of an increase in nondijunction in these females.We dedicate this article to the memory of Larry Sandler, who passed away suddenly on February 7, 1987     

Quantitative trait loci that modify the sootiness of yellow pigmentation in KK-A y /a mice

Compared with C57BL/6J-A ^y /a, KK-A ^y /a mice have yellow fur that is markedly darker. Furthermore, there is a considerable variation in the tone of color with a continuous range in F₂ progeny produced from C57BL/6J females and KK-A ^y /a males. The aims of this study are to reveal the phenotypic differences between the two A ^y congenic strains and to elucidate the genetic factors responsible for the sooty yellow pigmentation in the KK background. On the basis of a chemical analysis, the sootiness in KK-A ^y /a was the result of increased eumelanin (PTCA) and decreased pheomelanin (AHP). A statistically significant QTL was identified on Chromosome (Chr) 15, responsible for the AHP content. No significant loci responsible for PTCA were identified. On the other hand, on the basis of an optical analysis for color difference and overall sootiness, significant evidence of linkage was identified on the proximal part of Chr 15, in the region similar to AHP QTL. The overall sootiness is thus controlled solely by the locus on Chr 15 in F₂ progeny; however, the KK allele at this locus significantly increased the AHP content. Received: 8 September 1999 / Accepted: 18 April 2000     

The effect of genetic environment on locus-specific instability of the <Emphasis Type="Italic">yellow</Emphasis> gene in the Uman’ population of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

The effects of genotype of the laboratory strains, C(1)DX, ywf/Y, 23.5 MRF/CyL ⁴, and C(1)DX,yf; π₂, on locus-specific instability in the yellow gene of the strains y ^2-217, y ^2-715, and y ^2-700 from Uman’ population of Drosophila melanogaster was studied. Crosses of the males from Uman’-derived lines with the C(1)DX,ywf/Y females yielded a cascade of derivatives, mostly consisting of y ⁺ and y ² alleles, while their crosses with the 23.5 MRF/CyL ⁴ and C(1)DX,yf; π₂ females mostly resulted in the appearance of y ⁺ and y ¹ derivatives. The genomes of laboratory strains used in the study contained the full-sized hobo elements, which could differ from one another relative to the structure of variable region and affinity to different DNA sequences.     

Expression of the H-Y Antigen on thymus cells and skin: Differential genetic control linked toK end ofH-2

The strength of the H-Y antigen on thymus cells and on skin was compared in differentH-2-congenic mouse strains using a host-versus-graft reaction popliteal lymph node assay, and skin grafts from males of parental strains grafted to F₁ hybrid females. The results revealed considerable differences in the strength of the H-Y antigen among different congenic strains; these differences demonstrate the effect of theH-2-linked gene on the expression of the H-Y antigen. The linkage withH-2 was also confirmed in tests with segregating F₂ generations. In the strains bearing recombinantH-2 haplotypes, the strength of the H-Y antigen is similar to that of parental strain from which the recombinant received itsK end, and the responsible gene (or genes) map to the left ofI-C. The effect of theH-2-linked gene(s) on thymus cells and skin is different. The gene linked to theK end ofH- 2^b determines a strong H-Y antigen on thymus cells, but a relatively weak H-Y antigen on skin. The gene linked to theK end ofH- 2^k determines a weak H-Y antigen on thymus cells, but a strong H-Y antigen on skin. The gene linked to theK end ofH- 2^d determines a weak H-Y antigen on both thymus cells and skin. Our observations raise the possibility that the structural gene for the H-Y antigen is linked toH-2. Alternative (but not exclusive) explanations invoke regulatory effects ofH-2 on the expression of the H-Y antigen, possibly by means of the control of the cellular andogen receptors.     

Comparison of lethal mutations of Drosophila melanogaster with D. simulans when detected by the attached-X method

The purpose of this study was to evaluate the attached-X method compared with the standard Basc method, and, using this method, to find out whether the observed differences in genetic polymorphisms are related to differences in lethal mutation rates in D. melanogaster and D. simulans. When EMS-treated Drosophila melanogaster males are mated to untreated attached-X females, a decrease in the progeny sex ratio (/+) is observed due to the induced lethal mutations on the X chromosome. The decrease in the frequency of male progeny were shown as the attached-X index. The expected male number is calculated from the control sex ratio. The difference between the expected and the observed male numbers, expressed as the ratio to the expected male number, defines the attached-X index. The index values for various EMS concentrations were compared to the lethal frequencies obtained by the standard Basc method for the same EMS treatments, and gave a highly positive correlation (=0.993, p<0.01, d.f.=2), thus providing an alternative method for evaluation of possible mutagens. The attached-X method was applied to D. simulans, of which natural populations are known to have relatively low genetic variation, and frequencies of the EMS-induced X chromosome lethal mutations were estimated and compared with those in D. melanogaster. The results indicate that D. melanogaster is slightly more sensitive in the sperm and spermatogonial stages, but less susceptible in the spermatid stage when compared with D. simulans. Since the spermatid stage occupies a relatively short period in spermatogenesis, a higher mutability of D. simulans during this stage probably does not make a significant contribution to the genetic variability of this species.     

Inheritance of a darkened caudal peduncle and yellow body coloration in the gilthead sea bream (Sparus aurata L.)

This study presents data on inheritance of a darkened caudal peduncle (ebony) and yellow body coloration (yellow) in the gilthead sea bream (Sparus aurata). Fifteen progeny groups, obtained by crossing fish with three color phenotypes and of known origin, were analyzed. Analyzes of segregation in F₁ progeny involving groups from parental crosses of wild‐type colored × wild‐type colored; ebony × ebony; yellow × yellow, showed that the parents produced the offspring only with the same phenotypes (true breeding). Crosses involving F₁ wild‐type colored parents (that resulted from crosses of wild‐type parents with either ebony or yellow fish) showed in their F₂ progeny groups of which their phenotypic segregations did not differ significantly from a 3 : 1 Mendelian ratio. The progeny of back‐cross of ebony × (F₁ wild‐type colored × ebony) showed phenotypic segregations that did not differ significantly from the 1 : 1 Mendelian ratio. Overall, the results of the crossing experiments demonstrated that, similar to albinism described in a number of aquacultured species, ebony and yellow body coloration in S. aurata are both due to a single recessive allele. However, the yellow mutation of a gene controlling yellow pigment synthesis affects the yellow color of the whole fish body, whereas the ebony mutation causes production of melanin only in a specific area of the fish body, resulting in the development of a black coloration of the caudal peduncle. Experiments to assess culture performance showed that the color genes controlling ebony and yellow coloration had significant detrimental pleiotropic effects on growth, survival and body shape. Color mutations in the gilthead sea bream may be used as models for the study of: (i) genetic and physiological mechanisms of sterility, (ii) stress and disease resistance, (iii) effects of heterosis, (iv) genetic polymorphism in populations, and (v) methods of genetic protection in selected sea bream strains as well as in experiments on chromosome set manipulation.