Genetic analysis of recessive lethal mutations induced by the influenza virus in the X chromosome of Drosophila melanogaster

Mutagenic potential of the influenza virus was evaluated. Based on its capacity of inducing recessive lethal mutations in the X chromosome of Drosophila melanogaster, the influenza virus can be classified as a moderate-activity mutagen. Its mutagenicity does not depend on ability to reproduce in the cell system. This virus was shown to disrupt formation of the wing, particularly wing vein M1 + 2. Cytogenetic examination of polytene X chromosomes bearing recessive lethal mutations in Drosophila salivary glands did not reveal chromosome rearrangements. These lethals are assumed to be small deletions or point mutations. The determination of the lethal activity stage of these mutations showed that they disrupt the expression of genes functioning at various developmental stage of Drosophila. Two of them were conditionally lethal (temperature-sensitive). Two of 15 mutations analyzed were mapped to region 2B9-10-3C10-11.     

I-R hybrid dysgenesis in Drosophila melanogaster. Use of in situ hybridization to show the association of I factor DNA with induced sex-linked recessive lethals.

The purpose of this paper is the genetic visualization by in situ hybridization of 130 sex-linked recessive lethals plus a non-lethal induced by I-R dysgenesis. This collection of lethals involves inducer strains which differ in the position of the I elements on the X chromosomes. The I-R interaction was strong. Our previous results have shown that about 30% of the induced recessive lethals are associated with cytologically visible chromosomal rearrangements. (1) The rearrangements induced by I-R-type hybrid dysgenesis often exhibit homology with the I factor at the level of one or both junction points, depending on the types of chromosome rearrangements. These results suggest that the chromosome rearrangements arise directly from the transposition of I elements. However, the breakpoints of some types of cytologically non-visible deficiencies and of 2 small cytologically visible deficiencies do not present detectable homology with the I factor. (2) The majority of rearrangements do not involve the I elements already present on the paternal X chromosome. (3) The hybridization signal distributions on the X chromosome are not uniform. They present peaks of various heights which may correspond to specific anchoring areas of copies of I in the course of integration. (4) The data presented here agree with the literature with respect to the mean number of copies of I per X chromosome and to the excess of copies of I at locus 1A. Two rearrangement formation mechanisms are envisaged: crossing-over and 'target' exchanges.     

Genetic Analysis of Recessive Lethal Mutations Induced by the Influenza Virus in the X Chromosome of Drosophila melanogaster

Mutagenic potential of the influenza virus was evaluated. Based on its capacity of inducing recessive lethal mutations in the X chromosome of Drosophila melanogaster, the influenza virus can be classified as a moderate-activity mutagen. Its mutagenicity does not depend on ability to reproduce in the cell system. This virus was shown to disrupt formation of the wing, particularly wing vein M_{1 + 2}. Cytogenetic examination of polytene X chromosomes bearing recessive lethal mutations in Drosophilasalivary glands did not reveal chromosome rearrangements. These lethals are assumed to be small deletions or point mutations. The determination of the lethal activity stage of these mutations showed that they disrupt the expression of genes functioning at various developmental stages of Drosophila.Two of them were conditionally lethal (temperature-sensitive). Two of 15 mutations analyzed were mapped to region 2B9-10–3C10-11.     

Autosomal recessive lethal mutations in two mutator stocks of Drosophila ananassae.

The frequency of recessive lethals in the 2nd chromosome was examined in two mutator stocks of Drosophila ananassae, ca and ca; px. They are characterized respectively by possessing an extrachromosomal clastogenic mutator in males, and by the retrotransposon "tom", which induces Om mutability only in females. The frequencies of recessive lethal mutations in the 2nd chromosome among progenies from males and females of the ca; px stock are 0.35 and 0.34 percent, respectively. Similarity of these frequencies indicates that tom does not induce recessive lethals in females. In contrast to the ca; px stock, the frequency of recessive lethals in males of the ca mutator stock was estimated to be 1.54 percent for the 2nd chromosome. No visible mutants except Minutes were recovered. Some recessive lethals derived from ca stock males were associated with chromosomal rearrangements. Being consistent with its high rate of Minute mutation it was demonstrated that the ca clastogenic mutator also induced recessive lethals.     

The stability of mutator (MR)-induced X-chromosomal recessive visible mutations in Drosophila melanogaster

In Drosophila, MR (male recombination) second chromosomes are known to act as mutators and recombination inducers in males. The induction of visible mutations by MR is observed at only a limited number of genes, such as singed bristle (sn). raspberry eye colour (ras), yellow body colour (y) and carmine eye colour (car). Futhermore, sn mutations induced by MR are highly unstable, changing from a strong to a weak expression or reverting to the wild-type. It has been hypothesized, by analogy with IS mutations in microorganism, that MR-induced mutations also represent mutations of the insertion type.

In this investigation the stability of two MR-hl22-induced X-linked visible mutations was tested, one singed (sn^MR) and one raspberry (ras^MR). The reversion frequency of both MR-induced mutations was low in the base population as well as upon outcrossing to C(1)DX, y^w f females. The data reported here show that the MR-induced mutations become highly unstable when MR is re-introduced. The change of expression of an MR-induced mutation to a weaker phenotype or to the wild-type occurred at a frequency of 3.3 × 10⁻³ (ras) to 20.4 × 10⁻ (sn).

Recessive lethal mutations induced by MR in the X-chromosomes carrying the MR-inducedsinged or raspberry mutation were isolated and analysed. Among 11 independently MR-induced lethals in the ras^MR-carrying X-chromosome, 4 were found to be allelic to a small deficiency that included the raspberry gene, 13 lethals were induced by MR in the sn^MR-carrying X-chromosome. Of these, 3 were located near the sn locus but none was allelic to a deficiency including the singed gene.     

Investigations on radiosensitive and radioresistant populations of Drosophila melanogaster: XI. The resistance factor rar-3: effects in inmature oocytes

The effects of the radioresistance factor rar-3 on the X-ray induction of various types of genetic damage in immature oocytes (about stage7) of Drosophila melanogaster were studied.

The dose-reduction factors previously postulated for rar-3 with respect to dominant lethals (1.58), sex-linked recessive lethals (1.87), non-disjunction of major chromosomes (1.58), and homologous interchanges (1.58)_were confirmed experimentally. It is concluded that all effects attributed arbitrarily to rar-3 are contributed by the single genetic factor rar-3.

No difference were found in quality of sex-linked recessive lethals (Y suppression, distribution over the X) induced in either rar-3 or rar-3⁺. Recombination frequencies were normal in unirradiated rar-3.     

Genetic Damage at Specific Gene Loci in Drosophila with Betatron X-Rays

The mutation rate was determined for mature sperm at eight specific gene loci on the third chromosome of Drosophila melanogaster using the low ion density radiations of 22 Mev betatron X-rays. A dose of 3000 rads of betatron X-rays produced a mutation rate of 4.36 x 10^-8 per rad/locus. Among the mutations observed, 66% were recessive lethals and 34% viable when homozygous. Only one of the 24 viable mutations was associated with a chromosome aberration. Among the 47 recessive lethals, no two-break aberrations were detected in 48.9% of the lethals, deletions were associated with 42.2%, inversions with 6.7% and translocations with 2.2%.—When these genetic results are compared to those for 250 KV X-rays, the mutation rate for betatron treatments was slightly lower (.76), the recessive lethal rate among induced mutations was higher, and the chromosome aberrations among lethal mutations were slightly lower than with 250 KV X-rays. Although the two types of irradiations differ by an ion density of approximately ten, the amount and types of inheritable genetic damage induced by the two radiations in mature sperm were not significantly different.     

Studies on mutagen-sensitive strains of Drosophila melanogaster VIII. Further data on differences between Canton-S and ebony strains with respect to maternal effects for the X-ray induction of autosomal translocations and ring-X chromosome losses in mature spermatozoa

The influence of the maternal genotype (Canton-S, proficient in the repair of X-ray-induced chromosome breaks and ebony, less proficient in this regard) on the recovery of X-ray-induced autosomal (II–III) translocations and ring-X chromosome losses in mature spermatozoa was studied. In the first series of experiments, males carrying appropriate markers on their second and third chromosomes were irradiated and mated to Canton-S or ebony females and the frequencies of II–III translocations were determined. In the second series of experiments, males carrying ring-X chromosomes were irradiated in N₂ or in O₂, mated to Canton-S or ebony females and the frequencies of XO males were determined; additionally, under similar gas-treatment and radiation conditions, the pattern of egg-mortality was also assessed.

The data on translocations show that the yields are higher with ebony than with Canton-S females; these and earlier results on dominant lethals and sex-linked recessive lethals support the interpretation that the maternal repair system in the ebony strain is less proficient and more error-prone than that of the Canton-S strain.

Those on the losses of ring-X chromosomes demonstrate that (i) the absolute yields of XO males are lower with ebony than with Canton-S females irrespective of whether the parental males are irradiated in N₂ or in O₂; (ii) the exposure-frequency relationships are all linear, but the slopes are higher when the males are irradiated in O₂ and are consistent with an oxygen-enhancement-ratio of about 1.5 and (iii) the relationships between the logarithm of egg-survival and XO male frequency are also linear, but the slopes for the O₂ groups are lower than those for the N₂ groups (slope ratios of 0.86–0.87).

The finding that at given survival levels, the XO frequencies are lower in the O₂ than in the N₂ groups of both the Canton-S and ebony series viewed in the context of the mechanisms that have been postulated to explain the loss of ring-X chromosomes in irradiated mature spermatozoa permits the following interpretation for the observed results: (i) a higher proportion of potential XO zygotes is lost through dominant lethality in the O₂ groups than in the N₂ ones presumably because the chromosome breaks induced in O₂ are qualitatively different in the sense that they have higher probability to undergo reunions relative to restitution, compared with breaks induced under anoxia and (ii) this leads to lower than expected oxygen-enhancement ratios (i.e., expected on the basis of published data on sex-linked recessive lethals, another kind of genetic damage which shows a linear exposure-frequency relationship).     

Spontaneous and Ethyl Methanesulfonate-Induced Mutations Controlling Viability in DROSOPHILA MELANOGASTER. I. Recessive Lethal Mutations

The efficiency of the adult feeding method for EMS treatment in Drosophila melanogaster was studied by measuring the frequency of induced recessive lethals on the second chromosome. The treatment was most effective when mature spermatozoa or spermatids were treated and was much less effective on earlier stages. The number of mutations induced was proportional to the concentration except at the highest doses. The recessive lethal rate was estimated to be about 0.012 per second chromosome per 10(-4) M. In addition, about 0.004-0.005 recessive lethals per 10(-4) M were found in a later generation in chromosomes that had not shown the lethal effect in the previous generation. When the experiments are done in a consistent manner and gametes treated as mature sperm or spermatids are sampled, the results are highly reproducible. However, modifications of the procedure, such as starvation before EMS treatment, can considerably alter the effectiveness of the mutagen.     

Site-Specific Instability in DROSOPHILA MELANOGASTER: The Origin of the Mutation and Cytogenetic Evidence for Site Specificity

During a study of delayed mutations, an unstable X chromosome (Uc) was detected. Spontaneous X-linked recessive lethal mutations were detected in 34 of 993 sperm sampled from 50 males carrying this chromosome. All but three of the 34 lethals originated as clusters in three of the 50 males Cytogenetic and complementation analyses revealed 14 intrachromosomal rearrangements: ten inversions, two reverse repeats, one deficiency and one transposition. Eight of the 14 rearrangements have one break in the 6F1-2 doublet and two rearrangements have a break in 6F1-5 of the X chromosome. The remaining four rearrangements have in addition to the aberrations a lethal point mutation between 6F1 and 6F5. Though each of the lethal lines was established from a single lethal-bearing female, chromosome polymorphism is evident in 17 of the 18 lines having rearrangements, with certain aberrations recurring in several lines. The lethal mutations revert frequently to the nonlethal state, and cytological evidence indicates that more than one mutational event may occur at the unstable locus of the chromosome during one generation. Two lethal lines had more than one type of chromosome rearrangement sharing a common breakpoint. These observations are consistent with the view that the instability of the Uc lines is caused by a transposable element capable of site-specific chromosome breaks and perpetual generation of mutations. The mutagenic and genetic properties of transposable elements can be related to the two-mutation theory of KNUDSON (1971) for cancer initiation.     

The main effect of chromosomal rearrangement is changing the action of regulatory genes

Effect of chromosomal rearrangements on the expression of mutations was studied in Drosophila melanogaster regulatory genes. These were facultative dominant lethals and recessive lethals on the X chromosome obtained by the classical Muller-5 method. Chromosomal rearrangements drastically changed the expression of regulatory gene mutations. Rearrangements either caused the lethal effect of mutations or suppressed the already present lethality. The action of rearrangements exhibited the maternal or paternal effect. Irrespective of the presence in the genome of mutations at regulatory genes, a rearrangement acted as a factor decreasing fertility of the organism. The rearrangement effect is identical to the expression of regulatory genes per se. It is concluded that the chromosomal rearrangement affects the examined regulatory genes indirectly through a change in the operation of regulatory genes located within the rearrangement. Thus, rearrangements gain great importance for the definition of the pattern of genome functional activity. Widespread distribution of rearrangements in individual genotypes and their effectivity in the process of speciation are thus explained.     

Metronidazole (Flagyl): lack of induction of sister-chromatid exchanges in CHO-K1 cells

328 X-linked recessive lethal mutations induced in late spermatids by hycanthone methanesulfonate were tested for coverage by duplications that comprised, in total, about 24% of the euchromatic X chromosome; 78 lethals appeared to be covered. Crossover localization tests of a random sample of 38 non-covered lethals revealed 4 chromosomes carrying a lethal within a duplicated segment. Lethals localized to a particular region were crossed to reference deficiencies and single-locus mutations, and inter se, to ascertain their genetic extent. The proportion of multi-locus deletions among these 78 covered and 4 non-covered lethals was 3/48, 1/10 and 13/24 for the distal, medial and proximal regions, respectively. A storage period of 9 days did not noticeably influence these proportions. In the sample of 38 non-covered lethals, and among 17 of the covered single-site lethals, 4 cases of strong crossover suppression were detected. Comparison of these results with data obtained with other mutagens suggests that induction of multi-locus deletions, and possibly of other types of chromosome rearrangement, could in part depend on other mechanisms than those acting in the formation of translocations and chromosome loss. For the purpose of mutagen testing, these findings imply that, in Drosophila, results in the regular genetic tests for chromosome breakage events do not always accurately predict the capacity of a mutagen to induce multi-locus deletions. This is of importance since transmissible multi-locus deletions have been considered a significant source of genetic damage in man.     

Analysis of hexamethylphosphoramide (HMPA)-induced genetic alterations in relation to DNA damage and DNA repair in Drosophila melanogaster

This paper reports the results of a study on the mutagenic profile of HMPA in Drosophila melanogaster. HMPA produced all types of genetic damage tested for in post-meiotic cells of treated males; at the concentrations used, recessive lethals and ring-X losses were induced at significant rates while 2–3 translocations, entire and partial Y-chromosome losses only occurred at low rates. From a comparison with alkylation-induced mutational spectra, we note a number of peculiarities of HMPA mutagenesis:

1. (1) there is no storage effect on HMPA-induced translocations;

2. (2) the ratio of F₂-lethals: F₃-lethals varies from 6 : 1 to 9 : 1, indicating a low capacity of HMPA for delayed mutations;

3. (3) the use of the DNA-repair-deficient mei-9^L1 females instead of an excision-proficient control strain has no influence on the recovery of mutations )recessive lethals) induced in males;

4. (4) the high frequencies of chromosome loss (CL) induced by HMPA, which are mostly due to ring-X loss, leads us to speculate that one (or more) of its metabolites acts as a DNA-crosslinking agent. In experiments on maternal effects with mei-9^L1 females, there is a 20–40% reduction in the rates of induced CL. Conversely, with mei-41^D5 females, there is a weak increase in CL frequencies.

5. (5) HPLC analysis of DNA reacted with [¹⁴C]HMPA exhibits no methylation at the O⁶ or the N-7 of guanine. This finding, together with the observed inactivity of hexaethylphosphoramide (HEPA) in the recessive lethal assay, suggests that the formation of DNA-bound forms from HMPA may not be the result of simple methylation reactions. This conclusion is supported by the genetic data, i.e., the lack of a storage effect on HMPA-induced chromosome rearrangements.

Consistent with a hypothesis by Brodberg et al. (1983) to explain the action of cisplatin in Drosophila, comparisons of the spectra of genetic alterations produced by HMPA, A 139 (bifunctional) and Thio-TEPA (trifunctional) in the assay for chromosome loss suggest the involvement of two distinct mechanisms in the formation of ring-X loss by crosslinking agents. One pathway concerns induction of chromosome loss as a consequence of sister-chromatid exchanges (SCEs). The second mechanism may be due to DNA adducts or a single adduct responsible for both a fraction of CL and for induced partial Y-loss (PL). Inactivation of the mei-9⁺ function has two consequences: SCE-mediated ring-X loss frequency is lowered in mei-9 females in comparison to the repair-proficient control strain, while the opposite effect is indicated for that fraction of ring-X loss generated by the second mutational pathway. Additional complicating factors include the observation of a dual role of storage in our study: the proportion of SCE-related chromosome losses decreases with increasing time of storage, but that produced by the alternative pathway increases. Thus, the CL frequencies actually recorded under the heading ‘chromosome loss’ appear as the net result of two mechanisms counteracting each other in their effects.     

The Main Effect of Chromosomal Rearrangement Is Changing the Action of Regulatory Genes

Effect of chromosomal rearrangements on the expression of mutations was studied in Drosophila melanogaster regulatory genes. These were facultative dominant lethals and recessive lethals on the X chromosome obtained by the classical Muller-5 method. Chromosomal rearrangements drastically changed the expression of regulatory gene mutations. Rearrangements either caused the lethal effect of mutations or suppressed the already present lethality. The action of rearrangements exhibited the maternal or paternal effect. Irrespective of the presence in the genome of mutations of regulatory genes, a rearrangement acted as a factor decreasing fertility of the organism. The rearrangement effect is identical to the expression of regulatory genes per se. It is concluded that the chromosomal rearrangement affects the examined regulatory genes indirectly through a change in the operation of regulatory genes located within the rearrangement. Thus, rearrangements gain great importance for the definition of the pattern of genome functional activity. Widespread distribution of rearrangements in individual genotypes and their effectivity in the process of speciation are thus explained.     

Cytological study of Rubenstrema exasperatum (Trematoda: Omphalometridae)

Cytological studies on Rubenstrensa exasperatum were carried out. The number of chromosomes in diploid cells (2n=16), and the morphological characteristics of the karyotype were determined. All the chromosomes (from Nos 2 to 8) had a well-defined short arm and, in accordance with the I^c values, were determined to be meta-submetacentric. Polymorphism was established in the length of the 2 bomologues of the 1st chromosome. This pair is probably linked with sex determination.     

Mutagenesis in CAENORHABDITIS ELEGANS. II. a Spectrum of Mutational Events Induced with 1500 R of γ-RADIATION

We previously established a gamma-ray dose-response curve for recessive lethal events (lethals) captured over the eT1 balancer. In this paper we analyze the nature of lethal events produced, with a frequency of 0.04 per eT1 region, at a dose of 1500 r. To do so, we developed a protocol that, in the absence of cytogenetics, allows balanced lethals to be analyzed for associated chromosomal rearrangements. A set of 35 lethal strains was chosen for the analysis. Although the dosage was relatively low, a large number of multiple-break events were observed. The fraction of lethals associated with rearrangements was found to be 0.76. Currently most X- and gamma-ray dosages used for mutagenesis in C. elegans are 6000-8000 r. From our data we conservatively estimated that 43% of rearrangements induced with 8000 r would be accompanied by additional chromosome breaks in the genome. With 1500 r the value was 5%. The 35 lethals studied were derived from 875 screened F1's. Among these lethals there were (1) at least two unc-36 duplications, (2) at least four translocations, (3) at least six deficiencies of chromosome V (these delete about 90% of the unc-60 to unc-42 region) and (4) several unanalyzed rearrangements. Thus, it is possible to recover desired rearrangements at reasonable rates with a dose of only 1500 r. We suggest that the levels of ionizing radiation employed in most published C. elegans studies are excessive and efforts should be made to use reduced levels in the future.     

Neutron- and X-ray-induced mutations at the yellow, white, forked and vermilion loci of Drosophila melanogaster; a preliminary analysis

Neutrons and X-rays were used to induce mutations at the yellow, white, vermilion and forked loci of Drosophila melanogaster by irradiation of spermatozoa in males. The mutations were characterized for the presence and location of simultaneously induced rearrangements and recessive lethal mutations. F1 females carrying induced visible mutations were identified, described and tested for fertility. The data are given in this paper. The proportions of mutants at the 4 loci, the ratios of whole-body: mosaic mutations, and the fertility of the mutant-carrying F1 females were similar for both types of radiation. Differences were observed between the frequencies of induced visible mutations and the rates of coincident visible and lethal induction. Although the analysis of the mutant chromosomes has not yet been completed, our data can be interpreted as providing confirmation that there are qualitative differences between the genetic effects of neutrons and X-rays.     

Ionizing radiation and genetic risks. II. Nature of radiation-induced mutations in experimental mammalian in vivo systems

This paper reviews data on the nature of spontaneous and radiation-induced mutations in the mouse. The data are from studies using a variety of endpoints scorable at the morphological or the biochemical level and include pre-selected as well as unselected loci at which mutations can lead to recessive or dominant phenotypes. The loci used in the morphological recessive specific-locus tests permit the recovery of a wide spectrum of induced changes. Important variables that affect the nature of radiation-induced mutations (assessed primarily using tests for viability of homozygotes) include: germ cell stage, type of irradiation and the locus. Most of the results pertain to irradiated stem cell spermatogonia. The data on morphological specific-locus mutations show that overall, more than two-thirds of the X- or gamma-ray-induced mutations are lethal when homozygous. This proportion may be lower for those that occur spontaneously, but the numbers of tested mutants are small. For spontaneous mutations, there is evidence for the occurrence of mosaics and for proviral insertions. Most or all tested induced enzyme activity variants, dominant visibles (recovered in specific-locus experiments) and dominant skeletal mutations are lethal when homozygous and this is true of 50% of dominant cataract mutations, but again, the numbers of tested mutants are small. Electrophoretic mobility variants, which are known to be due to base-pair changes, are seldom induced by irradiation. At the histocompatibility loci, no radiation-induced mutations have been recovered, presumably because deletions are incompatible with survival even in heterozygotes. All these findings are consistent with the view that in mouse germ cells, most radiation-induced mutations are DNA deletions. Some mutations (in the morphological specific-locus tests) which had previously been inferred to be deletions on the basis of genetic analyses have now been shown to be DNA deletions by molecular methods. However, the possibility cannot be excluded that at least a small proportion of induced mutations may be intragenic changes. The data on the rates of induction of recessive lethals and of dominant skeletal and dominant cataract mutations (and proportions of the latter two which are homozygous lethal) can be used to estimate the proportions of recessive lethals which are expressed as skeletal abnormalities or cataracts. These calculations show that about 10% of recessive lethals manifest themselves as skeletal and less than 0.2% as cataract mutations.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evidence of an essential difference between point mutations and chromosome breaks induced by triethylene melamine inDrosophila spermatozoa

Summary Storing of triethylene melamine-treated mature spermatozoa in untreated females was found to result in increased frequencies of both sex-linked recessive lethals and translocations involving the Y, II and III chromosomes. Frequencies of these mutations in effectively unstored spermatozoa were determined from progenies produced using sperm 2–4 days after treatment. The increase in translocation frequencies was on the order of 12-fold in progenies from sperm utilized 11–13 days after treatment when the sperm were stored at 25°C, and 3- to 6-fold when comparable sperm were stored at 12.5°C. Consistent but much smaller increases in frequencies of sex-linked lethals were found, with the increase in lethals tending to be correlated with relative increase in translocation frequency in a given experiment. On the assumption that sex-linked lethals related to chromosome breakage would be expected to increase in frequency in the same proportion as do translocations, approximate agreement was obtained when the proportions of breakage-related lethals among unstored lethals were estimated from the data in the four experimental series. The data are thus consistent with the hypothesis that chromosome breaks but not point mutations are realized during storage of treated spermatozoa. Possible interpretations of a differential effect of storage on treated chromosomes are discussed.Studies carried out while the author was a guest investigator at the Institute of Animal Genetics on sabbatical leave from the University of Minnesota.     

A Cytogenetic Analysis of the Chromosomal Region Surrounding the α-Glycerophosphate Dehydrogenase Locus of DROSOPHILA MELANOGASTER

The chromosomal region surrounding the structural gene for α-glycerophosphate dehydrogenase (αGpdh, 2-20.5) of Drosophila melanogaster has been studied in detail. Forty-three EMS-induced recessive lethal mutations and five previously identified visible mutations have been localized within the 25A-27D region of chromosome 2 by deficiency mapping and in some cases by a recombination analysis. The 43 lethal mutations specify 17 lethal loci. αGpdh has been localized to a single polytene chromosome band, 25F5, and there apparently are no lethals that map to the αGpdh locus.