Mechanism of hycanthone mutagenesis: the induction of temperature-sensitive mutations in Drosophila melanogaster.

A total of 358 sex-linked recessive lethals induced by hycanthone methane sulphonate (HMS) were checked for temperature sensitivity, along with 239 EMS-induced lethals as a positive control. Only about 1-2% of the HMS-induced lethals were temperature-sensitive, in contrast to about 7-8% for EMS-induced lethals. This can be reasonably explained by assuming that in Drosophila, HMS mainly acts by inducing frame-shift mutations or deletions.     

Studies on mutagen-sensitive strains of Drosophila melanogaster. II. Detection of qualitative differences between genetic damage induced by X-irradiation of mature spermatozoa in oxygenated and anoxic atmospheres through the use of the repair-deficient mutant mei-9a

Muller-5 males were irradiated with X-rays in nitrogen, in air or in oxygen (followed by nitrogen or oxygen post-treatments in the nitrogen and oxygen series) and were mated to females of a repair-proficient strain (mei+) or to those of a strain known to be deficient in excision repair of UV damage (in somatic cells). The latter strain, designated as mei-9a, is also known to be sensitive, in the larval stages, to the killing effects of UV, X-rays and to a number of chemical mutagens. The frequencies of sex-linked recessive lethals and autosomal translocations induced in the spermatozoa of males were determined and compared. The frequencies of sex-linked recessive lethals in the mei-9 control groups were consistently higher than in the mei+ groups. Irradiation in air or in nitrogen led to significantly higher yields of recessive lethals when the irradiated males were mated to mei-9 females, whereas, after irradiation in oxygen, the yields were similar with both kinds of female. No significant differences in the frequencies of reciprocal translocations were observed between the mei+ and mei-9 groups after irradiation of the males in nitrogen, in air or in oxygen. Likewise, no differential effects of the contrasting post-treatments (nitrogen versus oxygen), either for recessive lethals or for translocations, could be discerned. These results are considered to support the notion that the kinds of genetic damage induced in mature spermatozoa in air or in nitrogen are qualitatively similar (at least with respect to the component(s) that lead to the production of recessive lethal mutations), but clearly different when induced in an oxygen atmosphere. The enhanced yields of recessive lethals with mei-9 females (after irradiation of the males either in air or in nitrogen) has been interpreted on the assumption that the mei-9 mutant is also deficient for the repair of X-ray-induced, recessive lethal-generating premutational lesions. Possible reasons for the lack of differences between the mei+ and mei-9 groups with respect to translocation yields and for the absence of measurable differences in response between the contrasting post-treatments (after irradiation of the males in nitrogen) are discussed.     

Dose-response relationships and R.B.E. values of dominant lethals induced by X-rays and 1.5 MeV neutrons in prophase-1 oocytes and in mature sperm of the two-spotted spider mite Tetranychus urticae Koch (acari, tetranychidae)

Mature sperm and prophase-1 oocytes of Tetranychus urticae Koch were irradiated with 250-kVp X-rays or 1.5 MeV fast neutrons. The X-ray doses ranged from 0.5 to 24.0 krad, and those of the fast neutrons from 0.1 to 16.0 krad. The genetic endpoint measured was lethality, expressed in the stages from egg to adulthood in the F1 progeny. The frequency of recessive lethals in female germ cells was estimated by comparing survival of fertilized versus unfertilized F1 eggs, after irradiation with the same dosage. X-Rays induce dominant lethals in prophase-1 oocytes by the action of both single hits on single targets and multiple hits on multiple targets. 1.5-MeV neutrons induce these effects predominantly by the action of multiple tracks on multiple targets. Dominant lethals were induced in mature sperm by X-rays and by fast neutrons by the action of both single hits on single targets and multiple hits on multiple targets. Both for prophase-1 oocytes and for mature sperm the low R.B.E. value corresponded with the relatively large multiple-target component of induction of dominant lethals by fast neutrons. The nature of dominant lethality in relation to the kinetochore organization of the chromosome is discussed. A non-linear trend in the dose--effect relationship was observed for both X-rays and fast neutrons for the estimated frequency of recessive lethals induced in prophase-1 oocytes. X-Rays were more effective than neutrons in inducing recessive lethals in prophase-1 oocytes at doses lower than 3 krad.     

Studies on mutagen-sensitive strains of Drosophila melanogaster. IV. Modification of genetic damage induced by X-irradiation of spermatozoa and spermatids in N2 or O2 by mei-9a, mei-41D5 and mus(1)101D1

The influence of defects in DNA repair processes on X-ray-induced genetic damage in post-meiotic male germ cell stages of Drosophila melanogaster was studied using the 'maternal effects approach'. Basc males were irradiated in N2, air or O2 either as 48-h-old pupae (to sample spermatids) or as 3-4-day-old adults (to sample mature spermatozoa) and mated to females of 3 repair-deficient strains (mei-9a: excision-repair-deficient; mei-41D5: post-replication-repair-deficient; mus(1)101D1: post-replication-repair-deficient and impaired in DNA synthesis). Simultaneous controls involving mating of males to repair-proficient females (mei+) were run. The frequencies of sex-linked recessive lethals and of autosomal translocations were determined following standard genetic procedures. The responses elicited in the different crosses with repair-deficient females were compared with those in mei+ crosses. The main findings are the following: with mei-9 females, the frequencies of recessive lethals are higher after irradiation of spermatids in N2, but not after irradiation in air of O2 (relative to those in the mei+ crosses); this result is different from that obtained in earlier work with spermatozoa, in which cell stage, higher yields of recessive lethals were obtained after irradiation of males in either N2 or air; in the mei-9 crosses, there are no significant differences in response (relative to mei+) after irradiation of either spermatozoa or spermatids in O2; the translocation frequencies in the mei-9 crosses are similar to those in the mei+ crosses, irrespective of the treated germ cell stage or the irradiation atmosphere; irradiation of either spermatozoa or spermatids in N2, air or O2 does not result in any differential recovery of recessive lethals in the mei-41 relative to mei+ crosses; irradiation of spermatids in N2 and of spermatozoa in air leads to a higher recovery of translocations in the mei-41 crosses; and after irradiation of spermatids or spermatozoa in any of the gaseous atmospheres, the frequencies of recessive lethals and of translocations are lower in the mus-101 crosses. The differences in responses (between cell stages, in different gaseous atmospheres and with different repair-deficient females) are explained on the basis of both qualitative and quantitative differences in the composition of the initial lesions and the extent to which their repair may be affected by the defects present in the different repair-deficient females. Several discrepancies between expectations based on biochemical results and the genetic results are pointed out.(ABSTRACT TRUNCATED AT 400 WORDS)     

The mutational spectrum of procarbazine in Drosophila melanogaster.

The antineoplastic agent Procarbazine was tested for the induction of genetic damage in Drosophila melanogaster. The compound was administered to adult males by oral application. The following types of genetic damage were measured: (1) sex-linked recessive lethals; (2) dominant lethals; (3) total and partial sex-chromosome loss; and (4) translocations. Procarbazine is highly mutagenic in causing recessive lethal mutations in all stages of spermatogenesis. In sperm a clear-cut concentration-effect relationship is not apparent, but in spermatids such a relationship is obtained for mutation induction at low levels of procarbazine exposure, while at high concentrations the induction of recessive lethals is not a function of concentration. A low induction of total sex-chromosome loss (X,Y) and dominant lethals was observed in metabolically active germ cells (spermatids), but procarbazine failed to produce well-defined breakage events, such as partial sex-chromosome loss (YL,YS) and II-III translocations. The results obtained in Drosophila melanogaster are discussed and compared with the mutational pattern reported in the mouse after procarbazine treatment.     

A Method for Detecting and Measuring Concealed Variability in the Mosquito, CULEX TRITAENIORHYNCHUS

A natural population of Culex tritaeniorhynchus was sampled to test the efficacy of a proposed method to detect and measure concealed variability. Thirty-nine lethals and ten recessive visible mutations were uncovered out of a total of 125 chromosomes tested.     

The relationship between radiation-induced and transposon-induced genetic damage during Drosophila oogenesis

The combined effect of X-irradiation and transposon mobility on the frequencies of X-linked recessive lethals and dominant lethals was investigated in female hybrids in the P-M system of hybrid dysgenesis. X-linked lethals were measured in G2 hybrid dysgenic females whose X chromosome was derived from the M X P cross. To test for additivity or synergism, the mutation rate in irradiated dysgenic females was compared to that of unirradiated females as well as to irradiated nondysgenic hybrid females derived from M X M crosses. Eggs collected for 2 days after irradiation, were represented by the more radiation-sensitive A and B oocytes (about 75%) and the least sensitive C oocytes (about 25%). The production of X-linked lethal events in X-irradiated dysgenic females was 8.1%, as compared to 4.5% in dysgenic controls and 3.4% in irradiated, nondysgenic controls, demonstrating an additive effect of radiation and dysgenesis-induced genetic damage. The effect of irradiation on sterility of dysgenic hybrid females was a negative one, resulting in 20% less sterility than expected from an additive effect. The combined effect of radiation and dysgenesis on dominant lethality tested in A, B and C oocytes of the same hybrid females was synergistic. Egg broods collected for 3.5 days after irradiation showed that significantly more damage was induced in the presence of ionizing radiation in dysgenic females than in their nondysgenic counterparts. This effect was most obvious in B and C oocytes. The synergism observed may be related to the inability of cells to repair the increased number of chromosome breaks induced both by radiation and transposon mobility.     

Investigations on radiosensitive and radioresistant populations of Drosophila melanogaster. IV. The genetics of the relative radioresistance in stage-7 oocytes of the irradiated population RO I

The genetic system that controls the relative radioresistance in an irradiated laboratory population of Drosophila melanogaster (RÖ I) was studied. Comparisons were made between an unirradiated control population (+60, +K), the population RÖ I (after 227–333 generations of irradiation at 2100 R per generation), the sub-population RÖ I₀ (derived from RÖ I after 260 generations of irradiation and kept without irradiation for up to 74 generations), the F₁ hybrids +60/RÖ I, various homo- and heterozygous carriers of the 3 major chromosomes of RÖ I and +60, respectively, in combination with suitable balancers, and several chromosome substitution stocks of +K and RÖ I. The criteria used to assess the magnitude of radiosensitivity were dominant lethals, X-chromosome loss, and sex-linked recessive lethals induced in stage-7 oocytes at various exposure levels of X-irradiation.The data show that the radioresistance in RÖ I is controlled by a stable and homozygous genetic system. The system is semidominant. With respect to the induction of dominant lethals and sex-linked recessive lethals, the relative resistance is mainly contributed by chromosomes I and II. The effects of the two chromosomes are additive, each contributing about half the relative resistance. Resistance to the X-ray induction of X-chromosome loss is solely contributed by chromosome II.The findings suggest that at least 2 different and independent mechanisms are involved in determining the resistance of the RÖ I population.     

The detection of autosomal lethals in mice induced by mutagenic agents

Journal of Genetics - A method is proposed for searching for recessive lethals in mice. A multiple recessive stock is irradiated, and members of it are crossed to a multiple dominant stock. Lethal...     

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.     

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)     

Radiosensitivity of Drosophila lines. VII. The effect of the maternal genotype on the yield of recessive and dominant lethal mutations induced by the gamma irradiation of males

The effect of material repair on induction of paternal mutations was tested with radiosensitive rad(2)201G1 mutant. Basc males were irradiated at doses from 0 to 60 Gy of gamma-rays and mated to the radiosensitive mutant or control females. Frequencies of sex-linked recessive lethals and dominant lethals (induced in the paternal genome) were determined. With control females, the rate of recessive lethals increased linearly from 0 to 60 Gy. With rad(2)201G1 mutant, an increase in spontaneous and induced rates of paternal dominant lethals was observed; the rate of sex-linked recessive lethals increased non-linearly from 0 to 60 Gy.     

Effect of glyoxal pretreatment on radiation-induced genetic damage in Drosophila melanogaster

The effects of glyoxal and of glyoxal pretreatments on radiation-induced genetic damage were investigated in Drosophila melanogaster mature sperm, by means of sex-linked recessive and dominant lethality, reciprocal translocation and chromosome loss tests. In addition, the possible mutagenic effect of glyoxal was assessed in postmeiotic cells up to 7 days after treatment. The results obtained show: (1) the frequencies of recessive lethals after glyoxal treatment were within control values, (2) no clastogenic effect of glyoxal was observed, (3) glyoxal pretreatment did not modify the frequency of recessive lethals induced by X-rays, (4) after pretreatment with glyoxal a consistent, though not significant, increase was seen in the frequency of reciprocal translocations in 3 replicate experiments, (5) the yield of dominant lethals and of complete and partial chromosome loss induced by radiation was significantly increased by pretreatments with glyoxal. It is suggested that the increase of the frequency of genetic endpoints resulting from chromosome breakage, when glyoxal was administered prior to irradiation, could be ascribed to: (a) a sensitizing action of glyoxal to the clastogenic effect of ionizing radiation; (b) the formation of reactive species by the interaction of glyoxal with radiation; and/or (c) interference of glyoxal with the normal handling of radiation-induced lesions in mature postmeiotic male cells.     

Distribution of MR-induced sex-linked recessive lethal mutations in Drosophila melanogaster

In the ‘doubling-dose’ method currently used in genetic risk evaluation, two principle assumptions are made and these are: (1) there is proportionality between spontaneous and induced mutations and (2) the lesions that lead to spontaneous and induced mutations are essentially similar. The studies reported in this paper were directed at examining the validity of these two assumptions in Drosophila. An analysis was made of the distribution of sex-linked recessive lethals induced by MR, one of the well-studied mutator systems in Drosophila.

Appropriate genetic complementation tests with 15 defined X-chromosome duplications showed that MR-induced lethals occurred at many sites along the X-chromosome (in contrast to the known locus specificity of MR-induced visible-mutations); some, but not all these sites at which recessive lethals arose in the MR-system are the same as those known to be hot-spots for X-ray-induced lethals. With in situ hybridization we were able to demonstrate that a majority of MR-induced lethals is associated with a particular mobile DNA sequence, the P-element, i.e. they arose as a result of transposition.

The differences between the profiles of MR-induced and X-ray-induced recessive lethals, and the nature of MR-induced and X-ray-induced mutations, thus raise questions about the validity of the assumptions involved in the use of the ‘doubling-dose’ method.     

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.     

Effects of a chromosome-3 mutator gene on radiation-induced mutability in Drosophila melanogaster females

A series of X-irradiation experiments was carried out using Drosophila melanogaster females homozygous for a third chromosome mutator gene and females which had a similar genetic background except that the mutator-bearing third chromosomes were substituted by normal wild-type chromosomes. The mutator females had been previously shown by Gold and Green to manifest a higher level of radiation-induced mutability (as measured by the X-ray-induction of sex-linked recessive lethals) in their pre-meiotic germ cells compared to normal females at an exposure of 100 R. In the presence work, the sensitivity of the pre-meiotic germ cells of mutator and normal females to the X-ray induction (2000 R) of sex-linked recessive lethals was studied. In addition, experiments were conducted to examine the sensitivity of the immature (stage 7; prophase I of meiosis) oocytes of both kinds of females to the induction of dominant lethals, X-linked recessive lethals and X-chromosome losses. The result show that in pre-meiotic germ cells, the frequencies of radiation-induced recessive lethals are similar in both kinds of females. However, the proportion of these mutations that occur in clusters of size 3 and higher, is higher in mutator than in normal females. In stage-7 oocytes, the frequencies of radiation-induced dominant lethals and sex-linked recessive lethals were similar in both kinds of females. The X-loss frequencies however, were consistently higher in mutator females although statistical significance was obtained only at higher exposures (3000 and 3750 R) and not at lower ones (750-2250 R). Possible reasons for the discrepancy between the present results and those of Gold and Green with respect to pre-meiotic germ cells are discussed.     

Distribution of MR-induced sex-linked recessove lethal mutations in Drosophila melanogaster

In the ‘doubling-dose’ method currently used in genetic risk evaluation, two principle assumptions are made and these are: (1) there is proportionality between spontaneous and induced mutations and (2) the lesions that lead to spontaneous and induced mutations are essentially similar. The studies reported in this paper were directed at examining the validity of these two assumptions in Drosophila. An analysis was made of the distribution of sex-linked recessive lethals induced by MR, one of the well-studied mutator systems in Drosophila.Appropriate genetic complementation tests with 15 defined X-chromosome duplications showed that MR-induced lethals occurred at many sites along the X-chromosome (in contrast to the known locus specificity of MR-induced visible-mutations); some, but not all these sites at which recessive lethals arose in the MR-system are the same as those known to be hot-spots for X-ray-induced lethals. With in situ hybridization we were able to demonstrate that a majority of MR-induced lethals is associated with a particular mobile DNA sequence, the P-element, i.e. they arose as a result of transposition.The differences between the profiles of MR-induced and X-ray-induced recessive lethals, and the nature of MR-induced and X-ray-induced mutations, thus raise questions about the validity of the assumptions involved in the use of the ‘doubling-dose’ method.     

Effect of storage and dose on MMS-induced deletions. Complementation analysis of X-chromosomal recessive lethals in the zeste-white and maroon-like regions of Drosophila melanogaster

The effect of storage on MMS-induced recessive lethals in the zeste-white (3A1-3C2) and the maroon-like (18F4-20F) regions was studied by complementation analysis. (1) Without any exception, all 52 mutants (from unstored spermatozoa) mapped in the zeste-white region were restricted to single complementation units. Furthermore, none of an additional 15 lethals, sampled from sperm that had been stored in females for 9-12 days, was associated with a deletion. (2) Of 34 mutations induced by 8.5 X 10(-2) mM MMS in the maroon-like (mal) region, 4 spanned 2 or more complementation units, and thus are considered to be deletions. A high dose of 2.5 mM MMS provided 55 lethals for analysis of which 4 were deletions. There was no evidence for any difference in the frequency of deletions as the MMS concentration was enhanced from 8.5 X 10(-2) mM to 2.5 mM. However, with storage, 47.1% lethals (16 of 34 mutants induced by 2.5 mM MMS) mapped in the mal region were found to involve large structural changes. (3) A high proportion of double mutants in both the zeste-white (z w) and the maroon-like regions was found among the chromosomes analyzed. These double mutants have one lethal positioned within the region studied and the other outside it. Clearly, the proportion of double mutants increased with dose, from 6.3 to 41.7% in z w and from 14.7 to 61.8% in the mal section. Apurinic sites in DNA reacted with MMS are considered as the likely primary lesions responsible for the storage effect on MMS-induced recessive lethals in the mal region. Thus, the ability of MMS to produce delayed deletion lethals seems to correlate with preference for alkylation of base nitrogens. An interesting aspect for further analysis is the apparent infrequency in the zeste-white region of alkylation-induced chromosomal breakage, as observed by various investigators for MMS, EMS and MNNG.     

Inbreeding depression maintained by recessive lethal mutations interacting with stabilizing selection on quantitative characters in a partially self‐fertilizing population

The bimodal distribution of fitness effects of new mutations and standing genetic variation, due to early‐acting strongly deleterious recessive mutations and late‐acting mildly deleterious mutations, is analyzed using the Kondrashov model for lethals (K), with either the infinitesimal model for selfing (IMS) or the Gaussian allele model (GAM) for quantitative genetic variance under stabilizing selection. In the combined models (KIMS and KGAM) high genomic mutation rates to lethals and weak stabilizing selection on many characters create strong interactions between early and late inbreeding depression, by changing the distribution of lineages selfed consecutively for different numbers of generations. Alternative stable equilibria can exist at intermediate selfing rates for a given set of parameters. Evolution of quantitative genetic variance under multivariate stabilizing selection can strongly influence the purging of nearly recessive lethals, and sometimes vice versa. If the selfing rate at the purging threshold for quantitative genetic variance in IMS or GAM alone exceeds that for nearly recessive lethals in K alone, then in KIMS and KGAM stabilizing selection causes selective interference with purging of lethals, increasing the mean number of lethals compared to K; otherwise, stabilizing selection causes selective facilitation in purging of lethals, decreasing the mean number of lethals.     

Temperature-Sensitive Mutations in DROSOPHILA MELANOGASTER. Xvii. Heat- and Cold-Sensitive Lethals on Chromosome 3

Ethyl methanesulfonate-treated third chromosome of Drosophila melanogaster were tested for the presence of dominant and recessive temperature-sensitive lethal mutations at 17 degrees , 22 degrees and 29 degrees C. Out of 1,176 chromosomes tested, no dominant ts lethals, 21 heat-sensitive, 22 cold-sensitive and 10 heat-cold-sensitive lethals were recovered. Heat-cold sensitivity was produced by a single mutation in all cases. Sixty-two percent of the ts lethals were fertile as homozygotes in both sexes. Surprisingly, 88% of the ts lethals mapped between st and Sb, a region straddling the centromere and estimated to comprise 12.9% of the genetic length and 55% of the physical length of chromosome 3. All but one of the heat- and cold-sensitive lethals complemented with each other at their respective restrictive temperatures.