Components of fitness in a compound chromosome strain of Drosophila melanogaster

Summary The relative net fitness of a compound chromosome strain of Drosophila melanogaster was about 0.05, compared with the chromosomally normal strain from which it was derived. Based on meiotic considerations alone, the expected relative fitness was about 0.25. There were no significant differences in fertility between the compound and normal strains; the compound strain produced about 28% as many offspring as the normal strain and developed faster than the normal strain in two replicates, and slower in one replicate. The low relative fitness of the compound strain was apparently due to assortative mating, in which normal females discriminated strongly against compound males. Implications for pest control projects are dicussed.     

'Exceptional sons' from Drosophila melanogaster mothers carrying a balancer X chromosome

This study reports on exceptional males which are obtained by using Drosophila melanogaster mothers carrying the balancers In(1)FM6 or In(1)FM7 as one of their X chromosomes. The phenomenon was first observed in interspecific crosses between D. melanogaster females and males of its closest relatives which normally produce unisexual female hybrid progeny. Whereas hybrid sons from these crosses die as third instar larvae, the presence of the particular X balancers in the mother allows a low percentage of sons to survive. Similar sterile males are also observed among non-hybrid flies. Data are presented which suggest that the males thus generated could be hyperploid for part of their X chromosome as a result of a meiotic event in their mothers or else they could start life as female zygotes and change sex through a mitotic event at an early stage.     

Rapid divergence of gene duplicates on the Drosophila melanogaster X chromosome

The recent sequencing of several eukaryotic genomes has generated considerable interest in the study of gene duplication events. The classical model of duplicate gene evolution is that recurrent mutation ultimately results in one copy becoming a pseudogene, and only rarely will a beneficial new function evolve. Here, we study divergence between coding sequence duplications in Drosophila melanogaster as a function of the linkage relationship between paralogs. The mean K(a)/K(s) between all duplicates in the D. melanogaster genome is 0.2803, indicating that purifying selection is maintaining the structure of duplicate coding sequences. However, the mean K(a)/K(s) between duplicates that are both on the X chromosome is 0.4701, significantly higher than the genome average. Further, the distribution of K(a)/K(s) for these X-linked duplicates is significantly shifted toward higher values when compared with the distributions for paralogs in other linkage relationships. Two models of molecular evolution provide qualitative explanations of these observations-relaxation of selective pressure on the duplicate copies and, more likely, positive selection on recessive adaptations. We also show that there is an excess of X-linked duplicates with low K(s), suggesting a larger proportion of relatively young duplicates on the D. melanogaster X chromosome relative to autosomes.     

Genetic duplication in the white-split interval of the X chromosome in Drosophila melanogaster

A detailed cytogenetic study of male-viable and lethal deficiencies affecting the w-spl interval in Drosophila melanogaster has revealed the existence of genetic duplication such that, for example, the consequences of the loss of salivary chromosome band 3C3 are essentially compensated for by the presence of band 3C5-6, and vice versa. Although each of the duplicate elements possesses rst ⁺ and vt ⁺ activity, rst and vt phenotypes appear in males when 3C3 and part, but not all, of 3C5-6 are deleted. The degree of rst and vt expression can be correlated with the amount of material lost from 3C5-6. Deletions removing the entire 3C3-6 interval are male lethal. Despite the duplicate elements, at least one EMS-induced, presumptive point mutation expressing only rst is known; two others express both rst and vt. No loci other than rst and vt occur between W and spl. Band 3C2 appears to be associated with the w locus, which probably extends into the interband space between 3C1 and 3C2. The w locus is not involved in the rst-vt duplication in the 3C3-6 region. — The cytogenetic characteristics of the 3C region—a high coefficient of crossing over, frequent induced chromosome breakage, ectopic pairing, constriction, and an extended replication period—can be correlated with the fact that in 3C a relatively long stretch of DNA, nearly 2% of the entire X chromosome, is highly compacted into but few adjacent bands. These characteristics do not necessarily represent special properties of intercalary heterochromatin; they can be interpreted as reflecting the properties of any similarly organized euchromatic region.This investigation was aided by research grants from the U. S. Public Health Service (GM 13631) to G. Lefevre, Jr. and the National Science Foundation (GB 27599) to M. M. Green.     

Electron microscopic band-interband pattern of the X chromosome in Drosophila hydei

The band-interband pattern of the salivary gland X chromosome in Drosophila hydei was studied by electron microscopy (EM) using the technique of surface-spread polytene (SSP) chromosome preparation. We observed 526 chromosome bands, i.e. 135 additional bands as compared with the original light microscopic chromosome map (Berendes 1963). Individual interband lengths and band thicknesses were measured for the entire X chromosome in electron micrographs of ten SSP chromosome preparations. Average values were used to plot an EM chromosome map. The average interband had an axial length of 0.38 m. Depending upon the extension of the DNA packing ratio in interbands, this indicates 1.1 kb of totally extended DNA or 3.8 kb, if a DNA packing ratio of 0.10 m/kb is assumed for SSP chromosomes (Kress et al. 1985).     

Dynamic organization of the β-heterochromatin in the Drosophila melanogaster polytene X chromosome

Region 20 of the polytene X chromosome of Drosophila melanogaster was studied in salivary glands (SG) and pseudonurse cells (PNC) of otu mutants. In SG chromosomes the morphology of the region strongly depends on two modifiers of position effect variegation: temperature and amount of heterochromatin. It is banded in XYY males at 25°?C and β-heterochromatic in X0 males at 14°?C, i.e. it shows dynamic transitions. In PNC chromosomes region 20 is not heterochromatic, but demonstrates a clear banding pattern. Some molecular markers of mitotic heterochromatin were localized by means of in situ hybridization on PNC chromosomes: DNA of the gene su(f) in section 20C, the nucleolar organizer and 359-bp satellite in 20F. The 359-bp satellite, which has been considered to be specific for heterochromatin of the mitotic X chromosome, was found at two additional sites on chromosome 3L, proximally to 80C. The right arm of the X chromosome in SG chromosomes was localized in the inversion In(1LR)pn2b: the telomeric HeT-A DNA and AAGAG satellite from the right arm are polytenized, having been relocated from heterochromatin to euchromatin.     

Feminization of complex traits in Drosophila melanogaster via female-limited X chromosome evolution*

A handful of studies have investigated sexually antagonistic constraints on achieving sex-specific fitness optima, although exclusively through male-genome-limited evolution experiments. In this article, we established a female-limited X chromosome evolution experiment, where we used an X chromosome balancer to enforce the inheritance of the X through the matriline, thus removing exposure to male selective constraints. This approach eliminates the effects of sexually antagonistic selection on the X chromosome, permitting evolution toward a single sex-specific optimum. After multiple generations of selection, we found strong evidence that body size and development time had moved toward a female-specific optimum, whereas reproductive fitness and locomotion activity remained unchanged. The changes in body size and development time are consistent with previous results, and suggest that the X chromosome is enriched for sexually antagonistic genetic variation controlling these particular traits. The lack of change in reproductive fitness and locomotion activity could be due to a number of mutually nonexclusive explanations, including a lack of sexually antagonistic variance on the X chromosome for those traits or confounding effects of the use of the balancer chromosome. This study is the first to employ female-genome-limited selection and adds to the understanding of the complexity of sexually antagonistic genetic variation.     

Suppression of transcription of the ribosomal RNA cistrons of Drosophila melanogaster in a structurally rearranged chromosome

Evidence has been sought on the possible existence of multiple forms of the enzyme controlled by the Li locus in white clover. During purification of enzyme from LiLi plants, there was no separation of activities against the -glucosides, p-nitrophenyl -d-glucoside, salicin, and linamarin-lotaustralin, and the -galactoside, p-nitrophenyl -d-galactoside. In addition, tests on mixtures of these four substrates provided no evidence for the existence of more than one enzyme. Immunological tests have shown that plants homozygous for the recessive li allele do not contain an enzymatically inactive protein, antigenically related to the normal enzyme. This suggests that li alleles either specify a low-activity immunologically altered protein or control the synthesis of very low levels of normal enzyme.     

Digest: Female‐limited X chromosome evolution in Drosophila melanogaster*

Sexual dimorphism can cause sexual antagonism of phenotypic traits. Lund‐Hansen and colleagues (2020) investigated female‐limited X chromosome evolution in Drosophila melanogaster using forced matrilineal inheritance. Body size and developmental time evolved toward their female optima, but reproductive fitness and locomotion remained unchanged. These findings imply that some sexually antagonized loci may be distributed across the genome and that some phenotypes may have already reached their female optima in nature.