Frequency of telomere repeat units in the Drosophila miranda genome

Cloned DNA fragments of Drosophila miranda which label all chromosome ends show a basic tandem repeat unit of 4.4 kb. The D. miranda telomere specific tandem repeats do not cross-hybridize with genomic D. melanogaster DNA which itself contains telomere repeat units of 3 kb. For a more detailed analysis of the functional criteria of telomere specific sequences we determined the repetition frequency of the tandem repeat units. As a low estimate we found a repetition frequency of 20 for female D. miranda DNA. This is on average equivalent to 2 telomere repeat units per chromosome end in the female D. miranda karyotype. However, a variable number of tandem repeat units per chromosome end would describe more closely the obtained differences in the labeling intensity between the individual chromosomes (X¹L-5). For the D. miranda male DNA we determined a repetition frequency of 90. The frequency difference of 70 copies between male and female DNA must be due to the Y-chromosome.     

Multiple sex chromosomes in Drosophila miranda: A system to study the degeneration of a chromosome

Drosophila miranda possesses an intriguing sex chromosome constitution. While female metaphase plates have 10 chromosomes (diploid set), in males only 9 chromosomes can be identified. The missing homologue has been translocated to the Y, forming a neo-Y chromosome which is polytenized in the salivary gland cells. This report presents a detailed characterization of DNA, isolated from D. miranda flies. In situ hybridizations, using cRNA transcribed from unfractionated D. miranda DNA, reveal hybridization to the neo-Y with label distributed over the entire chromosome. The original partner of the translocated chromosome, X², is essentially unlabelled. These results suggest that repetitive DNA sequences invade the translocated chromosome. This result is discussed with reference to the hypothesis of degeneration of the Y chromosome, formulated by Muller (1918, 1932a).     

Autosomal suppression and fitness costs of an old driving X chromosome in Drosophila testacea

Driving X chromosomes (X^Ds) bias their own transmission through males by killing Y‐bearing gametes. These chromosomes can in theory spread rapidly in populations and cause extinction, but many are found as balanced polymorphisms or as “cryptic” X^Ds shut down by drive suppressors. The relative likelihood of these outcomes and the evolutionary pathways through which they come about are not well understood. An X^D was recently discovered in the mycophagous fly, Drosophila testacea, presenting the opportunity to compare this X^D with the well‐studied X^D of its sister species, Drosophila neotestacea. Comparing features of independently evolved X^Ds in young sister species is a promising avenue towards understanding how X^Ds and their counteracting forces change over time. In contrast to the X^D of D. neotestacea, we find that the X^D of D. testacea is old, with its origin predating the radiation of three species: D. testacea, D. neotestacea and their shared sister species, Drosophila orientacea. Motivated by the suggestion that older X^Ds should be more deleterious to carriers, we assessed the effect of the X^D on both male and female fertility. Unlike what is known from D. neotestacea, we found a strong fitness cost in females homozygous for the X^D in D. testacea: a large proportion of homozygous females failed to produce offspring after being housed with males for several days. Our male fertility experiments show that although X^D male fertility is lower under sperm‐depleting conditions, X^D males have comparable fertility to males carrying a standard X chromosome under a free‐mating regime, which may better approximate conditions in wild populations of D. testacea. Lastly, we demonstrate the presence of autosomal suppression of X chromosome drive. Our results provide support for a model of X^D evolution where the dynamics of young X^Ds are governed by fitness consequences in males, whereas in older X^D systems, both suppression and fitness consequences in females likely supersede male fitness costs.     

Dosage compensation of a retina-specific gene in Drosophila miranda

The X1R chromosome of Drosophila miranda and the 3L autosome of Drosophila melanogaster are thought to have originated from the ancestral D chromosomal element and therefore may contain the same set of genes. It is expected that these genes will be dosage compensated in D. miranda because of their X linkage. To test these possibilities and to study evolution of the dosage compensation mechanism, we used the 3L-linked autosomal head-specific gene 507ml of D. melanogaster to isolate the homologous gene (507 mr) from a D. miranda genomic library. In situ hybridization showed that gene 507 is located at the 12A region of the X1R chromosome of D. miranda, indicating that the chromosomal homology deduced by cytogenetic means is correct. Restriction analysis and cross-specific DNA and RNA blot hybridization revealed the presence of extensive restriction pattern polymorphism and lack of sequence similarity in some areas of the 507 mr and 507 ml DNA, including the 3 portion of the transcribed region. However, the 5 portion of the transcribed region and the DNA sequences, located approximately 0.8 kb upstream and 3 kb downstream from the 507 ml gene showed a high degreee of similarity with the DNA sequences of comparable regions of the 507 mr gene. In both species gene 507 codes for a highly abundant 1.8 kb RNA which is expressed in the retina of the compound eye. Although in D. miranda the males have one and the females have two copies of the 507 gene, the steady-state levels of the 507 mRNA in both sexes were found to be similar, indicating that gene 507 is dosage compensated in D. miranda. Thus, along with the disparate rates of evolution in different areas of the DNA associated with gene 507, in D. miranda this gene has come under the regulation of the X chromosomal dosage compensation mechanism.by M.L. Pardue     

Telomere repeats within the neo-Y-chromosome of Drosophila miranda

The clone Dmir1098, isolated from a genomic lambda library of Drosophila miranda labels exclusively the tips of the giant chromosomes in the highly polytenized nuclei of the female larval salivary glands. However, the in situ hybridizations to male metaphase plates, using the same probe, reveal a massive labeling block within the neo-Y-chromosome in addition to the labeling blocks at both chromosome ends. From the comparison with the Y chromosome labeling pattern of D. pseudoobscura, a sibling species to D. miranda, an end-to-end fusion mechanism involving the telomere repeats would be the most straightforward explanation for the karyotype change in D. miranda.     

<Emphasis Type="Italic">Drosophila simulans Lethal hybrid rescue</Emphasis> mutation (<Emphasis Type="Italic">Lhr</Emphasis>) rescues inviable hybrids by restoring X chromosomal dosage compensation and causes fluctuating asymmetry of development

The Drosophila simulans Lhr rescues lethal hybrids from the cross of D. melanogaster and D. simulans. We describe here, the phenotypes of Lhr dependent rescue hybrids and demonstrate the effects of Lhr on functional morphology of the salivary chromosomes in the hybrids. Our results reveal that the phenotypes of the ‘Lhr dependent rescued’ hybrids were largely dependent on the genetic background and the dominance in species and hybrids, and not on Lhr. Cytological examination reveal that while the salivary chromosome of ‘larval lethal’ male carrying melanogaster X chromosome was unusually thin and contracted, in ‘rescued’ hybrid males (C _mel X _mel Y _sim ; A _mel A _sim ) the X chromosome showed typical pale staining, enlarged diameter and incorporated higher rate of ³H-uridine in presence of one dose Lhr in the genome. In hybrid males carrying simulans X chromosome (C _mel X _sim Y _mel ; A _mel A _sim ), enlarged width of the polytene X chromosome was noted in most of the nuclei, in Lhr background, and transcribed at higher rate than that of the single X chromosome of male. In hybrid females (both viable, e.g., C _mel X _mel X _sim ; A _mel A _sim and rescued, e.g., C _mel X _mel X _mel ; A _mel A _sim ), the functional morphology of the X chromosomes were comparable to that of diploid autosomes in presence of one dose of Lhr. In hybrid metafemales, (C _mel X _mel X _mel X _sim ; A _mel A _sim ), two dose of melanogaster X chromosomes and one dose of simulans X chromosome were transcribed almost at ‘female’ rate in hybrid genetic background in presence of one dose of Lhr. In rescued hybrid males, the melanogaster-derived X chromosome appeared to complete its replication faster than autosomes. These results together have been interpreted to have suggested that Lhr suppresses the lethality of hybrids by regulating functional activities of the X chromosome(s) for dosage compensation.     

GENETICS OF STERILITY IN HYBRIDS BETWEEN TWO SUBSPECIES OF DROSOPHILA

Hybrids between D. pseudoobscura bogotana and D. pseudoobscura pseudoobscura are fertile except for males produced in one of the two reciprocal crosses. As there is no premating isolation between these subspecies, nonreciprocal male sterility represents the first step in speciation. Genetic analysis reveals two causes of hybrid F₁ sterility: a maternal effect and incompatibilities between chromosomes within males. The maternal effect appears to play the greatest role in hybrid sterility. The X chromosome has the largest effect on fertility of any chromosome, a ubiquitous result in analyses of hybrid sterility and inviability in Drosophila. This effect is entirely attributable to a region comprising less than 30% of the X chromosome. These results are compared to those from a similar study of D. pseudoobscura-D. persimilis hybrids, an older and more reproductively isolated species pair in the same lineage. Such comparisons may allow one to identify the genetic changes characterizing the early versus late stages of speciation.     

A three-locus system of interspecific incompatibility underlies male inviability in hybrids between Drosophila buzzatii and D. koepferae

In hybrids between the sibling species D. buzzatii and D. koepferae, both sexes are more or less equally viable in the F₁: However, backcross males to D. buzzatii are frequently inviable, apparently because of interspecific genetic incompatibilities that are cryptic in the F₁. We have performed a genetic dissection of the effects of the X chromosome from D. koepferae. We found only two cytological regions, termed hmi-1 and hmi-2, altogether representing 9% of the whole chromosome, which when introgressed into D. buzzatii cause inviability of hybrid males. Observation of the pattern of asynapsis of polytene chromosomes (incomplete pairing, marking introgressed material) in females and segregation analyses were the technique used to infer the X chromosome regions responsible for this hybrid male inviability. The comparison of these results with those previously obtained with the same technique for hybrid male sterility in this same species pair indicate that in the X chromosome of D. koepferae there are at least seven times more regions that produce hybrid male sterility than hybrid male inviability. We have also found that the inviability brought about by the introgression of hmi-1 is suppressed by the cointrogression of two autosomal sections from D. koepferae. Apparently, these three regions conform to a system of species-specific complementary factors involved in an X-autosome interaction that, when disrupted in backcross hybrids by recombination with the genome of its sibling D. buzzatii, brings about hybrid male inviability.     

Chromosome banding in amphibia

A cytogenetic study performed on a population of the South American leptodactylid frog Eleutherodactylus maussi revealed multiple sex chromosomes of the X₁X₁X₂X₂/X₁X₂Y (=XXAA/XXA^Y) type. The diploid chromosome number is 2n=36 in all females and 2n=35 in most males. The multiple sex chromosomes originated by a centric fusion between the original Y chromosome and a large autosome. In male meiosis the X₁X₂Y (=XXA^Y) multiple sex chromosomes form a classical trivalent configuration. E. maussi is the first species discovered in the class Amphibia that is distinguished by a system of multiple sex chromosomes. Only one single male was found in the population with 2n=36 chromosomes and lacking the Y-autosomal fusion. This karyotype (XYAA) is interpreted as the ancestral condition, preceding the occurrence of the Y-autosome fusion.by H.C. Macgregor     

Spermiogenesis of inversion heterozygotes in backcross hybrids between Drosophila buzzatii and D. serido

Interspecific F1 hybrid females of D. serido and D. buzzatii are fertile, but hybrid males are sterile. By successive backcrossing of hybrid females to D. buzzatii males it is possible to diminish the genomic contribution of D. serido to the hybrid karyotype. Finally, only selected chromosome sections of D. serido known as inversions restricted to this species were individually left in the otherwise D. buzzatii karyotype, namely: 2 C2b-F4a (j⁹m⁹n⁹), 2 B2c-F4a (j⁹k⁹), 3 C5a-G1b (k²), 4 E2a-G2f (m) and 5 C5d-F2h (w). The present paper deals with the influence of these chromosome sections on sperm differentiation. Any of them produces hybrid male sterility in heterozygous condition. We analyzed spermiogenesis using the DNA specific fluorescence dye BAO in hybrid males which were heterozygous either for only one inversion, as in chromosomes 3, 4 and 5, or for a series of inversions on the same chromosome, as in chromosome 2. The abnormalities recorded included abnormal formation of the cysts, lower than normal number of cysts, abnormal number of nuclei per cyst, incomplete elongation of the cyst, incomplete elongation of the nuclei, displacement of the nuclei from the head region of the cyst and lack of individualization. In no case was there any contents in the seminal vesicle. The section from chromosome 2 of D. serido had the most drastic effect; the disruption produced by the chromosome section corresponding to inversion 3 k² was only a little more severe than that due to 5 w, and both may be distinguished only quantitatively; inversion 4 m produced the slightest deviation from normal spermiogenesis. The larger the serido section introduced in the hybrid, the more severe were the abnormalities it produced. An interpretation in terms of a balance genic theory on the functioning of the genetic system is given.This is paper No. VII in the series The evolutionary history of Drosophila buzzatii.     

Complex sex-linked fusion heterozygosity in the Australian huntsman spider Delena cancerides (Araneae: Sparassidae)

In the vast majority of spider species studied to date, the karyotype is homogeneous in morphology and exclusively telocentric. The sex-determining system consists of one to three X chromosomes in the male and, correspondingly, two to six in the female. This is the case in species of huntsman spiders belonging to the genera Heteropoda (2n=40+3X), Isopoda, Olios, and Pediana (2n=40+3X) and some populations of the colonial species Delena cancerides (2n=40+3X). In other populations of D. cancerides, wholesale fusion of the karyotype has occurred, reducing the standard huntsman karyotype of 43 telocentric chromosomes to 21 metacentrics and 1 telocentric. Eight of the centric fusion products, including an X-autosome fusion, are maintained in the heterozygous condition in males and, with the single telocentric, form a chain of nine chromosomes at meiosis. The two complexes comprising the chain behave as neo-X and neo-Y chromosomes, and thus the ancestral X₁X₂X₃X₁X₁X₂X₂X₃X₃ sex-determining system has been converted to a system of six X and four Y chromosomes in the male and twelve X chromosomes in the female. Since sex-linked complex heterozygosity is also found in a number of species of social termites, it is suggested that such heterozygosity may have adaptive significance for a colonial lifestyle. Breakdown products of the chain of nine are present in specimens of D. cancerides from Canberra and these appear to represent hybrid products between the 2n=22 and 2n=43 forms. Hybridisation may also have been involved in the origin of the chain-forming races.     

A unique cytogenetic system in monotremes

All 3 extant genera of monotremes show a unique kind of cytogenetic system involving the formation of a structurally heterozygous chain multiple apparently coupled with a system of complementary gametic elimination. In the echidna Tachyglossus there are 63 chromosomes in the male and 64 in the female. This is associated with an X₁X₂Y/X₁X₁X₂X₂ sex chromosome system. Additionally in both sexes there are 6 mitotic chromosomes (a-f) which have no obvious homologous partners. At male meiosis these are included with the 3 sex chromosomes in a chain multiple of nine which has the constitution X₁·Y·X₂·f·e·d·c·b·a. This shows convergent orientation at first metaphase leading to the production of two kinds of sperm, namely X₁X₂ eca and Yfdb. Since no individual of either sex has been found homozygous for any of the a-f elements it follows that only gametes carrying different combinations of the three unpaired elements give rise to viable offspring. Whether this depends on gametic selection or on zygotic lethality is not known. An apparently identical system operates in Zaglossus. In the platypus Ornithorhynchus, on the other hand, there are 52 chromosomes in both males and females associated with an XY/XX sex chromosome mechanism and the presence of 4 consistently unpaired elements (a-d) at mitosis. A chain multiple of 10 forms at male meiosis involving the 2 sex chromosomes, the 4 unpaired elements and two of the small pairs of autosomes. Additionally the six longest autosome pairs in Tachyglossus and the X₁ show a polymorphism for size which in heterozygous combination leads to the formation of unequal bivalents at male meiosis.     

Differential replication of male and female X-chromosomes in Drosophila

The replication patterns of larval salivary gland chromosomes of D. hydei and D. melanogaster were studied by autoradiography with tritiated thymidine injected in mid third instar larvae. The male X chromosome showed a different replication behavior in comparison to that of the female X chromosome and autosomes. It is concluded that the male X chromosome finishes its replication earlier than the female X chromosome. Moreover, the time needed for a complete replication cycle of individual identical replication units was found to be shorter in the male than in the female X chromosome. Although the whole X chromosomes behave different there were no differences observed in the sequence of the discontinuous labeling patterns of the two types of X chromosome. One autosomal replication unit was observed which showed a different replication behavior in males and females. The possible origin of the differential behavior of the two X chromosomes is discussed in terms of their difference in degree of polyteny.     

Fine Mapping of Dominant X-Linked Incompatibility Alleles in Drosophila Hybrids

Sex chromosomes have a large effect on reproductive isolation and play an important role in hybrid inviability. In Drosophila hybrids, X-linked genes have pronounced deleterious effects on fitness in male hybrids, which have only one X chromosome. Several studies have succeeded at locating and identifying recessive X-linked alleles involved in hybrid inviability. Nonetheless, the density of dominant X-linked alleles involved in interspecific hybrid viability remains largely unknown. In this report, we study the effects of a panel of small fragments of the D. melanogaster X-chromosome carried on the D. melanogaster Y-chromosome in three kinds of hybrid males: D. melanogaster/D. santomea, D. melanogaster/D. simulans and D. melanogaster/D. mauritiana. D. santomea and D. melanogaster diverged over 10 million years ago, while D. simulans (and D. mauritiana) diverged from D. melanogaster over 3 million years ago. We find that the X-chromosome from D. melanogaster carries dominant alleles that are lethal in mel/san, mel/sim, and mel/mau hybrids, and more of these alleles are revealed in the most divergent cross. We then compare these effects on hybrid viability with two D. melanogaster intraspecific crosses. Unlike the interspecific crosses, we found no X-linked alleles that cause lethality in intraspecific crosses. Our results reveal the existence of dominant alleles on the X-chromosome of D. melanogaster which cause lethality in three different interspecific hybrids. These alleles only cause inviability in hybrid males, yet have little effect in hybrid females. This suggests that X-linked elements that cause hybrid inviability in males might not do so in hybrid females due to differing sex chromosome interactions.     

Chromosome homologies within the Drosophila obscura group probed by in situ hybridization

Probes specific to chromosome elements were used to investigate chromosome homologies between seven species of the Drosophila obscura group by in situ hybridization. Our results were in perfect agreement with the already established chromosome element homologies between D. subobscura, D. pseudoobscura, D. persimilis, and D. miranda. Furthermore, we were able to identify the chromosomal elements of D. obscura, D. ambigua, and D. subsilvestris. Of special interest was the localization of the two D. melanogaster-derived representatives of the tandemly repetitive genes, cDm500 and 12D8. In contrast to the findings with the element-specific probes, the localizations of the repetitive genes varied in the various species. Whereas D. melanogaster, D. subobscura, D. pseudoobscura, D. persimilis, and D. miranda showed only one strong block of label in the cross in situ hybridizations with cDm500, three labeling blocks were found on two elements for both D. ambigua and D. obscura. The two labeling blocks on one element occur in very close proximity, but are clearly separated in both species by cytologically detectable chromosomal material. We used the distribution of the cDm500 labeling sites to postulate a series of chromosomal rearrangements involved in the karyotype evolution of the analyzed species. Our results support the conclusion that the chromosomal elements retain their essential identity and that the observed gross structural rearrangements are due to fusions and paracentric or pericentric inversions. Cytologically obvious translocations were not recorded and are considered by us to be rare. The frequently occurring translocations of the tandemly repeated gene clusters observed in this study are probably due to a different mechanism, which may be an intrinsic property of this category of genes.This paper is dedicated to Prof. Hans Bauer on the occasion of his 80th birthday with our best wishes     

Multiple sex chromosome system of X1X1X2X2/X1X2)Y type in lutjanid fish, Lutjanus quinquelineatus (Perciformes)

The karyotype and other chromosomal markers as revealed by C-banding and Ag-staining were studied in Lutjanus quinquelineatus and L. kasmira (Lutjanidae, Perciformes). While in latter species, the karyotype was invariably composed of 48 acrocentric chromosomes in both sexes, in L. quinquelineatus the female karyotype had exclusively 48 acrocentric chromosomes (2n = 48) but that of the male consisted of one large metacentric and 46 acrocentric chromosomes (2n = 47). The chromosomes in the first meiotic division in males showed 22 bivalents and one trivalent, which was formed by an end-to-end association and a chiasmatic association. Multiple sex chromosome system of X₁X₁X₂X₂/X₁X₂Y type resulting from single Robertsonian fusion between the original Y chromosome and an autosome was hypothesized to produce neo-Y sex chromosome. The multiple sex chromosome system of L. quinquelineatus appears to be at the early stage of the differentiation. The positive C-banded heterochromatin was situated exclusively in centromeric regions of all chromosomes in both species. Similarly, nucleolus organizer region sites were identified in the pericentromeric region of one middle-sized pair of chromosomes in both species. The cellular DNA contents were the same (3.3 pg) between the sexes and among this species and related species.     

Meiotic segregation of compound-3 chromosomes in Drosophila

Analysis of crossos between genetically marked stocks of Drosophila melanogaster showed, that the compound-3 chromosomes C(3L)RM and C(3R)RM segregate preterentially in female meiosis, and the following two types of eggs are formed predominantly: C(3L)RM; 0 and 0; C(3R)RM. In male meiosis segregation is almost random and four types of sperm are formed: 1. C(3L)RM; C(3R)RM, 2. 0; 0, 3. C(3L)RM; 0, 4. 0; C(3R)RM. The frequencies of these sperm types vary with the genotypes tested. In the stock C(3L)RM, st; C(3R)RM, p ^p, males produce 76.8% type 1 and 2, and 23.2% type 3 and 4; males of the stock C(3L)RM, ri; C(3R)RM, sr form 63.2% type 1 and 2, and 36.8% type 3 and 4.The segregational behaviour of compound-3 chromosomes found in female meiosis is expected according to the distributive pairing hypothesis. In the male however, where there is no distributive pairing, the stock-specific segregation of compound-3 chromosomes may be due to the presence of small homologous chromosome segments near the centromere which influence chromosome distribution.