An analysis of white-mottled mutants inDrosophila hydei,with observations on X-Y exchanges in the male

Chromosomes and phenotypes of four different sex-linkedwhite-mottled mutants of the position-effect variogation type were studied. Three mutants (w ^m1,w ^m2,w ^m3) are X-chromosomal rearrangements which shift the w⁺ locus into a position close to heterochromatin, but which have different ouchromatic and heterochromatic breaks. The fourth, a spontaneous derivative ofw ^m1, is an insertional duplication of part of the X chromosome, including thew ⁺ andN ⁺loci. The duplicated segment is inserted into the distal part of the long arm of the heterochromatic Y chromosome. It is designated,w ^m CoY, orXw ^m Co when transferred to the X chromosome.Three chromosomal types (w ^m1,w ^m CoY) and (Xw ^m Co) having the same cuchromatic break near thew ⁺ locus, cause large-spotted eyes whereas two others (w ^m2,w ^m3) produce a popper-and-salt type of mottling. From the position of the various eu- and heterochromatic breaks, it appears that the distance of thew ⁺ locus to the point of reunion with heterochromatin, rather than the amount or type of adjoining heterochromatin, dietates the phenotypic action of the displacedw ⁺ locus, in the sense of a spreading effect on two proposed functional subunits within thew ⁺ locus.The pigmentation background against which the mottling effect is produced, i.e., a givenw-allele with its characteristic colour, or other eye colour mutations, does not seem to affect the type of mottling. Drosopterins and ommochromes react in the same way to modifing factors like temperature and supernumerary Y chromosomes. Two mutants (w ^m2 andw ^m CoY) while reacting in the same manner to Y chromosomes showed an opposite temperature response.By exchange between the heterochromatin of the Y and X chromosome inw/w ^m CoY males thew ^m Co duplication was transferred between the sex chromosomes with a certain regularity. It is not yet known wether the exchanges are mitotic or meiotic in origin but their heterochromatic nature has been demonstrated cytologically.     

Genetic factors affecting normal growth of testes inDrosophila hydei

Summary A marked growth in the length of testes ofDrosophila hydei males occurred during pupal development. This growth continued over the first 8 days of adult life and in the young adults sperm were not produced until the testes increased approximately threefold in length to about 28 mm. The length of testes is correlated with genetic factors on the X and Y chromosomes. In males lacking a Y chromosome (X/O) or the short arm (Y^S) of the Y chromosome (X/Y^L) the testes were about half the length of testes of control males (X/Y) or double Y males (X/Y/Y). Males with deletions of the distal Y^L chromosome arm had testicular lengths equivalent to the controls. Males with short testes (X/O and X/Y^L) showed disruptions to spermatogenesis at meiosis and an absence of normal spermatid elongation. Reduction of active ribosomal RNA genes on the X chromosome in X/O caused an increased expression ofbobbed (bb) and a corresponding reduction in length of testes. Severelybobbed X/O males had very few cysts of spermatogonia and these cysts did not develop into primary spermatocytes.     

Autonomy of the wingless mutation in Drosophila melanogaster

Summary T(Y;2) translocations were used to cytologically localise the wingless locus of Drosophila melanogaster. We found that an existing T(Y;2), which is an insertion of a segment of 2L into the Y chromosome, has wg ⁺ within this insert. This Y chromosome was used to generate an attached XY chromosome containing wg ⁺. The mutation claret-nondisjunctional (ca ^nd) was used to induce the loss of this XY chromosome and thus generate gynandromorphs with wg ¹/wg ¹ male tissue and wg ⁺/wg ¹/wg ¹ female tissue. Analysis of these gynanders demonstrated that a genotypically wingless mutant hemithorax is usually also phenotypically mutant in these half body mosaics; thus wg ¹ is discautonomous. This observation is of interest as it is known that wg is not cell autonomous.     

Third chromosome suppressor of position-effect variegation loci in Drosophila melanogaster

Summary As a result of a genetic analysis of 63 third chromosome suppressor mutations of position-effect variegation 12 different loci showing dominant suppression have been identified and their map positions determined. A compilcation of the genetic data available for each suppressor locus is given. The strong suppressor effects of the mutations have been quantified by measurements of white variegation inw ^m4h /w ^m4h ,w ^m4h /Y andw ^m4h /O flies. Mutant alleles of three loci were found in these studies to dominate over the strong enhancer effect of complete loss of the Y chromosome. Most of the identified loci suppressing position-effect variegation represent essential genetic funtions; only three loci represent nonessential functions. Mutations of two loci display recessive butyrate sensitivity and lethal interaction with the heterochromatic Y chromosome suggesting that these genes affect chromosomal condensation. Studies with deficiencies and triploids revealed that most of the loci represent haplo-abnormal suppressor functions. The use of the isolated mutant material for genetic, developmental and molecular studies of processes connected with gene inactivation in position-effect variegation is discussed.Dedicated to Prof. H.J. Becker on the occasion of his 6th birthday     

X-Y exchanges in males of Drosophila hydei carrying the w m Co duplication

Males carrying, inserted on their Y chromosome, a small fragment of X including the w ⁺ (and N ⁺) locus (white-mottled Confluens, w ^m Co), were crossed with the purpose of scoring exceptional progeny. Some of the male and female exceptions were progeny tested and further analysed. Among the various mechanisms which may lead to exceptional offspring, X-Y exchanges proved to occur with a not negligible frequency. The rate was 3%. Nondisjunction accounts for the bulk of the remaining exceptions and appears to be increased considerably in the presence of rearrangements on one or the other of the sex chromosomes.The w ^m Co fragment after having been switched from Y to X by some mechanism other than regular crossing over, may become retransferred to a normal Y chromosome, but at a rate below 3%.     

Cytological identification of two X-chromosome types in the wood lemming (Myopus schisticolor)

In the wood lemming (Myopus schisticolor) three genetic types of sex chromosome constitution in females are postulated: XX, X^*X and X^*Y (X^*=X with a mutation inactivating the male determining effect of the Y chromosome). Males are all XY. It is shown in the present paper that the two types of X chromosomes, X and X^*, exhibit differences in the G-band patterns of their short arms. In addition, it was demonstrated in unbanded chromosomes that the short arm in X^* is shorter than in X. The origin of these differences is still obscure; but they allow to identify and to distinguish the individual types of sex chromosome constitution, as of XX versus X^*X females and of X^*Y females versus XY males, on the basis of G-banded chromosome preparations from somatic cells.     

Doc and copia instability in an isogenic Drosophila melanogaster stock

A high degree of heterogeneity and an overall increase in number of insertion sites of the mobile elements Doc and copia were revealed in one substock of an isogenic Drosophila melanogaster stock, while in two other substocks the distribution of copia sites was highly homogenous, but that of Doc sites was again heterogenous. We therefore concluded that copia was unstable in one of the substocks and Doc was unstable in all. Doc instability presumably arose earlier than copia instability. Doc and copia transpositions were directly observed in experiments with one substock. An abundance of copia insertions was revealed in the X chromosome where insertions with deleterious effects are exposed to selection in hemizygous condition. The locations of many other mobile elements (mdg1, mdg2, mdg3, mdg4, 297, B104, H.M.S. Beagle, I, P, BS, FB) were found to be conserved in each substock and did not differ between them, indicating that these mobile elements were stable. This homogeneity is a strong argument against any possibility of inadvertent contamination.     

Genetic instability in Drosophila melanogaster

Summary An unstable long tandem duplication which includes the white locus twice, marked with w ^sp in the left and w ^17G in the right locus, when kept in males has been found to produce red-eyed sons which have lost the long duplication and with it the w ^sp and w ^17G mutants. Such exceptions were produced also when w ^17G had been exchanged for w ^a.Stocks originating from these exceptions are unstable, producing: 1) zeste males, also unstable, 2) w ^- deletions, stable, 3) transpositions of the white locus to sites in other chromosomes.The instability is interpreted as the effect of an IS element, within or adjacent to the white locus, which is supposed to retain a duplication of the proximal zeste interacting part of this locus. According to the orientation of the IS element the duplicated part can be active or inactive, giving a zeste or red eye phenotype.The frequency of exceptional offspring after X-ray treatment of the red and zeste unstable stocks have been compared to stable stocks with corresponding genotypes.     

An X‐linked Myh11‐CreERT2 mouse line resulting from Y to X chromosome‐translocation of the Cre allele

The Myh11‐CreER^T2 mouse line (Cre⁺) has gained increasing application because of its high lineage specificity relative to other Cre drivers targeting smooth muscle cells (SMCs). This Cre allele, however, was initially inserted into the Y chromosome (X/Y^Cre+), which excluded its application in female mice. Our group established a Cre⁺ colony from male ancestors. Surprisingly, genotype screening identified female carriers that stably transmitted the Cre allele to the following generations. Crossbreeding experiments revealed a pattern of X‐linked inheritance for the transgene (k > 1000), indicating that these female carries acquired the Cre allele through a mechanism of Y to X chromosome translocation. Further characterization demonstrated that in hemizygous X/X^Cre+ mice Cre activity was restricted to a subset arterial SMCs, with Cre expression in arteries decreased by 50% compared to X/Y^Cre+ mice. This mosaicism, however, diminished in homozygous X^Cre+/X^Cre+ mice. In a model of aortic aneurysm induced by a SMC‐specific Tgfbr1 deletion, the homozygous X^Cre+/X^Cre+ Cre driver unmasked the aortic phenotype that is otherwise subclinical when driven by the hemizygous X/X^Cre+ Cre line. In conclusion, the Cre allele carried by this female mouse line is located on the X chromosome and subjected to X‐inactivation. The homozygous X^Cre+/X^Cre+ mice produce uniform Cre activity in arterial SMCs.     

Bestimmung des Heterochromatisierungsstadiums beim white-Positionseffekt mittels r?ntgeninduzierter mitotischer Rekombination in der Augenanlage von Drosophila melanogaster

Summary Position-effect variegation of eye pigmentation in the examined Dp(1;3)N ^264-58 females is due to an insertion of a X-chromosome section including the white-locus into the proximal heterochromatic region of the third chromosome. The light and dark pigmented areas have a cell lineage basis (Fig. 2). Flies bearing the w ⁺-duplication had two X-chromosomes marked with w ^a lz ⁵⁰ e and w ^a rb rux ² respectively (Fig. 3). X-ray induced mitotic recombination in presumptive eye cells of larvae resulted in w ^a lz ^50e /w ^a rb rux ² twin mosaic spots in the adult eyes. After young larvae were treated twin spots appeared, which had one partner light colored and one dark. Such combinations were rarely found after older larvae were treated. Treatment of young larvae in addition produced twin spots with one or both partners variegated (Figs. 5 and 6). Sometime after the stage at which younger larvae were treated and before the stage at which older larvae were treated the translocated w ⁺-gene in each cell was determined for function or no function. As a result the progeny of each of these cells synthesized pigment or not during the pupal stage. At a temperature of 25.5° C the developmental phase during which determination, i.e. heterochromatization of the white gene, takes place, begins not earlier than 39 hours after egg laying and ends about 8 hours later (Fig. 7). In females heterozygous for the short arm of the heterochromatic Y-chromosome linked distally to the X-chromosome (Y ^S X/X) one twin spot partners is homozygous for this arm (Y ^SX/Y^S X), the other lacks it (X/X; Fig.4a). The Y ^SX/Y^S X-partner were more frequently dark pigmented than the X/X-partners (Tables 3 and 4). This shows that heterochromatization of the translocated w ⁺-genes is markedly influenced by the genotype of the single cell. When two genotypes with varied amounts of heterochromatin were compared (Fig. 4) no difference in the phases of heterochromatization could be observed (Table 5). Therefore, when position-effect variegation is modified by varying the amount of heterochromatin in the genome the modification is probably not due to a shift in the phase of heterochromatization.

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Vorgelegt von E. Hadorn     

A marked ring-Y-chromosome in Drosophila hydei with a new type of white variegation

A ring-Y chromosome, R(Y)w ^m, of D. hydei is described which carries a complete set of fertility genes, a NOR region and a small X-chromosomal insertion (w ^m), which may be used as a marker. The ring has been characterized by various staining techniques. It was derived from a w ^mCo Y chromosome by X-ray treatment of spermatocytes. Its mode of origin allows to fix the gene order in the distal region of the long arm of the w ^mCoY chromosome. The white ⁺ gene included in the ring shows a new type of position-effect variegation which is described and discussed in the context of an earlier hypothesis on a dual function of the white locus.     

Distamycin A-DAPI banding of nonfluorescent Y (Ynf) chromosomes in 45,X/46,XYnf mosaicism

Summary The distamycin A-DAPI banding patterns of nonfluorescent, nonheterochromatic Y chromosomes (Y^nf) in two patients with 45,X/46,XY^nf mosaicism were investigated. In both cases moderately fluorescent bands were observed near the centromere and on the distal long arm of the Y^nf. These bands were similar to the centrometric band on normal Y chromosomes and support the hypothesis that the Y^nf is an isodicentric chromosome derived from the proximal portion of the Y chromosome.     

Heterochromatin of the Drosophila melanogaster Y chromosome as modifier of position effect variegation: the time of its action.

Summary Addition of heterochromatin suppresses while subtraction enhances position effect variegation. The heterochromatin-sensitive period has been determined in white/white-apricot variegated eyes of Y ^S w ^a /w ^a ; Dp (1;3) w ^265-58 flies. When such larvae, carrying a Y-short (Y ^S ) arm at the distal end of one X chromosome, are X-rayed, mitotic recombination leads to one daughter cell with two Y ^S arms and an adjacent daughter cell with no Y ^S arm. When induced after clonal initiation, the frequency of dark clones developing from daughter cells with two Y ^S arms is significantly higher than the frequency of dark clones in the rest of the eye; and this frequency is. even higher when induced before clonal initiation. The modifying action of the Y-heterochromatin is exerted, therefore, during and after clonal initiation. Surprisingly, the frequency of dark clones developing from cells with no Y ^S arm is not lower than the frequency of dark clones in the rest of the eye.     

Univalent sex chromosomes in spermatocytes of Sxr-carrying mice

Pachytene configurations of the sex chromosomes were studied in whole-mount, silver-stained preparations of spermatocytes in mice with XY,Sxr, XX,Sxr, XO,Sxr, XO,Sxr+5¹² and T(X;4)37H,YSxr chromosomes, and non-Sxr-carrying controls. XY,Sxr males showed an increased number of X and Y univalents and of self-synapsed Y chromosomes. In T(X;4)37H,YSxr males an increased proportion of trivalent+Y configurations was also accompanied by higher numbers of self-paired Y univalents; the proportion of trivalent+X⁴ was not increased, but that of self-synapsed X⁴ univalents was. There was more selfsynapsis in cells containing one univalent than in cells containing two univalents. Spermatocytes of XX,Sxr mice contained single univalent X, which was never seen to be self-synapsed, but self-synapsis of the X occurred in a proportion of cells in XO,Sxr males. There were no self-paired X chromosomes in the XO,Sxr+5¹² mouse although lowlevel pairing of the 5¹² chromosome occurred. All four XX,Sxr and XO,Sxr males contained testicular sperm, and testicular sperm were also present in one T(X;4)37H male, while another such male had sperm in the caput. It is concluded that (1) self-synapsis of univalents is affected by variable conditions in the cell as well as by the DNA sequences of the chromosome, and (2) that the level of achievable spermatogenesis is not always rigidly predetermined by a chromosome anomaly but can be modulated by the genetic background.     

Indirect evidence of alteration in the expression of the rDNA genes in interspecific hybrids betweenDrosophila melanogaster andDrosophila simulans

Crosses betweenDrosophila melanogaster females andD. simulans males produce viable hybrid females, while males are lethal. These males are rescued if they carry theD. simulans Lhr gene. This paper reports that females of the wild-typeD. melanogaster population Staket do not produce viable hybrid males when crossed withD. simulans Lhr males, a phenomenon which we designate as the Staket phenotype. The agent responsible for this phenomenon was found to be the StaketX chromosome (X ^mel ,Stk). Analysis of the Staket phenotype showed that it is suppressed by extra copies ofD. melanogaster rDNA genes and that theX ^mel ,Stk chromosome manifests a weak bobbed phenotype inD. melanogaster X ^mel ,Stk/0 males. The numbers of functional rDNA genes inX ^mel ,Stk andX ^mel ,y w (control) chromosomes were found not to differ significantly. Thus a reduction in rDNA gene number cannot account for the weak bobbedX ^mel ,Stk phenotype let alone the Staket phenotype. The rRNA precursor molecules transcribed from theX ^mel ,Stk rDNA genes seem to be correctly processed in both intraspecific (melanogaster) and interspecific (melanogaster-simulans) conditions. It is therefore suggested that theX ^mel ,Stk rDNA genes are inefficiently transcribed in themelanogaster-simulans hybrids.     

Genetic instability in Drosophila melanogaster. Evidence for insertion mutations

Summary An X chromosome in Drosophila melanogaster is described which is mutationally unstable. Mutational events were identified through phenotypic changes associated with a tandem duplication of the X chromosome in which the white locus is present in duplicate. The left segment of the tandem duplication was marked with the mutant w ^sp, the right segment with mutant w ^17G. Some of the phenotypic changes were identified as deletions involving the w ^17G marked segment of the duplication. Other phenotypic changes involved the left segment in which phenotypically w ^sp mutated to w. Experimental evidence is presented which attributes these latter mutations to insertions of foreign DNA into the w locus equivalent to the insertion mutations of E. coli.     

Cytogenetical localization of Zygotic hybrid rescue (Zhr), a Drosophila melanogaster gene that rescues interspecific hybrids from embryonic lethality

Hybrid females from crosses between Drsophila melanogaster males and females of its sibling species, D. simulans, D. mauritiana, or D. sechellia die as embryos. This lethality is believed to be caused by incompatibility between the X chromosome of D. melanogaster and the maternal cytoplasm. Zygotic hybrid rescue (Zhr) prevents this embryonic lethality and has been cytogenetically mapped to a proximal region of the X chromosome of D. melanogaster, probably in the centromeric heterochromatin. We have carried out high resolution cytological mapping of Zhr using deficiencies and duplications of the X heterochromatin. Deletions of the Zhr ⁺ gene from the hybrid genome exhibit the Zhr phenotype. On the contrary, addition of the wild-type gene to the hybrid genome causes embryonic lethality, regardless of sex. The Zhr locus has been narrowed down to the region covered by Dp(1;f)1162 but not covered Dp(1;f)1205, a chromosome carrying a duplication of heterochromatin located slightly distal to the In(1)sc ⁸ heterochromatic breakpoint.     

Properties of the sex chromosomes of Lucilia cuprina deduced from radiation studies

From a study of radiation-induced X-chromosome deletions the locus of black body (b) has been localized to the proximal portion of C-band defined euchromatin. Radiation produced mostly X-chromosome deletions rather than point mutations, total X or Y chromosome loss through breakage, or increased frequency of non-disjunction. Aberrant sex ratios obtained indicate that the X chromosome carries vital loci that were deleted with b ⁺ in many cases. The X/O karyotype produces fertile adult females with a characteristic phenotype which is also produced by X deletions. Sex chromosome non-disjunction to give X/O females and X/X/Y males is normally rare but is enhanced by the presence of chromosome rearrangements even when the X and Y are not involved.     

Specific recognition and differential affinity of meiotic X-Y pairing sites in Lucilia cuprina males (Diptera: Calliphoridae)

Meiotic pairing of X and Y chromosomes in male Lucilia cuprina was studied by cytological observation of normal, rearranged and deficient sex chromosome karyotypes in spermatogenesis. Two X-Y pairing regions located distally in each arm of the X and Y chromosomes were defined. Contrasting with findings in Drosophila melanogaster, these pairing regions show specific recognition of their partners. By studying rearranged sex chromosomes short arm pairing was localised to their distal ends, closely associated with secondary constrictions containing nucleolar organisers in both sex chromosomes. Short arm pairing is very tight and not greatly disrupted by chromosome rearrangement, deficiency for the Y chromosome long arm or the presence of supernumerary X chromosomes. The pairing region of the long arms could not be precisely localised but probably also occurs at their distal ends. Pairing between the long arm sites is much weaker and is easily disrupted by chromosome rearrangement, failing completely in flies deficient for the Y chromosome short arm. No cytologically visible pairing was seen between X chromosomes and the remainder of the Y. In males with an extra X chromosome, the ends of both X chromosomes pair to form multivalents with normal and rearranged Y chromosomes provided the Y short arm is present, otherwise an independent X chromosome bivalent is formed. The mechanism of pairing in male Lucilia sex chromosomes thus seems to depend on specific loci of distinctive structure within the X and Y heterochromatin. Comparison of cytological and genetic data shows that increasing cytological pairing failure is matched by higher genetic X-Y nondisjunction but that the former occurs at much higher levels. In some karyotypes cytologically observed X-Y pairing failure is not matched by high frequencies of nondisjunction presumably because weak pairing associations are disrupted during slide preparation.