Molecular Aspects of Intron Evolution in Dynein Encoding Mega-Genes on The Heterochromatic Y Chromosome of Drosophila sp.

Fertility genes on the heterochromatic Y chromosome of various Drosophilaspecies are unique for several reasons. Most of them are megabase-sized. Their expression is restricted to premeiotic spermatocytes and often associated with unfolding of huge species-specific lampbrush loops. Molecular analysis of the orthologous dynein genes Dhc-Yh3, DhDhc7(Y)and DeDhc7(Y)on the Y chromosome of the three species D. melanogaster, D. hydeiand D. eohydei, respectively, revealed that the megabase gene size as well as the species-specific morphology of the corresponding lampbrush loops kl-5, Threadsand diffuse loopsresult from huge introns and their specific sequence composition, whereas the majority of all 20 introns in each of the three genes is in a size of 45–72 bp. The loop-specifying introns are extreme exceptions due to extended assemblies of degenerated transposable elements and/or large clusters of satellite DNAs. Here we use sequence information from the complete intron sets of three orthologous Y chromosomal dynein genes to deduce a scenario for an evolutionary pathway leading to the megabase-sized genes on the heterochromatic Y chromosome of Drosophila. The obvious bias between very small and species-specific mega introns is explained as the result of an autocatalytic mode of intron growth. An initial coincidental hit by a single transposable element extends the size of a 50 bp intron for about two orders of magnitude and determines it for preferential extension by similar insertion events. This phase of continuous moderate growth is followed by rapid size enlargements by repeating amplifications generating extended clusters of satellite DNA. Size control by recombination, on the other hand, is suppressed in Drosophilamales by achiasmatic meiosis. This revised version was published online in July 2006 with corrections to the Cover Date.     

Y chromosomal fertility genes of Drosophila: a new type of eukaryotic genes

The Y chromosomal fertility genes of Drosophila are required for sperm differentiation. They are active only in primary spermatocytes where they form giant lampbrush loops. The molecular structure of these genes was investigated and revealed an unusual composition of DNA. Short, tandemly repeated sequence clusters are interrupted by longer and more heterogeneous sequences, which probably all represent transposable elements. No indication of the presence of protein-coding regions has been found within the fertility genes. However, the lampbrush loops bind site-specific proteins recognized by immunofluorescence techniques. This, together with other experimental data, led to the hypothesis that the Y chromosomal genes have a function in binding chromosomal proteins. The data and arguments in support of this gene model are summarized in this paper.     

Y Chromosome Loops in Drosophila Melanogaster

Primary spermatocyte nuclei of fixed testes of Drosophila melanogaster exhibit three large clusters of thread-like structures, each consisting of two long, continuous, loop-shaped filaments. No comparable intranuclear structures are observed in spermatogonia, secondary spermatocytes or spermatids. The threads begin to form in young spermatocytes, grow throughout spermatocyte development, reach their maximum size in mature spermatocytes and disintegrate prior to meiotic metaphase I. The presence of each cluster of threads depends upon the presence of a specific region of the Y chromosome; when this region is deleted the cluster is absent, and when it is duplicated the cluster is also duplicated. Together these observations strongly suggest that these structures represent giant Y chromosome lampbrush-like loops analogous to those described in Drosophila hydei. Two antibodies, one polyclonal and one monoclonal, differentially react with the three loops of D. melanogaster. Moreover, two of these loops are specifically stained by Giemsa at pH 10. By indirect immunofluorescence with these antibodies followed by Giemsa staining, each loop can be unambiguously identified and its presence and normality readily assessed. This enabled us to perform fine mapping experiments to determine the relationships between the Y chromosome fertility factors and the loops. The loop-forming sites map within the kl-5, kl-3 and ks-1 fertility factors. Regions h3 and h21 of the Y chromosome correspond to the loop-forming sites of kl-5 and ks-1, respectively. Each of these regions contains about 1300 kb of DNA and spans about one-third of its locus. The loop-forming site of the kl-3 locus is coextensive with region h7-h9 which contains about 4300 kb of DNA and corresponds to the minimum physical size of this locus. These data suggest that each loop is an integral part of a different fertility factor, representing the cytological manifestation of its activity in primary spermatocytes. The kl-2, kl-1 and ks-2 fertility regions do not produce any visible intranuclear structure and do not affect the kl-5, kl-3 and ks-1 loops. Thus, these loci may either not form loops at all or produce loop-like structures that we are unable to see because they are physically minute, destroyed by our fixation procedure, or both.     

The function of the lampbrush loops formed by the Y chromosome of Drosophila hydei in spermatocyte nuclei

Summary The function of pairs of translocated fragments of the Y chromosome of Drosophila hydei was tested. As the pairs of fragments together had a complete set of Y chromosomal sites, complementation of their function could be predicted according to results of earlier experiments. In contrast to the earlier experiments the development of lampbrush loops during the spermatocyte stage was blocked in one partner of each combined pair. As a consequence, no complementary effect on spermiogenesis is detectable. The results indicate that the formation of lampbrush loops by seven sites in the Y chromosome is a necessary prerequisite for the normal progress of spermiogenesis. This can be considered as further support of the view that the lampbrush loops in spermatocyte nuclei of Drosophila are phenotypic manifestations of the activity of male fertility factors.Supported by the Deutsche Forschungsgemeinschaft.     

Molecular structure of the lampbrush loops nooses of the Y chromosome of Drosophila hydei

The molecular structure of the lampbrush loopforming fertility gene nooses from the short arm of the Y chromosome of Drosophila hydei is described on the basis of cloned DNA sequences which are characteristic for the sequence organization in the lampbrush loop. Y chromosomal lampbrush loops are organized into tandem repeat clusters of loop-specific repetitive DNA sequences and in interspersed repetitive DNA sequences with homologies elsewhere in the genome. In this paper, the basic properties of a repeat unit of the tandemly repeated sequence family ay1 are described. Moreover, it is shown that a loop contains several different domains carrying repeat clusters of the same repeated DNA family but with divergent sequence character. One of these clusters is characterized by an internal duplication of the basic repeat unit. We propose that the tandem repeat DNA family ay1 forms a frame of the lampbrush loop which is required for structural and functional reasons.     

Evolution of Y chromosomal lampbrush loop DNA sequences of Drosophila

The evolutionary conservation of Y chromosomal DNA sequences of Drosophila hydei in different species of the genus Drosophila was studied by in situ hybridization and on genomic DNA blots of restriction enzyme digested DNA. We demonstrated that Y specific DNA sequences, which form major parts of lampbrush loops related to the male fertility genes, are only retained in a few closely related species during evolution. Other Y chromosomal DNA sequences, also present in lampbrush loops but with homology to autosomal and X chromosomal locations, were found in distant species. We propose a model for the evolution of the Y chromosomal lampbrush loops.     

Y chromosomal DNA of Drosophila hydei

Six recombinant DNA clones are described, which are derived from the Y chromosome of Drosophila hydei. They reveal characteristic features of Y chromosomal DNA sequences. Three of the cloned inserts are Y-specific and are members of the same family of repeated sequences associated with the lampbrush loop-forming fertility gene "nooses" in the short arm of the Y chromosome. The other three cloned sequences are members of three different families of repeated sequences, but display a small amount of homology to one another and to the family of the nooses sequences. These three cloned sequences are found preferentially in the Y chromosome, but also in other chromosomal positions. The Y chromosomal copies are located in the short arm of the Y chromosome. The other copies are found in autosomal kinetochore-associated heterochromatin or, for one of the cloned sequences, in one band of the giant chromosome 4, in addition to the kinetochore heterochromatin.     

Genetic function correlated with unfolding of lampbrush loops by the Y chromosome in spermatocytes of Drosophila hydei

Summary Deficiencies of the Y chromosome of Drosophila hydei including sites which develop lampbrush loops invariably cause sterility of males. Suppression of loop unfolding in one or more sites equally results in similar morphogenetic defects of spermiogenesis. A variegated type repression of lampbrush loop unfolding observed during the spermatocyte stage results in varying morphogenetic effects on spermiogenesis. This demonstrates the existence of causal relationships between the active phase of Y chromosomal factors in spermatocytes and the differentiation processes in spermatids.In some translocated Y fragments the mode of unfolding of a particular pair of lampbrush loops may be permanently changed. As a result, lampbrush loops of a mutant phenotype are developed. Some alterations of this type are correlated with functional alterations resulting in defective spermiogenesis.Three different fragments of the Y chromosome in which lampbrush loop formation was repressed have been tested for possible reversions of loop suppression by means of X irradiations. In none of the three cases reversion has been detected among two thousand tested chromosomes.To the memory of Karl-Heinz Bier.     

Temperatursensitive Mutanten im Y-chromosom von Drosophila hydei

Mutations were induced in the Y chromosomal fertility genes of Drosophila hydei by EMS treatment of adult males. Four types of mutants were observed: 1. Sterile mutants without detectable cytological changes in Y chromosomal lampbrush loops. 2. Sterile males with morphologically changed loops. 3. Sterile males where one or several Y chromosomal loops are missing in the spermatocytes. 4. Mutants which are temperature-sensitive for sterility, development of loops or altered loop morphology. In this paper four Y mutants are described which are temperature-sensitive as regards fertility but which show unchanged lampbrush loops. They can be mapped in four different complementation groups. Two of those occur probably in regions of the Y chromosome without cytologically detectable lampbrush loops. All mutations are found in the distal half of the long arm. The temperature-sensitive period occurs during the primary spermatocyte stage and in early spermatid development while the manifestation of the effect occurs postmeiotically. The mutants are further characterized with respect to changes in the ultrastructure of the sperm at the restrictive temperature.     

Molecular cloning of microdissected lampbrush loop DNA sequences of Drosophila hydei

We microdissected a Y chromosomal lampbrush loop pair from primary spermatocyte nuclei of Drosophila hydei and cloned the DNA directly at the microscale. Four of the 12 recombinant DNA clones recovered display in situ hybridization to mitotic metaphase Y chromosomes, preferentially in the chromosomal region identified as the origin of the lampbrush loop pair. All clones, however, also hybridize to autosomal and X chromosomal loci in polytene chromosomes. Y chromosomal DNA sequences of D. hydei again prove to be members of different families of repeated sequences distributed throughout the genome. These microcloning experiments, which were carried out under very unfavourable experimental conditions (low DNA content of the lampbrush loops in the presence of large amounts of RNA) prove that almost any chromosomal structure detected by light microscopy is directly accessible to molecular cloning experiments by micromethods.