Coding region deletions associated with the major form of rDNA interruption in Drosophila

The nucleotide sequences at and around the termini of 5 kb type 1 interruptions in three separate clones of D. melanogaster rDNA repeats have been determined, and have been compared with the sequence of the corresponding region of an insertion-free rDNA repeat. All three interrupted rDNA repeats contain a small deletion of 28S rRNA coding material at the left coding/insertion sequence junction. A second deletion was found in one of the three clones, ad other aberrations were suggested by the results of restriction enzyme digestions of unfractionated rDNA. The termini of 5 kb type 1 rDNA insertions in D. melanogaster were also compared with the corresponding regions of 28S rDNA interruptions in D. virilis: the insertion site is identical in the two species, but the termini of the two species' interruptions show no homology. I sequenced a 1.1 kb region of the 5 kb type 1 D. melanogaster rDNA interruption that covers the sequences of the 1 kb and 0.5 kb insertions. There is 98% homology between the rightmost 1 kb of the 5 kb interruption and the sequences of the shorter insertions. Data suggest that Drosophila rDNA interruptions arose as a transposable element, and that divergence had included length alterations generated by unequal crossing over.     

Ribosomal DNA in Drosophila melanogaster. II. Heteroduplex mapping of cloned and uncloned rDNA.

Sequences in the cloned Drosophila melanogaster rDNA fragments described by Dawid et al. (1978) were compared by heteroduplex mapping. The nontranscribed spacer regions in all fragments are homologous but vary in length. Deletion loops were observed at variable positions in the spacer region suggesting that spacers are internally repetitious.Many rDNA repeats in D. melanogaster have a 28 S gene interrupted by a region named the ribosomal insertion. Insertions of 0.5, 1 and 5 kb were found in repeat-length EcoRI fragments. These DNA regions, named type 1 insertions, are homologous at their right ends. Although 1 kb insertions are quite precisely twice as large as 0.5 kb insertions they do not represent a duplication of the shorter sequence. Some insertions have at least one EcoRI site and therefore yield EcoRI fragments which are only part of a repeat. The sequences in two cloned right-hand partial insertion sequences are homologous, but the sequences in two lefthand partial insertions are not. None of the EcoRI-restrictable insertion sequences has any homology to any part of type 1 insertions; they are thus grouped together as type 2. Evidence for insertion sequences of at least two types in uncloned rDNA was obtained by annealing a cloned fragment with a 1 kb insertion to genomic rDNA. About 15% of the rDNA repeats show substitution type loops between the 1 kb type 1 insertion derived from the cloned fragment and type 2 insertions in the rDNA.     

Ribosomal DNA in Drosophila melanogaster. I. Isolation and characterization of cloned fragments.

Fragments of rDNA3 from Drosophila melanogaster produced by the restriction endonuclease EcoRI were cloned in the form of recombinant plasmids in Escheriehia coli. Maps were prepared showing the location of the coding regions and of several restriction endonuclease sites. Most rDNA repeats have a single EcoRI site in the 18 S gene region. Thus, 19 of 24 recombinant clones contained a full repeat of rDNA. Ten repeats with continuous 28 S genes and repeats containing insertions in the 28 S gene of 0.5, 1 and 5 kb were isolated. The 0.5 and 1 kb insertion sequences are homologous to segments of the 5 kb insertions; because of this homology they are grouped together and identified as type 1 insertions. Four recombinant clones contain an rDNA fragment that corresponds to only a portion of a repeating unit. In these fragments the 28 S gene is interrupted by a sequence which had been cleaved by EcoRI. The interrupting sequences in these clones are not homologous to any portion of type 1 insertions and are therefore classified as type 2. In one of the above clones the 28 S gene is interrupted at an unusual position; such a structure is rare or absent in genomic rDNA from the fly. Another unusual rDNA fragment was isolated as a recombinant molecule. In this fragment the entire 18 S gene and portions of the spacer regions surrounding it are missing from one repeat. A molecule with the same structure has been found in uncloned genomic rDNA by electron microscopic examination of RNA/DNA hybrids.     

A DNA segment from D. melanogaster which contains five tandemly repeating units homologous to the major rDNA insertion

We describe a cloned segment of D. melanogaster DNA (cDm219) that contains five tandemly arranged sequence units homologous to the type I insertion sequence found in the majority of 28S rRNA genes on the X chromosome. Heteroduplex studies show that two of the units have a deletion corresponding to a 1.1 kb piece of DNA close to the right-hand end of the type I insertion. Another unit has a 7.5 kb sequence (zeta) substituted for a 0.95 kb piece of DNA close to the left-hand part of the type I rDNA insertion. The two remaining units are interrupted by the Col E1 plasmid vector. There are also differences in the restriction endonuclease cleavage maps both between the units of cDm219 themselves and compared to the restriction endonuclease cleavage maps of cloned rDNA segments that contain type I insertions. Quantitation of the gel transfer hybridization of zeta element probes to restriction endonuclease digests of D. melanogaster DNA indicates there are 30--40 copies of zeta sequences distributed in seven major arrangements within the haploid genome. The hybridization of zeta and insertion sequence probes to a library of D. melanogaster DNA segments cloned in bacteriophage lambda indicates at least 4--6 copies of the zeta element could be linked to insertion sequences. The common site of in situ hybridization of zeta sequences is to the chromocentral heterochromatin of polytene chromosomes.     

Differential elimination of rDNA genes in bobbed mutants of Drosophila melanogaster.

In Drosophila melanogaster, the multiply repeated genes encoding 18S and 28S rRNA are located on the X and Y chromosomes. A large percentage of these repeats are interrupted in the 28S region by insertions of two types. We compared the restriction patterns from a subcloned wild-type Oregon R strain to those of spontaneous and ethyl methanesulfonate-induced bobbed mutants. Bobbed mutations were found to be deficiencies that modified the organization of the rDNA locus. Genes without insertions were deleted about twice as often as genes with type I insertions. Type II insertion genes were not decreased in number, except in the mutant having the most bobbed phenotype. Reversion to wild type was associated with an increase in gene copy number, affecting exclusively genes without insertions. One hypothesis which explains these results is the partial clustering of genes by type. The initial deletion could then be due either to an unequal crossover or to loss of material without exchange. Some of our findings indicated that deletion may be associated with an amplification phenomenon, the magnitude of which would be dependent on the amount of clustering of specific gene types at the locus.     

Male sterility and meiotic drive associated with sex chromosome rearrangements in Drosophila. Role of X-Y pairing.

In Drosophila melanogaster, deletions of the pericentromeric X heterochromatin cause X-Y nondisjunction, reduced male fertility and distorted sperm recovery ratios (meiotic drive) in combination with a normal Y chromosome and interact with Y-autosome translocations (T(Y;A)) to cause complete male sterility. The pericentromeric heterochromatin has been shown to contain the male-specific X-Y meiotic pairing sites, which consist mostly of a 240-bp repeated sequence in the intergenic spacers (IGS) of the rDNA repeats. The experiments in this paper address the relationship between X-Y pairing failure and the meiotic drive and sterility effects of Xh deletions. X-linked insertions either of complete rDNA repeats or of rDNA fragments that contain the IGS were found to suppress X-Y nondisjunction and meiotic drive in Xh-/Y males, and to restore fertility to Xh-/T(Y;A) males for eight of nine tested Y-autosome translocations. rDNA fragments devoid of IGS repeats proved incapable of suppressing either meiotic drive or chromosomal sterility. These results indicate that the various spermatogenic disruptions associated with X heterochromatic deletions are all consequences of X-Y pairing failure. We interpret these findings in terms of a novel model in which misalignment of chromosomes triggers a checkpoint that acts by disabling the spermatids that derive from affected spermatocytes.     

Characterization of cloned ribosomal DNA from Drosophila hydei.

The structure of ribosomal genes from the fly Drosophila hydei has been analyzed. EcoRI fragments, cloned in a plasmid vector, were mapped by restriction enzyme analysis. The lengths of the regions coding for 18S and 28S rRNA were defined by R-loop formation. From these data a physical map of the rRNA genes was constructed. There are two major types of rDNA units in D. hydei, one having a size of 11 kb and the other a size of 17 kb. The 17 kb unit results from an intervening sequence (ivs) of 6.0 kb, interrupting the beta-28S rRNA coding region. Some homology between th D. hydei ivs and D. melanogaster type 1 ivs has been described previously (1). However, the restriction sites within these ivs show considerable divergence. Whereas D. hydei rDNA D. melanogaster rDNA, the nontranscribed spacer has little, if any, sequence homology. Despite difference in sequence, D. hydei and D. melanogaster spacers show structural similarities in that both contain repeated sequence elements of similar size and location.     

Ribosomal DNA of the fly Sciara coprophila has a very small and homogeneous repeat unit

Summary In this report we show by hybridization of restriction fragments and by Miller spreads that the unit repeat of the fly Sciara coprophila is only 8.4 kb which is the smallest known for a multicellular eukaryote. The 8.4 kb EcoR1 fragment containing a complete unit of Sciara rDNA was cloned in pBR322, and mapped by the method of Parker (1977) and also by double digestion. The coding regions for 28S, 18S, and 5.8S RNA were localized by the method of Berk and Sharp (1977). From these data we conclude that the nontranscribed spacer, external transcribed spacer, and internal transcribed spacer are all shorter than in other organisms, thereby giving rise to the shorter overall rDNA repeat unit of Sciara.At least 90% of the Sciara rDNA repeats are homogeneous, with a length of 8.4 kb, but a 700 bp ladder of minor bands can also be found in digestions of total genome DNA. This profile of major and minor bands is identical between the X and X chromosomes, as seen by a comparison of several genotypes.There are only 45 rRNA genes per X chromosome of Sciara (Gerbi and Crouse, 1976). These can easily be counted by low magnification Miller speads which show that virtually all gene copies are actively being transcribed in the stage of spermatogenesis examined. This is the first demonstration for any reiterated gene family where all copies are shown to be simultaneously active.Present address same as last author     

Distribution of spacer length classes and the intervening sequence among different nucleolus organizers in Drosophila hydei

Drosophila hydei rRNA genes from different chromosomes and from different stocks have been studied by restriction enzyme analysis. In DNA from wild-type females, about half of the X chromosomal rRNA genes are interrupted by an intervening sequence within the 28S coding region. In contrast to D. melanogaster, the intervening sequences belong to a single size class of 6.0 kb. Although there are two nucleolus organizers on the Y chromosome, genes containing the intervening sequence seem to be restricted to the X chromosome. — As shown in four cloned rDNA fragments, the nontranscribed spacers differ in length by having varying numbers of a 242 base pair sequence located in tandem in the right section of the spacer. In genomic rDNA, the spacers also differ in length by a regular 0.25 kb interval. Spacers with between 5 and 15 subrepeats occur frequently within the X and Y chromosomal nucleolus organizers in different D. hydei stocks; shorter and longer spacers are also present but are relatively rare. — Although each genotype is characterized by different frequencies of some spacer classes, the prominent spacer length heterogeneity pattern is similar among the different nucleolus organizers and, therefore, seems to be conserved during evolution.This paper is dedicated to Professor Dr. W. Beermann on the occasion of his 60th birthday     

Differential replication of ribosomal gene repeats in polytene nuclei of Drosophila.

The genes coding for the 18S and 28S rRNAs in D. melanogaster were examined using Southern transfers of DNA from diploid or polytene tissue. A ribosomal gene repeat 12 kb in length is present in DNA from diploid tissue of males and is the major repeat on the Y chromosome. This repeat is present in low amounts on the X chromosome, which contains major repeats of 17 and 11.5 kb. In polytene nuclei of males, the 12 kb band is disproportionately replicated, and only a very low amount of the 11.5 kb repeat and no 17 kb repeat are detected. Polytene nuclei of females contain reduced amounts of the 17 kb repeat relative to the 11.5 kb repeat. This disproportionate replication of specific ribosomal gene repeats suggests that polytenization of the rDNA may involve an extrachromosomal mechanism. Evidence that genes from only one nucleolus organizer are replicated during polytenization in X/Y and X/X flies is discussed. A method for analyzing DNA from tissue of individual larvae was developed to test for population heterogeneity in ribosomal gene structure. Heterogeneity was observed in the ribosomal genes of three Ore R lines, four other D. melanogaster strains and between males and females of the same strain.     

Introns and their flanking sequences of Bombyx mori rDNA.

We obtained two different clones (16 kb and 13 kb) of B. mori rDNA with intron sequence within the 28S-rRNA coding region. The sequence surrounding the intron was found to be highly conserved as indicated in several eukaryotes (Tetrahymena, Drosophila and Xenopus). The 28S rRNA-coding sequence of 16 kb and 13 kb clone was interrupted at precisely the same sites as those where the D. melanogaster rDNA interrupted by the type I and type II intron, respectively. The intron sequences of B. mori were different from those of D. melanogaster. In 16 kb clone, the intron was flanked by 14 bp duplication of the junction sequence, which was also present once within the 28S rRNA-coding region of rDNA without intron. This 14 bp sequence was identical with those surrounding the introns of Dipteran rDNAs.     

X chromosome nucleolus organizer mutants which alter major type I repeat multiplicity in Drosophila melanogaster

The nucleolus organizer (NO) of the D. melanogaster X chromosome is composed of ribosomal repeat units which contain two types (I and II) of non-rDNA insertions (In+) and repeats with no insertions (In-). Evidence from other laboratories indicate random interspersion of all types of repeat units within the X NO. An EcoRI and BamHI examination of rDNA from two bobbed mutants, bb2rI and mal12 demonstrates segregation of the major type I repeat units. The 46 rDNA repeats of the bb2rI NO contain no detectable major type I repeats whereas the majority of the 68 rDNA mal12 repeats are major type I and tandemly linked. This observation suggests that gross deletions of rDNA can result in nucleolus organizer regions with predominantly one type of repeat unit. Additivity tests demonstrate that the 46 ribosomal repeats of the bb2rI chromosome revert the phenotype of other bobbed NOs, but the 68 mal12 ribosomal repeats show no or slight additivity. This is in agreement with the observation that In+ repeats do not significantly contribute to functional rRNA. A Southern blot analysis using BamHI which cuts only in type I insertions demonstrates that the majority of major type I In+ repeating units exist in tandem linkage group(s) within the X NO.     

Cloning of segments of the Drosophila melanogaster genome using artificial chromosomes of the yeast Saccharomyces cerevisiae]

A partial genomic library from the Batumi L stock of Drosophila melanogaster was constructed using yeast artificial chromosomes as vectors. The DNA was restricted by Not1 and large fragments were inserted into the YAC5 vector. The size of cloned DNA varied from 90 to 500 kb. 48 random clones were characterized by in situ hybridization to the Batumi L polytene salivary gland chromosome. Single euchromatic sites of hybridization were detected for 27 clones; 11 clones revealed the main euchromatic hybridization site and several additional sites scattered along the chromosomes; 8 clones carried repeats which hybridized to chromocenter and other chromosomal sites; clones with 500 and 90 kb inserts originated from the Y chromosomes and nucleolus, respectively. The library is enriched by the repeated sequences related to the b-heterochromatin.     

A novel arrangement of the 18S and 28S sequences in a repeating unit of Drosophila melanogaster rDNA.

The sequences corresponding to the 18S and 28S rRNAs have been mapped within a cloned 17 kilobase (kb) fragment formed by Eco R1 cleavage of Drosophila melanogaster rDNA. This fragment, Dm103, represents the longer of two major types of repeating units that are present in the rDNA of this fly, and was cloned as a hybrid plasmid, pDm103, consisting of Dm103 inserted at the Eco R1 site of the pSC101 vector (Glover et al., 1975). Mapping of the 18S and 28S rDNA in Dm103 was accomplished by quantitative determination of the amount of these rDNAs in each member of an ordered set of restriction fragments obtained by Hind III and Eco R1 ccleavage of pDm103. The amounts of 18S and 28S rDNAs were determined by hybridization of the rRNAs to fragments that were purified by cloning, and an unambiguous order of the fragments within pDm103 was established by heteroduplex mapping and from the stoichiometry of the fragment lengths. The resulting map revealed that the 4 kb of 28S rDNA within the long repeating unit represented by Dm103 is divided into two blocks that are separated by 5.4 kb of DNA of unknown function. It is this unusual arrangement of the 28S rDNA that distinguishes the long repeating units (17 kb) from the short units (11.5) kb), whose 4 kb of 28S rDna is confined to a single block, as is shown in the accompanying paper (White and Hogness, 1977). The remainder of the DNA in this long unit appears to be typically arranged, with the 2 kb of 18S rDNA confined to a single block that is separated by about 1 kb from the closest block of 28S rDNA.     

Characterisation of complete type II insertions in cloned segments of ribosomal DNA from Drosophila melanogaster

We have isolated cloned segments of ribosomal DNA that have EcoRI restrictable (type II) insertions in their 28 S genes. The type II insertions in these plasmids are homologous sequences and have three characteristic cleavage sites for EcoRI. One of these clones is unusual in that it has undergone a deletion of part of the 28 S gene at or near the site of the type II insertion. A second is unusual in that, in addition to the type II insertion in the rDNA, the transcribed spacer sequences are interrupted by an unidentified sequence. This sequence differs in its arrangement of restriction sites from the sequence that interrupts the transcribed spacer of cDm207 (Glover, 1977). The type II sequences in all these clones share homology with the unusually long ‘insertion’ that interrupts the 28 S gene of cDm207. We have re-examined the nature of the additional sequences linked to the type II sequences of cDm207 and find them to be related to type I rDNA insertion sequences.