IST2: an insertion sequence from Thiobacillus ferrooxidans.

The genome of Thiobacillus ferrooxidans (strain ATCC 19859) contains at least two families of repeated sequences, termed family 1 and 2. The nucleotide sequence of a family 2 member was determined. It is 1408 base pairs long and has structural features similar to those of insertion sequences (IS elements). Terminal inverted repeats 25 base pairs in length are present. These inverted repeats are imperfect and adjacent to target-site duplications 9 base pairs in length. Several open reading frames were detected (the longest was 888 base pairs). We have named this IS element-like sequence IST2. The ends of a second example of IST2 were analyzed and compared to those of the first. The DNA sequences are identical and similarly sized target-site duplications are present.     

Multiplicity of satellite DNA sequences in Drosophila melanogaster

Three Drosophila melanogaster satellite DNAs (1.672, 1.686, and 1.705 g/ml in CsCl), each containing a simple sequence repeated in tandem, were cloned in pBR322 as small fragments about 500 base pairs long. This precaution minimized deletions, since inserts of the same size as the fragments used for cloning were recovered in a stable form. A homogeneous tandem array of one sequence type usually extended the length of the insert. Eleven distinct repeat sequences were discovered, but only one sequence was predominant in each satellite preparation. The remaining classes were minor in amount. The repeat unit lengths were restricted to 5, 7, or 10 base pairs, with sequences closely related. Each sequence conforms to the expression (RRN)m(RN)n, where R is A or G. The multiplicity of simple repeated sequences revealed despite the small sample size suggests that numerous repeat sequences reside in heterochromatin and that particular rules apply to the structure of the repeating sequence.     

A transposable element that splits the promoter region inactivates a Drosophila cuticle protein gene.

Two mutations that affect larval cuticle protein gene expression in the 2/3 variant Drosophila melanogaster strain were investigated. We demonstrate that this strain synthesizes an electrophoretic variant, fast 2 (CPf2), of wild-type cuticle protein 2(CP2). It also lacks detectable amounts of cuticle protein 3 (CP3). The other major cuticle proteins are still present. Protein and DNA sequence analyses indicate that point mutations cause two amino acid substitutions that change the electrophoretic mobility of CPf2 relative to that of CP2. The mutation abolishing the expression of CP3 was found to be a 7.3-kilobase DNA insertion located within the T-A-T-A box region of this gene, at -31 base pairs from the mRNA start site. This DNA insertion, called H.M.S. Beagle, belongs to a conserved family of repeated DNA elements that have characteristics similar to those of previously characterized Drosophila transposable elements. H.M.S. Beagle elements are repeated approximately 50 times in the haploid genome and exhibit restriction fragment-length polymorphisms around points of insertion between Canton S, Oregon R, and 2/3 Drosophila strains. Sequence analysis indicates that H.M.S. Beagle contains 266-base-pair direct repeats at its termini and is flanked by a duplication of 4 base pairs of target DNA sequence, T-A-T-A, in the CP3 gene insertion. Thus, insertion of a transposable element into the putative promoter region of the CP3 gene is evidently responsible for inactivating CP3 gene expression.     

Middle repetitive DNA: a fluid component of the Drosophila genome.

Most of the middle repetitive DNA of Drosophila melanogaster appears to be organized into families of 10-100 repeated elements that are found at scattered locations in the chromosome arms and occupy new chromosomal positions as populations of D. melanogaster diverge. These "nomadic" DNA segments can be identified by an analysis of cDm plasmids, hybrids of ColE1 and segments of randomly sheared D. melanogaster DNA. Eighty cDm plasmids were withdrawn, at random, from a library of approximately 17,000 cDm clones. Fifty-seven of these seem to contain either DNA that is not repeated in the D. melanogaster genome or DNA that has a low repetition frequency. The remaining 23 cDm plasmids contain repetitive sequences. Seventeen of these 23 plasmids contain repetitive sequences that are demonstrably scattered to many chromosomal sites that can be mapped in two D. melanogaster strains, g-1 and g-X11. The repeated elements hybridizing with each of the different Dm segments are at quite different chromosomal locations in these two strains. However, the size of each family of repeated sequences remains fairly constant in both strains. It is proposed that the number of elements in each family has been fixed by selection.     

Oligonucleotide-directed site-specific mutagenesis in Drosophila melanogaster.

An efficient technique has been developed for performing in vivo site-directed mutagenesis in Drosophila melanogaster. This procedure involves directed repair of P-element-induced DNA lesions after injection of a modified DNA sequence into early embryos. An oligonucleotide of 50 base pairs, whose sequence spans the P-element insertion site, mediates base replacement in the endogenous gene. Restriction mapping, DNA sequencing, and polymerase chain reaction analysis demonstrate that base substitutions present in an injected oligonucleotide are incorporated into genomic sequences flanking a P insertion site in the white gene. This analysis suggests that progeny bearing directed mutations are recovered with a frequency of about 0.5 x 10(-3). Because Drosophila remains a premier organism for the analysis of eukaryotic gene regulation, this system should find strong application in that analysis as well as in the analysis of DNA recombination, conversion, repair, and mutagenesis.     

DNA-protein interactions in the Drosophila melanogaster mitochondrial genome as deduced from trimethylpsoralen crosslinking patterns.

The location of proteins on the mitochondrial DNA (mtDNA) of Drosophila melanogaster was investigated by trimethylpsoralen photoreaction of embryos disrupted by gentle homogenization. After photoreaction, the mtDNA was isolated and the pattern of DNA crosslinking was determined by electron microscopy of the DNA under totally denaturing conditions. In contrast to nuclear DNA, which showed periodic crosslinks indicative of a nucleosome structure, most of each mtDNA molecule exhibited uniformly heavy crosslinking. A 10% region of the mtDNA was, however, protected from psoralen crosslinking in a distinctive manner: five uncrosslinked segments were closely clustered in the mtDNA. Four were 394 +/- 13 (SD) base pairs in size, while the fifth measured about 200 base pairs. These protected segments mapped within the A+T-rich region of the mtDNA, extending from the end of the A+T-rich region near the Bg1 II cleavage site to the center of the A+T-rich region. Protection of this part of the mtDNA from crosslinking was interpreted to be the result of association with proteins in the mitochondrion because mtDNA that was deproteinized before the photoreaction was uniformly crosslinked over its entire length. The origin of replication of the mtDNA is also located at the center of the A+T-rich region, which suggests that the protection from the psoralen photoreaction may be due to proteins involved in membrane attachment or replication.     

Mitochondrial DNA heteroplasmy in Drosophila mauritiana.

Mitochondrial DNA extracted from an isofemale strain of Drosophila mauritiana (subgroup melanogaster) appeared to be heterogeneous in size. A short genome [S; 18,500 base pairs (bp)] and a longer one (L; 19,000 bp) coexist in the preparation. The additional 500 bp have been located within the A+T-rich region. Hpa I digest patterns suggest that the S genome may carry a duplication of a 500-bp sequence including an Hpa I site and that the L genome may carry a triplication of the same sequence. At the 30th generation of the isofemale strain, 60 female genotypes were examined individually. Half of the files were pure either for the S or the L DNA. The remaining 50% exhibited various degrees of heteroplasmy for the two DNA types. Among metazoan animals, this D. mauritiana strain offers an exceptional situation with regard to the number of individuals heterogeneous for mtDNA and the relative stability of heteroplasmy through generations.     

Molecular structure of a somatically unstable transposable element in Drosophila.

A transposable element has been isolated from an unstable white mutation in Drosophila mauritiana, a sibling species of Drosophila melanogaster. The unstable white-peach (wpch) allele exhibits a spectrum of germ-line and somatic mutability more similar to insertion mutations in maize and in the nematode Caenorhabditis elegans than has been reported for insertion mutations in Drosophila. The inserted element mariner is 1286 nucleotides long and has terminal inverted repeats. The element contains a single open reading frame encoding 346 amino acids. A duplication of 2 base pairs of white sequence is present at the insertion site. Mariner is present in approximately 20 copies in the D. mauritiana genome, is present from 0 to 7 copies in other members of the sibling species group, and is apparently absent from the genome of D. melanogaster.     

DNA sequences similar to those around the simian virus 40 origin of replication are present in the monkey genome.

We report the molecular cloning of African green monkey genomic DNA segments that include regions of homology to the origin of replication of simian virus 40 (SV40). Three clearly different cloned segments 14 to 17 kilobase pairs (kb) long were isolated from a genomic library in lambda phage. We estimate that each of the three is repeated fewer than four times in the monkey genome. The SV40-like regions represent a small portion of the cloned segments, and these regions cross hybridize only weakly with one another. One of the three segments is described here in detail. Although the entire segment occurs only once or twice in the monkey genome, it contains DNA sequences (other than the SV40-like sequences) that are repeated elsewhere in the genome including in the other two cloned segments. The homology to SV40 is contained within about 300 base pairs of monkey DNA and is limited to the region around the viral replication origin. The nucleotide sequence of the SV40-like region was determined. It contains a large number of short stretches homologous to three specific noncoding domains around the SV40 origin of replication: the 27-base-pair region of dyad symmetry, the first set of (short) repeats that occur just on the late side of the origin, and, further in the late direction, the two 72-base-pair-long repeats. Although these components are grouped in the monkey DNA, as they are in SV40 DNA, their relative juxtaposition is scrambled.     

Sequences homologous to ribosomal insertions occur in the Drosophila genome outside the nucleolus organizer

Many repeating units of Drosophila melanogaster rDNA contain a DNA sequence within the gene for 28S rRNA that does not code for rRNA. This sequence has been called the ribosomal insertion [Wellauer, P. K. & Dawid, I. B. (1977) Cell 10, 193-212]. We report here that members of the same sequence family occur outside the ribosomal locus. "Non-rDNA insertion DNA" was separated from rDNA by density gradient centrifugation, and sequences homologous to the ribosomal insertion were detected by hybridization with restriction endonuclease fragments derived from a cloned rDNA repeating unit. Pure insertion sequences from cloned rDNA separated from main band DNA and behaved like a component with high G + C content. Non-rDNA components hybridizing to the insertion also separated from main band DNA but less so than pure insertion sequences, suggesting that non-rDNA insertion sequences are linked to DNA of different nucleotide composition. Restriction endonuclease analysis of non-rDNA insertion DNA showed many fragments of different sizes. The patterns obtained were similar in embryonic, larval, pupal, and adult DNA and DNA from cultured cells (Schneider cell line 3). Non-rDNA insertion sequences account for about 0.2% of the genome or about 400 kbases of DNA per haploid complement.     

Lack of correlation between interspecific divergence and intraspecific polymorphism at the suppressor of forked region in Drosophila melanogaster and Drosophila simulans.

Levels of DNA sequence polymorphism at the suppressor of forked [su(f)] region in natural populations of Drosophila melanogaster and Drosophila simulans are estimated by restriction map analysis. su(f) is located at the base of the euchromatic portion of the X chromosome where the level of crossing-over per physical length is extremely low. In a survey of 55 alleles from three natural populations of D. melanogaster, only 2 restriction sites of 27 hexanucleotide and 108 tetranucleotide restriction sites scored are polymorphic. Among 103 alleles from three natural populations of D. simulans, just one polymorphic restriction site is found in 109 tetranucleotide-recognizing restriction sites scored. The few polymorphisms in these surveys yield estimates of per site heterozygosities (0.00, 0.0002, and 0.0005, respectively) at least a factor of 10 less than the average observed at loci located in regions of the genome with normal levels of crossing-over. Because under a broad category of models of molecular evolution (including the neutral theory) a correlation between levels of polymorphism and interspecific divergence is expected, the DNA sequence divergence is examined for the su(f) region. Contrary to the predicted correlation, the estimated divergence (0.12 substitution per silent site) is, in fact, greater than that observed at loci in regions of normal crossing-over. According to an alternative hypothesis (hitchhiking effect model) intraspecific polymorphism is swept out of the population in regions of the genome closely linked to rare but selectively favored variants as they quickly go to fixation; the rate of divergence is, however, unaffected by these rare hitchhiking events. Thus, the observed paucity of polymorphism and lack of correlation with divergence are in accord with the theory of the hitchhiking effect and several recent reports of polymorphism and divergence in other genomic regions with reduced crossing-over per physical length.     

Chromosome ends in Drosophila without telomeric DNA sequences.

We have recovered terminal chromosome deletions of the X chromosome of Drosophila [Df(1)RT; RT = receding tips] that break in various positions of the yellow gene (y) region and delete all distal DNA sequences. Terminal DNA fragments are heterogeneous in length. Molecular cloning and sequencing of the terminal DNA fragments revealed that the broken ends of the deleted chromosomes do not carry any telomeric DNA sequences, yet the broken chromatids do not fuse to one another. Moreover, we confirmed by sequence analysis of 49 independently cloned terminal DNA fragments from two RT lines collected at different times that they lose DNA sequences from their distal ends at a rate of 70-75 base pairs per fly generation. We calculate that the rate of loss from these ends is consistent with the removal of an octanucleotide RNA primer at each round of DNA replication in the germ line.     

Transposable and nontransposable elements similar to the I factor involved in inducer-reactive (IR) hybrid dysgenesis in Drosophila melanogaster coexist in various Drosophila species

The I factor is a transposable element controlling inducer-reactive (IR) hybrid dysgenesis in Drosophila melanogaster, which occurs when males from the class of inducer strains are crossed with females from the class of reactive strains. Inducer strains contain several copies of the complete 5.4-kilobase (kb) I factor at various sites on the chromosomal arms; reactive strains contain no complete I factor. Incomplete and defective I elements occur at constant locations in pericentromeric heterochromatin of both types of strains. The 5.4-kb I factors transpose, whereas incomplete I elements do not transpose. The constant location of defective I elements in all strains indicates that they were in the genome before the spread of D. melanogaster throughout the world. Sequences homologous to I occur in other Drosophila species, and their distribution correlates with the phylogenetic relationships between species. We have studied the organization of I homologues in Drosophila simulans and Drosophila teissieri. These species seem to contain both transposable I elements, even though their structure may differ from that of the 5.4-kb I factors of the inducer strains of D. melanogaster, and nontransposable I elements, which are always at the same place in the genome when different stocks of the same species are compared. These results suggest that both mobile and nonmobile I elements are very old components of the Drosophilidae genome.     

A gene adjacent to satellite DNA in Drosophila melanogaster.

Several copies of a sequence adjacent to 1.688 g/cm3 satellite DNA in the Drosophila melanogaster genome have been isolated by molecular cloning. This sequence, called the Dm142 gene, is homologous to a 1.6-kilobase RNA found in both D. melanogaster embryos and tissue culture cells. One cloned DNA segment includes two copies of the Dm142 gene and 1.688 g/cm3 satellite DNA sequences, which are located between and flanking both gene copies. The Dm142 gene is repeated many times in the D. melanogaster genome, and some copies are not flanked by 1,688 g/cm3 satellite DNA.     

Sequences of two kinetoplast DNA minicircles of Tryptanosoma brucei.

Kinetoplast DNA of Trypanosoma brucei is composed of a network of about 10,000 interlocked minicircle DNA molecules (1.0 kilobase) that are catenated with about 50 maxicircle DNA molecules (23 kilobases). Several different DNA . DNA hybridization techniques using individual minicircle DNA sequences cloned in Escherichia coli have indicated that each minicircle molecule contains about one-fourth of its sequence in common with most other minicircles and the remaining three-fourths in common with about 1 out of every 300 minicircles. We have determined the complete sequence of two cloned minicircle DNA molecules that were released from the total kinetoplast DNA network by different restriction enzymes; one minicircle is 1004 base pairs long, the other is 983 base pairs. Both are about 72% dA + dT. They share about 27% of their sequences; the largest continuous region in common is 122 base pairs of near-perfect homology. Twelve other regions of perfect homology equal to or greater than 10 base pairs are also present. Both sequences contain a large number of translation termination codons in all potential translation reading frames. The largest oligopeptide potentially specified by one minicircle sequence is 52 amino acids; the largest by the other minicircle sequence is 71 amino acids. One minicircle contains a decanucleotide sequence that is repeated in tandem five times. It is proposed that massive recombination among the interlocked minicircles in the kinetoplast DNA network may account for much of the homology observed in the two minicirce sequences.