Unequal crossing-over within the B duplication of Drosophila melanogaster: a molecular analysis.

The B mutation is associated with a tandem duplication of 16A1-16A7. It is unstable, mutating to wild type and to a more extreme form at a frequency of one in 1000 to 3000. The reversion to wild type is associated with the loss of one copy of the duplication, whereas the mutation to extreme B is associated with a triplication of the region. The instability of B has been attributed to unequal crossing-over between the two copies of the duplication. Recent molecular data show that there is a transposable element, B104, between the two copies of the duplication and support the hypothesis that this element generated the duplication via a recombination event. These data suggest that unequal crossing-over within the duplication may not be the cause of the instability of B. Instead, the instability may be caused by a recombination event involving the B104 element. This issue was addressed using probes for the DNA on either side of the B104 element at the B breakpoint. All of the data indicate that the B104 element is not involved in the instability of B and support the original unequal crossing-over model.     

Structure of circular copies of the 412 transposable element present in Drosophila melanogaster tissue culture cells, and isolation of a free 412 long terminal repeat

We have isolated, from Drosophila melanogaster tissue culture cells, extrachromosomal circular forms of the transposable element 412, and have cloned some of them in bacteriophage lambda. A total of 24 clones have been analysed in detail by restriction and heteroduplex mapping. Seventeen clones are virtually identical, and contain complete 412 elements with one copy of the long terminal direct repeat (LTR). The remaining seven clones are all different and contain various rearrangements. Four have deletions, two have some 412 sequence substituted by other DNA and one has both an inversion and a deletion. The clone containing the inversion has two LTRs in inverted orientation and separated by a few thousand bases of 412 DNA. The base sequences of the two LTRs in this clone, and of the LTR in one of the 17 clones containing complete elements are very similar to that of the 481 base-pair LTR of a genomic 412 element. We have found no evidence, in either cloned or uncloned material, for 412 elements with two LTRs as a tandem direct repeat. We have found that there are several "free" 412 LTRs in genomic DNA from D. melanogaster strains Canton S and Oregon R, and from D. melanogaster tissue culture cells. We have cloned and sequenced one of these free LTRs. It is 475 base-pairs long and is flanked by a direct repeat four base-pairs long. This sequence differs from that of the 481 base-pair repeat at 16 places including a ten base deletion.     

Nucleotide sequence and characterization of a repetitive DNA element from the genome of Bordetella pertussis with characteristics of an insertion sequence

A repeating element of DNA has been isolated and sequenced from the genome of Bordetella pertussis. Restriction map analysis of this element shows single internal ClaI, SphI, BstEII and SalI sites. Over 40 DNA fragments are seen in ClaI digests of B. pertussis genomic DNA to which the repetitive DNA sequence hybridizes. Sequence analysis of the repeat reveals that it has properties consistent with bacterial insertion sequence (IS) elements. These properties include its length of 1053 bp, multiple copy number and presence of 28 bp of near-perfect inverted repeats at its termini. Unlike most IS elements, the presence of this element in the B. pertussis genome is not associated with a short duplication in the target DNA sequence. This repeating element is not found in the genomes of B. parapertussis or B. bronchiseptica. Analysis of a DNA fragment adjacent to one copy of the repetitive DNA sequence has identified a different repeating element which is found in nine copies in B. parapertussis and four copies in B. pertussis, suggesting that there may be other repeating DNA elements in the different Bordetella species. Computer analysis of the B. pertussis repetitive DNA element has revealed no significant nucleotide homology between it and any other bacterial transposable elements, suggesting that this repetitive sequence is specific for B. pertussis.     

The transposable portion of the genome of Drosophila algonquin is very different from that in D. melanogaster

Four clones containing different transposable elements were isolated from a genomic library of Drosophila algonquin. Each clone was hybridized to salivary-gland chromosomes of three lines of D. algonquin and two lines of D. affinis. The estimated copy number in D. algonquin of the four element families varied from 59 to 333. The occupancy per site varied from 0.64 to 0.75. Thus the transposable portion of the D. algonquin genome is dominated by a few high-copy-number elements, each characterized by high occupancies. The copy number and occupancy values were very similar in D. affinis. This differs from the situation in D. melanogaster mobile middle-repetitive DNA, which has at least 30 and perhaps as many as 100 different families of mobile elements, with copy numbers ranging from 5 to 100. When several lines have been examined, elements in D. melanogaster are revealed to have very low occupancies. The four D. algonquin elements do not hybridize with D. melanogaster DNA, but they did hybridize with 15 obscura-group species, thereby revealing a pattern that is consistent with concerted evolution.     

A transposon-like sequence with short terminal inverted repeats in the nuclear genome of Chlamydomonas reinhardtii

A 1.2 kb DNA sequence, flanked by a potential seven base target-site duplication, was found inserted into a TOC1 transposable element from Chlamydomonas reinhardtii. The insertion sequence, named TOC2, is a member of a family of repeated DNA sequences that is present in all the C. reinhardtii strains tested. It resembles class II transposable elements: it possesses short 14 bp imperfect terminal repeats that begin AGGAGGGT, and sub-terminal direct repeats located within 250 bp of the termini. No large open reading frames were found. The terminal bases and length of target-site duplication are important in classifying transposable elements. On this basis TOC2 does not fall readily into existing families of class II transposable elements found in plants.     

Stable Non-Mutator Stocks of Maize Have Sequences Homologous to the Mu1 Transposable Element

Mutator stocks of maize produce mutants at many loci at rates 20- to 50-fold above spontaneous levels. Current evidence suggests that this high mutation rate is mediated by an active transposable element system, Mu. Members of this transposable element family are found in approximately 10-60 copies in Mutator stocks. We report here an initial characterization of previously undetected sequences homologous to Mu elements in eight non-Mutator inbred lines and varieties of maize that have a normal low mutation rate. All stocks have approximately 40 copies of sequences homologous only to the terminal repeat and show weak homology to an internal probe. In addition, several of the stocks contain an intact Mu element. One intact Mu element and two terminal-specific clones have been isolated from one non-Mutator line, B37. The cloned sequences have been used to demonstrate that in genomic DNA the intact element, termed Mu1.4B37, is modified, such that restriction sites in its termini are not accessible to cleavage by the HinfI restriction enzyme. This modification is similar to that observed in Mutator lines that have lost activity. We hypothesize that the DNA modification of the Mu-like element may contribute to the lack of Mutator activity in B37.     

Structure and unusual characteristics of a new family of transposable elements in the sea urchin Strongylocentrotus purpuratus.

The transposable element family TU of the sea urchin Strongylocentrotus purpuratus, a higher eucaryote, has recently been described (D. Liebermann, B. Hoffman-Liebermann, J. Weinthal, G. Childs, R. Maxson, A. Mauron, S.N. Cohen, and L. Kedes, Nature [London] 306:342-347, 1983). A member of this family, TU4, has an insertion, called ISTU4, of non-TU DNA. ISTU4 is a member of a family of repetitive sequences, which are present in some 1,000 copies per haploid S. purpuratus genome (B. Hoffman-Liebermann, D. Liebermann, L.H. Kedes, and S.N. Cohen, Mol. Cell. Biol. 5:991-1001, 1985). We analyzed this insertion to determine whether it is itself a transposable element. The nucleotide sequence of ISTU4 was determined and showed an unusual structure. There are four, approximately 150 nucleotides long, imperfect direct repeats followed by a single truncated version of these repeats. This region is bounded at either side by approximately 100-nucleotide-long sequences that are not related to each other or to the repeats. Nucleotide sequences at the boundaries of ISTU4-homologous and flanking regions in five genomic clones show that ISTU4 represents a family of sequences with discrete ends, which we call Tsp elements. We showed that the genomic locus that carries a Tsp element in one individual was empty in other individuals and conclude that Tsp elements are a new and different type of transposable element. Tsp elements lack two features common to most other transposable elements: Tsp integration does not result in the duplication of host DNA, and there are no inverted repeats at their termini, although short inverted repeats are present at a distance from the termini.     

Aberrant splicing of the Drosophila melanogaster phenylalanine hydroxylase pre-mRNA caused by the insertion of a B104/roo transposable element in the Henna locus.

We report the insertion of the transposable element B104 in the Phenylalanine hydroxylase gene of the Drosophila mutant Henna-recessive 3. Its presence alters the Phenylalanine hydroxylase splicing pattern, producing at least two aberrant mRNAs which contain part of the B104 sequence interrupting the coding region. This aberrant splicing is provoked by the use of a cryptic donor site encoded by the B104 3' long terminal repeat in combination with either the gene intron 3 acceptor site or a novel acceptor site generated by the target duplication caused by transposition. One of them, referred as mRNA type 1, encodes a truncated protein that could be predictably non-functional. In mRNA type 2, in spite of a 42 nt insertion, the Phenylalanine hydroxylase reading frame is not altered and it would encode for a protein with 14 extra amino acids which would be able to account for the low enzyme activity detected in this mutant. These results demonstrated that Henna locus encodes the enzyme phenylalanine hydroxylase providing direct evidence of its participation in pteridine synthesis. Moreover, it constitutes an example of the ability of transposable elements to generate protein variation in populations with the evolutionary consequences that this implies.     

Enrichment for histone H3 lysine 9 methylation at Alu repeats in human cells

The aim of this study was to identify in human cells common targets of histone H3 lysine 9 (H3-Lys9) methylation, a modification that is generally associated with gene silencing. After chromatin immunoprecipitation using an H3-Lys9 methylated antibody, we cloned the recovered DNA and sequenced 47 independent clones. Of these, 38 clones (81%) contained repetitive elements, either short interspersed transposable element (SINE or Alu elements), long terminal repeat (LTR), long interspersed transposable element (LINE), or satellite region (ALR/Alpha) DNA, and three additional clones were near Alu elements. Further characterization of these repetitive elements revealed that 32 clones (68%) were Alu repeats, corresponding to both old Alu (23 clones) and young Alu (9 clones) subfamilies. Association of H3-Lys9 methylation was confirmed by chromatin immunoprecipitation-PCR using conserved Alu primers. In addition, we randomly selected 5 Alu repeats from the recovered clones and confirmed association with H3-Lys9 by PCR using primer sets flanking the Alu elements. Treatment with the DNA methyltransferase inhibitor 5-aza-2'-deoxycytidine rapidly decreased the level of H3-Lys9 methylation in the Alu elements, suggesting that H3-Lys9 methylation may be related to the suppression of Alu elements through DNA methylation. Thus H3-Lys9 methylation is enriched at human repetitive elements, particularly Alu elements, and may play a role in the suppression of recombination by these elements.     

The pogo transposable element family of Drosophila melanogaster.

Summary A 190 by insertion is associated with the white-eosin mutation in Drosophila melanogaster. This insertion is a member of a family of transposable elements, pogo elements, which is of the same class as the P and hobo elements of D. melanogaster. Strains typically have many copies of a 190 by element, 10–15 elements 1.1–1.5 kb in size and several copies of a 2.1 kb element. The smaller elements all appear to be derived from the largest by single internal deletions so that all elements share terminal sequences. They either always insert at the dinucleotide TA and have perfect 21 bp terminal inverse repeats, or have 22 by inverse repeats and produce no duplication upon insertion. Analysis by DNA blotting of their distribution and occupancy of insertion sites in different strains suggests that they may be less mobile than P or hobo. The DNA sequence of the largest element has two long open reading frames on one strand which are joined by splicing as indicated by cDNA analysis. RNAs of this strand are made, whose sizes are similar to the major size classes of elements. A protein predicted by the DNA sequence has significant homology with a human centrosomal-associated protein, CENP-B. Homologous sequences were not detected in other Drosophila species, suggesting that this transposable element family may be restricted to D. melanogaster.     

Identification of new transposable genetic elements in Burkholderia pseudomallei using subtractive hybridisation

A subtraction library of Burkholderia pseudomallei was constructed by subtractive hybridisation of B. pseudomallei genomic DNA with Burkholderia thailandensis genomic DNA. Two clones were found to have significant sequence similarity to insertion sequences which have previously not been found in B. pseudomallei (designated ISA and ISB); and two clones showed sequence similarity to different regions of Burkholderia cepacia IS407 that has recently been detected in B. pseudomallei. The former, though possibly non-functional, represents new transposable genetic elements of B. pseudomallei. All three sequences were found to be present in multi-copy in the genomes of a number of B. pseudomallei strains and in B. thailandensis, which are the first transposable elements identified in this species.     

A new family of the poly-deoxyadenylated class of Drosophila transposable elements identified by a representative member at the dunce locus

Summary Two transposable elements have been identified at the dunce locus in chromosomes recovered after a premeiotic and interchromosomal conversion event occurred at this gene. One is approximately 8.2 kb and is inserted near the 5 end of the gene. This element was identified by sequence analysis as a member of the B104 (roo) family of copia-like transposable elements. The second resides near the 3 end of the gene and represents a new family of the class of poly-deoxyadenylated [poly(dA)] transposable elements. It is 0.38 kb in length and has one terminus consisting of a stretch of 29 deoxyadenosine residues with a polyadenylation site like those found in mRNA molecules, located about 20 pb away from the poly(dA) stretch. Fourteen base pairs of genome DNA is duplicated at the target site of this element.     

A transposon-like element in the deletion-prone region of the dystrophin gene.

The central portion of the dystrophin gene locus is a preferential site for deletions causing progressive muscular dystrophy of the Duchenne type (DMD). The nucleotide sequence of a deletion junction fragment from a DMD patient was determined, revealing that the proximal breakpoint of the deletion in intron 43 fell within the sequence of a transposon-like element. This segment, belonging to the THE-1 family of human transposable elements, is normally present in a complete form in intron 43 of the dystrophin gene. The deletion mutation was maternally transmitted and eliminated two-thirds of the THE-1 element. Analysis of DNA from additional DMD patients revealed a second deletion with the proximal breakpoint mapping within the same THE-1 element.     

A detailed look at 7 million years of genome evolution in a 439 kb contiguous sequence at the barley Hv-eIF4E locus: recombination, rearrangements and repeats

Six overlapping BAC clones covering the Hv-eIF4E gene region in barley were sequenced in their entire length, resulting in a 439.7 kb contiguous sequence. The contig contains only two genes, Hv-eIF4E and Hv-MLL, which are located in a small gene island and more than 88% of the sequence is composed of transposable elements. A detailed analysis of the repetitive component revealed that this chromosomal region was affected by multiple major duplication and deletion events as well as the insertion of numerous transposable elements, resulting in a complete reshuffling of genomic DNA. Resolving this highly complex pattern resulted in a model unraveling evolutionary events that shaped this region over an estimated 7 million years. Duplications and deletions caused by illegitimate recombination and unequal crossing over were major driving forces in the evolution of the Hv-eIF4E region, equaling or exceeding the effects of transposable element activities. In addition to a dramatic reshuffling of the repetitive portion of the sequence, we also found evidence for important contributions of illegitimate recombination and transposable elements to the sequence organization of the gene island containing Hv-eIF4E and Hv-MLL.     

Rearrangements of the 5S RNA gene cluster of Drosophila melanogaster associated with the insertion of a B104 element

The organization of the 5S RNA gene cluster of Drosophila melanogaster is different in two Oregon R stocks that have been separated for a number of years. The Oregon R Yale population contains various different arrangements of the cluster. One of these is due to the insertion of a B104 element near one end of the cluster. Other arrangements lack the B104 insertion and have instead a variety of deletions originating in the vicinity of the B104 insertion site and removing from 0 to 60% of the 5S RNA genes without affecting nearby tRNA genes. In contrast, the Oregon R Heidelberg population has no B104 element in the 5S gene cluster and no heterogeneity in the arrangement of the cluster. We propose that transposable elements inserted at a genomic locus generate heterogeneity in a population at that locus due to excision of the element with and without accompanying deletions of flanking sequences. As a consequence, a fly population would accumulate a large number of deletions scattered throughout the genome in as many loci as contain transposable elements. We show further that D. melanogaster contains a large redundancy of 5S RNA genes since the 60% deletion of the cluster shows no visible phenotype when homozygous or when heterozygous against a total deletion of the entire 5S gene cluster.