Mitochondrial-like DNA sequences flanked by direct and inverted repeats in the nuclear genome of Toxoplasma gondii.

In the course of our genetic studies on Toxoplasma gondii, it was discovered that one cosmid hybridized to a repetitive element. The hybridization pattern observed for the enzyme BglII indicated that this cosmid hybridized to a large number of discrete, but related elements. Four BglII fragments were subcloned from the cosmid, and each was shown to hybridize with all the others, as well as to numerous dispersed sequences in genomic DNA. Three subclones were sequenced in their entirety, and shown to contain fragments of the genes for cytochrome oxidase subunit I and apocytochrome b, complete and functional copies of which have been found in only mitochondrial genomes. All the subcloned fragments were bounded at both ends by a 91 base-pair sequence, which contains a site for BglII. This 91 base-pair sequence could be found as either a direct or inverted repeat. It was determined that the BglII elements are arrayed downstream from a single copy nuclear gene. Comparison of genomic and cosmid DNAs confirmed that the cosmid faithfully reflects the nuclear genome. Although the mitochondrial genome of Toxoplasma has not been characterized, these nuclear mitochondrial-like sequences appear to be internally rearranged with respect to known, functional mitochondrial genomes, and with respect to each other. The finding of short repeated sequences flanking these elements may be a clue to the mechanism of their dissemination.     

Detection of deletions flanked by short direct repeats in mitochondrial DNA of aging Drosophila

Cumulative damage due to reactive oxygen species (ROS) in mitochondria, especially in mitochondrial DNA (mtDNA), would result in a decrease in mitochondrial respiratory function and contributes to the age-related decline in the physiological functioning of organisms. Previously, we reported the tissue-specific accumulation of deleted mtDNA with age in Drosophila melanogaster. In the present study, to understand the mechanism by which mtDNA deletion is generated with age, nucleotide sequences of deleted mtDNA were determined. Consequently, 33 different sequences each containing a deletion were obtained from flies that were more than 55-day-old. Most of the deletions were found to be flanked by short direct repeats. The present results, together with those from other animals, suggest that there is a common mechanism generating mtDNA deletions through direct repeats.     

Loss of the pigmentation phenotype in Yersinia pestis is due to the spontaneous deletion of 102 kb of chromosomal DNA which is flanked by a repetitive element

The pigmentation (Pgm+) phenotype of Yersinia pestis encompasses a variety of different physiological traits, all of which are missing in Pgm- mutants. We have previously shown that loss of the Pgm+ phenotype is accompanied by the spontaneous deletion of at least 45 kb of chromosomal DNA, referred to as the pgm locus. Using chromosomal walking, we have now mapped the full extent of the pgm locus in Y. pestis strain KIM6+. Our results indicate that the locus spans 102 kb of DNA which is absent in the spontaneous Pgm- mutant, KIM6. Yersinia pseudotuberculosis PB1/0 contains sequences homologous to the entire pgm locus while only part of this region hybridized to Yersinia enterocolitica WA-LOX DNA. Restriction enzyme mapping and hybridization studies revealed the presence of a repetitive element at both ends of the pgm locus and in multiple copies elsewhere in the Y. pestis genome. This element may be responsible for generating the deletion.     

Identification and nucleotide sequences of two similar tandem direct repeats in Epstein-Barr virus DNA

Epstein-Barr virus DNA is known to have partially homologous segments, designated DL and DR, near the left and right ends of the long unique region (Raab-Traub et al., Cell 22:257-267, 1980). DL and DR are each partially composed of tandem direct repeat sequences. DL contains 11 to 14 repeats of a 124-base-pair sequence designated IR2. DR contains approximately 30 direct repeats of a 103-base-pair sequence designated IR4. The DL and DR sequences have colinear partial homology for approximately 2.4 and 1.5 kilobase pairs to the right of IR2 and IR4, respectively. IR2 and IR4 are similar sequences and evolved in part from a common ancestor. Both sequences are 84% guanine and cytosine and have limited homology to Epstein-Barr virus IR1 and to the herpes simplex virus type 1 inverted terminal repeat "a" sequence. IR2 encodes part of an abundant 2.5-kilobase persistent early EBV RNA expressed in productively infected cells, but does not encode part of the 3-kilobase Epstein-Barr virus RNA which is transcribed from the adjacent IR1-U2 region of the Epstein-Barr virus genome in latently infected cells.     

Short direct repeats mediate spontaneous high-frequency deletions in DNA of minute virus of mice.

Previous work (E. A. Faust and D. C. Ward, J. Virol. 32:276-292, 1979) revealed a remarkably high rate of spontaneous deletion in viral DNA during lytic infection of cultured murine cells with minute virus of mice (MVM), an autonomous parvovirus. In the present study, we have isolated plasmid and phage recombinants containing MVM DNA inserts bearing deletions and we have determined the DNA sequence spanning three deletion junctions. The deletions, which average 3 kilobases in length, occur between pairs of perfectly homologous 4- to 10-base-pair direct repeats, such that one copy of the repeated sequence is lost, whereas the other remains behind at the deletion junction. When compared, the three sets of direct repeats exhibit no apparent sequence homology and have an A + T content of between 50 and 80%. These results indicate that 4- to 10-base-pair homologies mediate spontaneous deletion formation in the MVM genome and highlight parvoviruses as novel model systems for studies of this ubiquitous pathway of genetic variation.     

A developmentally regulated deletion element with long terminal repeats has cis-acting sequences in the flanking DNA

Approximately 6000 specific DNA deletion events occur during development of the somatic macronucleus of the ciliate Tetrahymena. The eliminated Tlr1 element is 13 kb or more in length and has an 825 bp inverted repeat near the rearrangement junctions. A functional analysis of the cis-acting sequences required for Tlr1 rearrangement was performed. A construct consisting of the entire inverted repeat and several hundred base pairs of flanking DNA on each side was rearranged accurately in vivo and displayed junctional variability similar to the chromosomal Tlr1 rearrangement. Thus, 11 kb or more of internal element DNA is not required in cis for DNA rearrangement. A second construct with only 51 bp of Tetrahymena DNA flanking the right junction underwent aberrant rearrangement. Thus, a signal for determination of the Tlr1 junction is located in the flanking DNA, 51 bp or more from the right junction. Within the Tlr1 inverted repeat are 19 bp tandem repeats. A construct with the 19mer repeat region deleted from the right half of the inverted repeat utilized normal rearrangement junctions. Thus, despite its transposon-like structure, Tlr1 is similar to other DNA rearrangements in Tetrahymena in possessing cis-acting sequences outside the deleted DNA.     

RAD52-dependent and -independent homologous recombination initiated by Flp recombinase at a single FRT site flanked by direct repeats

We have devised a system for isolating yeast DNA sequences that are able to act as initiators of recombination leading to deletions in mitotically growing yeast cells. This system has allowed us to identify the FRT site of the 2μ site-specific recombinase Flp as such a sequence. We show that Flp is able to initiate recombination leading to deletions at a single FRT site in cir ^o strains. These results indicate that Flp is able to cleave a single FRT site, supporting the observation that the mechanism of cleavage by Flp is trans-horizontal. Interestingly, Flp can induce homologous recombination in both a RAD52-dependent and RAD52-independent manner. Our work provides a new system for the study of homologous recombination leading to deletions, in which the initiation step can be efficiently controlled. We discuss the possibility that Flp-induced, RAD52-independent events occur by single-strand annealing. Received: 20 July 1999 / Accepted: 27 October 1999     

The effect of the length of direct repeats and the presence of palindromes on deletion between directly repeated DNA sequences in bacteriophage T7.

The frequency of genetic deletion between directly repeated DNA sequences in bacteriophage T7 was measured as a function of the length of the direct repeat. The non-essential ligase gene (gene 1.3) of bacteriophage T7 was interrupted with pieces of synthetic DNA bracketed by direct repeats of various lengths. Deletion of these 76 bp long inserts was too low to be measured when the direct repeats were less than 6 bp long. However, the frequency of deletion of inserts with longer direct repeats increased exponentially as the length of the repeats increased from 8 to 20 bp. When inverted repeats (palindromes) were designed in the midst of the insert there was essentially no increase in deletion frequency between 10 bp direct repeats. But, the same palindromic sequences increased the deletion frequency between 5 bp direct repeats by at least two orders of magnitude. Thus, in this system homology at the endpoints is a more important determinant of deletion frequency than is the presence of palindromes between the direct repeats.     

Transposition of a DNA fragment flanked by two inverted Tn1 sequences

The 32 Md fragment (derived from plasmid RP4::Tn1) carrying the Km^r gene and flanked by two inverted Tn1 elements is capable of recA-independent translocation to other plasmids. We designated this new transposon Tn1755. In various crosses, frequencies of Tn1755 transposition to plasmids Co1B-R3, R15 and F′ColVBtrp varied from 2.5 to 90% of the frequencies of Tn1 transposition. Tn1755 can integrate into various sites of the recipient plasmids. We failed to observe transposition of another RP4::Tn1 fragment flanked by two opposingly oriented Tn1 transposons and harboring the Tc^r gene. Presumably, to form a new transposable structure, other features must also be of importance.     

Discovery of cyanophage genomes which contain mitochondrial DNA polymerase

DNA polymerase γ is a family A DNA polymerase responsible for the replication of mitochondrial DNA in eukaryotes. The origins of DNA polymerase γ have remained elusive because it is not present in any known bacterium, though it has been hypothesized that mitochondria may have inherited the enzyme by phage-mediated nonorthologous displacement. Here, we present an analysis of two full-length homologues of this gene, which were found in the genomes of two bacteriophages, which infect the chlorophyll-d containing cyanobacterium Acaryochloris marina. Phylogenetic analyses of these phage DNA polymerase γ proteins show that they branch deeply within the DNA polymerase γ clade and therefore share a common origin with their eukaryotic homologues. We also found homologues of these phage polymerases in the environmental Community Cyberinfrastructure for Advanced Microbial Ecology Research and Analysis (CAMERA) database, which fell in the same clade. An analysis of the CAMERA assemblies containing the environmental homologues together with the filter fraction metadata indicated some of these assemblies may be of bacterial origin. We also show that the phage-encoded DNA polymerase γ is highly transcribed as the phage genomes are replicated. These findings provide data that may assist in reconstructing the evolution of mitochondria.     

Frequency of deletion formation decreases exponentially with distance between short direct repeats

The effect of distance between 18 bp direct repeats on deletion formation has been examined in Bacillus subtilis. The deletion frequency decreased exponentially by more than 1000-fold as the distance increased from 33 to 2313 bp. This decrease occurred in two distinct phases, which may be determined by DNA-duplex flexibility. A similar relationship between deletion formation and distance was observed in a θ-replicating plasmid and in the chromosome, indicating that this relationship might have a general validity.     

G-quadruplex formation by single-base mutation or deletion of mitochondrial DNA sequences

Background

Mitochondrial DNA (mtDNA) mutations could lead to mitochondrial dysfunction, which plays a major role in aging, neurodegeneration, and cancer. Recently, we have highlighted G-quadruplex (G4) formation of putative G4-forming (PQF) mtDNA sequences in cells. Herein, we examine structural variation of G4 formation due to mutation of mtDNA sequences in vitro.

Swelfe: a detector of internal repeats in sequences and structures

Intragenic duplications of genetic material have important biological roles because of their protein sequence and structural consequences. We developed Swelfe to find internal repeats at three levels. Swelfe quickly identifies statistically significant internal repeats in DNA and amino acid sequences and in 3D structures using dynamic programming. The associated web server also shows the relationships between repeats at each level and facilitates visualization of the results. AVAILABILITY: http://bioserv.rpbs.jussieu.fr/swelfe. SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.     

The tolerance of a modular protein to duplication and deletion of internal repeats

Ankyrin repeat polypeptides contain repeated structural elements that pack to produce modular architectures lacking in close contacts between distant segments of the polypeptide chain. Despite this lack of sequence-distant contacts, ankyrin repeat polypeptides have been shown to fold in a cooperative manner. To determine the distance over which cooperative interactions can be propagated in a repeat protein, and to investigate the tolerance to internal duplication and deletion of modules, we have constructed a series of ankyrin repeat variants of the Notch ankyrin domain in which repeat number is varied by duplication and deletion of internal repeats. A construct with two copies of the fifth ankyrin repeat shows a modest increase in stability compared to the parent construct and retains apparent two-state unfolding behavior. Although constructs containing three and four copies of the fifth repeat retain this increased resistance to urea, they exhibit broad, multi-state unfolding transitions compared to the parent construct. For the Notch ankyrin domain, these larger constructs may represent a limit beyond which full cooperativity cannot be maintained. Deletions of internal repeats from the Notch ankyrin domain significantly destabilize the domain. This severe destabilization, which is larger than that resulting from end-repeat deletion, may arise from unfavorable interactions within the new non-native interfaces produced by internal repeat deletion. These results demonstrate both an asymmetry between the duplication and deletion of internal repeats, and a difference between deletion of internal and end-repeats, suggesting preferred mechanisms for evolution of repeat proteins.     

Two distinct mechanisms for deletion in mitochondrial DNA of Schizosaccharomyces pombe mutator strains. Slipped mispairing mediated by direct repeats and erroneous intron splicing

Mutator strains of the fission yeast Schizosaccharomyces pombe produce mitochondrial respiratory deficient mutants at a high rate, and roughly 20% of these mutants carry deletions in the range of 50 to 1500 base-pairs. To elucidate the mechanism of deletion we have sequenced ten deletion mutants in the mosaic gene encoding apocytochrome b (cob) and three in the split gene coding for the first subunit of cytochrome c oxidase (cox1). Of 13 deletions, ten are correlated with the presence of direct repeats, which could promote deletions by slipped mispairing during DNA replication. In some of these mutants, the termini are located in possible DNA secondary structures. In three independently isolated mutants with identical deletions in the cob gene, the 5' deletion endpoint coincides with the 3' splice point of the intron, whereas the 3' endpoint of the deletion exhibits pronounced homology with the 5' splice point of the intron. This result suggests that these deletions might be initiated by erroneous RNA splicing.