Testing the palindromic target site model for DNA transposon insertion using the Drosophila melanogaster P-element

Understanding the molecular mechanisms that influence transposable element target site preferences is a fundamental challenge in functional and evolutionary genomics. Large-scale transposon insertion projects provide excellent material to study target site preferences in the absence of confounding effects of post-insertion evolutionary change. Growing evidence from a wide variety of prokaryotes and eukaryotes indicates that DNA transposons recognize staggered-cut palindromic target site motifs (TSMs). Here, we use over 10 000 accurately mapped P-element insertions in the Drosophila melanogaster genome to test predictions of the staggered-cut palindromic target site model for DNA transposon insertion. We provide evidence that the P-element targets a 14-bp palindromic motif that can be identified at the primary sequence level, which predicts the local spacing, hotspots and strand orientation of P-element insertions. Intriguingly, we find that the although P-element destroys the complete 14-bp target site upon insertion, the terminal three nucleotides of the P-element inverted repeats complement and restore the original TSM, suggesting a mechanistic link between transposon target sites and their terminal inverted repeats. Finally, we discuss how the staggered-cut palindromic target site model can be used to assess the accuracy of genome mappings for annotated P-element insertions.     

Tam3 in Antirrhinum majus is exceptional transposon in resistant to alteration by abortive gap repair: identification of nested transposons

Most transposon families consist of heterogeneous copies with varying sizes. In contrast, the Tam3 copies in Antirrhinum majus are known to have exceptionally conserved structures of uniform size. Gap repair has been reported to be involved in the structural alteration of copies from several transposon families. In this study, we have asked whether or not gap repair has affected Tam3 copies. Five Tam3 copies carrying aberrant sequences were selected from 40 independent Tam3 clones and their sequences were analyzed. Two of the five copies contain insertions in the Tam3 sequence. These two insertions, designated Tam356 and Tam661, are typical transposon-like sequences, which have terminal inverted repeats and cause target site duplication. These nested transposons were obviously associated with transpositional events, and did not originate from the gap-repair process. The remaining three copies had lost large parts of the Tam3 sequence. We could not find any relationship between the deletions of Tam3 sequence in the three copies and gap repair. PCR analysis of a Tam3 excision site in the nivea ^{recurrence:Tam3} mutant also showed that most of the repair events after the Tam3 excision involved end-joining. In addition to the results obtained here, among the other clones isolated, we could not find any of the internally deleted copies that comprise a major part of other transposon families. All of these data suggest that some feature of the Tam3 structure suppresses the structural alterations that are otherwise generated during the gap repair process.     

The <Emphasis Type="Italic">piggyBac</Emphasis> Transposon as a Tool in Genetic Engineering

Transposons are mobile genetic elements that are part of the genomic DNA of numerous organisms and belong to two classes. Unlike class I transposons, class II DNA transposons do not use the stage of RNA synthesis in their transition; they perform it by the cut-and-paste mechanism or with a replicative transposition. The integration of a DNA transposon in a new site results in the duplication of a target sequence on either side of a transposon, and its excision is, as a rule, associated with insertions and deletions. The piggyBac transposon isolated from the Trichoplusia ni moth differs from other mobile elements of its class. Due to its unique ability to leave no traces after excision from an insertion site and to perform successful transposition and transference of large DNA fragments, piggyBac is a convenient tool for the development of gene engineering approaches. The TTAA sequence serves as a target site for transposon integration: insertion in the AT-rich DNA regions is more frequent. The ability of piggyBac to be transferred to a new area independently of the cell apparatus and to restore a DNA site without error after excision lies in the mechanism of its transposition, which is discussed in detail in the present review. Along with other transposons and viruses, the piggyBac transposon is widely used in the transgenesis of various organisms; it also finds application in insertion mutagenesis and gene therapy.     

Analysis of extrachromosomal Ac/Ds transposable elements

The mechanism of transposition of the maize Ac/Ds elements is not well understood. The true transposition intermediates are not known and it has not been possible to distinguish between excision models involving 8-bp staggered cuts or 1-bp staggered cuts followed by hairpin formation. In this work, we have analyzed extrachromosomal excision products to gain insight into the excision mechanism. Plasmid rescue was used to demonstrate that Ds excision is associated with the formation of circular molecules. In addition, we present evidence for the formation of linear extrachromosomal species during Ds excision. Sequences found at the termini of circular and linear elements showed a broad range of nucleotide additions or deletions, suggesting that these species are not true intermediates. Additional nucleotides adjacent to the termini in extrachromosomal elements were compared to the sequence of the original donor site. This analysis showed that: (1) the first nucleotide adjacent to the transposon end was significantly more similar to the first nucleotide flanking the element in the donor site than to a random sequence and (2) the second and farther nucleotides did not resemble the donor site. The implications of these findings for excision models are discussed.     

Molecular genetics of the chloramphenicol-resistance transposon Tn4451 from Clostridium perfringens: the TnpX site-specific recombinase excises a circular transposon molecule

The chloramphenicol-resistance transposon Tn4451 undergoes precise conjugative deletion from its parent plasmid piP401 in Clostridium perfringens and precise spontaneous excision from multicopy plasmids in Escherichia coli. The complete nucleotide sequence of the 6338 bp transposon was determined and it was found to encode six genes. Genetic analysis demonstrated that the largest Tn4451-encoded gene, tnpX, was required for the spontaneous excision of the transposon in both E. coli and C. perfringens, since a Tn4451 derivative that lacked a functional tnpX gene was completely stable in both organisms. Because the ability of this derivative to excise was restored by providing the tnpX gene on a compatible plasmid, it was concluded that this gene encoded a trans-acting site-specific recombinase. Allelic exchange was used to introduce the tnpXΔ allele onto plP401 and it was shown that TnpX was also required for the conjugative excision of Tn4451 in C. perfringens. It was also shown by hybridization and polymerase chain reaction (PCR) studies that TnpX-mediated transposon excision resulted in the formation of a circular form of the transposon. The TnpX recombinase was unique because it potentially contained the motifs of two independent site-specific recombinase families, namely the resolvase/invertase and integrase families. Sequence analysis indicated that the resolvase/invertase domain of TnpX was likely to be involved in the excision process by catalysing the formation of a 2bp staggered nick on either side of the GA dinucleotide located at the ends of the transposon and at the junction of the circular form. The other Tn4451-encoded genes include tnpZ, which appears to encode a second potential site-specific recombinase. This protein has similarity to plasmid-encoded Mob/Pre proteins, which are involved in plasmid mobilization and multimer formation. Located upstream of the tnpZ gene was a region with similarity to the site of interaction of these mobilization proteins.     

A paucity of palindromes in φX174

The nucleotide sequence of the bacteriophage φX174 contains surprisingly few restriction endonuclease recognition sites. The observed frequency of those sites which consist of a six-nucleotide palindromic sequence would occur by chance with a probability of less than 8 × 10^?5. The genome of φX174 does not contain the four-nucleotide palindromic recognition site for the enzyme MboI and this finding has a probability of only 1·7 × 10^?9. A further analysis of the nucleotide sequence revealed that there is a marked scarcity of palindromic sequences with a length of four or six nucleotides while all other palindromes occur with a frequency close to that dictated by chance. A preliminary analysis of the genomes of other DNA viruses indicated that this palindrome avoidance is associated with single-stranded viruses only. The reasons for the paucity of these short even-numbered palindromes remains to be determined.     

Tam3 in Antirrhinum majus is exceptional transposon in resistant to alteration by abortive gap repair: identification of nested transposons

Most transposon families consist of heterogeneous copies with varying sizes. In contrast, the Tam3 copies in Antirrhinum majus are known to have exceptionally conserved structures of uniform size. Gap repair has been reported to be involved in the structural alteration of copies from several transposon families. In this study, we have asked whether or not gap repair has affected Tam3 copies. Five Tam3 copies carrying aberrant sequences were selected from 40 independent Tam3 clones and their sequences were analyzed. Two of the five copies contain insertions in the Tam3 sequence. These two insertions, designated Tam356 and Tam661, are typical transposon-like sequences, which have terminal inverted repeats and cause target site duplication. These nested transposons were obviously associated with transpositional events, and did not originate from the gap-repair process. The remaining three copies had lost large parts of the Tam3 sequence. We could not find any relationship between the deletions of Tam3 sequence in the three copies and gap repair. PCR analysis of a Tam3 excision site in the nivea ^{recurrence:Tam3} mutant also showed that most of the repair events after the Tam3 excision involved end-joining. In addition to the results obtained here, among the other clones isolated, we could not find any of the internally deleted copies that comprise a major part of other transposon families. All of these data suggest that some feature of the Tam3 structure suppresses the structural alterations that are otherwise generated during the gap repair process. Received: 22 April 1998 / Accepted: 15 June 1998     

Precise and imprecise somatic excision of the transposon Tc1 in the nematode C. elegans.

Eleven chromosomal products of somatic excision of Tc1 transposable elements have been cloned and sequenced. The cloning method did not involve genetic reversion; therefore the products analyzed should be representative. Six empty religated target sites were from excision of one Tc1 element inserted near actin genes on linkage group V; five were from a second Tc1 element inserted elsewhere on the same linkage group. All six products from the first element were identical in sequence to an empty target site from a second strain, indicating excision had been precise. Two of the products from the second element were also precise, whereas the other three contained four extra nucleotides at the point of excision, indicating an imprecise excision. The four nucleotides are the same in all cases and could represent two terminal nucleotides of the transposon plus a two-nucleotide target site duplication. The difference in the ratio of precise to imprecise excision at the two insertion sites suggests a possible chromosomal position effect on the pathway of Tc1 somatic excision.     

Sequence Analysis of Amplified DNA Fragments Containing the Region Encoding the Putative Lipase Substrate-Binding Domain and Genotyping of Aeromonas hydrophila

DNA fragments were amplified by PCR from all tested strains of Aeromonas hydrophila, A. caviae, and A. sobria with primers designed based on sequence alignment of all lipase, phospholipase C, and phospholipase A1 genes and the cytotonic enterotoxin gene, all of which have been reported to have the consensus region of the putative lipase substrate-binding domain. All strains showed lipase activity, and all amplified DNA fragments contained a nucleotide sequence corresponding to the substrate-binding domain. Thirty-five distinct nucleotide sequence patterns and 15 distinct deduced amino acid sequence patterns were found in the amplified DNA fragments from 59 A. hydrophila strains. The deduced amino acid sequences of the amplified DNA fragments from A. caviae and A. sobria strains had distinctive amino acids, suggesting a species-specific sequence in each organism. Furthermore, the amino acid sequence patterns appear to differ between clinical and environmental isolates among A. hydrophila strains. Some strains whose nucleotide sequences were identical to one another in the amplified region showed an identical DNA fingerprinting pattern by repetitive extragenic palindromic sequence-PCR genotyping. These results suggest that A. hydrophila, and also A. caviae and A. sobria strains, have a gene encoding a protein with lipase activity. Homologs of the gene appear to be widely distributed in Aeromonas strains, probably associating with the evolutionary genetic difference between clinical and environmental isolates of A. hydrophila. Additionally, the distinctive nucleotide sequences of the genes could be attributed to the genotype of each strain, suggesting that their analysis may be helpful in elucidating the genetic heterogeneity of Aeromonas.     

Resistance to Nucleotide Excision Repair of Bulky Guanine Adducts Opposite Abasic Sites in DNA Duplexes and Relationships between Structure and Function

The nucleotide excision repair of certain bulky DNA lesions is abrogated in some specific non-canonical DNA base sequence contexts, while the removal of the same lesions by the nucleotide excision repair mechanism is efficient in duplexes in which all base pairs are complementary. Here we show that the nucleotide excision repair activity in human cell extracts is moderate-to-high in the case of two stereoisomeric DNA lesions derived from the pro-carcinogen benzo[a]pyrene (cis- and trans-B[a]P-N ²-dG adducts) in a normal DNA duplex. By contrast, the nucleotide excision repair activity is completely abrogated when the canonical cytosine base opposite the B[a]P-dG adducts is replaced by an abasic site in duplex DNA. However, base excision repair of the abasic site persists. In order to understand the structural origins of these striking phenomena, we used NMR and molecular spectroscopy techniques to evaluate the conformational features of 11mer DNA duplexes containing these B[a]P-dG lesions opposite abasic sites. Our results show that in these duplexes containing the clustered lesions, both B[a]P-dG adducts adopt base-displaced intercalated conformations, with the B[a]P aromatic rings intercalated into the DNA helix. To explain the persistence of base excision repair in the face of the opposed bulky B[a]P ring system, molecular modeling results suggest how the APE1 base excision repair endonuclease, that excises abasic lesions, can bind productively even with the trans-B[a]P-dG positioned opposite the abasic site. We hypothesize that the nucleotide excision repair resistance is fostered by local B[a]P residue—DNA base stacking interactions at the abasic sites, that are facilitated by the absence of the cytosine partner base in the complementary strand. More broadly, this study sets the stage for elucidating the interplay between base excision and nucleotide excision repair in processing different types of clustered DNA lesions that are substrates of nucleotide excision repair or base excision repair mechanisms.     

Tn554: Isolation and characterization of plasmid insertions

Tn554, a transposon in Staphylococcus aureus that carries determinants of spectinomycin resistance and inducible macrolide-lincosamide resistance, is characterized by a highly efficient transposition, exceptional site specificity for insertion, and inhibition of transposition by a copy of the transposon inserted at its preferred chromosomal site. In this communication we describe the characteristics of a number of rare, secondary-site insertions of Tn554 into several related penicillinase plasmids. These plasmid insertions display considerable variation in the frequencies with which they can act as transposon donors, as well as in the frequencies at which they undergo apparently precise excision. Transposition from the plasmid transposon donors is ordinarily a duplicative process and these subsequent transposition events always return Tn554 to its preferred site in the S. aureus chromosome; such derivatives are indistinguishable from the primary chromosomal insertion from which they were originally derived. We also report an unusual relationship between Tn554 and the transducing phage, φ11, in which Tn554 is frequently transferred independently of its plasmid carrier. We suggest that the bacteriophage may play an important role in the mobility of Tn554, in addition to the usual transduction mechanism, in a process that we have referred to as “hitchhiking.”     

Intragenomic variation in non-adaptive nucleotide biases causes underestimation of selection on synonymous codon usage

Patterns of non-uniform usage of synonymous codons vary across genes in an organism and between species across all domains of life. This codon usage bias (CUB) is due to a combination of non-adaptive (e.g. mutation biases) and adaptive (e.g. natural selection for translation efficiency/accuracy) evolutionary forces. Most models quantify the effects of mutation bias and selection on CUB assuming uniform mutational and other non-adaptive forces across the genome. However, non-adaptive nucleotide biases can vary within a genome due to processes such as biased gene conversion (BGC), potentially obfuscating signals of selection on codon usage. Moreover, genome-wide estimates of non-adaptive nucleotide biases are lacking for non-model organisms. We combine an unsupervised learning method with a population genetics model of synonymous coding sequence evolution to assess the impact of intragenomic variation in non-adaptive nucleotide bias on quantification of natural selection on synonymous codon usage across 49 Saccharomycotina yeasts. We find that in the absence of a priori information, unsupervised learning can be used to identify genes evolving under different non-adaptive nucleotide biases. We find that the impact of intragenomic variation in non-adaptive nucleotide bias varies widely, even among closely-related species. We show that the overall strength and direction of translational selection can be underestimated by failing to account for intragenomic variation in non-adaptive nucleotide biases. Interestingly, genes falling into clusters identified by machine learning are also physically clustered across chromosomes. Our results indicate the need for more nuanced models of sequence evolution that systematically incorporate the effects of variable non-adaptive nucleotide biases on codon frequencies.     

Precise marker excision system using an animal‐derived piggyBac transposon in plants

Accurate and effective positive marker excision is indispensable for the introduction of desired mutations into the plant genome via gene targeting (GT) using a positive/negative counter selection system. In mammals, the moth‐derived piggyBac transposon system has been exploited successfully to eliminate a selectable marker from a GT locus without leaving a footprint. Here, we present evidence that the piggyBac transposon also functions in plant cells. To demonstrate the use of the piggyBac transposon for effective marker excision in plants, we designed a transposition assay system that allows the piggyBac transposition to be visualized as emerald luciferase (Eluc) luminescence in rice cells. The Eluc signal derived from piggyBac excision was observed in hyperactive piggyBac transposase‐expressing rice calli. Polymerase chain reaction, Southern blot analyses and sequencing revealed the efficient and precise transposition of piggyBac in these calli. Furthermore, we have demonstrated the excision of a selection marker from a reporter locus in T₀ plants without concomitant re‐integration of the transposon and at a high frequency (44.0% of excision events), even in the absence of negative selection.     

A transposase-independent mechanism gives rise to precise excision of IS256 from insertion sites in Staphylococcus epidermidis

The mobile element IS256 causes phase variation of biofilm formation in Staphylococcus epidermidis by insertion and precise excision from the icaADBC operon. Precise excision, i.e., removal of the target site duplications (TSDs) and restoration of the original DNA sequence, occurs rarely but independently of functional transposase. Instead, the integrity of the TSDs is crucial for precise excision. Excision increased significantly when the TSDs were brought into closer spatial proximity, suggesting that excision is a host-driven process that might involve most likely illegitimate recombination.     

Nucleotide sequence and exact localization of the neomycin phosphotransferase gene from transposon Tn5

The nucleotide sequence of 1200 bp from the unique region of transposon Tn5 containing the neomycin phosphotransferase gene (neo) was determined, and the location of the neo gene was identified by deletion mutants in a translational reading frame of 792 bp. The derived gene product, an aminoglycoside 3′-phosphotransferase (APH) II, consists of 264 amino acid residues and has a calculated M_r of 29053. Its amino acid sequence shows sequence homologies to the APH type I enzyme coded for by transposon Tn903 (Oka et al., 1981).     

Multilocus Sequence Typing of Lactobacillus casei Reveals a Clonal Population Structure with Low Levels of Homologous Recombination

Robust genotyping methods for Lactobacillus casei are needed for strain tracking and collection management, as well as for population biology research. A collection of 52 strains initially labeled L. casei or Lactobacillus paracasei was first subjected to rplB gene sequencing together with reference strains of Lactobacillus zeae, Lactobacillus rhamnosus, and other species. Phylogenetic analysis showed that all 52 strains belonged to a single compact L. casei-L. paracasei sequence cluster, together with strain CIP107868 (= ATCC 334) but clearly distinct from L. rhamnosus and from a cluster with L. zeae and CIP103137^T (= ATCC 393^T). The strains were genotyped using amplified fragment length polymorphism, multilocus sequence typing based on internal portions of the seven housekeeping genes fusA, ileS, lepA, leuS, pyrG, recA, and recG, and tandem repeat variation (multilocus variable-number tandem repeats analysis [MLVA] using nine loci). Very high concordance was found between the three methods. Although amounts of nucleotide variation were low for the seven genes (π ranging from 0.0038 to 0.0109), 3 to 12 alleles were distinguished, resulting in 31 sequence types. One sequence type (ST1) was frequent (17 strains), but most others were represented by a single strain. Attempts to subtype ST1 strains by MLVA, ribotyping, clustered regularly interspaced short palindromic repeat characterization, and single nucleotide repeat variation were unsuccessful. We found clear evidence for homologous recombination during the diversification of L. casei clones, including a putative intragenic import of DNA into one strain. Nucleotides were estimated to change four times more frequently by recombination than by mutation. However, statistical congruence between individual gene trees was retained, indicating that recombination is not frequent enough to disrupt the phylogenetic signal. The developed multilocus sequence typing scheme should be useful for future studies of L. casei strain diversity and evolution.     

Genetic organization and transposition properties of IS511

IS511 is an endogenous insertion sequence (IS) of the bacterium Caulobactercrescentus strain CB15 and it is the first Caulobacter IS to be characterized at the molecular level. We determined the 1266-bp nucleotide sequence of IS511 and investigated its genetic organization, relationship to other ISs, and transposition properties. IS511 belongs to a distinct branch of the IS3 family that includes ISRI, IS476, and IS1222, based on nucleotide sequence similarity. The nucleotide sequence of IS511 encodes open reading frames (orfs) designated here as orfA and orfB, and their relative organization and amino acid sequences of the predicted protein products are very similar to those of orfAs and orfBs of other IS3 family members. Nuclease S1 protection assays identified an IS511 RNA, and its 5′ end maps approximately 16 nucleotides upstream of orfA and about six nucleotides downstream of a sequence that is similar to the consensus sequence of C. crescentus housekeeping promoters. Evidence is presented that IS511 is capable of precise excision from the chromosome, and transposition from the chromosome to a plasmid. Transpositional insertions of IS511 occurred within sequences with a relatively high G?+?C content, and they were usually, but not always, flanked by a 4-bp direct repeat that matches a sequence at the site of insertion. We also determined the nucleotide sequence flanking the four endogenous IS511 elements that reside in the chromosome of C. crescentus. Our findings demonstrate that IS511 is a transposable IS that belongs to a branch of the IS3 family.