DNA sequence requirements for hobo transposable element transposition in Drosophila melanogaster

We have conducted a structure and functional analysis of the hobo transposable element of Drosophila melanogaster. A minimum of 141 bp of the left (L) end and 65 bp of the right (R) end of the hobo were shown to contain sequences sufficient for transposition. Both ends of hobo contain multiple copies of the motifs GGGTG and GTGGC and we show that the frequency of hobo transposition increases as a function of the copy number of these motifs. The R end of hobo contains a unique 12 bp internal inverted repeat that is identical to the hobo terminal inverted repeats. We show that this internal inverted repeat suppresses transposition activity in a hobo element containing an intact L end and only 475 bp of the R end. In addition to establishing cis-sequences requirements for transposition, we analyzed trans-sequence effects of the hobo transposase. We show a hobo transposase lacking the first 49 amino acids catalyzed hobo transposition at a higher frequency than the full-length transposase suggesting that, similar to the related Ac transposase, residues at the amino end of the transposase reduce transposition. Finally, we compared target site sequences of hobo with those of the related Hermes element and found both transposons have strong preferences for the same insertion sites.     

Identification of a new hobo element in the cabbage moth, Mamestra brassicae (Lepidoptera)

A complete hobo-like element, called Mbhobo, was identified in the cabbage moth, Mamestra brassicae. This element has a high sequence similarity to the HFL1 hobo element of Drosophila melanogaster. Amplification of Mbhobo termini indicated that transposition occurred into a 5'-GTGGGTAC-3' target sequence that was duplicated upon insertion. This target site conforms to the consensus sequence established for the insertion sites of insect hAT elements. Mbhobo has a single 1935 bp long ORF with significant homology to the D. melanogaster HFL1 hobo transposase. FISH experiments evidenced Mbhobo clusters located in heterochromatic regions of Z and W sex chromosomes and in heterochromatic areas of chromosome pair 10.     

Molecular architecture of a eukaryotic DNA transposase

Mobile elements and their inactive remnants account for large proportions of most eukaryotic genomes, where they have had central roles in genome evolution. Over 50 years ago, McClintock reported a form of stress-induced genome instability in maize in which discrete DNA segments move between chromosomal locations. Our current mechanistic understanding of enzymes catalyzing transposition is largely limited to prokaryotic transposases. The Hermes transposon from the housefly is part of the eukaryotic hAT superfamily that includes hobo from Drosophila, McClintock's maize Activator and Tam3 from snapdragon. We report here the three-dimensional structure of a functionally active form of the transposase from Hermes at 2.1-A resolution. The Hermes protein has some structural features of prokaryotic transposases, including a domain with a retroviral integrase fold. However, this domain is disrupted by the insertion of an additional domain. Finally, transposition is observed only when Hermes assembles into a hexamer.     

Structure and evolution of the hAT transposon superfamily.

The maize transposon Activator (Ac) was the first mobile DNA element to be discovered. Since then, other elements were found that share similarity to Ac, suggesting that it belongs to a transposon superfamily named hAT after hobo from Drosophila, Ac from maize, and Tam3 from snapdragon. We addressed the structure and evolution of hAT elements by developing new tools for transposon mining and searching the public sequence databases for the hallmarks of hAT elements, namely the transposase and short terminal inverted repeats (TIRs) flanked by 8-bp host duplications. We found 147 hAT-related sequences in plants, animals, and fungi. Six conserved blocks could be identified in the transposase of most hAT elements. A total of 41 hAT sequences were flanked by TIRs and 8-bp host duplications and, out of these, 34 sequences had TIRs similar to the consensus determined in this work, suggesting that they are active or recently active transposons. Phylogenetic analysis and clustering of hAT sequences suggest that the hAT superfamily is very ancient, probably predating the plant-fungi-animal separation, and that, unlike previously proposed, there is no evidence that horizontal gene transfer was involved in the evolution of hAT elements.     

Identification of a full-size hobo element and deletion-derivatives in Korean populations of Drosophila melanogaster.

We have isolated and characterized several members of the hobo transposable element family from Korean populations of Drosophila melanogaster. All of the Korean lines tested appeared to have 3.0 kb hobo elements and a high copy number of smaller derivatives of the element. To determine whether a 3.0 kb hobo element of these populations is consistent with the role of an autonomous hobo element, we cloned and sequenced this hobo element. Based on the result of the entire DNA sequence, a cloned 3.0 kb element called HKN96, it was found to be the same as a fully-functional 2959 bp HFL1-type sequence. Each small element appeared to have arisen from the HFL1 element by a different internal deletion. A specific 1.7 kb Kh hobo element, which is the most abundant in the Korean lines tested, seems to have originated from the HFL1 hobo element by an internal deletion of 1253 bp by the removal of nucleotides between positions 939 and 2191. The sequences of the Th1 and Th2 elements appeared to be identical to that of the HFL1 with the exception of internal deletions of 1442 bp and 1455 bp removing nucleotides 940-2381 and 923-2377, respectively. Based on the number of TPE repeats, all of the members of the hobo element family in Korean lines tested have three perfect S repeats. The widespread presence of identical copies of the Kh deletion derivative suggests that it might have a role in the regulation of hobo-induced hybrid dysgenesis.     

Cloning and expression of a gene from Streptomyces scabies encoding a putative pathogenicity factor.

We cloned a 9.4-kb DNA fragment from Streptomyces scabies ATCC 41973 that allows the nonpathogen Streptomyces lividans 66 TK24 to necrotize and colonize potato tuber slices and produce scab-like symptoms on potato minitubers. Deletion analysis demonstrated that activity was conferred by a 1.6-kb DNA region. Sequence analysis of a 2.4-kb DNA fragment spanning the DNA region necessary for activity revealed three open reading frames (ORFs). The deduced amino acid sequence of ORF1, designated ORFtnp, showed high levels of identity with the first 233 amino acids of the putative transposases of the IS1164 elements from Rhodococcus rhodochrous (71%) and Mycobacterium bovis (68%), members of the Staphylococcus aureus IS256 family of transposases. No significant homologies to ORF2 and ORF3 were found in the nucleic acid and protein databases. ORFtnp is located 5' of ORF3. ORF2 is incomplete and is located 3' of ORF3. Subcloning of the individual ORFs demonstrated that ORF3, designated nec1, is sufficient for necrotizing activity in S. lividans 66 TK24. S. lividans 66 TK24 expressing nec1 does not produce thaxtomin A but produces an unidentified extracellular water-soluble compound that causes necrosis on potato tuber discs. The G+C content of nec1 suggests that it has moved horizontally from another genus. Southern analysis of ORFtnp and nec1 demonstrate that these genes are physically linked in Streptomyces strains, including S. scabies and Streptomyces acidiscabies strains, that are pathogenic on potato and that produce the phytotoxin thaxtomin A. These data suggest that nec1 may have been mobilized into S. scabies through a transposition event mediated by ORFtnp.     

Transposition of the Tol2 element, an Ac-like element from the Japanese medaka fish Oryzias latipes, in mouse embryonic stem cells

The Tol2 transposable element of the Japanese medaka fish belongs to the hAT family of transposons including hobo of Drosophila, Ac of maize, and Tam3 of snapdragon. To date, Tol2 is the only natural transposon in vertebrates that has ever been shown to encode a fully functional transposase. It has not been known, however, whether Tol2 can transpose in vertebrates other than fish. We report here transposition of Tol2 in mouse embryonic stem (ES) cells. We constructed a transposon donor plasmid containing a nonautonomous Tol2 element with the neomycin resistance gene and a helper plasmid capable of expressing the transposase and introduced the donor plasmid with various amounts of the helper plasmid by electroporation into mouse ES cells. The number of G418-resistant ES colonies increased as the amount of helper plasmid was increased, in a dose-dependent manner, indicating that the transposase activity elevated the integration efficiency. These G418-resistant ES colonies were cloned and the structure of the junction of the integrated Tol2 element and the genomic DNA was analyzed by inverse PCR. In those clones, Tol2 was surrounded by mouse genomic sequences and an 8-bp direct repeat was created adjacent to both ends of Tol2, indicating that Tol2 was integrated in the genome through transposition. The Tol2 transposon system is thus active in mouse as well as in fish. We propose that it should be used as a genetic tool to develop novel gene transfer, transgenesis, and mutagenesis methods in mammals.     

DNA sequence of IS91 and identification of the transposase gene.

IS91 is a 1,830-bp insertion sequence that inserts specifically at the sequence CAAG or GAAC of the target and does not duplicate any sequence upon insertion (23). By transposon mutagenesis, we have identified open reading frame 426 (ORF426; bp 454 to 1731) as the putative ORF for the transposase. It displays a cysteine-rich, potential metal-binding domain in its N-terminal region. Adjacent to ORF426, there is an ORF (ORF121) which precedes and terminally overlaps ORF426 by one amino acid. Tn1732 insertions in ORF121 do not affect the transposition frequency. IS91 has sequence similarities to IS801 from Pseudomonas syringae. Their putative transposases are 36% identical, including conservation of the cysteine-rich cluster. The information concerning IS801 insertion specificity and target duplication has been reevaluated in the light of our results.     

Presence of a characteristic D-D-E motif in IS1 transposase

Transposases encoded by various transposable DNA elements and retroviral integrases belong to a family of proteins with three conserved acidic amino acids, D, D, and E, constituting the D-D-E motif that represents the active center of the proteins. IS1, one of the smallest transposable elements in bacteria, encodes a transposase which has been thought not to belong to the family of proteins with the D-D-E motif. In this study, we found several IS1 family elements that were widely distributed not only in eubacteria but also in archaebacteria. The alignment of the transposase amino acid sequences from these IS1 family elements showed that out of 14 acidic amino acids present in IS1 transposase, three (D, D, and E) were conserved in corresponding positions in the transposases encoded by all the elements. Comparison of the IS1 transposase with other proteins with the D-D-E motif revealed that the polypeptide segments surrounding each of the three acidic amino acids were similar. Furthermore, the deduced secondary structures of the transposases encoded by IS1 family elements were similar to one another and to those of proteins with the D-D-E motif. These results strongly suggest that IS1 transposase has the D-D-E motif and thus belongs to the family of proteins with the D-D-E motif. In fact, mutant IS1 transposases with an amino acid substitution for each of the three acidic amino acids possibly constituting the D-D-E motif were not able to promote transposition of IS1, supporting this hypothesis. The D-D-E motif identified in IS1 transposase differs from those in the other proteins in that the polypeptide segment between the second D and third E in IS1 transposase is the shortest, 24 amino acids in length. Because of this difference, the presence of the D-D-E motif in IS1 transposase has not been discovered for some time.     

HB mobile element in the Drosophila melanogaster genome: structural and functional analyses

The structure was analyzed for 60 annotated copies of the mobile genetic element (MGE) HB from the Drosophila melanogaster genome. The genomic distribution of HB copies was studied, and preferential insertion sites (hot spots) were identified, which presumably amount to several kilobases. Structural analysis of the open reading frame (ORF) and terminal repeats of HB was performed. All 26 HB copies retaining the ORF sequence have a stop codon in the same position. Consequently, the HB ORF proved indeed to code for an enzyme of 148 amino acid residues, relatively small for Tc1-family transposases. The ORF consensus sequence was established. HB{}1185 was identified as the only HB copy potentially coding for a functional protein. All 37 repeat-containing HB copies were analyzed. Of these, only four had functional terminal sequences, lacking, however, a functional transposase gene. A new 7762-bp copy of MGE roo was found in the D. melanogaster genome; the copy was earlier unavailable from databases and represents an insert in the HB{}1605 sequence.     

DNA sequence of the control region of phage D108: the N-terminal amino acid sequences of repressor and transposase are similar both in phage D108 and in its relative, phage Mu.

We have determined the DNA sequence of the control region of phage D108 up to position 1419 at the left end of the phage genome. Open reading frames for the repressor gene, ner gene, and the 5' part of the A gene (which codes for transposase) are found in the sequence. The genetic organization of this region of phage D108 is quite similar to that of phage Mu in spite of considerable divergence, both in the nucleotide sequence and in the amino acid sequences of the regulatory proteins of the two phages. The N-terminal amino acid sequences of the transposases of the two phages also share only limited homology. On the other hand, a significant amino acid sequence homology was found within each phage between the N-terminal parts of the repressor and transposase. We propose that the N-terminal domains of the repressor and transposase of each phage interact functionally in the process of making the decision between the lytic and the lysogenic mode of growth.     

Low transposition frequency of the medaka fish Tol2 element may be due to extranuclear localization of its transposase

Transposase proteins of some highly active DNA-based transposable elements, such as the maize Activator element, are known to possess nuclear localization signals (NLSs). We examined if this is also the case for the transposase of the medaka fish Tol2 element, a member of the hAT (hobo/Activator/Tam3) transposable element family, using human and mouse culture cells. Unexpectedly, the transposase-lacZ fusion protein, in which the lacZ is a location marker, was found to be present in the cytoplasm rather than in the nucleus, suggesting that the Tol2 transposase contains a signal for extranuclear localization. The same staining pattern was also observed with a fusion protein containing a 33-amino-acid region at about the center of the primary structure of the transposase. The Tol2 element might have a mechanism to control its transposition frequency that includes extranuclear localization of its transposase.     

Three new insertion sequence elements ISLdl2, ISLdl3, and ISLdl4 in Lactobacillus delbrueckii: isolation,molecular characterization,and potential use for strain identification

A group of new insertion sequence (IS) elements, ISLdl2, ISLdl3, and ISLdl4, from Lactobacillus delbrueckii subsp. lactis ATCC 15808 was isolated, characterized, and used for strain identification together with ISLdl1, recently characterized as an L. delbrueckii IS element belonging to the ISL3 family. ISLdl2 was 1367 bp in size and had a 24 bp IR and an 8 bp DR. The single ORF of ISLdl2 encoded a protein of 392 aa similar to transposases of the IS256 family. ISLdl3 had a single ORF encoding a protein of 343 aa similar to transposases of the IS30 family. Finally, ISLdl4 had a single ORF encoding a protein of 406 aa and displayed homology to the transposases of the IS110 family. ISLdl4 was only slight different from ISL4 (Accession No. AY040213). ISLdl1, ISLdl2, and ISLdl4 were present in all of the 10 L. delbrueckii subsp. lactis and subsp. delbrueckii strains tested, as well as in three of the 11 L. delbrueckii subsp. bulgaricus strains tested. ISLdl3 was present only in four closely related strains of L. delbrueckii subsp. lactis. These IS elements were not observed in Lactobacillus rhamnosus, Lactobacillus acidophilus, Lactobacillus helveticus, or Lactobacillus plantarum. A cluster of IS elements, ISLdl1, ISLdl2, ISLdl3, ISLdl4, and ISL6, was observed in L. delbrueckii subsp. lactis strain ATCC 15808. Within this cluster, ISLdl4 was inserted into ISLdl1 between the left IR and the start codon of ORF455, encoding a putative transposase. Most of the integration sites of the IS elements were strain-specific. We have observed that IS elements can migrate from one strain to another as integral parts of bacterial DNA by using phage LL-H as a vehicle. We demonstrate for the first time that inverse PCR and vectorette PCR methods with primers based on sequences of the IS elements could be used for identification of L. delbrueckii strains.     

The structure of hobo transposable elements and their insertion sites

The hobo transposable elements of Drosophila form a family of 3.0-kb elements and their deletion derivatives. Their distribution is consistent with the model that 3.0-kb elements are functionally complete but that smaller hobos are defective and require complete elements in trans for transposition. The sequence of one 3.0-kb element is presented; it has several interesting features, including a 1.9-kb open reading frame downstream from potential TATA and CAT sequences. Comparison of 11 independent insertion sites shows that in every case the hobo element has integrated at and duplicated either the sequence NNNNNNAC or CTTTNNNN. There is evidence that an eight nucleotide sequence internal to hobo that matches both of these sequences has been used as an insertion site for a second hobo element, as the first step in the creation of an internal deletion derivative. Structural similarities between hobo and the eukaryotic transposable elements P, Ac, 1723, and Tam3, found in widely divergent host organisms, suggest that they all transpose by a common mechanism.     

Construction of hybrid Tn501/Tn21 transposases in vivo: identification of a region of transposase conferring specificity of recognition of the 38-bp terminal inverted repeats.

In order to study the transposase enzymes of Class II prokaryotic transposable elements, we have constructed genes encoding hybrid transposase proteins. This was done by recombination in vivo between the tnpA genes of transposons Tn501 and Tn21. These hybrid genes can complement in trans a transposition-defective mutant of Tn501. The structures of the products of this complementation indicate whether the specificity of the hybrid transposase in recognising the 38 bp terminal inverted repeats is that of Tn501 or that of Tn21. The determinant of this specificity is in the N-terminal region of the transposase protein, between amino acids 28 and 216. The predicted amino acid sequences so far determined of transposases from the Class II family reveal an area of homology in this region.     

Identification of a fully-functional hobo transposable element and its use for germ-line transformation of Drosophila.

The transposable element hobo can be mobilized to induce a variety of genetic abnormalities within the germ-line of Drosophila melanogaster. Strains containing hobos have 3.0 kb elements and numerous smaller derivatives of the element. By analogy with other transposable element systems, it is likely that only the 3.0 kb elements are capable of inducing hobo mobilization. Here, we report that a cloned 3.0 kb hobo, called HFL1, is able to mediate germ-line transformation and therefore is an autonomous (fully-functional) transposable element. Germ-line transformation was observed when HFL1 and a marked hobo element were co-injected into recipient embryos devoid of endogenous hobos. Integration did not occur in the absence of the 3.0 kb element. A single copy of the marked hobo transposon inserted at each site, and the target sites were widely distributed throughout the genome. Integration occurred at (or very near) the termini of hobo, without internal rearrangement of the hobo or marker gene sequences. The hobo transformation system will allow us to determine the structural and regulatory features of hobo responsible for its mobilization and will provide novel approaches for the molecular and genetic manipulation of the Drosophila genome.     

A comparative study of Tam3 and Ac transposition in transgenic tobacco and petunia plants

Transposition of the Anthirrinum majus Tam3 element and the Zea mays Ac element has been monitored in petunia and tobacco plants. Plant vectors were constructed with the transposable elements cloned into the leader sequence of a marker gene. Agrobacterium tumefaciens-mediated leaf disc transformation was used to introduce the transposable element constructs into plant cells. In transgenic plants, excision of the transposable element restores gene expression and results in a clearly distinguishable phenotype. Based on restored expression of the hygromycin phosphotransferase II (HPTII) gene, we established that Tam3 excises in 30% of the transformed petunia plants and in 60% of the transformed tobacco plants. Ac excises from the HPTII gene with comparable frequencies (30%) in both plant species. When the -glucuronidase (GUS) gene was used to detect transposition of Tam3, a significantly lower excision frequency (13%) was found in both plant species. It could be shown that deletion of parts of the transposable elements Tam3 and Ac, removing either one of the terminal inverted repeats (TIR) or part of the presumptive transposase coding region, abolished the excision from the marker genes. This demonstrates that excision of the transposable element Tam3 in heterologous plant species, as documented for the autonomous element Ac, also depends on both properties. Southern blot hybridization shows the expected excision pattern and the reintegration of Tam3 and Ac elements into the genome of tobacco plants.     

Unexpected diversity and differential success of DNA transposons in four species of entamoeba protozoans

We report the first comprehensive analysis of transposable element content in the compact genomes (approximately 20 Mb) of four species of Entamoeba unicellular protozoans for which draft sequences are now available. Entamoeba histolytica and Entamoeba dispar, two human parasites, have many retrotransposons, but few DNA transposons. In contrast, the reptile parasite Entamoeba invadens and the free-living Entamoeba moshkovskii contain few long interspersed elements but harbor diverse and recently amplified populations of DNA transposons. Representatives of three DNA transposase superfamilies (hobo/Activator/Tam3, Mutator, and piggyBac) were identified for the first time in a protozoan species in addition to a variety of members of a fourth superfamily (Tc1/mariner), previously reported only from ciliates and Trichomonas vaginalis among protozoans. The diversity of DNA transposons and their differential amplification among closely related species with similar compact genomes are discussed in the context of the biology of Entamoeba protozoans.