A Chimeric Ty3/Moloney Murine Leukemia Virus Integrase Protein Is Active In Vivo

This report describes the results of experiments to determine whether chimeras between a retrovirus and portions of Ty3 are active in vivo. A chimera between Ty3 and a Neo^r-marked Moloney murine leukemia virus (M-MuLV) was constructed. The C-terminal domain of M-MuLV integrase (IN) was replaced with the C-terminal domain of Ty3 IN. The chimeric retroviruses were expressed from an amphotrophic envelope packaging cell line. The virus generated was used to infect the human fibrosarcoma cell line HT1080, and cells in which integration had occurred were selected by G418 resistance. Three independently integrated viruses were rescued. In each case, the C-terminal Ty3 IN sequences were maintained and short direct repeats of the genomic DNA flanked the integration site. Sequence analysis of the genomic DNA flanking the insertion did not identify a tRNA gene; therefore, these integration events did not have Ty3 position specificity. This study showed that IN sequences from the yeast retrovirus-like element Ty3 can substitute for M-MuLV IN sequences in the C-terminal domain and contribute to IN function in vivo. It is also one of the first in vivo demonstrations of activity of a retrovirus encoding an integrase chimera. Studies of chimeras between IN species with distinctive integration patterns should complement previous work by expanding our understanding of the roles of nonconserved domains.     

Isolation and characterization of a Ty element inserted into the ribosomal DNA of the yeast Saccharomyces cerevisiae.

The yeast Saccharomyces cerevisiae has about 30 to 50 copies of a transposable element Ty. Most of these elements are located at the 5' ends of protein coding sequences and are flanked by a 5 bp duplication. We report below an insertion of a Ty element into one of the repeated ribosomal RNA (rRNA) genes of yeast. The element is located between the 3' ends of the divergentally transcribed 37S and 5S rRNA's and is not flanked by a 5 bp duplication. In addition, one end of the Ty insertion is contiguous with a 306 bp deletion of the sequences of the rRNA gene. We find that this insertion, unlike most Ty insertions, is mitotically unstable.     

Ty1 Transposition in Saccharomyces Cerevisiae Is Nonrandom

A large collection of Ty1 insertions in the URA3 and LYS2 loci was generated using a GAL1-Ty1 fusion to augment the transposition frequency. The sites of insertion of most of these Ty elements were sequenced. There appears to be a gradient of frequency of insertion from the 5' end (highest frequency) to the 3' end (lowest frequency) of both loci. In addition we observed hotspots for transposition. Twelve of the 82 Ty1 insertions in the URA3 locus were inserted in exactly the same site. Hotspots were also observed in the LYS2 locus. All hotspots were in the transcribed part of the genes. Alignment of the sites of insertion and of the neighboring sequences only reveals very weak sequence similarities.     

Mitotic and Meiotic Gene Conversion of Ty Elements and Other Insertions in Saccharomyces Cerevisiae

We examined meiotic and mitotic gene conversion events involved in deletion of Ty elements and other insertions from the genome of the yeast Saccharomyces cerevisiae. We found that Ty elements and one other insertion were deleted by mitotic gene conversion less frequently than point mutations at the same loci. One non-Ty insertion similar in size to Ty, however, did not show this bias. Mitotic conversion events deleting insertions were more frequently associated with crossing over than those deleting point mutations. In meiosis, conversion events duplicating the element were more common than those that deleted the element for one of the loci (HIS4) examined.     

'Calling Cards' method for high-throughput identification of targets of yeast DNA-binding proteins

We present a protocol for a novel method for identifying the targets of DNA-binding proteins in the genome of the yeast Saccharomyces cerevisiae. This is accomplished by engineering a DNA-binding protein so that it leaves behind in the genome a permanent mark -- a 'calling card' -- that provides a record of that protein's visit to that region of the genome. The calling card is the yeast Ty5 retrotransposon, whose integrase interacts with the Sir4 protein. If Sir4 is fused to a DNA-binding protein, it recruits the Ty5 integrase, which directs insertion of a Ty5 calling card into the genome. The calling card along with the flanking genomic DNA is harvested by inverse PCR and its genomic location is determined by hybridization of the product to a DNA microarray. This method provides a straightforward alternative to the 'ChIP-chip' method for determining the targets of DNA-binding proteins. This protocol takes approximately 2 weeks to complete.     

Mutational analysis of att554, the target of the site-specific transposon Tn554.

Tn554 is a high-frequency, site-specific transposable element of Staphylococcus aureus which has integrative properties resembling those of temperate bacteriophages. Tn554 inserts at a unique chromosomal location, designated att554. att554 contains a core hexanucleotide sequence, 5'-GATGTA-3' (nucleotides numbered -3 to +3). Most of the time (greater than 99%) insertion occurs immediately 3' to this sequence; the resulting orientation of Tn554 to att554 is designated as the (+) orientation. Infrequent insertions immediately 5' to the core sequence result in the opposite, or (-) orientation. Mutational analysis of a cloned att554 site indicates that deletions extending from the left and ending at -15 or from the right ending between +8 and +12 reduced attachment site efficiency. Plasmids with deletions extending closer to the insertion site, although still retaining the core sequence from -3 to +3, were totally inactive. Tn554 insertions into partially active att554 sites retained normal site- and orientation-specificity with respect to att554, but they frequently contained abnormal sequences at the junction of att554 and the 3' end of Tn554. These data indicate that att554 contains a short nucleotide sequence essential for transposition and flanking sequences that greatly increase the frequency of recombination.     

Human U1 RNA pseudogenes may be generated by both DNA- and RNA-mediated mechanisms.

Analysis of cloned human genomic loci homologous to the small nuclear RNA U1 established that such sequences are abundant and dispersed in the human genome and that only a fraction represent bona fide genes. The majority of genomic loci bear defective gene copies, or pseudogenes, which contain scattered base mismatches and in some cases lack the sequence corresponding to the 3' end of U1 RNA. Although all of the U1 genes examined to date are flanked by essentially identical sequences and therefore appear to comprise a single multigene family, we present evidence for the existence of at least three structurally distinct classes of U1 pseudogenes. Class I pseudogenes had considerable flanking sequence homology with the U1 gene family and were probably derived from it by a DNA-mediated event such as gene duplication. In contrast, the U1 sequence in class II and III U1 pseudogenes was flanked by single-copy genomic sequences completely unrelated to those flanking the U1 gene family; in addition, short direct repeats flanked the class III but not the class II pseudogenes. We therefore propose that both class II and III U1 pseudogenes were generated by an RNA-mediated mechanism involving the insertion of U1 sequence information into a new chromosomal locus. We also noted that two other types of repetitive DNA sequences in eucaryotes, the Alu family in vertebrates and the ribosomal DNA insertions in Drosophila, bore a striking structural resemblance to the classes of U1 pseudogenes described here and may have been created by an RNA-mediated insertion event.     

Transposable elements associated with constitutive expression of yeast alcohol dehydrogenase II

The yeast structural gene ADR2, coding for the glucose-repressible alcohol dehydrogenase (ADHII), has been isolated by complementation of function in transformed yeast. The chromosomal DNA from nine yeast strains with cis-dominant constitutive mutations (ADR3^c) has been investigated by restriction enzyme analysis, using the cloned ADR2 DNA as a hybridization probe. Seven mutants appear to have insertions of approximately 5.6 kb near the 5′ end of the ADR2-coding region. Four of these insertions have the same restriction pattern as the yeast transposable element Tyl. Two differ from Tyl by the presence of an additional Hind III site, and a seventh insertion differs from Tyl at a number of restriction sites. All are inserted in the same orientation with respect to the structural gene. A DNA fragment containing the ADR2 gene and adjacent sequences from a constitutive mutant has been cloned and shown by heteroduplex analysis to contain an insertion near the 5′ end of the structural gene. The cloned insertion sequence hybridizes to multiple genomic DNA fragments, indicating that it contains a moderately repetitive sequence. Thus it appears that insertion of a transposable element near the 5′ terminus of the structural gene can produce constitutive expression of a normally glucose-repressed enzyme. Such insertions seem to be the most common way of generating cis-dominant constitutive mutations of ADHII.     

Mu1-Related Transposable Elements of Maize Preferentially Insert into Low Copy Number DNA

The Mutator transposable element system of maize was originally identified through its induction of mutations at an exceptionally high frequency and at a wide variety of loci. The Mu1 subfamily of transposable elements within this system are responsible for the majority of Mutator-induced mutations. Mu 1-related elements were isolated from active Mutator plants and their flanking DNA was characterized. Sequence analyses revealed perfect nine base target duplications directly flanking the insert for 13 of the 14 elements studied. Hybridizational studies indicated that Mu1-like elements insert primarily into regions of the maize genome that are of low copy number. This preferential selection of low copy number DNA as targets for Mu element insertion was not directed by any specific secondary structure(s) that could be detected in this study, but the 9-bp target duplications exhibited a discernibly higher than random match with the consensus sequence 5'-G-T-T-G-G/C-A-G-G/A-G-3'.     

Polymorphism in the structure of the yeast mitochondrial tRNA synthesis locus.

Yeast mitochondrial DNA contains a genetic locus, called the tRNA synthesis locus, which codes for information necessary for mitochondrial tRNA biosynthesis. A 9S RNA molecule coded by this locus is thought to be the trans-acting element required for the removal of 5' extensions from tRNA precursors. The DNA coding for this RNA maps to a region of mitochondrial DNA known to contain strain specific restriction site polymorphisms. Comparison of the tRNA synthesis locus in two such strains by sequence analysis demonstrates that the restriction enzyme polymorphisms are due to the deletion/insertion of a 50 base pair GC-rich element in the 5' flanking sequence of the 9S RNA coding region. There are also several differences between the 9S RNA coding region of these two strains which do not interfere with the tRNA synthesis function.     

Multimeric arrays of the yeast retrotransposon Ty.

We have identified a novel integrated form of the yeast retrotransposon Ty consisting of multiple elements joined into large arrays. These arrays were first identified among Ty-induced alpha-pheromone-resistant mutants of MATa cells of Saccharomyces cerevisiae which contain Ty insertions at HML alpha that result in the expression of that normally silent cassette. These insertions are multimeric arrays of both the induced genetically marked Ty element and unmarked Ty elements. Structural analysis of the mutations indicated that the arrays include tandem direct repeats of Ty elements separated by only a single long terminal repeat. The Ty-HML junction fragments of one mutant were cloned and shown to contain a 5-base-pair duplication of the target sequence that is characteristic of a Ty transpositional insertion. In addition, the arrays include rearranged Ty elements that do not have normal long terminal repeat junctions. We have also identified multimeric Ty insertions at other chromosomal sites and as insertions that allow expression of a promoterless his3 gene on a plasmid. The results suggest that Ty transposition includes an intermediate that can undergo recombination to produce multimers.     

Characterization and distribution of IS8301 in the radioresistant bacterium Deinococcus radiodurans

The insertion sequence element IS8301 isolated from the radiation resistant bacterium Deinococcus radiodurans strain KD8301 was characterized. IS8301 is comprised of 1,736-bp, lacks terminal inverted repeats and does not duplicate target DNA upon its insertion. The amino acid sequence homology of two open reading frames encoded in IS8301 indicates that this insertion sequence element belongs to the IS200/IS605 group. There were seven loci completely identical with the IS8301 sequence in the published D. radiodurans R(1) genome sequence. The genome distribution profiles of IS8301 in strain KD8301 as well as in the three different laboratory isolates (KR(1), MR(1), and R(1)) of wild-type D. radiodurans were investigated using genomic hybridization analysis. At least 21 strong hybridization signals were detected in strain KD8301 while only one hybridization signal was detected in strain KR(1), the parent strain of KD8301. In strain MR1, a different wild-type isolate, six strong hybridization signals were detected. In spite of the identification of seven copies of IS8301 in the published D. radiodurans R(1) genome sequence, only one hybridization signal was detected in strain R(1) purchased from American Type Culture Collection. Using inverse PCR and sequencing analyses, total 13 different insertion loci of IS8301 in the D. radiodurans genome were identified. Sequence comparison of the flanking region of insertion sites indicated that the sequence 5'-TTGAT-3' preceded the left end of IS8301 in all cases.     

Frameshift suppressor mutations affecting the major glycine transfer RNAs of Saccharomyces cerevisiae

Mutations have been identified in Saccharomyces cerevisiae glycine tRNA genes that result in suppression of +1 frameshift mutations in glycine codons. Wild-type and suppressor alleles of genes encoding the two major glycine tRNAs, tRNA(GCC) and tRNA(UCC), were examined in this study. The genes were identified by genetic complementation and by hybridization to a yeast genomic library using purified tRNA probes. tRNA(UCC) is encoded by three genes, whereas approximately 15 genes encode tRNA(GCC). The frameshift suppressor genes suf1+, suf4+ and suf6+ were shown to encode the wild-type tRNA(UCC) tRNA. The suf1+ and suf4+ genes were identical in DNA sequence, whereas the suf6+ gene, whose DNA sequence was not determined, was shown by a hybridization experiment to encode tRNA(UCC). The ultraviolet light-induced SU F1-1 and spontaneous SU F4-1 suppressor mutations were each shown to differ from wild-type at two positions in the anticodon, including a +1 base-pair insertion and a base-pair substitution. These changes resulted in a CCCC four-base anticodon rather than the CCU three-base anticodon found in wild-type. The RNA sequence of tRNA(UCC) was shown to contain a modified uridine in the wobble position. Mutant tRNA(CCCC) isolated from a SU F1-1 strain lacked this modification. Three unlinked genes that encode wild-type tRNA(GCC), suf20+, trn2, and suf17+, were identical in DNA sequence to the previously described suf16+ frameshift suppressor gene. Spontaneous suppressor mutations at the SU F20 and SU F17 loci were analyzed. The SU F20-2 suppressor allele contained a CCCC anticodon. This allele was derived in two serial selections through two independent mutational events, a +1 base insertion and a base substitution in the anticodon. Presumably, the original suppressor allele, SU F20-1, contained the single base insertion. The SU F17-1 suppressor allele also contained a CCCC anticodon resulting from two mutations, a +1 insertion and a base substitution. However, this allele contained an additional base substitution at position 33 adjacent to the 5' side of the four-base anticodon. The possible origin and significance of multiple mutations leading to frameshift suppression is discussed.