Transposition of the Escherichia coli insertion element gamma generates a five-base-pair repeat

Highly structured sequence homology between an insertion element and the gene in which it resides

The recessive allele for soybean seed lectin results from the insertion of a DNA segment (designated Tgm1) into the coding region of the gene. The termini of Tgm1 display structural features characteristic of a transposable element. The complete sequence of Tgm1 contains 3550 base pairs (bp) and can be divided into three regions (left arm, mid-section, and right arm). No large open reading frames were found, but an extensive, highly structured border with homology to the lectin gene was revealed. The left border (726 bp) comprising most of the left arm and extreme right border (144 bp) of the right arm consist of various forms of a basic 54-bp repeating unit. This 54-bp unit is comprised of a stem-loop structure and interhairpin sequence that occurs 13 times in the left arm and 2 times in the right arm of Tgm1. Progressively degenerate forms of this repeating unit appear toward the termini of Tgm1, but the dyad symmetry remains highly conserved. Seven nucleotides (A-C-A-T-C-G-G and its complement) maintained within the stem also appear as a subset of inverted repeats found at nearly equal distances from the target site in the lectin gene. Together with the inverted repeat termini and a duplication in the left arm, this 7-bp sequence occurs a total of 33 times in Tgm1. We infer that the dyad symmetries containing this sequence are involved in target gene selection. The repeating unit format of Tgm1 describes a distinct class of eukaryotic elements that includes representatives known to be mobile in snapdragon and maize.

The superantigen gene ypm is located in an unstable chromosomal locus of Yersinia pseudotuberculosis

Yersinia pseudotuberculosis produces YPM (Y. pseudotuberculosis-derived mitogen), a superantigenic toxin that exacerbates the virulence of the bacterium in vivo. To date, three alleles of the superantigen gene (ypmA, ypmB, and ypmC) have been described. These genes are not found in all Y. pseudotuberculosis strains and have a low GC content, suggesting their location on mobile genetic elements. To elucidate this question, the genetic environment of the superantigen-encoding genes was characterized and 11 open reading frames (ORFs) were defined. Sequence analysis revealed that the ypm genes were not associated with plasmids, phages, transposons, or pathogenicity islands and that the superantigen genes were always located in the chromosome between ORF3 and ORF4. Nonsuperantigenic strains exhibited the same genetic organization of the locus but lacked the ypm gene between ORF3 and ORF4. A new insertion sequence, designated IS1398, which displays features of the Tn3 family, was characterized downstream of the ypmA and ypmC genes. A 13.3-kb region containing the ypm genes was not found in the genome of Y. pestis (CO92 and KIM 5 strains). We experimentally induced deletion of the ypm gene from a superantigen-expressing Y. pseudotuberculosis: using the association of aph(3')-IIIa and sacB genes, we demonstrated that when these reporter genes were present in the ypm locus, deletion of these genes was about 250 times more frequent than when they were located in another region of the Y. pseudotuberculosis chromosome. These results indicate that unlike other superantigenic toxin genes, the Yersinia ypm genes are not associated with mobile genetic elements but are inserted in an unstable locus of the genome.

Isolation and characterization of a new transposable element in Chlamydomonas reinhardtii

A new transposable element, Tcr3, was identified in the unicellular green alga Chlamydomonas reinhardtii. The Tcr3 element contained imperfect terminal inverted repeat sequences of 56 bp and created a 2 bp target site duplication upon insertion. Insertion of Tcr3 into the 3'-untranslated region of the NIT8 gene, which is essential for nitrate assimilation, prevented expression of the gene. Excision of the Tcr3 element correlated with reversion of the mutant phenotype and left behind a 3 bp footprint. Tcr3 was found in all Chlamydomonas isolates tested and should prove to be useful for transposon-tagging experiments in Chlamydomonas.

Sequence of a transposon identified as Tn1000 (gamma delta)

We report the complete sequence of a transposon found in a cosmid clone of a human DNA sequence. The transposon is identified as the Escherichia coli transposon Tn1000 (also known as gamma delta) on the basis of the identity of the restriction map of the new sequence with that previously recorded for Tn1000 and homology between parts of the new sequence and that of published fragments of Tn1000 sequence. The transposon, which comprises 5,981 nucleotides including two 35 bp inverted terminal repeat sequences (ITRs), contains three open reading frames. The sequence of the resolvase coding region (tnpR) is identical to that published by others. A second reading frame can be identified as the tnpA gene, coding for the transposase, on the grounds of its strong homology with the corresponding gene from transposon Tn3. The third reading frame has the potential to code for a protein of unknown function containing 698 amino acids.

Identification of the region that determines the specificity of binding of the transposases encoded by Tn3 and gamma delta to the terminal inverted repeat sequences

To analyze the region that determines the specificity of binding of the Tn3 transposase to the terminal inverted repeat sequences (IR), we first determined the nucleotide sequence of a Tn3-family transposon, gamma delta, which is supposed to encode a transposase similar to that of Tn3. gamma delta was 5981 bp in length and contained three coding frames: Two were the genes, tnpA and tnpR, encoding transposase (1002 amino acids) and resolvase/repressor (183 amino acids), respectively, and the third, named tnpX, encoding a protein (698 amino acids) of unknown function but containing two NTP-binding motifs. Utilizing the tnpA sequence, we then constructed a series of Tn3-gamma delta hybrid genes encoding chimeric proteins in the N-terminal segments of the transposases (amino acid position 1 to 242 of Tn3 or 1' to 243' of gamma delta), which has been previously shown to be responsible for specific binding of transposase to IR sequences in Tn3. Examination of their DNA-binding activities revealed that the subsegment of the N-terminus from amino acid position 1 to 109 determines the specificity of binding to the IR sequences. The third coding frame found in gamma delta, tnpX, is located downstream of tnpR and is expressed from the tnpR promoter in the absence of the tnpR gene product, resolvase/repressor, to produce a protein that inhibits the growth of the host cells. Possible roles of this protein are discussed.

Rapid mapping by transposon mutagenesis of epitopes on the muscular dystrophy protein, dystrophin

Antibody-binding epitopes in the central helical region of the muscular dystrophy protein, dystrophin, have been mapped using a new strategy of transposon mutagenesis. Tn1000 transposons carrying translation termination codons were introduced randomly by bacterial mating into a large fragment of dystrophin cDNA in a pEX2 plasmid to produce a library of transformants expressing truncated dystrophin fusion proteins. Epitopes were progressively lost as the expressed sequences were shortened, enabling the epitopes recognised by 22 monoclonal antibodies to be placed in order along the dystrophin molecule without in vitro manipulation of DNA. The C-terminus of each truncated fusion protein was precisely located within the dystrophin sequence by direct sequencing of pEX2 transformants using transposon-specific primers. Sequences as short as 7 and 17 amino-acids have been identified as essential for antibody binding in this way. Nineteen of the 22 monoclonal antibodies had been selected for their ability to bind both native and SDS-denatured dystrophin and 15 of these bind to one sequence of 74 amino-acids (residues 1431-1505 of the 3684 residue sequence). This may be an area of high immunogenicity or of close structural similarity between native dystrophin and the SDS-treated recombinant fragment used for immunization.

Structural characterization of the Salmonella typhimurium LT2 umu operon

The umuDC operon of Escherichia coli encodes functions required for mutagenesis induced by radiation and a wide variety of chemicals. The closely related organism Salmonella typhimurium is markedly less mutable than E. coli, but a umu homolog has recently been identified and cloned from the LT2 subline. In this study the nucleotide sequence and structure of the S. typhimurium LT2 umu operon have been determined and its gene products have been identified so that the molecular basis of umu activity might be understood more fully. S. typhimurium LT2 umu consists of a smaller 417-base-pair (bp) umuD gene ending 2 bp upstream of a larger 1,266-bp umuC gene. The only apparent structural difference between the two operons is the lack of gene overlap. An SOS box identical to that found in E. coli is present in the promoter region upstream of umuD. The calculated molecular masses of the umuD and umuC gene products were 15.3 and 47.8 kilodaltons, respectively, which agree with figures determined by transpositional disruption and maxicell analysis. The S. typhimurium and E. coli umuD sequences were 68% homologous and encoded products with 71% amino acid identity; the umuC sequences were 71% homologous and encoded products with 83% amino acid identity. Furthermore, the potential UmuD cleavage site and associated catalytic sites could be identified. Thus the very different mutagenic responses of S. typhimurium LT2 and E. coli cannot be accounted for by gross differences in operon structure or gene products. Rather, the ability of the cloned S. typhimurium umuD gene to give stronger complementation of E. coli umuD77 mutants in the absence of a functional umuC gene suggests that Salmonella UmuC protein normally constrains UmuD protein activity.

Uncoupling of transpositional immunity from gamma delta transposition by a mutation at the end of gamma delta

The transposon gamma delta, in common with other members of the Tn3 family, confers transpositional immunity, a phenomenon by which plasmids containing a single transposon end show reduced activity as targets for further insertion by the same element. We found that a copy of a mutant delta end, in which the two terminal base pairs (5' GG) were substituted with cytosines, conferred the same degree of immunity as the unaltered delta end. However, a transposon analog with the mutant delta end as its termini could not transpose. These results suggest that the binding of transposase to a site on a target replicon is sufficient to confer immunity and that immunity does not involve subsequent DNA transactions at the bound target site, analogous to the catalytic processes that occur at the transposon ends during transposition.

The identification of the Escherichia coli ftsY gene product: an unusual protein

The ftsYEX operon in Escherichia coli encodes three proteins, two of which (FtsE and FtsX) are known to be required for cell division. Although FtsE and FtsX have been identified using SDS-PAGE, the FtsY protein has not. We have used in vitro insertion mutagenesis to identify FtsY as a 92 kD polypeptide in maxicell experiments, although predictions from the DNA sequence estimated FtsY to be 54 kD. Results suggest that this disparity could be due to the unusually high percentage of acidic residues within the protein. Complementation tests indicated the presence of a promoter within ftsY required for expression of ftsE and ftsX. The FtsY protein exhibits sequence homology with the SR alpha protein of eukaryotes which is involved in protein secretion. The essential nature of the ftsY gene was also demonstrated.

cis-acting DNA sequence requirements for P-element transposition

The P transposable element of Drosophila melanogaster has a complex array of cis-acting DNA sequences necessary for efficient transposition. At the 3' end these sequences extend over more than 150 bp and include 11- and 31-bp sequences found repeated in inverted orientation at the 5' end. The P element's 5' end, however, cannot function as its 3' end. When two 3' P-element ends are present, the more proximal end is used preferentially. We found also that the duplication of the target site does not appear to play a role in forward transposition.

A subsequence-specific DNA-binding domain resides in the 13 kDa amino terminus of the bacteriophage Mu transposase protein

We have previously reported that the 13 kDa amino terminus of the 70 kDa bacteriophage D108 transposase protein (A gene product) contains a two-component, sequence-specific DNA-binding domain which specifically binds to the related bacteriophage Mu's right end (attR) in vitro. To extend these studies, we examined the ability of the 13 kDa amino terminus of the Mu transposase protein to bind specifically to Mu attR in crude extracts. Here we report that the Mu transposase protein also contains a Mu attR specific DNA-binding domain, located in a putative alpha-helix-turn-alpha-helix region, in the amino terminal 13 kDa portion of the 70 kDa transposase protein as part of a 23 kDa fusion protein with beta-lactamase. We purified for this attR-specific DNA-binding activity and ultimately obtained a single polypeptide of the predicted molecular weight for the A'--'bla fusion protein. We found that the pure protein bound to the Mu attR site in a different manner compared with the entire Mu transposase protein as determined by DNase I-footprinting. Our results may suggest the presence of a potential primordial DNA-binding site (5'-PuCGAAA-3') located several times within attR, at the ends of Mu and D108 DNA, and at the extremities of other prokaryotic class II elements that catalyze 5 base pair duplications at the site of element insertion. The dissection of the functional domains of the related phage Mu and D108 transposase proteins will provide clues to the mechanisms and evolution of DNA transposition as a mode of mobile genetic element propagation.

Outreading promoters are located at both ends of the gamma-delta transposon

Two plasmids were isolated containing oppositely oriented gamma-delta insertions between the wild-type transcription initiation site of the nifHDKY operon and the nifH coding sequence. The nifHDKY promoter of Klebsiella pneumoniae, similar to other nitrogen fixation (nif) promoters, normally requires the products of ntrA and nifA for activity. Mutations that allowed constitutive expression of the nifHDKY operon were searched for by transforming a plasmid, containing the regulatory region of this operon followed by an in-frame nifH'-'lacZ fusion, into a Lac- Escherichia coli strain (which contains no nifA) and screening for Lac+ derivatives. The plasmids described here were isolated from such derivatives and directed the constitutive expression of beta-galactosidase. Deletion analysis indicated that gamma-delta promoters other than those transcribing tnpA and tnpR were involved in this expression. Nuclease S1 mapping revealed outward-reading transcription initiation sites in both the gamma end and the delta end of the transposon. Most interestingly, one initiation site on each end was located in corresponding positions within the terminal inverted repeats. The sites were in the center of the longest sequence, of 12 bp, contiguously conserved between the terminal inverted repeats of gamma-delta and the related transposon Tn3. In gamma-delta and Tn3, this sequence has been recently implicated in transposase binding. These results suggest a possible interrelationship between transcription from the "end" promoters and transposition.

The bacteriophage Mu transposase protein can form high-affinity protein-DNA complexes with the ends of transposable elements of the Tn 3 family

The 37 kb transposable bacteriophage Mu genome encodes a transposase protein which can recognize and bind to a consensus sequence repeated three times at each extremity of its genome. A subset of this consensus sequence (5'-PuCGAAA(A)-3') is found in the ends of many class II prokaryotic transposable elements. These elements, like phage Mu, cause 5 bp duplications at the site of element insertion, and transpose by a cointegrate mechanism. Using the band retardation assay, we have found that crude protein extracts containing overexpressed Mu transposase can form high-affinity protein-DNA complexes with Mu att R and the ends of the class II elements Tn 3 (right) and IS101. No significant protein-DNA complex formation was observed with DNA fragments containing the right end of the element IS102, or a non-specific pBR322 fragment of similar size. These results suggest that the Mu transposase protein can specifically recognize the ends of other class II transposable elements and that these elements may be evolutionarily related.

Transposition of Tn1000: in vivo properties

Transposition mediated by the Tn1000 transposase was investigated by using transposon variants carrying synthetic or wild-type termini but no intact Tn1000 genes. Transposon Tn1001, whose only homologies to Tn1000 are in its 38-base-pair terminal inverted repeats, transposed at the same rate as Tn1005, an artificial construct carrying wild-type Tn1000 termini and approximately 1 kilobase of flanking Tn1000 DNA at each end, when transposase was supplied in trans. The majority of the transpositions into pOX38 gave rise to cointegrates, but approximately 10% of the products expressed phenotypes of direct transpositions. The expression and temperature dependence of the tnpA gene product were examined by studying transposition of Tn1001 to bacteriophage lambda. The temperature optimum for transposition was 37 degrees C, and the transposase was stable for up to 2 h at this temperature.

Transposition of Tn1000: activity of single or directly repeated termini

Tn1000 (gamma delta) termini IRR and IRL, or direct repetitions of IRR-IRL carried by pBR322 derivatives mediate cointegration with pOX38 at similar rates. Structures of product plasmids indicate that the transposed segments correspond to DNA bounded by IR segments in the donor plasmid. Such structures could arise by symmetric transposition from a replication intermediate.

Rapid sequencing of cloned DNA using a transposon for bidirectional priming: sequence of the Escherichia coli K-12 avtA gene

A new approach to determining the sequence of cloned DNA is described. Unique regions near each end of the transposable element gamma-delta provide a pair of "portable" primer-specific sites for bidirectional sequencing by the dideoxy chain termination method. A set of gamma-delta insertions positioned about 200 bp apart over the entire cloned DNA allowed us to determine the sequence of both strands in a single parental plasmid without subcloning. The avtA (alanine-valine transaminase) gene of E. coli K-12 was sequenced by this approach. Surprisingly, gamma-delta insertions downstream of the coding region were found to significantly reduce avtA expression. We suggest that these nondisruptive insertions probably change the DNA topology and thereby alter gene expression.

Identification of the DNA sequence required for transposition immunity of the gamma delta sequence

A plasmid containing the transposon gamma delta sequence was immune to further insertion of gamma delta (transposition immunity). Plasmids carrying a fragment containing either 0.2 kilobase pairs of the gamma end or 0.4 kilobase pairs of the delta end of the gamma delta sequence were immune, and other parts of the gamma delta sequence did not confer immunity. The terminal 38-base-pair (bp) sequence of the delta end of the gamma delta was sufficient to confer immunity, the 38-bp sequence of the gamma end conferred only moderate immunity, and the terminal 35-bp sequence, which was completely identical at both the gamma and delta ends, was insufficient to confer immunity.

Nucleotide sequence analysis of RepFIC, a basic replicon present in IncFI plasmids P307 and F, and its relation to the RepA replicon of IncFII plasmids

RepFIC is a basic replicon of IncFI plasmid P307 which is located within a 3.09-kilobase SmaI fragment. The nucleotide sequence of this region has been determined and shown to be homologous with the RepFIIA replicon of IncFII plasmids. The two replicons share three homologous regions, HRI, HRII, and HRIII, which are flanked by two nonhomologous regions, NHRI and NHRII. A comparison of coding regions reveals that the two replicons have several features in common. RepFIC, like RepFIIA, codes for a repA2 protein with its amino-terminal codons in HRI and its carboxy-terminal codons in NHRI. Although the codons for the repA1 proteins are located in NHRII, the DNA region containing a putative promoter, ribosomal binding site, and initiation codons is located in HRII. This region also codes for an inc RNA. There are nine base-pair differences between the inc RNA of RepFIIA and that of RepFIC, and as a result, RepFIC and RepFIIA replicons are compatible. An EcoRI fragment from the F plasmid which shows homology with RepFIC of P307 has also been sequenced. This fragment contains only a portion of RepFIC, including the genes for the putative repA2 protein and inc RNA. The region coding for a putative repA1 protein is interrupted by the transposon Tn1000 and shows no homology with the repA1 region of RepFIIA and RepFIC of P307. Our comparative and structural analyses suggest that RepFIC and RepFIIA, although different, have a similar replication mechanism and thus can be assigned to the same replicon family, which we designate the RepFIIA family.

Cointegration and resolution mediated by IS101 present in plasmid pSC101

A certain class of cointegrate plasmids was found to occur between a pSC101 derivative and a second plasmid pBV320 in E. coli F- cells. Cleavage analysis and DNA sequencing showed that the cointegrate plasmid contained direct repeats of an insertion sequence IS101 at the recombination junctions, indicating that formation of cointegrates was mediated by IS101, which is a natural constituent of pSC101. These cointegrates were formed only in cells which contained the transposon gamma-delta, suggesting that the gamma-delta sequence, which provides transposase, is responsible for cointegration. Whenever the cointegrate plasmids were present in cells containing gamma-delta or its related transposon Tn3, the cointegrates were dissolved to give pBV320::IS101 due to recombination at duplicated IS101 sequences in the cointegrates, suggesting that both gamma-delta and Tn3, which provide a resolvase, are responsible for the resolution of the cointegrates. Comparison between the nucleotide sequence of IS101 and those of gamma-delta and Tn3 shows a high degree of homology in the regions that have been shown to be the binding sites of resolvases, as well as in the terminal inverted repeats. However, there is no homology between IS101 and the other element, gamma-delta or Tn3, in the internal resolution site, at which the resolution event may occur.

DNA sequences at the ends of the genome of bacteriophage Mu essential for transposition

We have determined the minimal DNA sequences at the ends of the genome of bacteriophage Mu that are required for its transposition. A mini-Mu was constructed on a multicopy plasmid that enabled the manipulation of the DNA sequences at its ends without affecting the genes essential for transposition. The genes A and B, which were cloned outside the ends of the mini-Mu on the same plasmid, were both needed for optimal transposition. In our experimental system the predominant end products of the transposition are cointegrates both in the presence and in the absence of B. Two regions ending approximately 25 and 160 bp from the left end and one ending approximately 50 bp from the right end appear to be essential for optimal transposition. Overlapping with these regions, a 22-base-pair sequence was recognized with the consensus Y-G-T-T-C-A-Y-T-N-N-A-A-R-Y-R-C-G-A-A-A-A, where Y and R represent any pyrimidine and purine, respectively. At the left end these sequences occur as direct repeats; at the right end this sequence is inverted with respect to those at the left end.

A cluster of five genes specifying the aerobactin iron uptake system of plasmid ColV-K30

The genetic determinants for the aerobactin iron uptake system of plasmid ColV-K30, cloned as recombinant plasmid pABN1, were mapped by insertional inactivation using Tn1000 (gamma delta). Sites of insertion resulting in loss of aerobactin biosynthesis spanned ca. 5.5 kilobase pairs of cloned ColV-K30 DNA contiguous with a 2-kilobase-pair region in which transposon insertion resulted in loss of the outer membrane ferric-aerobactin receptor protein. Translation products of plasmid pABN1, and of subclones specifying siderophore biosynthesis alone or receptor activity alone, were analyzed by using the maxicell and minicell expression system. Four polypeptides (Mr = 62,000, 35,000, 45,000, and 50,000) are required for biosynthesis of aerobactin. A fifth product (Mr = 74,000) of plasmid pABN1 represents the outer membrane receptor protein. The linear order of genes for these polypeptides was determined by comparing translation products of a series of smaller derivative plasmids and of a number of mutant plasmids carrying Tn1000 at known locations.

RecA-independent recombination at gamma delta termini and at IS3 producing inverted repetition in F' plasmids

Two F' plasmids isolated independently from a recA- strain of Escherichia coli and containing identical deletion end points and identical associated inverted duplications are described. In these plasmids, DNA of F plasmid from the IS3 element alpha 1 beta 1 up to the transposon gamma delta is duplicated in inverted orientation, and a 63-kilobase-pair segment from the chromosomal DNA of the plasmid is deleted. One deletion terminus is the chromosomal IS3 alpha 4 beta 3 carried by the parental plasmid, ORF203. It is proposed that these structures resulted from interduplex strand exchanges that occurred at the ends of the movable element gamma delta and at IS3. This indicates that the 35-base-pair gamma delta termini can participate in genome rearrangements by mechanisms that are distinct from complete transposition mechanisms.

Conduction of nonconjugative plasmids by F' lac is not necessarily associated with transposition of the gamma delta sequence

A nonconjugative kanamycin-resistant (Kmr) recombinant plasmid, pNR5311, transferred at a low frequency from an Hfr or F' lac Escherichia coli donor to an F- lac- recipient. Among the transconjugants, two types of Kmr plasmids were found: one was indistinguishable from pNR5311 (type A), and the other was a recombinant between pNR5311 and the gamma delta sequence (type B). When the F' lac strain was used as a donor, 5% of lactose-fermenting (Lac+) and 75% of lactose-nonfermenting (Lac-) transconjugants had type A plasmids. A kinetic study revealed that type A plasmids were transferred more readily in short mating periods than were type B plasmids. Involvement of Tn903, which is present in pNR5311, in transfer of type A plasmids was unlikely since there was no discernible change in the F' lac molecule coexisting with the type A plasmid in the transconjugant cells. The non-gamma delta-associated conduction of pNR5311 by F' lac did not require the recA+ function of the donor. Conduction of pBR322 by F' lac was also carried out, and two types of plasmids with and without gamma delta were found, as with pNR5311. These findings suggest that the transfer of nonconjugative plasmids is conducted by a novel pathway which is not associated with translocation of transposable elements into either plasmid.

IS30, a new insertion sequence of Escherichia coli K12

Three independent spontaneous mutations of prophage P1 affecting the ability of the phage to reproduce vegetatively are due to the insertion of a mobile genetic element, called IS30. The same sequence is also carried in the R plasmid NR 1-Basel, but not in the parental plasmid NR 1. Southern hybridisation study indicates that the Escherichia coli K 12 chromosome carries several copies of IS30 as a normal resident. IS30 is 1.2 kb long and contains unique restriction cleavage sites for BglII, ClaI, HindIII, NciI and HincII, and it is cleaved twice by the enzymes HpaII and TaqI. The ends of IS30 are formed by 26 bp long inverted repeats with 3 bases mismatched. Upon transposition IS30 generates a duplication of only 2 bp of the target. The following observations suggest a pronounced specificity in target selection by IS30. In transposition to the phage P1 genome a single integration site was used three times independently, and in both orientations. A short region of sequence homology has been identified between the P1 and NR 1-Basel insertion sites. IS30 has mediated cointegration as well as deletion. The entire IS30 sequences were duplicated in the cointegrates between a pBR322 derivative containing IS30 and the genome of phage P1-15, and several loci on the P1-15 genome served as fusion sites, some of which were used more than once.

Insertions of transposable elements in the promoter proximal region of the gene cluster for Escherichia coli H+-ATPase: 8 base pair repeat generated by insertion of IS1

A plasmid pKY159 (Yamaguchi and Yamaguchi 1983) carrying a promoter proximal portion of the gene cluster of the proton-translocating ATPase (H+-ATPase) of Escherichia coli causes growth inhibition of wild-type cells. Insertion of a transposable element in this plasmid released this inhibitory effect. In analyzing this inhibitory effect, we determined the insertion points at the nucleotide-sequence level of transposable elements on 30 independent derivatives of pKY159 . Insertions of IS1, IS5, and gamma delta were found between the promoter and the gene for a possible component of 14,000 daltons of the H+-ATPase. Of 31 insertions, 26 were of IS1 and were located at the same site, indicating that this site is a hotspot for IS1 insertion and that IS1 insertion is much more frequent than that of IS5 or gamma delta in this region. Four different sites for IS1 insertion were found; in two of these an 8 base pair (bp) duplicate of the target sequence ( AAAAACGT and AAACGTTG ) was generated, while in the other two a 9 bp duplicate was found. In all cases in this study the nucleotide sequence of IS1 was the same as that of IS1-K. In the two cases with an 8 bp duplicate in different sites, a common 6 bp sequence ( AAACGT ) was found. These results suggested that generation of the 8 bp duplicate is related to the common sequence rather than a mutation in IS1 suggested by Iida et al. (1981) and also suggested that the essential length of the duplicate is 8 bp or less than 8 bp. A 6 bp sequence ( GTGATG ) homologous to the end portion of IS1 was found at the hotspot , but not at other sites, suggesting that this homology contributed to the high frequency of IS1 insertion.(ABSTRACT TRUNCATED AT 250 WORDS)

The nucleotide sequence of replication and maintenance functions encoded by plasmid pSC101

The nucleotide sequence of 1100bp around the origin of replication of the pSC101 plasmid has been determined. This segment of DNA is capable of replication in the presence of a helper plasmid. The sequence data reveal similarities between pSC101 and several other replicons. The origin of replication contains three direct repeats of an 18bp sequence associated with a segment exceptionally rich in A-T base pairs. A promotor that probably directs transcription of a gene encoding an essential plasmid replication function is associated with a region of extensive potential secondary structure. The sequence presented here includes the sequence of the par region involved in partitioning of plasmids at cell division.

Recombination and balanced chromosome polymorphism suggested by DNA sequences 5' to the human delta-globin gene

Two types of chromosome (R and T) were found by cloning from six human individuals the 3.1-kilobase-pair EcoRI fragment that contains the bipolar Alu family repeat 5' to the delta-globin gene. Two type T fragments were identical in nucleotide sequence. Two type R fragments were identical except for one base. Both types are found in whites, blacks, and orientals. The differences between R and T sequences (16 base substitutions and two deletions) were mostly in the 5' domain of the fragment (0.91% difference in 1.7 kilobases), which contains the bipolar Alu repeat, whereas the 3' domain of the fragment was more conserved (0.14% difference in 1.4 kilobases). To help understand the history of this human polymorphism, the equivalent fragment from a chimpanzee was cloned and its sequence was determined. The chimpanzee sequence differed from both human sequences at 39 positions distributed almost uniformly along the whole 3.1-kilobase-pair fragment. Assuming that humans and chimpanzees diverged 4 to 5 million years ago, the data indicate that the divergence of the two types of human chromosome started about 3 million years ago but about 0.4 million years ago an interchromosomal recombination rendered the two types of human chromosome alike in their 3' domains. The two chromosomes have since remained discrete and have persisted in several populations. These observations suggest that factors are operating to maintain a balanced chromosomal polymorphism in this region 5' to the human delta-globin gene.

The nucleotide sequence of the rho gene of E. coli K-12

We have determined the nucleotide sequence of the rho gene which encodes the E. coli K-12 transcription termination factor. The structural gene was located on a cloned 3.6 kilobase BglII-HindIII restriction fragment by the introduction of the insertion element gamma delta and analysis of the recombinant plasmids by restriction analysis and in maxicells. The coding region consists of 1260 nucleotides directing the synthesis of a polypeptide 419 amino acids in length with a calculated molecular weight of 46,094. The deduced amino acid composition, amino-terminal protein sequence and calculated molecular weight are consistent with the data from the analysis of purified rho protein (16). We have shown that the rho genes from E. coli K-12, B and C strains are located on PvuII-HindIII fragments of the same size by hybridization to the rho (K-12) coding sequences.

Gamma delta-mediated deletions of chromosomal segments on F-prime plasmids

Deleted derivatives of F lac+ proC+ tsx+/- purE+ plasmids ORF203 and F13 were isolated and physically characterized. Among 31 deletions, 24 were adjacent to the gamma delta element on F, four were associated with IS2 or IS3 elements normally present on F, and three displayed additional DNA rearrangements. With the genetic selection employed, the deletion endpoints in the chromosomal segment could fall anywhere within a 210 kb (5 min) region between proC and lac. The distribution of endpoints in this region was not random: the endpoints primarily occurred in an extended region near purE, and a 50 kb segment between tsx and purE was devoid of deletion endpoints. Deletion termini for mutants obtained from F13, which contains an additional 48 kb-segment interposed between gamma delta and the target region on ORF203, displayed a distribution similar to that seen for ORF203. Among simple deletions, there was no marked tendency for the chromosomal deletion endpoints to fall at IS1, IS3, or IS5 elements normally present in this chromosomal region. Point mutations and mutations caused by gamma delta or IS transposition into lac appeared in a small proportion of all plasmids studied.

Fine structure of transposition genes on Tn2603 and complementation of its tnpA and tnpR mutations by related transposons

The fine structure of the genes tnpA, tnpR and res of Tn2603 required for its own transposition, was determined. The order of the genes was tnpA-tnpR-res from the right end of the right hand side region in Tn2603, the tnpA and tnpR encoded gene products having molecular weights of 110,000 and 21,000, respectively. The 110,000 molecular weight polypeptides was absolutely required for replicon fusion as the first stage of transposition, and named transposase. On the other hand, the 21,000 molecular weight polypeptide was necessary for resolution of the cointegrate as the second stage of transposition, and named resolvase. We also examined the ability of various transposons, assumed to be closely related, to complement the tnpA and tnpR mutations of Tn2603. The results indicated that the mercury resistance transposon, Tn2613, and Tn501, can complement both genes, but TnAs and gamma delta cannot at all. Tn501 had much less efficiency of complementation for tnpA than Tn2613. We have also discovered that the transposition frequency of transposons in the tn2613 family systematically depend on their size of transposon.

Identification of two genes immediately downstream from the polA gene of Escherichia coli

We have identified two genes within a 1-kilobase region immediately following the polA gene of Escherichia coli. The first, whose transcription is initiated about 150 base pairs beyond the end of the polA coding sequence, is the gene corresponding to the previously sequenced "spot 42 RNA" (B. G. Sahagan and J. E. Dahlberg, J. Mol. Biol. 131:573--592, 1979). The second, located further downstream and transcribed towards polA, is the structural gene for a 22-kilodalton polypeptide, which we have detected by using plasmid-directed protein synthesis in maxicells. Sequence analysis of this region of the E. coli genome suggests that it contains little, if any, redundant DNA.

Insertion sites and the terminal nucleotide sequences of the Tn4 transposon

The nucleotide sequences at the ends of the Tn4 transposon (mercury spectinomycin and sulfonamide resistance) have been determined. They are inverted repeated sequences of 38 nucleotides with three mismatched base pairs. These sequences are strongly homologous with the terminal sequences of Tn501 (mercury resistance) but less so with those of Tn3 (ampicillin resistance). The Tn4 transposon generates pentanucleotide members (Tn3, Tn1000, Tn501, Tn551, IS2) with the exception of Tn1721 and bacteriophage Mu. Among the three Tn4 insertion sites examined here, two of them occurred near a nonanucleotide sequence in perfect homology with part of the terminal inverted-repeat sequence of Tn4 and the third insertion occurred near a sequence of partial homology to one end of Tn4. All three insertions were in the same orientation such that IRb is proximal to its homologous sequence on the recipient DNA.

Transposon-specified site-specific recombination

Cointegrate DNA molecules containing two copies of a transposable element appear to be intermediates in the transposition process. These structures are resolved by site-specific recombination to yield the normal end products of transposition. The transposable element gamma delta (Tn1000) synthesizes a product interchangeable with the Tn1/3tnpR protein in promoting Tn1/3 site-specific recombination. These data support the hypothesis that cointegrates containing directly repeated copies of Tn1/3 are obligatory intermediates in interreplicon transposition of Tn1/3. In addition, we show here that the reaction is independent of the element-encoded tnpA gene product. Tn501, which specifies mercury resistance, also produces cointegrates as intermediates in interreplicon transposition. The appearance of Tn501-specified recombination activity that can act on these cointegrates requires growth of cells in the presence of Hg2+.

Cloning of a 1.1-kb fragment including srnB+ gene in the F plasmid and isolation of an srnB mutant

The srnB+ gene, promoting stable RNA degradation at 42 C in the presence of rifampin, was cloned by using pBR322 as a vector; it was located on a 1.1-kilobase (kb) Eco RI/Bam HI fragment between 1.4 and 2.5 kb of the F plasmid. The region between 93.3 and 4.0 kb of the F plasmid was physically mapped by using restriction endonucleases EcoRI, HindIII, BamHI, PstI, and SmaI, with reference to a standard HindIII site in IS3. An srnB1 mutant was isolated from a chimeric plasmid, pOY54, after treatment of its DNA with hydroxylamine. The srnB1 allele on the F fragment of the mutant plasmid was recessive to the wildtype allele. Thermal elevation of cell cultures to 39 C was high enough to promote RNA degradation in strain YS12 carrying plasmid pOY54.

Transposon Tn951 (TnLac) is defective and related to Tn3

Tn951 is flanked by two perfect inverted repeats of 41 bp which include the 38 bp sequence of the IR of Tn3. Tn951 also contains the last 100 bp of the tnpA gene but with at least two mutations. However, beyond nucleotide 137 the sequences diverge and hybridization experiments show that Tn951 lacks at least the first two thirds of the tnpA gene. In agreement with these observations Tn951 does not transpose by itself at a detectable frequency but can be complemented by the tnpA gene of Tn801 or Tn3. Tn501, Tn1721 and gamma delta do not complement Tn951 transposition. Transposition of Tn951 duplicates 5 bp of target DNA sequence.

Transposon Tn3 encodes a site-specific recombination system: identification of essential sequences, genes, and actual site of recombination

The bacterial transposon Tn3 encodes a site-specific recombination system. The recombination requires the product of tnpR, a gene previously identified as a repressor of the transposase. This recombination is site specific and takes place somewhere within the sequence C-G-A-A-A-T-A-T-T-A-T-A-A-A-T-T-A-T-C but requires at least one additional sequence outside this. The phenotype of mutations in this recombination system suggests that transposition proceeds by a mechanism in which cointegrates are intermediates.

The transposons Tn501(Hg) and Tn1721(Tc) are related

Internal sequences of Tn501(Hg) and Tn721(Tc) have been compared by hybridization. In spite of the difference in the resistance they code for, there is extensive homology between the two elements. This homology resides in the transposon-coded genes that are necessary for transposition and indicates that the elements are closely related.

Resolution of cointegrates between transposons gamma delta and Tn3 defines the recombination site

Transposition of the genetically related insertion elements gamma delta and Tn3 is thought to involve two steps. In the case of transposition from one replicon to another, the first step is fusion of the parent and target replicons with the element appearing in direct orientation at the two junctions. In a subsequent reaction, the cointegrate structure is resolved via a site-specific recombination event. I have constructed two plasmids, each carrying segments of gamma delta and Tn3, that contain the internal resolution site. The tnpR gene product encoded by either Tn3 or gamma delta mediates intramolecular recombination between these two sites. The product of this recombination is a hybrid region that contains gamma delta and Tn3 sequences fused at the point of crossover. DNA sequence analysis of such recombinants indicates that the recombination occurs within a 19-base-pair (bp) region of exact homology between gamma delta and Tn3. The site lies in the 160-bp center intercistronic region, 50 bp before the beginning of the tnpA gene. My results therefore suggest a model for the coupled regulation of the repressor (tnpR) and the transposase (tnpA) genes and site-specific recombination of transposition intermediates. The Tn3/gamma delta recombination system and bacteriophage lambda integration are compared.

The tetracycline resistance transposons Tn1721 and Tn1771 have three 38-base-pair repeats and generate five-base-pair direct repeats

The 10.7 kilobase (kb) tetracycline resistance transposons Tn1721 and Tn1771, isolated from disparate sources, are completely homologous on the basis of heteroduplex analyses. Both transposable elements are capable of forming multiple duplications of a 5.3 kb portion encompassing the resistance genes (tet region). A model accounting for both, recA-independent translocation and recA-dependent amplification, postulates two direct and one inverted repeat as essential constituents of the transposons. DNA sequence analyses of Tn1721 and Tn1771 have substantiated this model. They demonstrated three identical 38 base pair repeats identically in both transposons dividing them into a "minor transposon" and a tet region. Identical sequences of at least 87 base pairs providing recombination "hot spots" for gene duplication have been found at the ends of the repetitious tet region. Translocation of Tn1721 and Tn1771 generates five base pair direct repeats at the respective sites of insertion. On the basis of the heteroduplex molecules and sequences analyzed the two transposons are identical.

No apparent nucleotide sequence specificity in cellular DNA juxtaposed to retrovirus proviruses

The sequences of the virus-cell junctions of seven DNA clones of spleen necrosis virus provirus were analyzed to determine the nucleotide sequence specificity of the cellular integration sites. As previously reported for one provirus, all clones contain a 5-base-pair direct repeat of cellular DNA at the cell-virus junctions and a 3-base-pair inverted repeat at both ends of the provirus DNA. The sequences of the 5-base-pair direct repeats are different in each clone and have no apparent homology to viral DNA. No apparent common features and no sequences significantly homologous to the ends of the provirus DNA were found in the cellular DNAs surrounding the viral integration sites.

Insertion element IS102 resides in plasmid pSC101

In vivo recombination was found to occur between plasmid pHS1, a temperature-sensitive replication mutant of pSC101 carrying tetracycline resistance, and plasmid ColE1 after selection for tetracycline resistance at the restrictive temperature, 42 degrees C. Extensive analysis of the physical structures of three of these recombinant plasmids, using restriction endonucleases and the electron microscope heteroduplex method, revealed that the plasmid pHS1 was integrated into different sites on ColE1. The recombinant plasmids contained a duplication of a unique 1-kilobase (kb) sequence of pHS1 in a direct orientation at the junctions between the two parental plasmid sequences. This was confirmed by comparing the nucleotide sequence of the recombinants and their parental plasmids. Nucleotide sequence analysis further revealed that nine nucleotides at the site of recombination of ColE1 were duplicated at the junction of each of the 1-kb sequences. The formation of recombinants was independent of RecA function. Based on our previous finding that a plasmid containing a deoxyribonucleic acid insertion (IS) element can recombine with a second plasmid to generate a duplication of the IS element, we conclude that the 1-kb sequence is an insertion sequence, which we named IS102. For convenience, we have also denoted the IS102 sequence as eta theta to assign the orientation of the sequence. Eighteen nucleotides at one end (eta end) were found to be repeated in an inverted orientation at the other end (theta end) of IS102. The nucleotide sequence of the eta end of the sequence was found to be identical to the sequence at the ends of the transposon Tn903, which is responsible for transposition of the kanamycin resistance gene.

Physical mapping and expression of hybrid plasmids carrying chromosomal beta-lactamase genes of Escherichia coli K-12

Hybrid plasmids carrying the ampC gene of Escherichia coli K-12 that codes for the chromosomal beta-lactamase were physically studied. The ampC gene was mapped to a deoxyribonucleic acid segment encompassing 1,370 base pairs. The mapping was facilitated by the isolation of a plasmid carrying an insertion of the transposable element gamma delta (gamma delta) close to ampC. The ampA1 mutation, which increases the expression of ampC by a factor of about 20, was localized to a 370-base pair segment of the 1,370-base pair deoxyribonucleic acid segment that contains the ampC gene. Using a minicell protein labeling system, it was seen that plasmids carrying either ampA+, ampC, or ampA1 and ampC coded for a 36,000-dalton protein which comigrated with purified chromosomal beta-lactamase. In cells carrying plasmids that bore the ampA1 allele, the production of this protein was greater. In addition, a protein with a slightly higher molecular weight (38,000) was expressed by both ampA+ ampC and ampA1 ampC plasmids in this protein labeling system. This protein might represent a precursor form of chromosomal beta-lactamasee. From E. coli K-12 strains carrying the ampA1 allele, second-step mutants were isolated that hyperproduced chromosomal beta-lactamase. By reciprocal recombination, plasmid derivatives were isolated that carried these mutations. Two second-step regulatory mutations mapped within the same 370-base pair region as ampA1. This piece of deoxyribonucleic acid therefore contains ampA, a control sequence region for ampC.