Nucleotide sequence of the oncogene encoding the p21 transforming protein of Kirsten murine sarcoma virus.

The transforming protein of Kirsten murine sarcoma virus (Ki-MuSV) is a virally encoded 21-kilodalton protein called p21 kis. The sequences encoding p21 kis were genetically localized to a 1.3-kilobase segment near the 5' end of the viral genome by assaying the capacity of a series of defined deletion mutants of molecularly cloned Ki-MuSV DNA to induce focal transformation of mouse cells. Nucleotide sequencing of a portion of this region has led to the identification of an open reading frame of 567 nucleotides coding for p21 kis protein.

Mapping of insertion element IS5 in the Escherichia coli K-12 chromosome. Chromosomal rearrangements mediated by IS5.

We identified phage clones containing insertion element IS5 in a set of 476 lambda phage clones carrying chromosomal segments that cover almost the entire chromosome of Escherichia coli K-12 W3110. Precise locations and orientations of IS5 were then determined by cleavage analysis of phage DNAs containing them. We mapped 23 copies of IS5 (named is5A to is5W) on the W3110 chromosome. Among them, ten were identified as the common elements present at the same locations in both chromosomes of W3110 and another E. coli K-12 strain, JE5519. While most of the mapped IS5 elements were scattered over the W3110 chromosome, four copies of IS5 (designated is5L, is5M, is5N and is5O) were in a region representing tandem duplication of a DNA segment flanked by two copies of IS5. Interestingly, one unit of this DNA segment as well as a portion of it was seen also in a tandem array in a different region where two copies of IS5 (designated is5P and is5Q) were present. In particular two pairs of the mapped IS5 elements may have been involved in inversion of the chromosomal segments in two of the E. coli K-12 derivatives.

Relationship between helix-coil transition and gene organization of ColE1 plasmid DNA. Differential scanning calorimetric and theoretical studies.

Differential scanning calorimetry (DSC) was carried out to analyze the transition of helix to coil state of DNA, using ColE1 DNA molecules digested with EcoRI. The DSC curves showed multimodal transition, consisting of nine to 11 peaks over a temperature range, depending on the ionic strength of the DNA solution. These DSC curves were essentially in good agreement with the optical melting curves of ColE1 DNA. The theoretical melting profiles of ColE1 DNA were predicted from calculations based on the helix-coil transition theory and the nucleotide sequence of the DNA. These profiles resembled the DSC curves and made it possible to assign the peaks seen in the DSC curves to the helix-coil transition of particular regions of the nucleotide sequence of ColE1. The helix-coil transition of each of the small genes gave rise to a single peak in the DSC curve, while the helix-coil transition of large genes contributed to two or more peaks in the DSC curve. This multimodal transition within a single coding region might correspond to the melting of individual segments encoding the different domains of the proteins. The helix-coil transition at the specific sites including ori, the origin of replication of ColE1, was also found to occur in a particular temperature range. DSC, a simple method, is thus useful for analyzing the multimodal helix-coil transition of DNA, and for providing information on the genetic organization of DNA.

Mapping of insertion elements IS1, IS2 and IS3 on the Escherichia coli K-12 chromosome. Role of the insertion elements in formation of Hfrs and F' factors and in rearrangement of bacterial chromosomes.

The chromosome of an Escherichia coli K-12 strain W3110 contains seven copies of insertion element IS1, 12 copies of IS2 and six copies of IS3. We determined the approximate locations of six copies of IS1 (named is1A to is1F), ten copies of IS2 (named is2A to is2J), and five copies of IS3 (named is3A to is3E) on the W3110 chromosome by plaque hybridization using the "mini-set" of the lambda phage library that includes 476 clones carrying chromosomal segments that cover the W3110 chromosome almost entirely. Cleavage maps of the W3110 chromosome and cleavage analysis of phage DNAs carrying insertion elements allowed us to assign more precise locations to most of the insertion elements and to determine their orientations. Insertion elements were distributed randomly along the W3110 chromosome in one or other orientation. Several of these were located at the same positions on the chromosome of another E. coli K-12 strain, JE5519, and they were assumed to be the original complement of insertion elements in E. coli K-12 wild-type. Locations and orientations of such insertion elements were correlated well with Hfr points of origin and with crossover points for excision of some F' factors derived from several Hfrs. Insertion elements may be involved also in rearrangement of bacterial chromosomes.

Nucleotide sequence of the promoter-distal region of the tra operon of plasmid R100, including traI (DNA helicase I) and traD genes.

The nucleotide sequence of the promoter-distal region of the tra operon of R100 was determined. There are five open reading frames in the region between traT and finO, and their protein products were identified. Nucleotide sequences of plasmid F corresponding to the junction regions among the open reading frames seen in R100 were also determined. Comparison of these nucleotide sequences revealed strong homology in the regions containing traD, traI and an open reading frame (named orfD). The TraD protein (83,899 Da) contains three hydrophobic regions, of which two are located near the amino-terminal region. This protein also contains a possible ATP-binding consensus sequence at the amino-terminal region and a characteristic repeated peptide sequence (Gln-Gln-Pro)10 at the carboxy-terminal region. The TraI protein (191,679 Da) contains the sequence motif conserved in an ATP-dependent DNA helicase superfamily in its carboxy-terminal region. The protein product of orfD, which is probably a new tra gene (named traX), contains 65% hydrophobic amino acids, especially rich in alanine and leucine. There exist non-homologous regions between R100 and F that could be represented as four I-D (insertion or deletion) loops in heteroduplex molecules. Assignment of each loop to the strand of R100 or F was , however, found to be the reverse from that previously assumed. The three I-D loops that were located between traT and traD, between traD and traI, and between traI and finO had no terminal inverted repeat sequences nor had they any homology with known insertion sequences, while the fourth was IS3, located within the finO gene of F. The sequences in the I-D loops, except IS3, may also code for proteins that are, however, likely to be nonessential for transfer of plasmids.

Translational control in production of transposase and in transposition of insertion sequence IS3.

IS3 (1258 bp in length) contains two open reading frames, orfA and orfB, which are out of phase and overlap each other. We show here that three proteins of 10, 32 and 42 kDa in size are encoded by IS3. The 10 kDa protein is the product of orfA and is here called OrfA. The ATG codon of orfB which overlaps the termination codon of orfA is utilized to produce the 32 kDa protein (here called OrfB), in a manner depending on translation of orfA. The 42 kDa protein is a transframe protein (here called OrfB), which is synthesized from orfA and orfB by -1 translational frameshifting at the A4G motif present in the overlapping region. Both the frameshifting event to produce OrfB and the coupled translation event to produce OrfB are greatly stimulated by a pseudo knot structure located in the overlapping region between orfA and orfB. A mutant IS3 with a single base insertion in the A4G motif efficiently produces the OrfB transframe protein without frameshifting. This mutant was found not to mediate co-integration but to mediate adjacent deletion to produce various miniplasmids and minicircles in large amounts. The OrfB transframe protein is necessary and sufficient for formation of these deletion products, implying that it is the transposase. Most of the minicircles consisted solely of the entire IS3 sequence and a three base-pair sequence between the IS3 ends. The significance of minicircle formation is discussed.

Differential scanning calorimetric study of the effect of intercalators and other kinds of DNA-binding drugs on the stepwise melting of plasmid DNA.

The effect of intercalating drugs (the anthracycline group of antibiotics, ethidium bromide, actinomycin D) on stepwise melting of DNA was studied by differential scanning calorimetry (DSC). The DSC DNA melting profile of plasmid pJL3-TB5 DNA (5277 base-pairs in length) consists of seven peaks, and all the intercalators caused shifting of these peaks, particularly those formed at the high temperature ranges, to the higher temperature ranges in a characteristic manner depending upon the binding strength of the drug. The analysis of the anthracycline group of antibiotics, such as aclacinomycin A, daunomycin, adriamycin and pyrarubicin, indicates that the difference in binding is due to the sugar moiety at position O-7 of the chromophore in these antibiotics. Analysis on the basis of the helix-coil transition theory suggests that the anthracycline group of antibiotics interact preferentially with the 5'-CG-3' sequences. The effect of various DNA-binding drugs other than intercalators on stepwise melting of DNA was then studied by DSC. The representative drugs examined were distamycin A, peplomycin, cis-dichlorodiamine-platinum(II) (cis-DDP or cis-Platin) and mitomycin C, which differ in their mode of interaction with DNA; namely, minor groove binding, strand cleavage and intrastrand or interstrand cross-linking. Distamycin A caused shifting of the DSC peaks at the low temperature ranges to a higher temperature range, whereas peplomycin and cis-DDP caused shifting of all the DSC peaks to form a broad peak at a lower temperature range, suggesting that the DSC DNA melting profiles are affected in a characteristic manner depending upon the interaction mode of the drug.

Insertion element IS1 encodes two structural genes required for its transposition.

The nucleotide sequence analysis of insertion element IS1 has shown that IS1 could have as many as six translational reading frames encoding possible proteins. In order to determine which reading frames are actual structural genes responsible for IS1-mediated recombination, we introduced base substitution mutations including nonsense mutations into all of the potential reading frames and examined the ability of these IS1 mutants to mediate cointegration between two plasmids. The results reveal that IS1 has two structural genes (termed insA and insB), which are required for plasmid cointegration mediated by IS1.

Both inverted repeat sequences located at the ends of IS1 provide promoter functions.

Escherichia coli RNA polymerase was found to bind specifically to restriction fragments containing either end of IS1. DNase I footprint analyses indicate that RNA polymerase protects approximately 70 base-pairs at each end of IS1, including the left or right terminal inverted repeat sequences in IS1 (termed insL or insR, respectively) as well as some non-IS1 sequence directly adjacent to each end of IS1. Analysis of transcripts from the left terminal region of IS1 shows that the insL sequence contains a promoter (named insPL), and that RNA synthesis initiates apparently at one in a stretch of five adenylate residues within insL and continues toward the interior region of IS1. Interestingly, most of the resulting transcripts contain polyuridylate residues (more than 5 U residues) at their 5'-ends. Analysis of transcripts from the right terminal region of IS1 indicates that the insR sequence also contains a promoter (named insPR). RNA synthesis initiates specifically at an adenylate residue within insR and continues toward the interior region of IS1, i.e. in the opposite direction to RNA synthesis initiating at insPL, which is present at the other end of IS1. We propose that insPL is used to make the messenger RNA for the IS1-encoded genes insA and insB, while insPR might be used to synthesize an anti-mRNA and thereby negatively regulate insPL.

Linearization and transposition of circular molecules of insertion sequence IS3.

IS3 transposase has been shown to promote production of characteristic circular and linear IS3 molecules from the IS3-carrying plasmid; IS3 circles have the entire IS3 sequence with terminal inverted repeats, IRL and IRR, which are separated by a three base-pair sequence originally flanking either end in the parental plasmid, whereas linear IS3 molecules have three nucleotide overhangs at their 5' ends. Here, we showed that a plasmid carrying an IS3 derivative, which is flanked by different sequences at both ends, generated IS3 circles and linear IS3 molecules owing to the action of transposase. Cloning and sequencing analyses of the linear molecules showed that each had the same 5'-protruding three nucleotide overhanging sequences at both ends, suggesting that the linear molecules were not generated from the parental plasmid by the two double-strand breaks at both end regions of IS3. The plasmid carrying IS3 with a two base-pair mutation in the terminal dinucleotide, which would be required for transposase to cleave the 3' end of IS3, could still generate linear molecules as well as circles. Plasmids bearing an IS3 circle were cleaved by transposase and gave linear molecules with the same 5'-protruding three nucleotide overhanging sequences. These show that the linear molecules are generated from IS3 circles via a double-strand break at the three base-pair intervening sequence. Plasmids carrying an IS3 circle with the two base-pair end mutation still were cleaved by transposase, though with reduced efficiencies, suggesting that IS3 transposase has the ability to cleave not only the 3' end of IS3, but a site three nucleotides from the 5' end of IS3. IS3 circles also were shown to transpose to the target plasmids. The end mutation almost completely inhibited this transposition, showing that the terminal dinucleotides are important for the transfer of the 3' end of IS3 to the target as well as for the end cleavage.

Unidirectional replication of plasmid R100.

We isolated a 284 base-pair BamHI fragment of plasmid R100 that supports initiation of replication of a plasmid regardless of the orientation of the fragment. Analysis of the specific radioactivity of restriction fragments from 32P-labeled replication intermediates synthesized in vitro shows that replication of the plasmid carrying the 284 base-pair fragment is unidirectional. The direction of replication depends on the orientation of the fragment present in the plasmid. The 5' ends of the leading-strand DNA formed in the early stage of replication were mapped to a region downstream from the 284 base-pair fragment in the direction of replication. The lagging-strand DNA products were also identified and their 3' ends mapped to unique sites within the 284 base-pair fragment causing unidirectional replication of R100.

Isolation and characterization of IS elements repeated in the bacterial chromosome.

Shigella sonnei contains repetitive sequences, including an insertion element IS1, which can be isolated as double-stranded DNA fragments by DNA denaturation and renaturation and by treatment with S1 nuclease. In this paper, we describe a method of cloning the IS1 fragments prepared by the S1 nuclease digestion technique into phage M13mp8 RFI DNA. Several clones contained IS1, usually with a few additional bases. We isolated and characterized five other repetitive sequences using this method. One sequence, 1264 base-pairs in length, had terminal inverted repeats and contained two open reading frames. This sequence, called IS600, showed about 44% sequence homology with IS3 and was repeated more than 20 times in the Sh. sonnei chromosome. Another sequence (named IS629, 1310 base-pairs in length), which was repeated six times, was found also to be related to IS3 and thus IS600. Two other sequences (named IS630 and IS640, 1159 and 1092 base-pairs in length, respectively), which were repeated approximately ten times, had characteristic terminal inverted repeats and contained a large open reading frame coding for a protein. The inverted repeat sequences of IS630 were similar to the sequence at one end of IS200, a Salmonella-specific IS element. The fifth sequence, repeated ten times in Sh. sonnei, had about 98% sequence homology with a portion of IS2. The method described here can be applied to the isolation of IS or iso-IS elements present in any other bacterial chromosome.

Energetics of coupled twist and writhe changes in closed circular pSM1 DNA.

The extent of local denaturation in closed circular pSM1 DNA depends upon the linking difference, delta Lk, and the temperature, t. We have determined the denaturation profiles, using gel electrophoresis, over the ranges -37 < or = delta Lk < or = +16 and 25 degrees C < or = t < or = 65 degrees C. We have applied statistical mechanical methods to these data to evaluate the free energies of superhelix formation, of the twisting of single strands around each other, and of the initration of local denaturation. Because the complete nucleotide sequence is needed for this analysis, the complete pSM1 DNA sequence was determined and is reported here. The values of the free energy parameters found in this work agree closely with those previously obtained from experiments with pBR322 DNA, suggesting that there is little dependence of these values on the particular DNA sequence. We find the temperature dependence of these free energies by the appropriate statistical mechanical analysis of the temperature-dependent denaturation profiles produced by supercoiling. Calculations of the transition probability profiles indicate that the course of local denaturation in pSM1 DNA involves a complex competition among several sites of comparable susceptibility. This contrasts with the melting of pBR322 DNA, in which one principal site dominates. In both molecules the sites of predicted denaturation occur at or near regulatory regions, suggesting that duplex destabilization may be associated with their biological activities.

A 37 X 10(3) molecular weight plasmid-encoded protein is required for replication and copy number control in the plasmid pSC101 and its temperature-sensitive derivative pHS1.

Nucleotide sequences were determined for a region essential for autonomous replication and partitioning of pSC101, a plasmid whose replication is dependent on the Escherichia coli dnaA gene product. The essential replication region contains one long coding sequence, rep101 , for a protein composed of 316 amino acids, and a polypeptide approximately 37 X 10(3) Mr in size was identified as the rep101 gene product. rep101 is preceded by two inverted repeat sequences, three directly repeated sequences and a region of high A + T content containing a sequence similar to the E. coli oriC consensus sequence. Because the lesions in seven replication-deficient insertion mutants, four mutants with increased copy number and one temperature-sensitive replication mutant occur within rep101 , the rep101 gene product must control pSC101 replication and copy number. par, a region adjacent to the replication region, which functions in stable plasmid inheritance, contains several inverted repeat sequences.

DNA replication errors produced by the replicative apparatus of Escherichia coli.

It has been hard to detect forward mutations generated during DNA synthesis in vitro by replicative DNA polymerases, because of their extremely high fidelity and a high background level of pre-existing mutations in the single-stranded template DNA used. Using the oriC plasmid DNA replication in vitro system and the rpsL forward mutation assay, we examined the fidelity of DNA replication catalyzed by the replicative apparatus of Escherichia coli. Upon DNA synthesis by the fully reconstituted system, the frequency of rpsL-mutations in the product DNA was increased to 1.9x10(-4), 50-fold higher than the background level of the template DNA. Among the mutations generated in vitro, single-base frameshifts predominated and occurred with a pattern similar to those induced in mismatch-repair deficient E. coli cells, indicating that the major replication error was slippage at runs of the same nucleotide. Large deletions and other structural alterations of DNA appeared to be induced also during the action of the replicative apparatus.

Tnat1 and Tnat2 from Arabidopsis thaliana: novel transposable elements with tandem repeat sequences.

A computer-aided homology search of databases found that the nucleotide sequences flanking ATLN44, a non-LTR retrotransposon (LINE) from Arabidopsis thaliana, are repeated in the A. thaliana genome. These sequences are homologous to flanking sequences of 664 bp with terminal inverted repeat sequences of about 70 bp. The 664-bp sequence and most of the 14 homologues identified were flanked by direct repeat sequences of 9 bp. These findings indicate that the repeated sequence, named Tnat1, is a transposable element that duplicates a 9-bp sequence at the target site on transposition and that ATLN44 is inserted in one Tnat1 member. Interestingly, all of the Tnat1 members had tandem repeats comprised of several units of a 60-bp sequence, the number of repeats differing among Tnat1 members. Of the Tnat1 members identified, one was inserted into another sequence repeated in the A. thaliana genome: that sequence is about 770 bp long and has terminal inverted repeat sequences of about 110 bp. The sequence is flanked by direct repeats of a 9-bp sequence, indicating that it is another transposable element, named Tnat2, from A. thaliana. Moreover, Tnat2 members had a tandem repeat about 240 bp long. Tnat1 and Tnat2 with tandem repeats in their internal regions show no homology to each other or to any of the elements identified previously; therefore they appear to be novel transposable elements.

A new class of LINEs (ATLN-L) from Arabidopsis thaliana with extraordinary structural features.

The Arabidopsis thaliana genome has about 250 copies of LINEs (here called ATLNs). Of these, some, called ATLN-Ls, have an extra sequence of about 2 kb in the region downstream of two consecutive open reading frames, orf1 and orf2. Interestingly, the extra sequences in these ATLN-L members have another open reading frame, designated as orf3. Each member is flanked by direct repeats of a target site sequence, showing that ATLN-L members with the three open reading frames have retrotransposed as a unit. The ATLN-L members are also distinct from other ATLN members: orf1 terminates with TAA (or TAG) and is located in the same frame as orf2, and the ATG initiation codon of orf2 is not present in the proximal region. A sequence that may form a pseudoknot structure in ATLN-L mRNA was present in the proximal region of orf2, therefore the TAA (or TAG) termination codon of orf1 is assumed to be suppressed to produce an Orf1-Orf2 transframe protein during the translation of the ATLN-L mRNA. The region between orf2 and orf3 is several hundred bp long, suggesting that orf3 expression is independent of orfl-orf2. The amino acid sequences of the proteins Orf1 and Orf3 are highly homologous in their N-terminal half regions that have a retroviral zinc-finger motif for RNA binding. Orf3, however, has a leucine-zipper motif in addition to the zinc-finger motif. The C-terminal regions of the Orf1 and Orf3 proteins have poor homology, but seem to have nuclear localization signals, suggesting that these proteins are involved in the transfer of ATLN-L mRNA to nuclei. A phylogenetic tree shows that Orf3 proteins form a branch distinct from the branches of the Orf1 proteins encoded by ATLN-L members. This indicates that an ancestor element of ATLN-Ls has incorporated the orf1 frame carried by another ATLN member into its distal region to orf1-orf2 during evolution.

ATLN elements, LINEs from Arabidopsis thaliana: identification and characterization.

Non-LTR retrotransposons (LINEs) are ubiquitous elements in the plant kingdom. Two hundred and nineteen LINE homologues (named ATLN) were identified in the A. thaliana genome, about 90% of which have been sequenced by a computer-aided homology search. Of these, the structures of 62 were analyzed in detail. Most, including those truncated for the 5' regions, were flanked by direct repeats of a sequence of 7-21 bp long, the target site sequence duplicated upon retrotransposition of each member. Thirty ATLN members had two consecutive open reading frames, corresponding to orf1 and orf2 essential for retrotransposition. The phylogenetic tree constructed from the amino acid sequences of the endonuclease domains of the Orf2 proteins showed that the ATLN members were grouped in two families (I and II) and that the members of each family could be further divided into several subfamilies. The members of each subfamily had several unique structural features in common in the intergenic region between orf1 and orf2 as well as in the downstream regions of orf2. Interestingly, orf2 in almost all the ATLN members is located in the -1 frame relative to orf1, indicative of the existence of such translational control mechanisms as translational coupling or frameshifting to produce an amount of Orf2 protein appropriate to that of Orf1. Moreover, the most proximal sequences in the 5' untranslated regions were non-homologous, even in members with the highest homology, unlike the LINEs in animals. The non-homologous sequences in the 5' untranslated regions might be acquired at or after transcription during retrotransposition of the ATLN elements.

Complete genome sequence of enterohemorrhagic Escherichia coli O157:H7 and genomic comparison with a laboratory strain K-12.

Escherichia coli O157:H7 is a major food-borne infectious pathogen that causes diarrhea, hemorrhagic colitis, and hemolytic uremic syndrome. Here we report the complete chromosome sequence of an O157:H7 strain isolated from the Sakai outbreak, and the results of genomic comparison with a benign laboratory strain, K-12 MG1655. The chromosome is 5.5 Mb in size, 859 Kb larger than that of K-12. We identified a 4.1-Mb sequence highly conserved between the two strains, which may represent the fundamental backbone of the E. coli chromosome. The remaining 1.4-Mb sequence comprises of O157:H7-specific sequences, most of which are horizontally transferred foreign DNAs. The predominant roles of bacteriophages in the emergence of O157:H7 is evident by the presence of 24 prophages and prophage-like elements that occupy more than half of the O157:H7-specific sequences. The O157:H7 chromosome encodes 1632 proteins and 20 tRNAs that are not present in K-12. Among these, at least 131 proteins are assumed to have virulence-related functions. Genome-wide codon usage analysis suggested that the O157:H7-specific tRNAs are involved in the efficient expression of the strain-specific genes. A complete set of the genes specific to O157:H7 presented here sheds new insight into the pathogenicity and the physiology of O157:H7, and will open a way to fully understand the molecular mechanisms underlying the O157:H7 infection.

Complete nucleotide sequences of 93-kb and 3.3-kb plasmids of an enterohemorrhagic Escherichia coli O157:H7 derived from Sakai outbreak.

Enterohemorrhagic Escherichia coli (EHEC) O157:H7, derived from an outbreak in Sakai city, Japan in 1996, possesses two kinds of plasmids: a 93-kb plasmid termed pO157, found in clinical EHEC isolates world-wide and a 3.3-kb plasmid termed pOSAK1, prevalent in EHEC strains isolated in Japan. Complete nucleotide sequences of both plasmids have been determined, and the putative functions of the encoded proteins and the cis-acting DNA sequences have been analyzed. pO157 shares strikingly similar genes and DNA sequences with F-factor and the transmissible drug-resistant plasmid R100 for DNA replication, copy number control, plasmid segregation, conjugative functions and stable maintenance in the host, although it is defective in DNA transfer by conjugation due to the truncation and deletion of the required genes and DNA sequences. In addition, it encodes several proteins implicated in EHEC pathogenicity such as an EHEC hemolysin (HlyA), a catalase-peroxidase (KatP), a serine protease (EspP) and type II secretion system. pOSAK1 possesses a ColE1-like replication system, and the DNA sequence is extremely similar to that of a drug-resistant plasmid, NTP16, derived from Salmonella typhimurium except that it lacks drug resistance transposons.