Insertion of IS3 Can “Turn-On” a Silent Gene in Escherichia coli

A silent argE gene became reactivated by the integration of IS3 in orientation II. IS3 itself is responsible for this effect, at least in part.     

A Novel Mechanism of Transposon-Mediated Gene Activation

Transposable Insertion Sequences (IS elements) have been shown to provide various benefits to their hosts via gene activation or inactivation under stress conditions by appropriately inserting into specific chromosomal sites. Activation is usually due to derepression or introduction of a complete or partial promoter located within the element. Here we define a novel mechanism of gene activation by the transposon IS5 in Escherichia coli. The glycerol utilization operon, glpFK, that is silent in the absence of the cAMP-Crp complex, is activated by IS5 when inserted upstream of its promoter. High-level expression is nearly constitutive, only mildly dependent on glycerol, glucose, GlpR, and Crp, and allows growth at a rate similar to or more rapid than that of wild-type cells. Expression is from the glpFK promoter and dependent on (1) the DNA phase, (2) integration host factor (IHF), and (3) a short region at the 3′ end of IS5 harboring a permanent bend and an IHF binding site. The lacZYA operon is also subject to such activation in the absence of Crp. Thus, we have defined a novel mechanism of gene activation involving transposon insertion that may be generally applicable to many organisms.     

Structural and biochemical characterization of the Escherichia coli argE gene product.

The DNA sequence of a 2,100-bp region containing the argE gene from Escherichia coli has been determined. The nucleotide sequence of the ppc-argE intergenic region was also solved and shown to contain six tandemly repeated REP sequences. Moreover, the oxyR gene has been mapped on the E. coli chromosome and shown to flank the arg operon. The codon responsible for the translation start of argE was determined by using site-directed mutants. This gene spans 1,400 bp and encodes a 42,350-Da polypeptide. The argE3 allele and a widely used argE amber gene have also been cloned and sequenced. N-Acetylornithinase, the argE product, has been overproduced and purified to homogeneity. Its main biochemical and catalytic properties are described. Moreover, we demonstrate that the protein is composed of two identical subunits. Finally, the amino acid sequence of N-acetylornithinase is shown to display a high degree of identity with those of the succinyldiaminopimelate desuccinylase from E. coli and carboxypeptidase G2 from a Pseudomonas sp. It is proposed that this carboxypeptidase might be responsible for the acetylornithinase-related activity found in the Pseudomonas sp.     

Nucleotide sequence of the Serratia marcescens SR50 chromosomal ampC β-lactamase gene

A novel type of osmoregulatory mutant of Escherichia coli K-12 exhibiting constitutive expression of the ompC gene was isolated and characterized at the molecular level In this particular mutant ( cec ; c onstitutive e xpression of Omp C ). an insertion sequence (IS-1) was found to be located at right upstream of the regulatory sequence for the ompC promoter. We demonstrate that the IS1 insertion observed in the cec mutant does not provide the ompC gene with an artificial promoter, but rather perturbs normal regulation of the ompC promoter, which is mediated by the regulatory gene, ompR .     

Lignin biodegradation by cultures of Rigidoporus lignosus in solid state conditions

A novel type of osmoregulatory mutant of Escherichia coli K-12 exhibiting constitutive expression of the ompC gene was isolated and characterized at the molecular level. In this particular mutant (cec; constitutive expression of OmpC), an insertion sequence (IS-1) was found to be located at right upstream of the regulatory sequence for the ompC promoter. We demonstrate that the IS1 insertion observed in the cec mutant does not provide the ompC gene with an artificial promoter, but rather perturbs normal regulation of the ompC promoter, which is mediated by the regulatory gene, ompR.     

Prevalence of IS(Aba1) in epidemiologically unrelated Acinetobacter baumannii clinical isolates

Seventy-five Acinetobacter baumannii strains belonging to different pulsetypes, plus one ceftazidime-susceptible strain, from a pulsetype in which all strains were resistant, were included in this study. The minimum inhibitory concentration of ceftazidime was determined by the microdilution method. The bla(ADC)-like gene, the IS(Aba1) element and the IS(Aba1) located in the bla(ADC)-like promoter were detected by PCR. The objective of the study was to determine the prevalence of IS(Aba1) in a collection of epidemiologically unrelated A. baumannii clinical isolates. The bla(ADC)-like gene was detected in 74 (97.3%) out of the 76 strains analysed. In these 74 strains, 51 (69%) were positive for the IS element and it was not detected in 23 (31%) strains. Among the A. baumannii strains containing the IS element, 40 (78.4%) had the IS element located in the promoter region of the bla(ADC)-like gene. In a high percentage of A. baumannii clinical isolates carrying the IS(Aba1), this is inserted into the promoter region of the bla(ADC)-like gene. In addition, two clinical isolates belonging to the same pulsetype, one with and one without the IS(Aba1), can be found in the clinical setting, suggesting the potential acquisition or loss of this genetic element in the hospital environment.     

Identification of transposable elements which activate gene expression in Pseudomonas cepacia.

This study demonstrated that transposable elements in Pseudomonas cepacia could be inserted upstream of a poorly expressed gene and increase its expression more than 30-fold. Five elements, TnPc1, IS402, IS403, IS404, and IS405, were isolated by their ability to increase expression of the beta-lactamase gene of the broad-host-range plasmid pRP1. Increased expression resulted only from insertion of these elements, suggesting that insertional activation is an important means of elevating gene expression in this organism. Four of the elements inserted between a PstI site within the beta-lactamase gene and a BamHI site located 375 base pairs upstream of its promoter. The element IS403 inserted distal to the BamHI site within the coding region for the gene tnpR, suggesting that insertional activation can act over greater than expected distances. In addition, the element IS402 activated the beta-lactamase genes carried on plasmids pRP1 and pMR5 (temperature-sensitive pRP1) equally well in opposite orientations, demonstrating that insertional activation by this element occurs independent of its orientation.     

Turn-on of Inactive Genes by Promoter Recruitment in ESCHERICHIA COLI: Inverted Repeats Resulting in Artificial Divergent Operons

We have characterized two rearrangements consisting of inverted repeats of the argE gene. The promoters (p) of argE and of argCBH face each other over an internal operator. The rearrangements were obtained as reactivations of argE in a strain harboring an argEp deletion on a lambda darg prophage. In both cases the repeat included argE and argCBHp on either side of a unique sequence; the result is a divergent operon in which each copy of argCBHp reads into the adjacent argE repeat. In one case, the pair of repeats adjoins the silent parental gene, forming a triplication (comes from leads to comes from). The other rearrangement consists of a single argE palindrome, but the whole prophage is rearranged into an inverted repeat, analogous to certain lambda dv's. Both structures could be explained by breakage of a replication fork passing argE and by inaccurate rejoining of strands. The lambda dv-like rearrangement would result from breakage at both replication forks of a phage or prophage replicating during transient release of immunity. The triplication would imply breaking of a chromosomal replication fork, formation of a cyclic intermediate by recombination between the daughter duplex molecules and reinsertion into the parental argE gene. Formation of a triplication by replication errors involving appropriate strand switchings and branch migrations can not be excluded however.     

LexA protein of Escherichia coli represses expression of the Tn5 transposase gene.

The LexA protein of Escherichia coli represses expression of a variety of genes that, by definition, constitute the SOS regulon. Genetic evidence suggests that Tn5 transposition is also regulated by the product of the lexA gene (C.-T. Kuan, S.-K. Liu, and I. Tessman, Genetics 128:45-57, 1991). We now show that the LexA protein represses expression of the tnp gene, located in the IS50R component of Tn5, which encodes a transposase, and that LexA does not repress expression of the IS50R inh gene, which encodes an inhibitor of transposition. Elimination of LexA resulted in increased expression of the tnp gene by a factor of 2.7 +/- 0.4, as indicated by the activity of a lacZ gene fused to the tnp gene. LexA protein retarded the electrophoretic movement of a 101-bp segment of IS50R DNA that contained a putative LexA protein-binding site in the tnp promoter; the interaction between the LexA repressor and the promoter region of the tnp gene appears to be relatively weak. These features show that the IS50R tnp gene is a member of the SOS regulon.     

Distal regulatory functions for the uvrC gene of E. coli.

We find that the uvrC gene is preceded by three promoters (P1, P2 and P3), identified by heparin-resistant RNA polymerase-DNA complex formation, P2 and P3 promoters are located proximal to the 5' end of the uvrC gene, while the P1 promoter is separated from the uvrC structural gene by an interposed DNA region of more than 1 kb. We have reported that P2 and P3 are not sufficient to promote uvrC complementation. However, plasmids containing the direct fusion of the P1 promoter to the uvrC gene complements the uvrC defect. Insertion of IS1 downstream from the P1 promoter leads to efficient synthesis of the uvrC protein as measured in maxicells. Fusion of the lac promoter to the uvrC structural gene can substitute for in vivo regulatory functions. We conclude that uvrC protein synthesis is controlled in a complex manner and that a distal promoter, P1, is required.     

Determination and characterization of IS4Bsu1-insertion loci and identification of a new insertion sequence element of the IS256 family in a natto starter

The insertion sequence IS4Bsu1 frequently causes Bacillus subtilis starters for the production of Japanese fermented soybean pasts (natto) to lose the ability to produce poly-gamma-glutamate, the viscous material characteristic of natto. Bacillus subtilis NAFM5, a derivative of a natto starter, has six IS4Bsu1 copies on its chromosome. In this study, we determined all six insertion loci of the insertion sequence (IS). One was located in the coding region of yktD, a putative gene involved in polyketide synthesis. Four were located in non-coding regions between iolR and iolA, between tuaA and lytC, between rapI and orf1 (a potential gene of unknown function), and between ynaE and orf3 (a putative gene similar to thiF), and one resided in an intergenic region between divergent possible orf4 and orf5 genes of unknown function. Here we describe the structural features of these loci and discuss the effects of the IS4Bsu1 insertions on the functions of the target gene and the expression of the downstream genes. In addition, we found that strain NAFM5 and commercial natto starters possess eight to 10 loci of another IS of the IS256 family (designated IS256Bsu1) on their chromosomes. IS256Bus1 appeared active in transposition, potentially causing phenotypic alterations in natto starters like those induced by IS4Bsu1.     

A transcriptional terminator sequence in the prokaryotic transposable element IS1

The prokaryotic transposable element IS1 is known to exert a strong polar effect upon integration into an operon. To elucidate this polar effect, we constructed a plasmid which has an IS1 integrated between the 5' half of the tet gene for tetracycline resistance and the cat structural gene for chloramphenicol resistance. The cat gene is expressed by the tet promoter and the presence of IS1 in orientation I, in which the IS1 transposase genes insA and insB are in the same orientation as the cat gene, reduced the cat expression. By introducing deletions or insertions within the IS1 sequence, we were able to map a rho-dependent terminator TIS1A between the insA and insB genes. Translational interruption between these ins genes is important for TIS1A to be an active terminator.     

Detection of an IS2-encoded 46-kilodalton protein capable of binding terminal repeats of IS2.

The genome of the transposable element IS2 contains five open reading frames that are capable of encoding proteins greater than 50 amino acids; however, only one IS2 protein of 14 kDa had been detected. By replacing the major IS2 promoter located in the right terminal repeat of IS2 with the T7 promoter to express IS2 genes, we have detected another IS2 protein of 46 kDa. This 46-kDa protein was designated InsAB'. Analyses of the InsAB' sequence revealed motifs that are characteristic of transposases of other transposable elements. InsAB' has the ability to bind both terminal repeat sequences of IS2. It was shown to bind a 27-bp sequence (5'-GTTAAGTGATAACAGATGTCTGGAAAT-3', positions 1316 to 1290 by our numbering system [16 to 42 by the previous numbering system]) located at the inner end of the right terminal repeat and a 31-bp sequence (5'-TTATTTAAGTGATATTGGTTGTCTGGAGATT-3', positions 46 to 16 [1286 to 1316]), including the last 27 bp of the inner end and the adjacent 4 bp of the left terminal repeat of IS2. This result suggests that InsAB' is a transposase of IS2. Since there is no open reading frame capable of encoding a 46-kDa protein in the entire IS2 genome, this 46-kDa protein is probably produced by a translational frameshifting mechanism.     

Recombination in recA cells between direct repeats of insertion element IS1.

The IS1 sequences that flank the Tn9 chloramphenicol acetyltransferase gene as direct repeats recombine after transformation into an Escherichia coli recA strain. The recombination requires the lambda pL promoter on the plasmid. A plasmid that contains mutant IS1 elements does not recombine. These results indicate that this recombination requires an IS1-specific gene product. The recombinational activity of IS1 may resolve transient cointegrates formed during the transposition of IS1. I discuss a possible role for the lambda pL promoter.