Transcription initiation sites within an IS2 insertion in a Gal-constitutive mutant of Escherichia coli

The transposon-like Correia elements encode numerous strong promoters and provide a potential new mechanism for phase variation in the meningococcus

Neisseria meningitidis is the primary causative agent of bacterial meningitis. The genome is rich in repetitive DNA and almost 2% is occupied by a diminutive transposon called the Correia element. Here we report a bioinformatic analysis defining eight subtypes of the element with four distinct types of ends. Transcriptional analysis, using PCR and a lacZ reporter system, revealed that two ends in particular encode strong promoters. The activity of the strongest promoter is dictated by a recurrent polymorphism (Y128) at the right end of the element. We highlight examples of elements that appear to drive transcription of adjacent genes and others that may express small non-coding RNAs. Pair-wise comparisons between three meningococcal genomes revealed that no more than two-thirds of Correia elements maintain their subtype at any particular locus. This is due to recombinational class switching between elements in a single strain. Upon switching subtype, a new allele is available to spread through the population by natural transformation. This process may represent a hitherto unrecognized mechanism for phase variation in the meningococcus. We conclude that the strain-to-strain variability of the Correia elements, and the large number of strong promoters encoded by them, allows for potentially widespread effects within the population as a whole. By defining the strength of the promoters encoded by the eight subtypes of Correia ends, we provide a resource that allows the transcriptional effects of a particular subtype at a given locus to be predicted.

Differential regulation of two genes encoding lysyl-tRNA synthetases in Escherichia coli: lysU-constitutive mutations compensate for a lysS null mutation

Lysyl-tRNA synthetases are synthesized in Escherichia coli from two distinct genes, lysS and lysU, which are regulated differentially. A strain which is null for lysS, the constitutive gene, was created by gene disruption (lysS1) and exhibited cold-sensitive lethality. Hence, lysS is dispensable at high temperatures. This cold sensitivity was suppressed by a multi-copy plasmid carrying lysU, the inducible gene. These data are interpreted as indicating that lysS is functionally replaceable by lysU for cell growth, and that the cold sensitivity of lysS1 is caused by insufficient expression of lysU at low temperatures. To investigate the mechanism of lysU expression, cold-resistant bypass mutations were isolated from lysS1, and named als (for abandonment of lysS). Two als mutations which were linked to lysU contain IS2 insertions upstream of the lysU promoter. They caused a 16-19-fold increase in the lysU-mRNA level. Furthermore, deletion mutations created immediately upstream of the lysU promoter restored growth of lysS1. These results suggest that transcription of lysU is negatively controlled by a cis-element located upstream of the promoter.

An Escherichia coli insertion element (IS2) provides a functional promoter in Bordetella pertussis

The adenylate cyclase (cyaA) gene of Bordetella pertussis is not expressed in Escherichia coli. Using cya-lac fusions, high-expression spontaneous mutants were isolated and shown to have the insertion element IS2 in orientation II integrated into the reading frame of cyaA. Upon transfer of the IS2-activated cya-lac fusion into B. pertussis, we found that the IS2-provided promoter is as efficient in B. pertussis as it is in E. coli. These results provide evidence that an insertion element derived from the E. coli chromosome can activate gene expression in B. pertussis, a taxonomically distant organism.

Constitutive activation of the fucAO operon and silencing of the divergently transcribed fucPIK operon by an IS5 element in Escherichia coli mutants selected for growth on L-1,2-propanediol

L-1,2-Propanediol is an irretrievable end product of L-fucose fermentation by Escherichia coli. Selection for increased aerobic growth rate on propanediol results in the escalation of basal synthesis of the NAD+-linked oxidoreductase encoded by fucO, a member of the fuc regulon for the utilization of L-fucose. In general, when fucO becomes constitutively expressed, two other simultaneous changes occur: the fucA gene encoding fuculose-1-phosphate aldolase becomes constitutively expressed and the fucPIK operon encoding fucose permease, fucose isomerase, and fuculose kinase becomes noninducible. In the present study, we show that fucO and fucA form an operon which is divergently transcribed from the adjacent fucPIK operon. In propanediol-positive and fucose-negative mutants the cis-controlling region shared by the operons fucAO and fucPIK is lengthened by 1.2 kilobases. DNA hybridization identified the insertion element to be IS5. This element, always oriented in the same direction with the left end (the BglII end) proximal to fucA, apparently causes constitutive expression of fucAO and noninducibility of fucPIK. The DNA of the fucAO operon and a part of the adjacent fucP was sequenced.

Analysis of relative reversion frequencies for IS2 insertion mutations in the regulatory region of the galOPETK operon of Escherichia coli

Two previously characterized mutations in the galOPETK operon of Escherichia coli, galOP-3 and galOPE-490, contain IS2 insertions only 1 bp apart in the gal regulatory region; yet only the former yields Gal+ phenotypic revertants at a detectable frequency. We have shown that the galOPE-490 allele comprises two mutations--an IS2(I) insertion at bp+(2-6) (relative to the gal mRNA start site) plus a C/G to A/T transversion at bp + 59. The latter creates an ochre stop codon and lies within the internal site of the bipartite gal operator; it acts as an operator mutation in an in vivo repressor titration assay. Analysis of a newly isolated allele (galOP-490*) which retains the IS2 of galOPE-490 but is galE+ reveals a reversion frequency approximately 30-fold higher than that of galOP-3. Reversion of galOPE-490 is at least 10,000-fold lower and has not been detectable even under conditions conducive to enhanced double mutations in other systems.

Activation of a cryptic pathway for threonine metabolism via specific IS3-mediated alteration of promoter structure in Escherichia coli

The tdh operon of Escherichia coli consists of two genes whose products catalyze sequential steps in the formation of glycine and acetyl coenzyme A from threonine. The operation of the tdh pathway can potentially confer at least two capabilities on the cell: the first is to provide a biosynthetic source of glycine, serine, or both that is an alternative to the conventional (triose phosphate) pathway; the second is to enable cells to utilize threonine as the sole carbon source. The latter capability is referred to as the Tuc+ phenotype. In wild-type E. coli, the tdh operon is expressed at levels that are too low to bestow the Tuc+ phenotype, even in leucine-supplemented media, where the operon is induced eightfold. In eight Tuc+ mutants, the expression of the tdh operon was elevated 100-fold relative to the uninduced wild-type operon. The physical state of the DNA at the tdh locus in these Tuc+ strains was analyzed by Southern blotting and by DNA sequencing. In eight independent isolates the mobile genetic element IS3 was found to lie within the tdh promoter region in identical orientations. In six cases that were examined by DNA sequencing, IS3 occupied identical sites between the -10 and -35 elements of the tdh promoter. The transcription start points for the wild-type tdh promoter and one IS3-activated tdh promoter were identical. In effect, the repeatedly observed transposition event juxtaposed an IS3-borne -35 region and the tdh-specific -10 region, generating a hybrid promoter whose utilization led to elevated, constitutive expression of the tdh operon. This is the first case of promoter activation by IS3 where the site of transcription initiation is unaltered.

Second-element turn-on of gene expression in an IS1 insertion mutant

To learn more about the ways in which genes silenced by insertion mutations can be reactivated, we have undertaken a systematic investigation of Gal+ revertants of the polar mutant galOP-306::IS1 in Escherichia coli K12. The selective conditions used excluded reversion to wild type by precise excision of IS1. In this system (which resided on a multi-copy plasmid) reversion to the Gal+ phenotype occurred with a frequency of about 10(-7) per cell and per generation. Analysis of the revertants revealed that - with the single exception of the previously published chromosomal mutant sis1 - alterations in the structure of IS1 lead to reactivation of gal operon expression. These events fall into four classes: (I) insertion of IS2 at position 327 in IS1, insertion of IS2 at position 687 in IS1, (III) insertion of a hitherto undetected mobile element, IS150, at position 387, (IV) a 16-bp deletion encompassing IS1 coordinates 553-568. Of some 200 independent reversion events studied, all but one were of types I-III i.e. they involved the intervention of a second mobile element.

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.

Promotion of RNA transcription on the insertion element IS30 of E. coli K12

Two promoters of RNA transcription have been identified on IS30 by an in vivo assay, in which various DNA fragments with IS30 sequences were inserted in front of the promoterless galK gene of plasmid pFD51. Both promoters have a similar activity of approximately 10% of the activity of the lacUV5 promoter. Promoter P30A precedes the long open reading frame (ORFA), and its proposed -35 region lies within the left-hand terminal inverted repeat of IS30. However, the apparent activity of promoter P30A is significantly reduced when measured in the 3' region of ORFA. Thus, either the activity of promoter P30A is controlled by an IS30-encoded product from the same element, or some termination of transcription from P30A occurs within the coding region of ORFA. Promoter P30C precedes a short open reading frame (ORFC) in-frame with ORFA, but in the opposite strand. Reading frame ORFC is closely followed by a terminator of RNA transcription, T30C. None of the other potential open reading frames predicted from the DNA sequence, with one possible exception, are preceded by a promoter of RNA transcription active in the assay. No significant transcription was detected out of the left-hand end of the complete element. However, a small amount, probably due to read-through from promoter P30A, was detected out of the right-hand end of a complete copy of IS30. In addition the right-hand end of IS30 has been shown to have the potential to create promoters by insertion.

Promotion of RNA transcription on the insertion element IS30 of E. coli K12

Two promoters of RNA transcription have been identified on IS30 by an in vivo assay, in which various DNA fragments with IS30 sequences were inserted in front of the promoterless galK gene of plasmid pFD51. Both promoters have a similar activity of approximately 10% of the activity of the lacUV5 promoter. Promoter P30A precedes the long open reading frame (ORFA), and its proposed -35 region lies within the left-hand terminal inverted repeat of IS30. However, the apparent activity of promoter P30A is significantly reduced when measured in the 3' region of ORFA. Thus, either the activity of promoter P30A is controlled by an IS30-encoded product from the same element, or some termination of transcription from P30A occurs within the coding region of ORFA. Promoter P30C precedes a short open reading frame (ORFC) in-frame with ORFA, but in the opposite strand. Reading frame ORFC is closely followed by a terminator of RNA transcription, T30C. None of the other potential open reading frames predicted from the DNA sequence, with one possible exception, are preceded by a promoter of RNA transcription active in the assay. No significant transcription was detected out of the left-hand end of the complete element. However, a small amount, probably due to read-through from promoter P30A, was detected out of the right-hand end of a complete copy of IS30. In addition the right-hand end of IS30 has been shown to have the potential to create promoters by insertion.

DNA rearrangements generating artificial promoters

The promoter-cloning plasmid pBRH4 (a derivative of pBR322 with a partially deleted promoter of the tet gene) is shown to contain a sequence which is located near the EcoRI site and can operate as an effective Pribnow box, but is not the remainder of the deletion-inactivated tet promoter of pBR322. If there is a sequence homologous to the '-35' promoter region at the border of the DNA fragment inserted at the EcoRI site, then a compound promoter arises and activates the tet gene. Point mutations in the nonfunctional--35 region of pBRH4 also activate the cryptic Pribnow box. Several compound promoters were obtained through deleting small portions of DNA around the HindIII site of pBR322; the deletions moved various sequences that could operate as Pribnow boxes towards the -35 region of the tet promoter.

Expression of the gin and mom genes of bacteriophage Mu

The gin and mom genes are located in the rightmost 1.6-kb segment, designated the beta segment, of bacteriophage Mu DNA. The gin gene is responsible for the inversion of the G segment of Mu, whereas the mom gene is involved in an unusual modification of the DNA. We have analyzed recombinant plasmids carrying one or both ends of Mu DNA for the expression of the Gin and Mom functions. The Gin protein and the presumptive Mom protein are not always detected in minicells, even though the plasmids being tested have the gin- and mom-containing segment of Mu DNA. However, some plasmids, in which the right end segment of Mu DNA is confined to the 1.6-kb beta segment, do give rise to these gene products in minicells. It seems that synthesis of the Gin and Mom proteins is inhibited in minicells, but this inhibition is lifted if most of the DNA to the left of the beta segment is eliminated from the plasmids. The most prominent Mu product detected in minicells is a 23-25-kDal polypeptide, termed here the zeta (zeta) protein. The function of the zeta protein remains unknown. In vitro transcription of Mu DNA with purified Escherichia coli RNA polymerase is limited to only two regions of the genome. The early region of Mu DNA is transcribed at a relatively high efficiency, whereas the beta region is transcribed at a low efficiency. This low-efficiency transcription appears to be specific for the gin gene; the mom gene transcript cannot be detected.

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.

A control system which causes alternating turn-off/turn-on of transcription on insertion element IS1

Presence of insertion element IS1 within an operon leads to absence of expression of genes distal to its integration site. This strong polar effect is observed irrespective of the orientation of IS1. Here I report on a mutant of E. coli K12 which allows turn-on of genes located distally to IS1. This turn-on is due to activation of transcription starting within IS1. The activation of transcription is under the control of a regulatory locus (sis1) which acts in trans. The regulatory locus itself changes its state, which leads to an alternating turn-off/turn-on of genes located distal to IS1: The rate of turn-off was observed with a frequency of about 0.3% (per cell and per generation), that of turn-on with a frequency of about 0.015% (per cell and per generation).

Specific in vitro transcription of the insertion sequence IS2

The insertion sequence IS2 is a small transposable element of Escherichia coli that lacks any known genetic markers. Insertion of this element in one orientation (I) within bacterial operons blocks expression of downstream genes. In the other orientation (II), IS2 has been associated with the constitutive expression of genes distal to its insertion, suggesting that IS2 might contain promoters directing transcription of IS2(II) into other genes. To test the transcription potential of IS2, we have transcribed in vitro DNA templates from gal3, a Gal- allele in which an IS2(I) is inserted between the gal promoter and the gal genes. We have detected two IS2-specific RNAs which initiate from promoters within IS2 and are transcribed in orientation II (away from the galETK genes). Though the presence and orientation of these promoters suggests that they could be responsible for the constitutive expression of genes adjacent to an IS2(II) element, an alternative role could be for transcription of IS2-encoded genes. Although IS2(I) insertions normally block expression of adjacent genes, certain altered (e.g. mutant) IS2(I) sequences lead to the constitutive expression of downstream genes. We have transcribed DNA templates from galwc5 and galc331, which are Galc alleles that contain altered IS2(I) insertions within the gal operon. For each allele, we have detected two gal-directed transcripts initiating within the IS2 sequence. These RNAs are not detected upon transcription of the unaltered IS2(I) DNA and the promoters arise as a direct consequence of the IS2(I) alterations. This result suggests that these promoters detected in vitro are responsible for the Galc phenotype of these alleles.

Compilation and analysis of Escherichia coli promoter DNA sequences

The DNA sequence of 168 promoter regions (-50 to +10) for Escherichia coli RNA polymerase were compiled. The complete listing was divided into two groups depending upon whether or not the promoter had been defined by genetic (promoter mutations) or biochemical (5' end determination) criteria. A consensus promoter sequence based on homologies among 112 well-defined promoters was determined that was in substantial agreement with previous compilations. In addition, we have tabulated 98 promoter mutations. Nearly all of the altered base pairs in the mutants conform to the following general rule: down-mutations decrease homology and up-mutations increase homology to the consensus sequence.

Insertion of IS2 creates a novel ampC promoter in Escherichia coli

A class of ampC beta-lactamase-hyperproducing mutants of Escherichia coli were shown to have the insertion element IS2 inserted into the ampC promoter. The insertion of IS2 in orientation II created a novel promoter in which the -35 region and the 17 bp long spacing sequence between the two consensus sequences are present in IS2 DNA, whereas the -10 region from the original ampC promoter is retained. In vitro transcription revealed that the transcription initiation site in the ampC::IS2 mutants was identical with that of ampC wild-type promoter. The novel promoter exhibited a 20-fold increase in promoter strength relative to the original ampC promoter, presumably due to the increase in the spacing sequence from 16 to 17 bp. The evolution of transposable elements and of control elements such as promoters are discussed on the basis of the findings described herein.