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

Historical Contingency Causes Divergence in Adaptive Expression of the lac Operon

Populations of Escherichia coli selected in constant and fluctuating environments containing lactose often adapt by substituting mutations in the lacI repressor that cause constitutive expression of the lac operon. These mutations occur at a high rate and provide a significant benefit. Despite this, eight of 24 populations evolved for 8,000 generations in environments containing lactose contained no detectable repressor mutations. We report here on the basis of this observation. We find that, given relevant mutation rates, repressor mutations are expected to have fixed in all evolved populations if they had maintained the same fitness effect they confer when introduced to the ancestor. In fact, reconstruction experiments demonstrate that repressor mutations have become neutral or deleterious in those populations in which they were not detectable. Populations not fixing repressor mutations nevertheless reached the same fitness as those that did fix them, indicating that they followed an alternative evolutionary path that made redundant the potential benefit of the repressor mutation, but involved unique mutations of equivalent benefit. We identify a mutation occurring in the promoter region of the uspB gene as a candidate for influencing the selective choice between these paths. Our results detail an example of historical contingency leading to divergent evolutionary outcomes.

Activation of Escherichia coli antiterminator BglG requires its phosphorylation

Transcriptional antiterminator proteins of the BglG family control the expression of enzyme II (EII) carbohydrate transporters of the bacterial phosphotransferase system (PTS). In the PTS, phosphoryl groups are transferred from phosphoenolpyruvate (PEP) via the phosphotransferases enzyme I (EI) and HPr to the EIIs, which phosphorylate their substrates during transport. Activity of the antiterminators is negatively controlled by reversible phosphorylation catalyzed by the cognate EIIs in response to substrate availability and positively controlled by the PTS. For the Escherichia coli BglG antiterminator, two different mechanisms for activation by the PTS were proposed. According to the first model, BglG is activated by HPr-catalyzed phosphorylation at a site distinct from the EII-dependent phosphorylation site. According to the second model, BglG is not activated by phosphorylation, but solely through interaction with EI and HPr, which are localized at the cell pole. Subsequently BglG is released from the cell pole to the cytoplasm as an active dimer. Here we addressed this discrepancy and found that activation of BglG requires phosphorylatable HPr or the HPr homolog FruB in vivo. Further, we uniquely demonstrate that purified BglG protein becomes phosphorylated by FruB as well as by HPr in vitro. Histidine residue 208 in BglG is essential for this phosphorylation. These data suggest that BglG is in fact activated by phosphorylation and that there is no principal difference between the PTS-exerted mechanisms controlling the activities of BglG family proteins in Gram-positive and Gram-negative bacteria.

Mu and IS1 transpositions exhibit strong orientation bias at the Escherichia coli bgl locus

The region upstream of the Escherichia coli bgl operon is an insertion hot spot for several transposons. Elements as distantly related as Tn1, Tn5, and phage Mu home in on this location. To see what characteristics result in a high-affinity site for transposition, we compared in vivo and in vitro Mu transposition patterns near the bgl promoter. In vivo, Mu insertions were focused in two narrow zones of DNA near bgl, and both zones exhibited a striking orientation bias. Five hot spots upstream of the bgl cyclic AMP binding protein (CAP) binding site had Mu insertions exclusively with the phage oriented left to right relative to the direction of bgl transcription. One hot spot within the CAP binding domain had the opposite (right-to-left) orientation of phage insertion. The DNA segment lying between these two Mu hot-spot clusters is extremely A/T rich (80%) and is an efficient target for insertion sequences during stationary phase. IS1 insertions that activate the bgl operon resulted in a decrease in Mu insertions near the CAP binding site. Mu transposition in vitro differed significantly from the in vivo transposition pattern, having a new hot-spot cluster at the border of the A/T-rich segment. Transposon hot-spot behavior and orientation bias may relate to an asymmetry of transposon DNA-protein complexes and to interactions with proteins that produce transcriptionally silenced chromatin.

Identification and characterization of IS1411, a new insertion sequence which causes transcriptional activation of the phenol degradation genes in Pseudomonas putida

A new insertion sequence (IS element), IS1411, was identified downstream of the phenol degradation genes pheBA that originated from plasmid DNA of Pseudomonas sp. strain EST1001. According to sequence analysis, IS1411 belongs to a new family of IS elements that has recently been named the ISL3 family (J. Mahillon and M. Chandler, Microbiol. Mol. Biol. Rev. 62:725-774, 1998). IS1411 generates 8-bp duplication of the target DNA and carries 24-bp inverted repeats (IRs), highly homologous to the IRs of other IS elements belonging to this family. IS1411 was discovered as a result of insertional activation of promoterless pheBA genes in Pseudomonas putida due to the presence of outward-directed promoters at the left end of IS1411. Both promoters located on the IS element have sequences that are similar to the consensus sequence of Escherichia coli sigma70. IS1411 can produce IS circles, and the circle formation is enhanced when two copies of the element are present in the same plasmid.

Identification of chromosomal mobile element conferring high-level vancomycin resistance in Enterococcus faecium

A clinical isolate of Enterococcus faecium that contains a chromosomally encoded vanA gene cluster, Tn1546::IS1251, transferred vancomycin resistance to the plasmid-free strain Enterococcus faecalis JH2-2 during filter matings. Hybridization of a vanHAXY probe to SmaI restriction-digested genomic DNA separated by pulsed-field gel electrophoresis showed that the vanA gene cluster was located on a 40-kb fragment in the original donor strain and on fragments of different sizes (150 to 450 kb) in the transconjugants. No hybridization to vanA gene cluster probes was obtained with plasmid DNA preparations from the donor or transconjugants. These results suggested that in each case, the van genes had integrated into the recipient chromosome. The transconjugants in turn could act as donors of vancomycin resistance, and resistance was transferable to a Rec- recipient. The results of restriction analyses and DNA hybridizations of genomic DNA from the donor and transconjugants were consistent with the transfer of a mobile element that includes the 12.3-kb Tn1546::IS1251 gene cluster and at least 13 kb of additional DNA. This element has been tentatively designated Tn5482. DNA sequence analysis of a fragment predicted to contain the left end of Tn5482 revealed two insertion sequence-like elements: IS1216V and an apparently truncated IS3-like element. Restriction mapping and DNA hybridization patterns of the van gene clusters of three additional clinical isolates from New York City showed an element similar to Tn5482. Transfer of Tn5482 and related elements may be involved in dissemination of vancomycin resistance.

Molecular characterization of catalase from Bordetella pertussis: identification of the katA promoter in an upstream insertion sequence

In this report we evaluate the role of catalase in the survival of Bordetella pertussis within human polymorphonuclear leukocytes (PMNs). Crude extracts of B. pertussis exhibited a single catalase activity when subjected to non-denaturing polyacrylamide gel electrophoresis and assayed for catalase activity. A plasmid containing B. pertussis katA was identified by complementation of UM255, a catalase-deficient strain of Escherichia coli. The nucleotide sequence of katA predicts a 55 kDa protein that shares homology with a class of haem-containing catalases found in both eubacteria and eukaryotes. Analysis of the nucleotide sequence upstream of katA revealed the presence of a copy of IS481, a B. pertussis-specific insertion sequence. The start site of transcription of katA was mapped to a T residue in IS481 by primer extension analysis performed with B. pertussis RNA and a katA-specific primer. A catalase-deficient strain of B. pertussis, DD900, was constructed by gene replacement. DD900 was more sensitive to killing by 1 and 5 mM H2O2 than the parental strain, BP339. However, there was no difference in the ability of DD900 and BP339 to survive for 2 h in human PMNs. This suggests that catalase plays no significant role in the survival of B. pertussis within PMNs.

Isolation of a novel IS3 group insertion element and construction of an integration vector for Lactobacillus spp

An insertion sequence (IS) element from Lactobacillus johnsonii was isolated, characterized, and exploited to construct an IS-based integration vector. L. johnsonii NCK61, a high-frequency conjugal donor of bacteriocin production (Laf+) and immunity (Lafr), was transformed to erythromycin resistance (Emr) with the shuttle vector pSA3. The NCK61 conjugative functions were used to mobilize pSA3 into a Laf- Lafs EMs recipient. DNA from the Emr transconjugants transformed into Escherichia coli MC1061 yielded a resolution plasmid with the same size as that of pSA3 with a 1.5-kb insertion. The gram-positive replication region of the resolution plasmid was removed to generate a pSA3-based suicide vector (pTRK327) bearing the 1.5-kb insert of Lactobacillus origin. Plasmid pTRK327 inserted randomly into the chromosomes of both Lactobacillus gasseri ATCC 33323 and VPI 11759. No homology was detected between plasmid and total host DNAs, suggesting a Rec-independent insertion. The DNA sequence of the 1.5-kb region revealed the characteristics of an IS element (designated IS1223): a length of 1,492 bp; flanking, 25-bp, imperfect inverted repeats; and two overlapping open reading frames (ORFs). Sequence comparisons revealed 71.1% similarity, including 35.7% identity, between the deduced ORFB protein of the E. coli IS element IS150 and the putative ORFB protein encoded by the Lactobacillus IS element. A putative frameshift site was detected between the overlapping ORFs of the Lactobacillus IS element. It is proposed that, similar to IS150, IS1223 produces an active transposase via translational frameshifting between two tandem, overlapping ORFs.

High-level ribosomal frameshifting directs the synthesis of IS150 gene products

IS150 contains two tandem, out-of-phase, overlapping genes, ins150A and ins150B, which are controlled by the same promoter. These genes encode proteins of 19 and 31 kD, respectively. A third protein of 49 kD is a transframe gene product consisting of domains encoded by both genes. Specific -1 ribosomal frameshifting is responsible for the synthesis of the large protein. Expression of ins150B also involves frameshifting. The IS150 frameshifting signals operate with a remarkably high efficiency, causing about one third of the ribosomes to switch frame. All of the signals required for this process are encoded in a 83-bp segment of the element. The heptanucleotide A AAA AAG and a potential stem-loop-forming sequence mark the frameshifting site. Similar sequence elements are found in -1 frameshifting regions of bacterial and retroviral genes. A mutation within the stem-loop sequence reduces the rate of frameshifting by about 80%. Artificial transposons carrying this mutation transpose at a normal frequency, but form cointegrates at a approximately 100-fold reduced rate.

Genome mapping and protein coding region identification using bacteriophage Mu

Transposons such as bacteriophage Mu provide a means to clone bacterial genes as alternatives to using standard recombinant DNA technologies. A DNA-cloning and gene-expressing system has been developed with a bacteriophage Mu (DNA capacity of 38 kb) vector that combines the Mu transposition capabilities and a specialized promoter from bacteriophage T7. Genes cloned with this vector can be identified by transcription in vivo with T7 RNA polymerase and subsequent host translation. This system, illustrated with the characterization of a 35-kb region of the Escherichia coli K-12 chromosome, is applicable to other Enterobacteriaceae, which are hosts for Mu phage, and is potentially applicable to other bacteria, including Pseudomonas aeruginosa, which have Mu-like phage, and to other organisms for which high-frequency transposons are available.

Identification, DNA sequence, and distribution of IS981, a new, high-copy-number insertion sequence in lactococci

An insertion in the lactococcal plasmid pGBK17, which inactivated the gene(s) encoding resistance to the prolate-headed phage c2, was cloned, sequenced, and identified as a new lactococcal insertion sequence (IS). IS981 was 1,222 bp in size and contained two open reading frames, one large enough to encode a transposase. IS981 ended in imperfect inverted repeats of 26 of 40 bp and generated a 5-bp direct repeat of target DNA at the site of insertion. IS981 was present on the chromosome of Lactococcus lactis subsp. lactis LM0230 from where it transposed to pGBK17 during transformation. Twenty-three strains of lactococci examined for the presence of IS981 by Southern hybridization showed 4 to 26 copies per genome, with L. lactis subsp. cremoris strains containing the highest number of copies. Comparison of the DNA sequence and the amino acid sequence of the long open reading frame to other known sequences showed that IS981 is related to a family of IS elements that includes IS2, IS3, IS51, IS150, IS600, IS629, IS861, IS904, and ISL1.

Beta-glucoside permease represses the bgl operon of Escherichia coli by phosphorylation of the antiterminator protein and also interacts with glucose-specific enzyme III, the key element in catabolite control

The beta-glucoside (bgl) operon of Escherichia coli is subject to both positive control by transcriptional termination/antitermination and negative control by the beta-glucoside-specific transport protein, an integral membrane protein known as enzyme IIBgl. Previous results led us to speculate that enzyme IIBgl exerts its negative control by phosphorylating and thereby inactivating the antiterminator protein, BglG. Specifically, our model postulated that the transport protein enzyme IIBgl exhibits protein-phosphotransferase activity in the absence of beta-glucosides. We now present biochemical evidence that the phosphorylation of protein BglG does indeed occur in vivo and that it is accompanied by the loss of antitermination activity. BglG persists in the phosphorylated state in the absence of beta-glucosides but is rapidly dephosphorylated when beta-glucosides become available for transport. Our data also suggested specific interactions between the beta-glucoside transport protein and the glucose-specific enzyme III (enzyme IIIGlc), a component of glucose transport and a key element in regulation of catabolite repression. These observations indicate that enzyme IIIGlc may, in conjunction with enzyme IIBgl, modulate the transport of beta-glucosides and the phosphorylation of the antiterminator protein. In the absence of both sugars, when the catabolite-controlled promoter of the operon is derepressed, enzyme IIIGlc may mediate tight repression of antitermination.

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.

IS150: distribution, nucleotide sequence and phylogenetic relationships of a new E. coli insertion element

Recently we identified the new insertion (IS) sequence IS150 in various strains of Escherichia coli K-12. We have screened other strains of E. coli and Salmonella typhimurium for the presence of homologous sequences. The strains of E. coli K-12 and W tested contain one or more copies of homology to IS150. We have also determined the complete nucleotide sequence of a copy of IS150 inserted into IS1. Comparison of nucleotide and deduced amino acid sequences of IS150, IS2, IS3, IS51, IS600 and IS629 reveals significant homologies suggesting that these elements are members of a family of phylogenetically related insertion sequences.