The control region of the F plasmid transfer operon: DNA sequence of the traJ and traY genes and characterisation of the traY leads to Z promoter

Fine-tuning the regulation of Cas9 expression levels for efficient CRISPR-Cas9 mediated recombination in Streptomyces

CRISPR-Cas9 has proven as a very powerful gene editing tool for Actinomyces, allowing scarless and precise genome editing in selected strains of these biotechnologically relevant microorganisms. However, its general application in actinomycetes has been limited due to its inefficacy when applying the system in an untested strain. Here, we provide evidence of how Cas9 levels are toxic for the model actinomycetes Streptomyces coelicolor M145 and Streptomyces lividans TK24, which show delayed or absence of growth. We overcame this toxicity by lowering Cas9 levels and have generated a set of plasmids in which Cas9 expression is either controlled by theophylline-inducible or constitutive promoters. We validated the targeting of these CRISPR-Cas9 system using the glycerol uptake operon and the actinorhodin biosynthesis gene cluster. Our results highlight the importance of adjusting Cas9 expression levels specifically in strains to gain optimum and efficient gene editing in Actinomyces.

Cooperative Function of TraJ and ArcA in Regulating the F Plasmid tra Operon

The F plasmid tra operon encodes most of the proteins required for bacterial conjugation. TraJ and ArcA are known activators of the tra operon promoter P_Y, which is subject to H-NS-mediated silencing. Donor ability and promoter activity assays indicated that P_Y is inactivated by silencers and requires both TraJ and ArcA for activation to support efficient F conjugation. The observed low-level, ArcA-independent F conjugation is caused by tra expression from upstream alternative promoters. Electrophoretic mobility shift assays showed that TraJ alone weakly binds to P_Y regulatory DNA; however, TraJ binding is significantly enhanced by ArcA binding to the same DNA, indicating cooperativity of the two proteins. Analysis of binding affinities between ArcA and various DNA fragments in the P_Y regulatory region defined a 22-bp tandem repeat sequence (from -76 to -55 of P_Y) sufficient for optimal ArcA binding, which is immediately upstream of the predicted TraJ-binding site (from -54 to -34). Deletion analysis of the P_Y promoter in strains deficient in TraJ, ArcA, and/or H-NS determined that sequences upstream of -103 are required by silencers including H-NS for P_Y silencing, whereas sequences downstream of -77 are targeted by TraJ and ArcA for activation. TraJ and ArcA appear not only to counteract P_Y silencers but also to directly activate P_Y in a cooperative manner. Our data reveal the cooperativity of TraJ and ArcA during P_Y activation and provide insights into the regulatory circuit controlling F-family plasmid-mediated bacterial conjugation.IMPORTANCE Conjugation is a major mechanism for dissemination of antibiotic resistance and virulence among bacterial populations. The tra operon in the F family of conjugative plasmids encodes most of the proteins involved in bacterial conjugation. This work reveals that activation of tra operon transcription requires two proteins, TraJ and ArcA, to bind cooperatively to adjacent sites immediately upstream of the major tra promoter P_Y The interaction of TraJ and ArcA with the tra operon not only relieves P_Y from silencers but also directly activates it. These findings provide insights into the regulatory circuit of the F-family plasmid-mediated bacterial conjugation.

Conjugative coupling proteins interact with cognate and heterologous VirB10-like proteins while exhibiting specificity for cognate relaxosomes

Conjugative coupling proteins (CPs) are proposed to play a role in connecting the relaxosome to a type IV secretion system (T4SS) during bacterial conjugation. Here we present biochemical and genetic evidence indicating that the prototype CP, TrwB, interacts with both relaxosome and type IV secretion components of plasmid R388. The cytoplasmic domain of TrwB immobilized in an affinity resin retained TrwC and TrwA proteins, the components of R388 relaxosome. By using the bacterial two-hybrid system, a strong interaction was detected between TrwB and TrwE, a core component of the conjugative T4SS. This interaction was lost when the transmembrane domains of either TrwB or TrwE were deleted, thus suggesting that it takes place within the membrane or periplasmic portions of both proteins. We have also analyzed the interactions with components of the related IncN plasmid pKM101. Its CP, TraJ, did not interact with TrwA, suggesting a highly specific interaction with the relaxosome. On the other side, CPs from three different conjugation systems were shown to interact with both their cognate TrwE-like component and the heterologous ones, suggesting that this interaction is less specific. Mating experiments among the three systems confirmed that relaxosome components need their cognate CP for transfer, whereas T4SSs are interchangeable. As a general rule, there is a correlation between the strength of the interaction seen by two-hybrid analysis and the efficiency of transfer.

Regulatory mechanisms in expression of the traY-I operon of sex factor plasmid R100: involvement of traJ and traY gene products

BACKGROUND

The plasmid R100 encodes tra genes essential for conjugal DNA transfer in Escherichia coli. Genetic evidence suggests that the traJ gene encodes a positive regulator for the traY-I operon, which includes almost all the tra genes located downstream of traJ. The molecular mechanism of regulation by TraJ, however, is not yet understood. traY is the most proximal gene in the traY-I operon. TraY promotes DNA transfer by binding to a site, sbyA, near the origin of transfer. TraY is suggested to have another role in regulation of the traY-I operon, since it binds to two other sites, named sbyB and sbyC, located in the region preceding traY-I.

RESULTS

Using a traY-lacZ fusion gene, we showed that the traY-I operon was expressed only in the presence of traJ. The TraJ-dependent expression of traY-I required the E. coli arcA gene, which encodes a host factor required for conjugation. TraJ-dependent transcription occurred from a promoter (named pY) located upstream of traY-I. The isolated TraJ protein was found to bind to a dyad symmetry sequence, named sbj (specific binding site of TraJ), which existed in the intergenic region between traJ and traY-I. We also demonstrated that TraY repressed the TraJ-dependent expression of traY-I at the TraY binding sites, sbyB and sbyC, which overlapped with pY.

CONCLUSIONS

TraJ is a protein which binds to the sbj site in the region upstream of the promoter pY and positively regulates expression of the traY-I operon in the presence of the E. coli arcA gene. Since sbj is located 93bp upstream of pY in the intergenic region between traJ and traY-I, TraJ presumably contacts with a transcription apparatus to promote transcription from pY. TraY, which is known to activate the initiation of conjugal DNA transfer, has a new role in the transcriptional autoregulation of traY-I expression. At levels which are sufficient to initiate conjugal DNA transfer, TraY represses traY-I transcription in the presence of TraJ.

Analysis of the sequence and gene products of the transfer region of the F sex factor

Bacterial conjugation results in the transfer of DNA of either plasmid or chromosomal origin between microorganisms. Transfer begins at a defined point in the DNA sequence, usually called the origin of transfer (oriT). The capacity of conjugative DNA transfer is a property of self-transmissible plasmids and conjugative transposons, which will mobilize other plasmids and DNA sequences that include a compatible oriT locus. This review will concentrate on the genes required for bacterial conjugation that are encoded within the transfer region (or regions) of conjugative plasmids. One of the best-defined conjugation systems is that of the F plasmid, which has been the paradigm for conjugation systems since it was discovered nearly 50 years ago. The F transfer region (over 33 kb) contains about 40 genes, arranged contiguously. These are involved in the synthesis of pili, extracellular filaments which establish contact between donor and recipient cells; mating-pair stabilization; prevention of mating between similar donor cells in a process termed surface exclusions; DNA nicking and transfer during conjugation; and the regulation of expression of these functions. This review is a compendium of the products and other features found in the F transfer region as well as a discussion of their role in conjugation. While the genetics of F transfer have been described extensively, the mechanism of conjugation has proved elusive, in large part because of the low levels of expression of the pilus and the numerous envelope components essential for F plasmid transfer. The advent of molecular genetic techniques has, however, resulted in considerable recent progress. This summary of the known properties of the F transfer region is provided in the hope that it will form a useful basis for future comparison with other conjugation systems.

Bioenergetic aspects of the translocation of macromolecules across bacterial membranes

Bacteria are extremely versatile in the sense that they have gained the ability to transport all three major classes of biopolymers through their cell envelope: proteins, nucleic acids, and polysaccharides. These macromolecules are translocated across membranes in a large number of cellular processes by specific translocation systems. Members of the ABC (ATP binding cassette) superfamily of transport ATPases are involved in the translocation of all three classes of macromolecules, in addition to unique transport ATPases. An intriguing aspect of these transport processes is that the barrier function of the membrane is preserved despite the fact the dimensions of the translocated molecules by far surpasses the thickness of the membrane. This raises questions like: How are these polar compounds translocated across the hydrophobic interior of the membrane, through a proteinaceous pore or through the lipid phase; what drives these macromolecules across the membrane; which energy sources are used and how is unidirectionality achieved? It is generally believed that macromolecules are translocated in a more or less extended, most likely linear form. A recurring theme in the bioenergetics of these translocation reactions in bacteria is the joint involvement of free energy input in the form of ATP hydrolysis and via proton sym- or antiport, driven by a proton gradient. Important similarities in the bioenergetic mechanisms of the translocation of these biopolymers therefore may exist.

Contributions of promoter context and structure to regulated expression of the F plasmid traY promoter in Escherichia coli K-12

Expression of the F plasmid traY promoter in vivo requires both host (E. coli) and plasmid encoded proteins. As judged by transcript size and primer extension analyses, the F plasmid traY promoter was utilized in vitro by purified E. coli sigma 70 RNA polymerase in the absence of other proteins. However, in vitro transcription required supercoiled templates. Endonuclease protection experiments showed that RNA polymerase is unable to form a stable complex at the traY promoter in linear or relaxed circular templates. In vitro transcription with linear templates could be elicited by altering the traY -10 and -35 hexamers to the consensus sequences. Alterations that reduced the effect of template supercoiling on apparent promoter strength in vitro also reduced the effect of the F plasmid TraJ protein on traY expression in vivo. Apparent traY promoter strength in vitro, estimated in template competition experiments, was unaltered by deletion of tra DNA normally upstream of the promoter, a change in promoter context that elicited high levels of promoter activity in TraJ- cells. These data suggest a model for regulated traY promoter activity in which a nucleoprotein complex involving tra DNA immediately upstream locally relaxes traY promoter DNA. TraJ and perhaps other activators could disrupt the complex, allowing promoter DNA to equilibrate at the prevailing negative superhelical density and thereby eliciting transcription initiation.

Characterization of the Escherichia coli F factor traY gene product and its binding sites

The traY gene product (TraYp) from the Escherichia coli F factor has previously been purified and shown to bind a DNA fragment containing the F plasmid oriT region (E. E. Lahue and S. W. Matson, J. Bacteriol. 172:1385-1391, 1990). To determine the precise nucleotide sequence bound by TraYp, DNase I footprinting was performed. The TraYp-binding site is near, but not coincident with, the site that is nicked to initiate conjugative DNA transfer. In addition, a second TraYp binding site, which is coincident with the mRNA start site at the traYI promoter, is described. The Kd for each binding site was determined by a gel mobility shift assay. TraYp exhibits a fivefold higher affinity for the oriT binding site compared with the traYI promoter binding site. Hydrodynamic studies were performed to show that TraYp is a monomer in solution under the conditions used in DNA binding assays. Early genetic experiments implicated the traY gene product in the site- and strand-specific endonuclease activity that nicks at oriT (R. Everett and N. Willetts, J. Mol. Biol. 136:129-150, 1980; S. McIntire and N. Willetts, Mol. Gen. Genet. 178:165-172, 1980). As this activity has recently been ascribed to helicase I, it was of interest to see whether TraYp had any effect on this reaction. Addition of TraYp to nicking reactions catalyzed by helicase I showed no effect on the rate or efficiency of oriT nicking. Roles for TraYp in conjugative DNA transfer and a possible mode of binding to DNA are discussed.

Sequence alterations affecting F plasmid transfer gene expression: a conjugation system dependent on transcription by the RNA polymerase of phage T7

We constructed derivatives of the Escherichia coli conjugative plasmid F that carry altered sequences in place of the major transfer operon promoter, PY. Replacement of PY with a promoter-deficient sequence resulted in a transfer-deficient, F-pilus-specific phage-resistant plasmid (pOX38-tra701) that could still express TraJ and TraT; TraY, F-pilin, TraD, and TraI were not detectable on Western blots. On a second plasmid (pOX38-tra715) we replaced PY with a phage T7 late promoter sequence. In hosts carrying a lacUV5-promoter-regulated T7 RNA polymerase gene, all transfer-associated properties of pOX38-tra715 could be regulated with IPTG. After induction, pOX38-tra715 transferred at the wild-type frequency, expressed normal numbers of F-pili and conferred sensitivity to pilus-specific phages. No adverse effects on cell viability were apparent, and additional mutations could easily be crossed onto pOX38-tra715. A traJ deletion (pOX38-tra716) had no effect on the IPTG-induced transfer phenotype. Insertion of cam into trbC, resulted in a mutant (pOX38-tra715trbC33) which, after induction, exhibited the same phenotype associated with other trbC mutants; it could also be complemented by expression of trbC in trans. With pOX38-tra715 or its derivatives, we were able to label specifically the products of tra genes located throughout the long tra operon, by using rifampicin. This feature can be used to investigate transfer protein interactions and to follow changes in these proteins that are associated with conjugal mating events.

Expert system for predicting protein localization sites in gram-negative bacteria

We have developed an expert system that makes use of various kinds of knowledge organized as "if-then" rules for predicting protein localization sites in Gram-negative bacteria, given the amino acid sequence information alone. We considered four localization sites: the cytoplasm, the inner (cytoplasmic) membrane, the periplasm, and the outer membrane. Most rules were derived from experimental observations. For example, the rule to recognize an inner membrane protein is the presence of either a hydrophobic stretch in the predicted mature protein or an uncleavable N-terminal signal sequence. Lipoproteins are first recognized by a consensus pattern and then assumed present at either the inner or outer membrane. These two possibilities are further discriminated by examining an acidic residue in the mature N-terminal portion. Furthermore, we found an empirical rule that periplasmic and outer membrane proteins were successfully discriminated by their different amino acid composition. Overall, our system could predict 83% of the localization sites of proteins in our database.

Regulation of the F plasmid traY promoter in Escherichia coli K12 as a function of sequence context

TraJ and SfrA are, respectively, plasmid and host (Escherichia coli)-encoded proteins normally required for F plasmid traY promoter function. Beginning with plasmids in which a traY-lacZ fusion gene, designated phi (traY'-'lacZ)hyb, and lacY are expressed from the F plasmid traY promoter, we isolated mutants in which lac gene expression was SfrA or TraJ-independent. A total of 45 of 50 SfrA-independent isolates obtained after 2-aminopurine mutagenesis proved to have chromosomal mutations, whereas four out of four isolates obtained without mutagenesis had plasmid mutations. All of 17 isolates selected for TraJ-independent expression after mutagenesis had plasmid mutations. By restriction endonuclease digestions, 25 of 26 SfrA-independent and TraJ-independent plasmid mutations were insertions. Four of the former and three of the latter were examined further. By sequence analysis, all seven proved to be IS1 or IS2 insertions defining five insertion sites between base-pairs -49 and -82 with respect to the major traY transcription initiation site. In two cases, the same insertion allele was obtained from the two selection schemes. All three of the mutants selected for TraJ-independent gene expression manifested SfrA-independent expression as well, and levels of beta-galactosidase in different plasmid mutant strains lacking TraJ and SfrA were indistinguishable. By primer extension analysis, transcription initiation sites for traY mRNA synthesis were unaltered by the mutations. Replacing the tra sequence upstream from base-pair -78, without genetic selection, increased beta-galactosidase activity in the absence of TraJ and SfrA greater than tenfold. Activity increased two- to threefold more in a traJ+ sfrA mutant strain, and fivefold more in a traJ+ sfrA+ strain. Activity was unaltered in an sfrA+ strain without TraJ. By primer extension analysis, the traY promoter was utilized under all conditions. The data indicate that regulation of traY promoter activity is strongly dependent on sequence context.

Characterization of the oriT region of the IncFV plasmid pED208

DNA sequence analysis of a 2.2kb EcoRI-HindIII fragment from pED208, the derepressed form of the IncFV plasmid Folac, revealed sequences highly homologous to the oriT region, traM, and traJ genes of other IncF plasmids. The TraM protein was purified and immunoblots of fractionated cells containing pED208 or Folac showed that TraM was predominantly in the cytoplasm. Using DNA retardation assays and the DNase I footprinting technique, the TraM protein was found to bind to three large motifs in the oriT region: (I) an inverted repeat, (II) two direct repeats, and (III) the traM promoter region. These three footprint regions contained a Hinfl-like sequence (GANTC) that appeared 16 times, spaced 11-12 bp (or multiples thereof) apart, suggesting that TraM protein binds in a complex manner over this entire region.

Nucleotide sequence and functions of the oriT operon in IncI1 plasmid R64

Two transfer genes of IncI1 plasmid R64, tentatively designated nikA and nikB, were cloned and sequenced. They are located adjacent to the origin of transfer (oriT) and appear to be organized into an operon, which we call the oriT operon. On the basis of the DNA sequence, nikA and nikB were concluded to encode proteins with 110 and 899 amino acid residues, respectively. Complementation analysis indicated that these two genes are indispensable for the transfer of R64 but are not required for the mobilization of ColE1. By the maxicell procedure, the product of nikA was found to be a 15-kDa protein. On treating a cleared lysate prepared from cells harboring a plasmid containing oriT, nikA, and nikB with sodium dodecyl sulfate or proteinase K, superhelical plasmid DNA in the cleared lysate was converted to an open circular form (relaxation). Relaxation of plasmid DNA was found to require the oriT sequence in cis and the nikA and nikB sequences in trans. It would thus follow that the products of nikA and nikB genes form a relaxation complex with plasmid DNA at the oriT site.

Regulation of the F plasmid traY promoter in Escherichia coli by host and plasmid factors

F plasmid DNA transfer (tra) gene expression in Escherichia coli is regulated by chromosome- and F-encoded gene products. To study the relationship among these regulatory factors, we constructed low-copy plasmids containing a phi(traY'-'lacZ)hyb gene that couples beta-galactosidase and Lac permease synthesis to the F plasmid traY promoter. Wild-type transformants maintained high levels of beta-galactosidase over a broad range of culture densities. Primer extension analysis of tra mRNA from F'lac and phi(traY'-'lacZ)hyb strains indicated very similar, though not identical, transcription initiation sites. Moreover, phi(traY'-'lacZ)hyb gene expression required both TraJ and SfrA, as does tra gene expression in F+ strains. beta-Galactosidase activity was reduced approximately 30-fold in the absence of TraJ, which could be supplied in cis or in trans. In a two-plasmid system in which TraJ was supplied in trans by a lac-traJ operon fusion, phi(traY'-'lacZ)hyb expression was a linear, saturable function of traJ expression. Enzyme activity was reduced approximately tenfold in sfrA mutants. That reduction could not be attributed to an effect on the TraJ level. Several other cellular or environmental variables had only a modest effect on phi(traY'-'lacZ)hyb expression. Hyperexpression was observed at high cell density (twofold) and in anaerobic cultures (1.2- to 1.5-fold). In contrast, expression was reduced twofold in integration host factor mutants.

traY and traI are required for oriT-dependent enhanced recombination between lac-containing plasmids and lambda plac5

Recombination between F42lac and lambda plac5 is typically 20- to 50-fold more efficient than recombination between chromosomal lac and lambda plac5. This enhancement of recombination requires trans-acting factors located in the promoter-distal and promoter-proximal regions of the main traY-to-traI (traZ) operon. By testing the ability of deletion mutants of tra to support enhanced recombination, we have identified traY as the only product has been ruled out. We also report that traI is the only gene from the promoter-distal end of the traY to traI operon that is required for recombination enhancement. Of the two proposed domains of traI, we conclude that the oriT-nicking activity is essential, whereas the helicase activity is largely dispensable. The possibility of a third traI activity is also discussed.

The sequences of genes bordering oriT in the enterotoxin plasmid P307: comparison with the sequences of plasmids F and R1

The nucleotide sequences of the enterotoxin plasmid P307 transfer genes traM, finP, traJ, traY, and gene 19 were determined. Gene 19 is highly conserved; its product is very similar to that coded by the F and R1 plasmids. The TraM protein is similar in P307 and in F; the R1 sequence shows differences in the 40 N-terminal amino acids. The traJ product is very different in P307, F, and R1. The traY gene from P307, which in F is almost twice as long, is similar in size to that from R1. The finP RNA shows a high degree of homology with that from R1 and F, except for the two loop regions where base changes were observed. The genes coding for proteins, except traY, could be expressed in minicell- and T7 promoter-driven expression systems, whereas traJ and gene 19 could be expressed only in the latter system.

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.

Purified Escherichia coli F-factor TraY protein binds oriT

The traY gene of the Escherichia coli F plasmid has been shown by genetic studies (R. Everett and N. Willetts, J. Mol. Biol. 136:129-150, 1980) to be involved in the site-specific nicking reaction at oriT required for the initiation of DNA transfer during bacterial conjugation. In order to assign a biochemical function to TraY protein, the traY gene was cloned in a plasmid vector which utilizes the strong T7 phi 10 promoter to overproduce the protein. The plasmid-encoded TraY protein was specifically labeled with [35S]methionine, and purification of the polypeptide was accomplished by monitoring the radioactive label. Purified TraY protein had a relative molecular mass of approximately 17,000, as determined by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The amino terminus of the purified protein was sequenced to confirm that the protein was encoded by the traY gene. The protein sequence revealed that the start codon for the TraY protein was a UUG codon 36 base pairs upstream of the AUG start site originally deduced from the DNA sequence (T. Fowler, L. Taylor, and R. Thompson, Gene 26:79-89, 1983). This start sequence confirmed the premise of Inamoto et al. that the F-plasmid TraY polypeptide-coding sequence would begin with UUG, creating a reading frame which renders a large degree of amino acid sequence identity with the TraY polypeptide from R100 (S. Inamoto, Y. Yoshioka, and E. Ohtsubo, J. Bacteriol. 170:2749-2757, 1988). The purified TraY protein from F bound specifically to the origin of transfer region of the F plasmid. However, no nicking activity was detected at oriT by using TraY protein or TraY protein in conjunction with helicase I.

Derepression of conjugal transfer of the antibiotic resistance plasmid R100 by antisense RNA

Conjugal transfer of the normally repressed antibiotic resistance plasmid R100 was derepressed by fragments of R100 that carried the traJ promoter and the traJ leader but lacked the finP promoter.

Sense and antisense transcripts of traM, a conjugal transfer gene of the antibiotic resistance plasmid R100

The region of the antibiotic resistance plasmid R100 that encodes the plasmid-specific transfer gene traM has two tandemly aligned promoters separated by 145 nucleotides. The principal transcripts are 705 and 562 nucleotides long. Minor transcripts are 1550 and 1700 nucleotides long. The 705-base transcript appears to encode an 11 kD traM protein. The 562-base transcript does not encode a detectable protein. When subcloned on short fragments, the promoter for the 562-base transcript initiates efficiently but that for the 705 site does not. The 3' ends of the 705 and 562 base transcripts end inside the traJ ORF. Thus they provide additional sense RNA to compete with traJ for finP, the antisense translational regulator of traJ. A model is proposed for the participation of these sense and antisense transcripts in the control of expression of the traJ gene.

Structure and function of conjugative pili: inducible synthesis of functional F pili by Escherichia coli K-12 containing a lac-tra operon fusion

In vivo and in vitro recombination methods were used to construct the recombinant plasmid pTG801, in which the F-plasmid DNA transfer (tra) genes required for the formation of functional F pili were placed under the lac transcriptional control sequences of pUC19. The 20 kilobases of cloned F DNA includes genes traA through the 5'-terminal part of traG; the plasmid lacks the positive regulatory gene traJ and all of the known tra genes required for the DNA transfer stage of conjugation. pTG801 transformants were sensitive to the donor-specific bacteriophages Q beta and f1, as measured by the formation of infectious centers. They were relatively insensitive to bacteriophage R17, as expected from the absence of traD. In the presence of a lacIq allele, sensitivity of pTG801 transformants to f1 and Q beta depended on the concentration of inducer (isopropyl-beta-D-thiogalactopyranoside [IPTG]). Viewed by electron microscopy, pTG801 transformants elaborated 7- to 10-nm-diameter filaments that could be laterally decorated with RNA bacteriophage particles, consistent with the formation of F pili. In stationary-phase cultures, these filaments formed massive aggregates and could be seen to adhere lengthwise to the cell surface; few pili accumulated in the medium as single filaments.

Nucleotide sequence of traQ and adjacent loci in the Escherichia coli K-12 F-plasmid transfer operon

The F tra operon region that includes genes trbA, traQ, and trbB was analyzed. Determination of the DNA sequence showed that on the tra operon strand, the trbA gene begins 19 nucleotides (nt) distal to traF and encodes a 115-amino-acid, Mr-12,946 protein. The traQ gene begins 399 nt distal to trbA and encodes a 94-amino-acid, Mr-10,867 protein. The trbB gene, which encodes a 179-amino-acid, Mr-19,507 protein, was found to overlap slightly with traQ; its start codon begins 11 nt before the traQ stop codon. Protein analysis and subcellular fractionation of the products expressed by these genes indicated that the trbB product was processed and that the mature form of this protein accumulated in the periplasm. In contrast, the protein products of trbA and traQ appeared to be unprocessed, membrane-associated proteins. The DNA sequence also revealed the presence of a previously unsuspected locus, artA, in the region between trbA and traQ. The artA open reading frame was found to lie on the DNA strand complementary to that of the F tra operon and could encode a 104-amino-acid, 12,132-dalton polypeptide. Since this sequence would not be expressed as part of the tra operon, the activity of a potential artA promoter region was assessed in a galK fusion vector system. In vivo utilization of the artA promoter and translational start sites was also examined by testing expression of an artA-beta-galactosidase fusion protein. These results indicated that the artA gene is expressed from its own promoter.

Evidence that DNA helicase I and oriT site-specific nicking are both functions of the F TraI protein

Site-specific and strand-specific nicking at the origin of transfer (oriT) of the F sex factor is the initial step in conjugal DNA metabolism. Then, DNA helicase I, the product of the traI gene, processively unwinds the plasmid from the nick site to generate the single strand of DNA that is transferred to the recipient. The nick at oriT is produced by the combined action of two Tra proteins, TraY and TraZ. The traZ gene was never precisely mapped, as no available point mutation uniquely affected TraZ-dependent oriT nicking. With several new mutations, we have demonstrated that TraZ activity is dependent upon traI DNA sequences. The simplest interpretation of this finding is that the F TraI protein is bifunctional, with DNA unwinding and site-specific DNA nicking activities.

Identification and characterization of the products from the traJ and traY genes of plasmid R100

The nucleotide sequence of part of the tra region of R100 including traJ and traY was determined, and the products of several tra genes were identified. The nucleotide sequence of traJ, encoding a protein of 223 amino acids, showed poor homology with the corresponding segments of other plasmids related to R100, but the deduced amino acid sequences showed low but significant homology. The first four amino acids at the N-terminal region of the TraJ protein were not essential for positive regulation of expression of traY, the first gene of the traYZ operon. The nucleotide sequence of traY shows that this gene may use TTG as the initiation codon and that it encodes a protein of 75 amino acids. Analysis of the traY gene product, which was obtained as the fusion protein with beta-galactosidase, showed that the N-terminal region of the product has an amino acid sequence identical to that deduced from the assigned frame but lacks formylmethionine. traY of plasmid F, which encodes a larger protein than the TraY protein of R100, is thought to use ATG as an initiation codon. However, a TTG initiation codon was found in the preceding region of the previously assigned traY coding frame of F. Interestingly, when translation of traY of F was initiated from TTG, the amino acid sequence homologous to the TraY protein of R100 appeared in tandem in the TraY protein of F. This may suggest that traY of F has undergone duplication of a gene like the traY gene of R100.

Surface exclusion genes traS and traT of the F sex factor of Escherichia coli K-12. Determination of the nucleotide sequence and promoter and terminator activities

The DNA encoding the surface exclusion genes traS and traT of the F sex factor of Escherichia coli K-12 has been sequenced and the biological activity of the various terminators and promoters determined. The data show that traS encodes a 16,861 Mr protein with no apparent signal sequence, as expected for its cytoplasmic membrane location. The protein is extremely hydrophobic. traS has its own promoter and a weak terminator region follows the gene. After the traS termination loop there is a small intergenic region before the traT promoter. The traT gene encodes a 25,932 Mr precursor for the 23,709 Mr mature protein. The amino-terminal signal peptide is 21 amino acid residues, consistent with it being an outer membrane lipoprotein. A very strong termination loop follows the gene and adjacent to this a further loop can be predicted from the sequence. These secondary structures would be expected to enhance the stability of the mRNA in the presence of 3' specific ribonucleases accounting for the apparent long half-life of the messenger. The amino acid sequence of the mature product of traT of F differs from that of R100 by only a single amino acid substitution (Gly for Ala at position 119), whereas that of pED208 (Folac) differs at 40 positions. traT lies in a region of heteroduplex homology between F and R100, and the nucleotide sequence confirms this and demonstrates that this homology breaks down immediately preceding and following the coding region. Sequence analysis shows that this is also so for pED208. Thus the entire traS of F, R100 and pED208 are very different at the DNA level. An open reading frame, preceded by a typical promoter sequence and a weak and poorly located Shine-Dalgarno sequence, follows traT and corresponds to the start of traD. Alone, this promoter appears to be inactive.

Transcript analysis of the plasmid R100 traJ and finP genes

Single-stranded RNA probes were used to study the regulation of plasmid transfer in the infectious antibiotic resistance plasmid R100. Transcription of the positive transfer control gene traJ of R100 appears to be initiated continuously. In the presence of finO, the traJ transcript is 235 bases long, and in the absence of finO it is 1050. These sizes are strain specific. finO increases four-to tenfold the amount of the transcript from the finP gene that is detectable in cells containing R100, R136, or the sex factor F. The size of the principal finP transcript from R100 as determined on Northern blots is 105 bases. A secondary transcript with a size of 180 bases was detected in small amounts in R100 extracts. The finP transcript size was also determined by nuclease protection experiments. In this case the size was 74 bases. The 5' ends of the finP and traJ transcripts were located by primer extension experiments. A new model of FinO/P control is proposed.

Analysis of transfer genes and gene products within the traB-traC region of the Escherichia coli fertility factor, F

A series of plasmids that carry overlapping segments of F DNA encoding the genes in the traB-traC interval was constructed, and a restriction enzyme map of the region was derived. Plasmids carrying deletions that had been introduced at an HpaI site within this interval were also isolated. The ability of these plasmids to complement transfer of F lac plasmids carrying mutations in traB, traV, and traW, and traC was analyzed. The protein products of the plasmids were labeled in UV-irradiated cells and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. These analyses showed that the product of traV is a polypeptide that migrates with an apparent molecular weight of 21,000. It was not detected when [35S]methionine was used to label plasmid products, but was readily detected in 14C-amino acid labeling experiments. A 21,500-dalton product appeared to stem from the region assigned to traP. A 9,000-dalton product was found to stem from a locus, named traR, that is located between traV and traC. No traW activity could be detected from the region of tra DNA examined. Our data also indicated that traC is located in a more promoter-proximal position than suggested on earlier maps. The plasmids constructed are expected to be useful in studies designed to identify the specific functions of the traB, -P, -V, -R, and -C products.

The origin of transfer of P307

The DNA fragment carrying the oriT region from the enterotoxin plasmid P307 was isolated and its polynucleotide sequence was determined. Using Southern hybridization assays with a synthetic oligonucleotide probe, the oriT region was identified on a 7.9-kb EcoRI fragment from P307. By ligating the fragment with the cloning vector pUC119, plasmid pAG10 was obtained. The physical map of the insert was determined and oriT was located on a 540-bp BglII/SalI fragment. After this fragment was subcloned into sequencing phages, the polynucleotide sequence was established. Part of the sequence proved to be almost identical to segments of the oriT regions of the plasmids F and R1; another neighboring region was very different among all three sequences. The polynucleotide sequence proximal to traM is highly similar to that of F but different from that of R1.

Analysis of E. coli promoter sequences

We have compiled and analyzed 263 promoters with known transcriptional start points for E. coli genes. Promoter elements (-35 hexamer, -10 hexamer, and spacing between these regions) were aligned by a program which selects the arrangement consistent with the start point and statistically most homologous to a reference list of promoters. The initial reference list was that of Hawley and McClure (Nucl. Acids Res. 11, 2237-2255, 1983). Alignment of the complete list was used for reference until successive analyses did not alter the structure of the list. In the final compilation, all bases in the -35 (TTGACA) and -10 (TATAAT) hexamers were highly conserved, 92% of promoters had inter-region spacing of 17 +/- 1 bp, and 75% of the uniquely defined start points initiated 7 +/- 1 bases downstream of the -10 region. The consensus sequence of promoters with inter-region spacing of 16, 17 or 18 bp did not differ. This compilation and analysis should be useful for studies of promoter structure and function and for programs which identify potential promoter sequences.

Nucleotide sequence of the tra YALE region from IncFV plasmid pED208

The pED208 plasmid is a 90-kilobase conjugative plasmid which is the derepressed form of Fo lac plasmid (IncFV). A 3.3-kilobase HindIII-PstI fragment from the pED208 plasmid was cloned and sequenced and was found to contain four open reading frames which were highly homologous to the traA, traL, traE, and traY gene products of the F plasmid. The pED208 traA propilin protein was 119 amino acids in length, consisting of a leader sequence of 55 amino acids and a mature pilin subunit of 64 residues. The leader sequence contained a hydrophobic region followed by a classic signal peptidase cleavage site (Ala-Ser-Ala-55). F and pED208 pilin proteins shared 27 conserved residues and had similar predicted secondary structures. The pED208 traA and traL genes were separated by a single base pair, and no ribosome binding site preceded the traL gene. The pED208 traY gene contained an IS2 insertion element in orientation II 180 nucleotides (60 residues) upstream of the traY stop codon. This insertion of IS2 resulted in a predicted fusion peptide of 69 residues for traY which may provide the observed traY activity. Since IS2 is absent in the wild-type plasmid, Fo lac, derepression and concomitant multipiliation may be due to the insertion of IS2 providing constitutive expression of the pED208 tra operon.

Origin of transfer of IncF plasmids and nucleotide sequences of the type II oriT, traM, and traY alleles from ColB4-K98 and the type IV traY allele from R100-1

The complete nucleotide sequences of the ColB4-K98 (ColB4) plasmid transfer genes oriT, traM, and traY as well as the traY gene of R100-1 are presented and compared with the corresponding regions from the conjugative plasmids F, R1, and R100. The sequence encoding the oriT nick sites and surrounding inverted repeats identified in F was conserved in ColB4. The adenine-thymine-rich sequence following these nick sites was conserved in R1 and ColB4 but differed in F and R100, indicating that this region may serve as the recognition site for the traY protein. A series of direct repeats unique to the ColB4 plasmid was found in the region of dyad symmetry following this AT-rich region. This area also encodes 21-base-pair direct repeats which are homologous to those in F and R100. The traM gene product may bind in this region. Overlapping and following these repeats is the promoter(s) for the traM protein. The traM protein from ColB4 is similar to the equivalent products from F, R1, and R100. The traY protein from ColB4 is highly homologous to the R1 traY gene product, while the predicted R100-1 traY product differs at several positions. These differences presumably define the different alleles of traM and traY previously identified for IncF plasmids by genetic criteria. The translational start codons of the ColB4 and R100-1 traY genes are GUG and UUG, respectively, two examples of rare initiator codon usage.

Cloning, mapping, and sequencing of plasmid R100 traM and finP genes

The fertility control gene finP, the transfer gene traM, and the transfer origin, oriT, of plasmid R100 were isolated on a single 1.2-kilobase EcoRV fragment and were then subcloned as HaeIII fragments. The sequence of the 754-base-pair finP-containing fragment is reported here. In addition to the finP gene, the sequence includes all but two bases of the R100 traM open reading frame and apparently all of the leader mRNA sequence and amino end of the traJ gene of R100. The sequence contains two open reading frames which encode small proteins on the opposite strand from the traM and traJ genes. It also shows two sets of inverted repeats that have the characteristics of transcription terminators. One set is positioned as if it was the traM terminator, and the other set, which is downstream from the first, sits in the middle of the leader mRNA sequence for traJ. On the bottom strand, this inverted repeat has the structure of a rho-independent terminator. Other less-stable inverted repeats overlap this second terminator in the same way as is seen in attenuation sequences, and the two separate small open reading frames on the bottom strand also totally overlap the stem of the rho-independent terminator, suggesting that their translation would cause shifting of termination to the bottom strand homolog of the putative traM terminator. The finP gene product was not identified, but the gene was mapped to the sequence which contains the traJ gene. It either overlaps traJ or is antisense to it.

Nucleotide sequences of the R1-19 plasmid transfer genes traM, finP, traJ, and traY and the traYZ promoter

The complete nucleotide sequences of the R1 drd-19 (R1-19) plasmid transfer genes traM, finP, traJ, and traY and the region encoding the traYZ promoter were determined. The traM protein from R1-19 was similar to the 127-amino-acid traM product from the conjugative plasmid F; only 28 residues were not identical. finP, a negative regulatory element of the traJ gene, contained a 12-base-pair inverted repeat identical to that found in the F plasmid, but differed in the 7 base pairs found between the repeats. The traJ gene and the traYZ promoter (the site of transcriptional stimulation by the traJ product) were completely different from the equivalent sequences in plasmid F. Galactokinase fusion studies of the traYZ promoter indicated that the R1-19 and F plasmids have analogous but not homologous traYZ promoter strengths and regulation. The traY protein from R1-19 was 44 residues shorter than the traY product from plasmid F, but there was some homology within the C-terminal halves of the traY gene products. The predicted translational start codon for the traY gene is GUG.

The sequences of the traJ gene and the 5' end of the traY gene of the resistance plasmid R1

The traJ gene and the 5' end of the neighbouring traY gene of the resistance plasmid R1 were sequenced. Both structural genes show relatively little homology with the corresponding sequences of the related F plasmid. At the amino acid level sufficient homology is detected to allow an assignment of the two genes in R1. In traJ two methionine codons have to be regarded as potential chain initiation signals. Because of the analogy with the F plasmid sequence the second ATG is believed to be the main translational start site. The traJ gene codes for 228 amino acids. The 5' untranslated region of the traJ gene of R1 is highly homologous to the corresponding sequence in F indicating that it fulfills an important role in regulation. The transcription of the traY-Z operon starts in the structural gene of traJ. The amino terminal part of the TraY protein shows only limited homology with the F factor counterpart. However, the few conserved amino acids are a strong indication that our sequence contains the traY gene of R1.

Shadow promoters in the F plasmid transfer operon

The in vivo transcription start site for PYZ, the promoter of the F plasmid transfer operon, has been located. When transcription start sites for PYZ are deleted, two additional shadow promoters, upstream of PYZ, are activated in vivo. The shadow promoters correspond to those previously identified by in vitro run-off transcription experiments. The activated shadow promoters are stimulated by TraJ protein, a positive regulator of the transfer operon.

Characterization and sequence analysis of pilin from F-like plasmids

Conjugative pili are expressed by derepressed plasmids and initiate cell-to-cell contact during bacterial conjugation. They are also the site of attachment for pilus-specific phages (f1, f2, and QB). In this study, the number of pili per cell and their ability to retract in the presence of cyanide was estimated for 13 derepressed plasmids. Selected pilus types were further characterized for reactivity with anti-F and anti-ColB2 pilus antisera as well as two F pilus-specific monoclonal antibodies, one of which is specific for a sequence common to most F-like pilin types (JEL92) and one which is specific for the amino terminus of F pilin (JEL93). The pilin genes from eight of these plasmids were cloned and sequenced, and the results were compared with information on F, ColB2, and pED208 pilin. Six pilus groups were defined: I, was F-like [F, pED202(R386), ColV2-K94, and ColVBtrp]; IIA was ColB2-like in sequence but had a lowered sensitivity to f1 phage due to its decreased ability for pilus retraction [pED236(ColB2) and pED203(ColB4)]; IIB was ColB2-like but retained f1 sensitivity [pED200(R124) and pED207(R538-1)]; III contained R1-19, which had a ColB2-like amino terminus but had an additional lysine residue at its carboxy terminus which may affect its phage sensitivity pattern and its antigenicity; IV was R100-1-like [R100-1 and presumably pED241(R136) and pED204(R6)] which had a unique amino-terminal sequence combined with a carboxy terminus similar to that of F. pED208(Folac) formed group V, which was multipiliated and exhibited poor pilus retraction although it retained full sensitivity to f1 phage. The pED208 pilin gene could not be cloned at this time since it shared no homology with the pilin gene of the F plasmid.

Physical and genetic structure of the glpK-cpxA interval of the Escherichia coli K-12 chromosome

Mutations at the cpxA locus of Escherichia coli K-12 affect cellular processes that are not otherwise related. We have now determined the physical and genetic structure of the E. coli chromosome in the region of cpxA (87.5 min). Our results indicate that cpxA is a single gene. Previous studies showed cpxA to be linked to tpiA. We therefore isolated two tpiA+ recombinant plasmids, pRA200 and pRA300, from EcoRI and BamHI digests of F'133, respectively. By genetic complementation or enzyme overproduction, the 9.5 kb EcoRI fragment in pRA200 was shown to include glpK, tpiA and cdh. The 13.6 kb BamHI fragment of pRA300 lacks glpK, but includes tpiA, pfkA and cpxA. Neither fragment complemented a deletion of the rha operon. These data indicate the chromosomal gene order: 87 min-rha-cpxA-pfkA-cdh-tpiA-glpK-88 min. The EcoRI and BamHI fragments overlap in an interval corresponding to about 8.2 kb of DNA. The total region of the E. coli K12 chromosome covered by the two fragments is about 15 kb. A terminal 2 kb EcoRI-BamHI fragment from pRA300 complemented the chromosomal cpxA2[Ts] allele with respect to isoleucine and valine synthesis, RNA bacteriophage sensitivity and surface exclusion in Hfr strains, and envelope protein composition. Complementation occurred when the fragment was subcloned in pBR325 but not when it was subcloned in pBR322, suggesting that the 2 kb fragment lacks expression sequences that are supplied by cat (chloramphenicol acetyltransferase gene) expression sequences of pBR325. The cpxA locus on the E. coli chromosome was established with respect to two chromosomal Tn10 insertions by a combination of genetic and physical analyses. The locus established by those analyses was consistent with the location of the 2 kb EcoRI-BamHI fragment in the physical map of the region. Physical analyses of (rha-pfkA) and (rha-tpiA) deletion strains showed that they lack cpxA and surrounding genes. Since these strains were viable, cpxA is not essential under all growth conditions.

DNA sequence of the F traALE region that includes the gene for F pilin

The complete sequence of a 1.4-kilobase PstI fragment containing the F transfer genes traA, -L, and -E is presented. The traA reading frame has been located both genetically and by comparing the primary structure of F pilin (the traA product) predicted by the DNA sequence to the amino acid composition and sequence of N- and C-terminal peptides isolated from purified F pilin. Taken together, these data show that there is a leader peptide of 51 amino acids and that F pilin contains 70 amino acids, giving molecular weights of 13,200 for F propilin and 7,200 for mature F pilin. Secondary structure predictions for F pilin revealed a reverse turn that precedes the sequence Ala-Met-Ala51, a classic signal peptidase cleavage site. The N-terminal alanine residue is blocked by an acetyl group as determined by 1H-nuclear magnetic resonance spectroscopy. The traL and traE genes encode proteins of molecular weights 10,350 and 21,200, respectively. According to DNA sequence predictions, these proteins do not contain signal peptide leader sequences. Secondary structure predictions for these proteins are in accord with traLp and traEp being membrane proteins in which hydrophobic regions capable of spanning the membrane are linked by sequences that form turns and carry positively charged residues capable of interacting with the membrane surface.