Construction of a tyrP-lac operon fusion strain and its use in the isolation and analysis of mutants derepressed for tyrP expression

Screening of an Escherichia coli promoter library for a phenylalanine biosensor

In recent years, the application of transcription factor-based biosensors for the engineering of microbial production strains opened up new opportunities for industrial biotechnology. However, the design of synthetic regulatory circuits depends on the selection of suitable transcription factor-promoter pairs to convert the concentration of effector molecules into a measureable output. Here, we present an efficient strategy to screen promoter libraries for appropriate parts for biosensor design. To this end, we pooled the strains of the Alon library containing about 2000 different Escherichia coli promoter-gfpmut2 fusions, and enriched galactose- and L-phenylalanine-responsive promoters by toggled rounds of positive and negative selection using fluorescence-activated cell sorting (FACS). For both effectors, responsive promoters were isolated and verified by cultivation in microtiter plates. The promoter of mtr, encoding an L-tryptophan-specific transporter, was identified as suitable part for the construction of an L-phenylalanine biosensor. In the following, we performed a comparative analysis of different biosensor constructs based on the mtr promoter. The obtained data revealed a strong influence of the biosensor architecture on the performance characteristics. For proof-of-principle, the mtr sensor was applied in a FACS high-throughput screening of an E. coli MG1655 mutant library for the isolation of L-phenylalanine producers. These results emphasize the developed screening approach as a convenient strategy for the identification of effector-responsive promoters for the design of novel biosensors.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Further genetic analysis of the activation function of the TyrR regulatory protein of Escherichia coli

Previous reports (J. Cui and R. L. Somerville, J. Bacteriol. 175:1777-1784, 1993; J. Yang, H. Camakaris, and A. J. Pittard, J. Bacteriol. 175:6372-6375, 1993) have identified a number of amino acids in the N-terminal domain of the TyrR protein which are critical for activation of gene expression but which play no role in TyrR-mediated repression. These amino acids were clustered in a single region involving positions 2, 3, 5, 7, 9, 10, and 16. Using random and site-directed mutagenesis, we have identified an additional eight key amino acids whose substitution results in significant or total loss of activator function. All of these are located in the N-terminal domain of TyrR. Alanine scanning at these eight new positions and at five of the previously identified positions for which alanine substitutions had not been obtained has identified three amino acids whose side chains are critical for activation, namely, D-9, R-10, and D-103. Glycine at position 37 is also of critical importance. Alanine substitutions at four other positions (C-7, E-16, D-19, and V-93) caused partial but significant loss of activation, indicating that the side chains of these amino acids also play a contributing role in the activation process.

Mutations in the tyrR gene of Escherichia coli which affect TyrR-mediated activation but not TyrR-mediated repression

Site-directed mutagenesis has been used to further characterize amino acid residues necessary for the activation of gene expression by the TyrR protein. Amino acid substitutions have been made at positions 2, 4, 5, 6, 7, 8, 9, 10, and 16. TyrR mutants with amino acid substitutions V-5-->P (VP5), VF5, CS7, CR7, DR9, RI10, RS10, and ER16 show no or very little activation of expression of either mtr or tyrP. In each case, however, the ability to repress aroF is unaltered. Amino acid substitutions at positions 4, 6, and 8 have no effect on activation. Small internal deletions of residues 10 to 19, 20 to 29, or 30 to 39 also destroy phenylalanine- or tyrosine-mediated activation of mtr and tyrP. In these mutants repression of aroF is also unaltered. In activation-defective tyrR mutants, expression of mtr is repressed in the presence of tyrosine. This tyrosine-mediated repression is trpR dependent and implies an interaction between TrpR and TyrR proteins in the presence of tyrosine.

Production of L-dihydroxyphenylalanine in Escherichia coli with the tyrosine phenol-lyase gene cloned from Erwinia herbicola

The gene (tutA) encoding tyrosine phenol-lyase from Erwinia herbicola was cloned into Escherichia coli, and fusions to the lac and tac promoters were constructed. The enzyme was expressed at high levels in E. coli in the presence of isopropyl-beta-D-thiogalactopyranoside or lactose as an inducer. L-Dihydroxyphenylalanine was synthesized in high yield from catechol, pyruvate, and ammonia by induced cells.

Interaction between the antisense and target RNAs involved in the regulation of IncB plasmid replication

Physical analysis of RNA I, the small antisense RNA which regulates the replication of IncB miniplasmid pMU720, showed that it is a highly structured molecule containing an imperfectly paired stem closed by a 6-base hairpin loop. Mutational studies revealed that a 3-base sequence in the hairpin loop is critical to the interaction between RNA I and its complementary target in the RepA mRNA (RNA II). Furthermore, a 2-base interior loop in the upper stem was found to play an important role in facilitating effective binding between RNA I and RNA II. From these analyses, a model describing the molecular mechanism of binding between RNA I and RNA II is proposed.

A genetic analysis of various functions of the TyrR protein of Escherichia coli

The TyrR protein is involved in both repression and activation of the genes of the TyrR regulon. Correction of an error in a previously published sequence has revealed a Cro-like helix-turn-helix DNA-binding domain near the carboxyl terminus. Site-directed mutagenesis in this region has generated a number of mutants that can no longer repress or activate. Deletions of amino acid residues 5 to 42 produced a protein that could repress but not activate. The central domain of TyrR contains an ATP-binding site and is homologous with the NtrC family of activator proteins. A mutation to site A of the ATP-binding site and other mutations in this region affect tyrosine-mediated repression but do not prevent activation or phenylalanine-mediated repression of aroG.

Molecular analysis of the TyrR protein-mediated activation of mtr gene expression in Escherichia coli K-12

Expression of the mtr gene, which encodes a tryptophan-specific transport system in Escherichia coli K-12, is activated by the TyrR protein. Two TyrR protein binding sites (TYR R boxes) are positioned upstream of the -35 promoter region. Mutational and DNase protection studies indicate that TyrR protein binds preferentially to the TYR R box closest to the promoter, and this is essential for activation of gene expression. In the presence of tyrosine and ATP, a second TyrR molecule is able to cooperatively bind to the second box and cause a further increase in the level of activation.

Importance of the position of TYR R boxes for repression and activation of the tyrP and aroF genes in Escherichia coli

Tyrosine-mediated repression of aroF and tyrP was studied by inserting DNA sequences between the two adjacent TYR R boxes which, in each case, overlap the respective RNA polymerase binding sites of these genes. In both cases, repression was greatest when homologous regions of these two TYR R boxes were on the same face of the DNA helix and the boxes were directly adjacent. An insertion of 3 bases was sufficient to abolish repression, which was reestablished as the boxes became separated by one full turn of the helix. These observations, coupled with the results of in vitro DNase I protection studies, supported the hypothesis that the binding of TyrR protein to the downstream boxes required cooperative interaction with TyrR protein already bound to the upstream boxes. In the case of tyrP, moving the upstream box also affected activation. Maximal activation was observed when the box was moved 3 or 12 to 14 residues upstream. Practically no activation was seen at intermediate positions, such as +7 and -4. It is hypothesized that these results indicate positions allowing maximal interaction between TyrR protein bound to the upstream box and RNA polymerase bound to the RNA polymerase binding site.

Mutational analysis of repression and activation of the tyrP gene in Escherichia coli

In a previous report it had been suggested that the tyrP gene of Escherichia coli may be expressed from two separate promoters. We have endeavored to confirm this suggestion by primer extension studies and the separate subcloning of each of these promoters. In these studies, we found a single promoter whose expression was repressed by TyrR protein in the presence of tyrosine and activated by TyrR protein in the presence of phenylalanine. Two adjacent TYR R boxes, with the downstream one overlapping the tyrP promoter, are the likely targets for the action of TyrR protein. Mutational analysis showed that both TYR R boxes were required for tyrosine-mediated repression but that only the upstream box was required for phenylalanine-mediated activation. In vitro DNase protection studies established that whereas in the absence of tyrosine TyrR protein protected the region of DNA represented by the upstream box, at low TyrR protein concentrations both tyrosine and ATP were required to protect the region of DNA involving the downstream box and overlapping the RNA polymerase binding site.

Regulation of expression of the Escherichia coli K-12 mtr gene by TyrR protein and Trp repressor

The Escherichia coli K-12 mtr gene, which encodes a tryptophan-specific permease, was cloned, and its nucleotide sequence was determined. The precise location of the mtr gene at 69 min on the E. coli chromosome was determined. The mtr gene product was identified as a 414-amino-acid residue protein with a calculated molecular weight of 44,332. The protein is very hydrophobic, consistent with its presumed location spanning the cytoplasmic membrane. The initiation sites of transcription and translation were identified. Construction of an mtr-lacZ transcriptional fusion facilitated investigation of the molecular basis of mtr regulation. The TyrR protein in association with phenylalanine or tyrosine is responsible for the activation of mtr expression, whereas the Trp repressor in conjunction with tryptophan serves to repress expression of this gene. Site-directed mutagenesis confirmed that sequences in the mtr regulatory region homologous to TyrR protein and to Trp repressor-binding sites were involved in the activation and repression of mtr expression, respectively. Sequences homologous to sigma 70- and sigma 54-dependent promoters were identified upstream of the transcription start point of mtr. It was determined that transcription of mtr occurs only via a sigma 70-dependent promoter.

The tyrosine repressor negatively regulates aroH expression in Escherichia coli

The levels of the tryptophan-sensitive isoenzyme of 3-deoxy-D-arabino-heptulosonate 7-phosphate synthase of Escherichia coli, encoded by the aroH gene, were elevated in tyrR and/or trpR mutants. The effect of tyrR and trpR lesions on aroH expression was confirmed by using a lacZ reporter system. The mutational elimination of either repressor led to a threefold increase in beta-galactosidase.

The tryptophan-specific permease gene, mtr, is differentially regulated by the tryptophan and tyrosine repressors in Escherichia coli K-12

The regulation of transcription of the gene for the tryptophan-specific permease, mtr, was evaluated in several genetically marked Escherichia coli strains through the use of a single-copy lacZ reporter system. The expression of mtr was repressed 97-fold by tryptophan via the Trp repressor and induced 10-fold by phenylalanine or tyrosine via the Tyr repressor. By primer extension analysis two distinct mtr transcripts and their corresponding promoters were identified. One transcript was induced by the Tyr repressor. The tryptophan-dependent interaction of Trp repressor with an operator target within the mtr promoter was demonstrated by means of a restriction endonuclease protection assay.

Cloning, nucleotide sequence, and characterization of mtr, the structural gene for a tryptophan-specific permease of Escherichia coli K-12

The mtr gene of Escherichia coli K-12 encodes an L-tryptophan-specific permease. This gene was originally identified through the isolation of mutations in the 69-min region of the chromosome, closely linked to argG. Cells with lesions in mtr display a phenotype of 5-methyltryptophan resistance. The mtr gene was cloned by using the mini-Mu system. The amino acid sequence of Mtr (414 codons), deduced by DNA sequence analysis, was found to be 33% identical to that of another single-component transport protein, the tyrosine-specific permease, TyrP. The hydropathy plots of the two permeases were similar. Possible operator sites for the tyrosine and tryptophan repressors are situated within the region of DNA that is likely to be the mtr promoter.

Role of countertranscript RNA in the copy number control system of an IncB miniplasmid

Transcriptional mapping studies of the IncB minireplicon pMU720 demonstrated the existence of a long RNA molecule, RNA II, whose 5' portion is complementary to the product of the incompatibility gene RNA I. By using gene fusion and transcriptional fusion plasmids, it was shown that RNA I regulated the expression of the RNA II gene product and that it did so primarily at the level of translation. The target of RNA I was mapped to lie within a 216-base region of RNA II containing the sequence complementary to RNA I. Introduction of the target for RNA I in trans increased the copy number of an IncB minireplicon, indicating that RNA I and RNA II form the basis of the copy number control system of IncB plasmids.

DNA sequence of the gene (tyrP) encoding the tyrosine-specific transport system of Escherichia coli

The nucleotide sequence of 1,947 bases of DNA containing the tyrP structural gene was determined, and an open reading frame of 1,260 nucleotides was identified. The putative structural gene encodes an extremely hydrophobic protein which comprises 404 amino acids, 70% of which are nonpolar, and which has a molecular weight of 43,261.

Transcription control of the aroP gene in Escherichia coli K-12: analysis of operator mutants

The nucleotide sequence of the region containing the promoter-operator for the aroP gene was determined. The start site of aroP transcription was identified by using S1 nuclease mapping and primer extension techniques. Examination of the nucleotide sequence revealed the presence of two "TYR R" boxes which are similar to those identified in the regulatory regions of other genes in the tyrR regulon. Bisulfite-induced aroP operator-constitutive mutants were analyzed, and the base-pair changes responsible for alterations in aroP regulation were located within these boxes.

Molecular analysis of the promoter operator region of the Escherichia coli K-12 tyrP gene

The nucleotide sequence of the tyrP promoter region from Escherichia coli has been determined. Two TYR R boxes have been identified, and one of these was shown to overlap the -35 region of a major tyrP promoter (p1). S1 nuclease mapping of in vivo transcripts revealed that transcription from p1 is stimulated by phenylalanine and to a lesser extent by leucine. The demonstration that mutants in which TyrR-tyrosine-mediated repression of tyrP has been abolished have single base changes in the TYR R box which overlaps p1 suggests that TyrR-tyrosine-mediated repression of tyrP also involves p1. TyrR-independent stimulation of tyrP expression by Casamino Acids involves a second promoter 140 bases upstream of p1. There are no TYR R boxes in this region. The sequences of 10 TYR R boxes preceding the genes tyrP, tyrR, and aroG and the operons aroF tyrA and aroL aroM are compared and discussed.

Cloning of the tyrP gene and further characterization of the tyrosine-specific transport system in Escherichia coli K-12

The tyrP gene which codes for a component of the tyrosine-specific transport system of Escherichia coli has been cloned on a 2.8-kilobase insert into plasmid pBR322. Transposon mutagenesis, using Tn1000, indicates that the tyrP+ gene is at least 1.1 kilobase in length. Labeling of the tyrP protein in maxicells with [35S]methionine indicates an apparent molecular weight of ca. 24,500. Sedimentation analysis reveals that the tyrP protein is associated with the cell membrane and is not free in the cytoplasm or periplasm. Strains with many copies of the tyrP+ gene show an enhanced uptake of tyrosine, but the expression of the system is still modulated by tyrosine and phenylalanine in the presence of the tyrR+ regulator protein. Accumulated radioactive tyrosine is rapidly effluxed by the addition either of energy uncouplers or of excess nonradioactive tyrosine, indicating that the transport system is energized by the proton motive force and that the internal pool is readily exchangeable. The effect of increasing expression of the tyrP gene on the steady-state level of tyrosine accumulated by cells indicates that although the transport system may be dependent on the proton motive force to drive uptake, the system never reaches thermodynamic equilibrium with it.