The roles of indoleglycerol phosphate and the TrpI protein in the expression of trpBA from Pseudomonas aeruginosa.

The TrpI protein belongs to the LysR-family of procaryotic regulatory proteins. Members of this family share a characteristic similarity of their N-terminal amino acid sequences, and many of them are activators of divergently transcribed genes or operons. In Pseudomonas aeruginosa, the genes for tryptophan synthase, trpBA, are regulated by indoleglycerol phosphate (InGP) and TrpI. We demonstrate here that in the absence of InGP, the binding site of TrpI is located in the -52 to -77 region of the trpBA promoter; in the presence of InGP, the binding region is extended to the -32 region. In addition, two major, slow moving protein-DNA complexes are seen in gel retardation assays: the faster moving complex is formed in the absence of InGP and the amount of the slower moving complex is greatly enhanced in the presence of InGP. These results suggest that the binding of a second TrpI protein molecule, promoted by InGP, plays a crucial role in activating the expression of the trpBA gene pair.     

Sequence of the Pseudomonas aeruginosa trpI activator gene and relatedness of trpI to other procaryotic regulatory genes.

In Pseudomonas aeruginosa, the trpI gene product regulates the expression of the trpBA gene pair encoding tryptophan synthase. trpI and trpBA are transcribed divergently. The trpI DNA sequence and deduced amino acid sequence were determined. The trpI start codon was found to be 103 base pairs from that of trpB. trpI encodes a 293-residue protein and the size of the trpI gene product, measured on sodium dodecyl sulfatepolyacrylamide gels, was close to that calculated from the amino acid sequence. The amino acid sequence of trpI resembles that of Enterobacter cloacae ampR, the regulatory gene for the ampC cephalosporinase. The N-terminal portions of trpI and ampR resemble corresponding portions of ilvY, metR, and lysR in Escherichia coli and nodD in Rhizobium meliloti. This resemblance may help to define a trpI-related family of activator proteins sharing a common structural plan.     

The TraM protein of the conjugative plasmid F binds to the origin of transfer of the F and ColE1 plasmids

The gene encoding the TraM protein of the conjugative plasmid F was cloned, overexpressed and the gene product was purified. The TraM protein was found in the cytoplasm of cells carrying the F plasmid with a smaller amount in the inner membrane. DNase I footprinting experiments showed that the purified protein protects three regions in the F oriT locus with different affinity for the upper and lower strands of DNA. A 15-nucleotide motif was identified within the protected regions that represented the DNA-binding site. The TraM protein was also found to bind to a sequence in the oriT region of the non-conjugative plasmid ColE1 that resembles the three binding sites in the F oriT region.     

Interaction between the replication origin and the initiator protein of the filamentous phage f1. Binding occurs in two steps

The replication initiator protein of bacteriophage f1 (gene II protein) binds to the phage origin and forms two complexes that are separable by polyacrylamide gel electrophoresis. Complex I is formed at low gene II protein concentrations, and shows protection from DNase I of about 25 base-pairs (from position +2 to +28 relative to the nicking site) at the center of the minimal origin sequence. Complex II is produced at higher concentrations of the protein, and has about 40 base-pairs (from -7 to +33) protected. On the basis of gel mobility, complex II appears to contain twice the amount of gene II protein as does complex I. The 40 base-pair sequence protected in complex II corresponds to the minimal origin sequence as determined by in-vivo analyses. The central 15 base-pair sequence (from +6 to +20) of the minimal origin consists of two repeats in inverted orientation. This sequence, when cloned into a plasmid, can form complex I, but not complex II. We call this 15 base-pair element the core binding sequence for gene II protein. Methylation interference with the formation of complex I by the wild-type origin indicates that gene II protein contacts six guanine residues located in a symmetric configuration within the core binding sequence. Formation of complex II requires, in addition to the core binding sequence, the adjacent ten base-pair sequence on the right containing a third homologous repeat. A methylation interference experiment performed on complex II indicates that gene II protein interacts homologously with the three repeats. In complex II, gene II protein protects from DNase I digestion not only ten base-pairs on the right but also ten base-pairs on the left of the sequence that is protected in complex I. Footprint analyses of various deletion mutants indicate that the left-most ten base-pairs are protected regardless of their sequence. The site of nicking by gene II protein is located within this region. A model is presented for the binding reaction involving both protein-DNA and protein-protein interactions.     

Characterizing the DNA contacts and cooperative binding of F plasmid TraM to its cognate sites at oriT

TraM is a DNA binding protein required for conjugative transfer of the self-transmissible IncF group of plasmids, including F, R1, and R100. F TraM binds to three sites in F oriT: two high affinity binding sites, sbmA and sbmB, which are direct repeats of nearly identical sequence involved in the autoregulation of the traM gene; and a lower affinity site, sbmC, an inverted repeat important for transfer, which is situated nearest to the nic site where transfer originates. TraM bound cooperatively to its binding sites at oriT; the presence of sbmA and sbmB increased the affinity for sbmC 10-fold. Bending of oriT DNA by TraM was minimal, suggesting that TraM, a tetramer, was able to loop the DNA when bound to sbmA and sbmB simultaneously. Hydroxyl radical footprinting of DNA of sbmA and sbmC revealed that TraM contacted the DNA within a region previously delineated by DNase I footprinting. TraM protected the CT bases within the sequence CTAG, which occurred at 12-base intervals on the top and bottom strand of sbmA, most consistently with other protected bases. The footprint on sbmC revealed that the predicted inverted repeats were protected by TraM with a pattern that began at the center of the repeats and radiated outward at 11-12 base intervals toward the 5'-ends of either strand. At high protein concentrations, this pattern extended beyond the footprint defined by DNase I, suggesting that the DNA was wrapped around the protein forming a nucleosome-like structure, which could aid in preparing the DNA for transfer.     

Interaction of int protein with specific sites on lambda att DNA.

We have studied the interaction of highly purified Int protein with DNA restriction fragments from the lambda phage attachment site (attP) region. Two different DNA sequences are protected by bound Int protein against partial digestion by either pancreatic DNAase or neocarzinostatin. One Int binding site includes the 15 bp common core sequence (the crossover region for site-specific recombination) plus several bases of sequence adjoining the core in both the P and P' arms. The second Int-protected site occurs 70 bp to the right of the common core in the P' arm, just at the distal end of the sequence encoding Int protein. The two Int binding sites are of comparable size, 30-35 bp, but do not share any extensive sequence homology. The interaction of Int with the two sites is distinctly different, as defined by the observation that only the site in the P' arm and not the site at the common core region is protected by Int in the face of challenge by the polyanion heparin. Restriction fragments containing DNA from the bacterial attachment site (attB) region exhibit a different pattern of interaction with Int. In the absence of heparin, a smaller (15 bp) sequence, which includes the left half of the common core region and the common core-B arm juncture, is protected against nuclease digestion by Int protein. No sequences from this region are protected by Int in the presence of heparin.     

Studies on the binding of lambda Int protein to attachment site DNA: identification of a tight-binding site in the P'' region.

We have used three approaches to studying the interaction of lambda Int protein with bacteriophage attachment site DNA, POP': location of binding sites by retention of DNA fragments in a filter binding assay, reconstruction of a binding site by DNA synthesis and protection of a binding site from an exonuclease. Retention of restriction fragments on nitrocellulose filters in the presence of Int protein was used to locate binding sites. A high affinity binding site lies in P' between base pairs -6 and +173 from the center of the common core sequence, and low affinity sites are found in the 200 base pair region left of position -6. Reconstruction of the high affinity binding site region from the right using primed DNA synthesis and testing for filter binding in the presence of Int protein shows that sequences sufficient for tight binding of Int protein lie to the right of position +66. When attachment site DNA is protected by bound Int protein against digestion by exonuclease III, four Int dependent protection bands are seen in positions +58, +68, +79 and +88. This can be interpreted either as showing that four Int protein monomers bind to the high affinity region in series, or as evidence for wrapping of the DNA around Int protein, leading to structural changes resembling those occurring to DNA in nucleosomes.