Replication enhancer-independent mutation increases the co-operativity with which an initiator protein binds its origin

An amber-encoding helper phage for more efficient phage display of noncanonical amino acids

Using an amber suppression-based noncanonical amino acid (ncAA) mutagenesis approach, the chemical space in phage display can be significantly expanded for drug discovery. In this work, we demonstrate the development of a novel helper phage, CMa13ile40, for continuous enrichment of amber obligate phage clones and efficient production of ncAA-containing phages. CMa13ile40 was constructed by insertion of a Candidatus Methanomethylophilus alvus pyrrolysyl-tRNA synthetase/PylT gene cassette into a helper phage genome. The novel helper phage allowed for a continuous amber codon enrichment strategy for two different libraries and demonstrated a 100-fold increase in packaging selectivity. CMa13ile40 was then used to create two peptide libraries containing separate ncAAs, Nϵ-tert-butoxycarbonyl-lysine and Nϵ-allyloxycarbonyl-lysine, respectively. These libraries were used to identify peptide ligands that bind to the extracellular domain of ZNRF3. Each selection showed differential enrichment of unique sequences dependent upon the ncAA used. Peptides from both selections were confirmed to have low micromolar affinity for ZNRF3 that was dependent upon the presence of the ncAA used for selection. Our results demonstrate that ncAAs in phages provide unique interactions for identification of unique peptides. As an effective tool for phage display, we believe that CMa13ile40 can be broadly applied to a wide variety of applications.

Various mutations compensate for a deleterious lacZα insert in the replication enhancer of M13 bacteriophage

M13 and other members of the Ff class of filamentous bacteriophages have been extensively employed in myriad applications. The Ph.D. series of phage-displayed peptide libraries were constructed from the M13-based vector M13KE. As a direct descendent of M13mp19, M13KE contains the lacZα insert in the intergenic region between genes IV and II, where it interrupts the replication enhancer of the (+) strand origin. Phage carrying this 816-nucleotide insert are viable, but propagate in E. coli at a reduced rate compared to wild-type M13 phage, presumably due to a replication defect caused by the insert. We have previously reported thirteen compensatory mutations in the 5'-untranslated region of gene II, which encodes the replication initiator protein gIIp. Here we report several additional mutations in M13KE that restore a wild-type propagation rate. Several clones from constrained-loop variable peptide libraries were found to have ejected the majority of lacZα gene in order to reconstruct the replication enhancer, albeit with a small scar. In addition, new point mutations in the gene II 5'-untranslated region or the gene IV coding sequence have been spontaneously observed or synthetically engineered. Through phage propagation assays, we demonstrate that all these genetic modifications compensate for the replication defect in M13KE and restore the wild-type propagation rate. We discuss the mechanisms by which the insertion and ejection of the lacZα gene, as well as the mutations in the regulatory region of gene II, influence the efficiency of replication initiation at the (+) strand origin. We also examine the presence and relevance of fast-propagating mutants in phage-displayed peptide libraries.

Interactions of the integrase protein of the conjugative transposon Tn916 with its specific DNA binding sites

The binding of two chimeric proteins, consisting of the N-terminal or C-terminal DNA binding domain of Tn916 Int fused to maltose binding protein, to specific oligonucleotide substrates was analyzed by gel mobility shift assay. The chimeric protein with the N-terminal domain formed two complexes of different electrophoretic mobilities. The faster-moving complex, whose formation displayed no cooperativity, contained two protein monomers bound to a single DNA molecule. The slower-moving complex, whose formation involved cooperative binding (Hill coefficient > 1.0), contained four protein monomers bound to a single DNA molecule. Methylation interference experiments coupled with the analysis of protein binding to mutant oligonucleotide substrates showed that formation of the faster-moving complex containing two protein monomers required the presence of two 11-bp direct repeats (called DR2) in direct orientation. Formation of the slower-moving complex required only a single DR2 repeat. Binding of the N-terminal domains in vivo could serve to position two Int monomers on the DNA near each end of the transposon and assist in bringing together the ends of the transposon so that excision can occur. The chimeric protein with the C-terminal domain of Int also formed two complexes of different electrophoretic mobilities. The major, slower-moving complex, whose formation involved cooperative binding, contained two protein molecules bound to one DNA molecule. This finding suggested that while the C-terminal domain of Int can bind DNA as a monomer, a cooperative interaction between two monomers of the C-terminal domain may help to bring the ends of the transposon together during excision.

Filamentous phage replication initiator protein gpII forms a covalent complex with the 5' end of the nick it introduced

Rolling circle type DNA replication is initiated by introduction of a nick in the leading strand of the origin by the initiator protein, which in most cases binds covalently to the 5' end of the nick. In filamentous phage, however, such a covalent complex has not been detected. Using a suitable substrate and short reaction time, we show that filamentous phage initiator gpII forms a covalent complex with nicked DNA, which rapidly dissociates unless gpII is inactivated. A peptide-DNA complex was isolated from trypsin digest of the complex by ion-exchange column chromatography and gel filtration, and its peptide sequence was determined. The result indicated that gpII was linked to DNA by the tyrosine residue at position 197 from the N-terminus. The mutant protein in which this tyrosine was replaced by phenylalanine did not show any detectable activity to complement gene II amber mutant phage in vivo. In vitro, the mutant protein recognized the origin and bent DNA as well as the wild-type does, but failed to introduce a nick and to relax the superhelicity of cognate DNA.

Binding of a novel host factor to the pT181 plasmid replication enhancer

Replication enhancers are cis-acting genetic elements that stimulate the activity of origins of DNA replication. The enhancer found in plasmid pT181 of Staphylococcus aureus, called cmp, functions at a distance of 1 kb from the origin of DNA replication to stimulate the interaction between the replication initiation protein and the origin. DNA encoding cmp-binding activity was isolated by screening an expression library of S. aureus DNA in Escherichia coli, and a novel gene, designated cbf1, was identified. The cbf1 locus codes for a polypeptide of 313 amino acid residues (cmp-binding factor 1 [CBF1]; Mr = 35,778). In its COOH-terminal region, the protein sequence contains the helix-turn-helix motif common to many DNA binding proteins that usually bend DNA. The specificity of CBF1 binding for cmp was demonstrated by affinity chromatography using cmp DNA and by competition binding studies. DNase I footprinting analysis of the CBF1-cmp complexes revealed DNase I-hypersensitive sites in phase with the helical periodicity of DNA, implying that CBF1 increases distortion of the intrinsically bent cmp DNA.

Preponderance of Fis-binding sites in the R6K gamma origin and the curious effect of the penicillin resistance marker on replication of this origin in the absence of Fis

Fis protein is shown here to bind to 10 sites in the gamma origin of plasmid R6K. The Fis-binding sites overlap all the previously identified binding sites in the gamma origin for the plasmid-encoded pi initiator protein and three host-encoded proteins, DnaA, integration host factor, and RNA polymerase. However, the requirement of Fis for R6K replication depends on the use of copy-up pi-protein variants and, oddly, the antibiotic resistance marker on the plasmid. In Fis-deficient cells, copy-up pi variants cannot drive replication of R6K gamma-origin plasmids carrying the bla gene encoding resistance to penicillin (Penr) but can drive replication of plasmids with the same origin but carrying the chloramphenicol acetyltransferase gene encoding chloramphenicol resistance (Cmr). In contrast, R6K replication driven by wild-type pi is unaffected by the antibiotic resistance marker in the absence of Fis protein. Individually, none of these elements (copy-up pi, Fis deficiency, or drug markers) prevents R6K replication. The replication defect is not caused by penicillin in the medium or runaway replication and is unaffected by the orientation of the bla gene relative to the origin. Replication remains inhibited when part of the bla coding segment is deleted but the bla promoter is left intact. However, replication is restored by insertion of transcriptional terminators on either side of the gamma origin, suggesting that excess transcription from the bla gene may inactivate replication driven by pi copy-up mutants in the absence of Fis. This study suggests that vector sequences such as drug markers may not be inconsequential in replication studies, as is generally assumed.

The stoichiometry of binding of the herpes simplex virus type 1 origin binding protein, UL9, to OriS

A number of studies have demonstrated that the herpes simplex virus type 1 (HSV-1) UL9 protein, which is a homodimer in solution, binds to two high affinity binding sites in each origin of replication. Interaction between the proteins bound at the two sites leads to the formation of a complex nucleoprotein structure. The simplest models for this binding interaction predict two possible binding stoichiometries: 1) one UL9 dimer is bound at each site; or 2) one UL9 monomer is bound at each site so that one UL9 dimer occupies both sites. Two recent papers have addressed this issue by using indirect methods to measure the binding stoichiometry. Martin et al. (Martin, D. W., Muñoz, R. M., Oliver, D., Subler, M. A., and Deb, S. (1994) Virology 198, 71-80) reported that a monomer of UL9 binds to a single high affinity site, and Stabell and Olivo (Stabell, E. C., and Olivo, P.D. (1993) Nucleic Acids Res. 21, 5203-5211) concluded that a dimer of UL9 binds to a single high affinity site. We have directly measured the stoichiometry of binding of the carboxyl-terminal DNA binding domain of UL9 (t-UL9) to the origin of replication using a double-label gel shift assay. Using a short synthetic double-stranded oligonucleotide containing a single UL9 binding site, one protein-DNA complex was detected in the gel shift assay, and the molar ratio of UL9 DNA binding domains to DNA binding sites in this complex was determined to be 2.0 +/- 0.1 (n = 13). Using the minimal origin sequence excised from plasmid DNA, two protein-DNA complexes were detected. The binding stoichiometry of the faster migrating complex was 1.8 +/- 0.1 (n = 15), and the stoichiometry of the more slowly migrating band was 3.7 +/- 0.4 (n = 15). The simplest explanation for these data is that UL9 binds to the origin of replication as a homodimer with one dimer bound at both high affinity sites.

Genetic evidence for replication enhancement from a distance

Rolling circle replication of the Staphylococcus aureus plasmid pT181 requires interaction of the RepC initiator protein with the origin of replication (the ori site). A second site named cmp, which is distant from ori, is thought to stimulate replication, since a mutant pT181 plasmid lacking cmp cannot coexist with a cmp+ wild-type plasmid. Second-site mutations compensating for the loss of cmp were shown to map in repC. The compensatory mutations produced RepC proteins that, unlike the wild-type, either failed to discriminate between cmp+ and cmp- plasmids or preferred cmp- to cmp+ plasmids. These studies demonstrate that cmp stimulates the interaction of the replication initiator protein with the origin and therefore enhances DNA replication from a distance.

A single amino acid substitution reduces the superhelicity requirement of a replication initiator protein

The origin of rolling circle replication in filamentous coliphage consists of a core origin that is absolutely required and an adjacent replication enhancer sequence that increases in vivo replication 30 to 100-fold. The core origin binds the initiator protein (gpII) which either nicks or relaxes negatively superhelical replicative form DNA (RFI). Nicking at the origin, but not relaxation, leads to initiation of DNA replication. Our results indicate that the ratio of nicking to relaxation (nicking-closing) in vitro depends on the superhelical density of the substrate. We have studied the effect of a single amino acid substitution in gpII, which allows wild-type levels of replication in the absence of the enhancer, on origin nicking and binding. The enhancer-independent mutation yields more nicking and less relaxation of RFI, compared to the wild-type protein. The mutant gpII also shows a reduced requirement for superhelicity of the substrate in the nicking reaction. At the same time, the mutant gpII increases the cooperativity of protein-protein interactions in origin binding. We propose that the relaxation activity of gpII negatively regulates replication initiation, and that both increase in the negative superhelicity of the substrate and action of the replication enhancer may antagonize the relaxation activity.

Two MalT binding sites in direct repeat. A structural motif involved in the activation of all the promoters of the maltose regulons in Escherichia coli and Klebsiella pneumoniae

The maltose regulons of Escherichia coli and Klebsiella pneumoniae are very similar, comprising three operons that code for the proteins required for the utilization of maltodextrins as a carbon source. The maltose regulon of K. pneumoniae contains two additional operons, pulAB and pulC-O, which allow the use of starch as a carbon source. The promoters of all of these operons are strictly controlled by the activator protein MalT. In this paper, we report a detailed study of the structure and the functional role of the MalT binding sites located in the adjacent and divergent pulAp and pulCp promoters. By biochemical and genetic experiments, we show that the 134 base-pair region separating the transcription start sites of pulAp and pulCp contains four MalT binding sites, which leads us to propose a revised consensus for the asymmetrical nucleotide sequence recognized by MalT (5'-GGGGAT/GGAGG). MalT binds co-operatively to these four sites, contacting the major groove of the DNA helix. The genetic dissection of the pulAp-pulCp region shows that the promoters partially overlap: the two central MalT binding sites, which are in direct repeat, are required for the activation of both promoters. We further show that an analogous pair of directly repeated MalT binding sites is also involved in the activation of two other promoters of the regulon, malEp and malKp. This study, which confirms the striking structural diversity of the promoters of the maltose regulon, suggests that the motif formed by two MalT binding sites in direct repeat is a recurrent feature of these promoters and plays a crucial role in their activation.