Translational control of bacteriophage f1 gene II and gene X proteins by gene V protein

Hybridoma Screening by Antibody Capture: Dot Blot

A dot blot is an appropriate hybridoma screening procedure when the antigen is a protein that is available in purified form. The antigen is bound directly to a nitrocellulose sheet and incubated with hybridoma tissue culture supernatant. A dot blot is widely used to determine the productivity of a given hybridoma, and this is described here. This assay can also be used to screen a fusion or subclone plate for productive hybridoma clones.

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.

Simulation of the M13 life cycle I: Assembly of a genetically-structured deterministic chemical kinetic simulation

To expand the quantitative, systems level understanding and foster the expansion of the biotechnological applications of the filamentous bacteriophage M13, we have unified the accumulated quantitative information on M13 biology into a genetically-structured, experimentally-based computational simulation of the entire phage life cycle. The deterministic chemical kinetic simulation explicitly includes the molecular details of DNA replication, mRNA transcription, protein translation and particle assembly, as well as the competing protein-protein and protein-nucleic acid interactions that control the timing and extent of phage production. The simulation reproduces the holistic behavior of M13, closely matching experimentally reported values of the intracellular levels of phage species and the timing of events in the M13 life cycle. The computational model provides a quantitative description of phage biology, highlights gaps in the present understanding of M13, and offers a framework for exploring alternative mechanisms of regulation in the context of the complete M13 life cycle.

Simulation of the M13 life cycle II: Investigation of the control mechanisms of M13 infection and establishment of the carrier state

Bacteriophage M13 is a true parasite of bacteria, able to co-opt the infected cell and control the production of progeny across many cellular generations. Here, our genetically-structured simulation of M13 is applied to quantitatively dissect the interplay between the host cellular environment and the controlling interactions governing the phage life cycle during the initial establishment of infection and across multiple cell generations. Multiple simulations suggest that phage-encoded feedback interactions constrain the utilization of host DNA polymerase, RNA polymerase and ribosomes. The simulation reveals the importance of p5 translational attenuation in controlling the production of phage double-stranded DNA and suggests an underappreciated role for p5 translational self-attenuation in resource allocation. The control elements active in a single generation are sufficient to reproduce the experimentally-observed multigenerational curing of the phage infection. Understanding the subtleties of regulation will be important for maximally exploiting M13 particles as scaffolds for nanoscale devices.

Identification and characterization of mutant clones with enhanced propagation rates from phage-displayed peptide libraries

A target-unrelated peptide (TUP) can arise in phage display selection experiments as a result of a propagation advantage exhibited by the phage clone displaying the peptide. We previously characterized HAIYPRH, from the M13-based Ph.D.-7 phage display library, as a propagation-related TUP resulting from a G→A mutation in the Shine-Dalgarno sequence of gene II. This mutant was shown to propagate in Escherichia coli at a dramatically faster rate than phage bearing the wild-type Shine-Dalgarno sequence. We now report 27 additional fast-propagating clones displaying 24 different peptides and carrying 14 unique mutations. Most of these mutations are found either in or upstream of the gene II Shine-Dalgarno sequence, but still within the mRNA transcript of gene II. All 27 clones propagate at significantly higher rates than normal library phage, most within experimental error of wild-type M13 propagation, suggesting that mutations arise to compensate for the reduced virulence caused by the insertion of a lacZα cassette proximal to the replication origin of the phage used to construct the library. We also describe an efficient and convenient assay to diagnose propagation-related TUPS among peptide sequences selected by phage display.

A target-unrelated peptide in an M13 phage display library traced to an advantageous mutation in the gene II ribosome-binding site

Screening of the commercially available Ph.D.-7 phage-displayed heptapeptide library for peptides that bind immobilized Zn2+ resulted in the repeated selection of the peptide HAIYPRH, although binding assays indicated that HAIYPRH is not a zinc-binding peptide. HAIYPRH has also been selected in several other laboratories using completely different targets, and its ubiquity suggests that it is a target-unrelated peptide. We demonstrated that phage displaying HAIYPRH are enriched after serial amplification of the library without exposure to target. The amplification of phage displaying HAIYPRH was found to be dramatically faster than that of the library itself. DNA sequencing uncovered a mutation in the Shine-Dalgarno (SD) sequence for gIIp, a protein involved in phage replication, imparting to the SD sequence better complementarity to the 16S ribosomal RNA (rRNA). Introducing this mutation into phage lacking a displayed peptide resulted in accelerated propagation, whereas phage displaying HAIYPRH with a wild-type SD sequence were found to amplify normally. The SD mutation may alter gIIp expression and, consequently, the rate of propagation of phage. In the Ph.D.-7 library, the mutation is coincident with the displayed peptide HAIYPRH, accounting for the target-unrelated selection of this peptide in multiple reported panning experiments.

In‐frame overlapping genes: the challenges for regulating gene expression

In-frame overlapping genes in phage, plasmid and bacterial genomes permit synthesis of more than one form of protein from the same gene. Having one gene entirely within another rather than two separate genes presumably precludes recombination events between the identical sequences. However, studies of such gene pairs indicate that the overlapping arrangement can make regulation of the genes more difficult. Here, we extend studies of in-frame overlapping genes II and X from filamentous phage f1 to determine if translational controls are required to regulate the gene properly. These genes encode proteins (pII and pX) with essential but opposing roles in phage DNA replication. They must be tightly regulated to maintain production of the proteins at relative steady state levels that permit continuous replication without killing the host. To determine why little or no pX appears to be made on the gene II/X mRNA, gene II translation was lowered by progressively deleting into the gene II initiator region. Increased pX translation resulted, suggesting that elongating ribosomes on the gene II mRNA interfere with internal initiation on the gene X ribosome binding site and limit gene X translation. As judged from systematically lowering the efficiency of suppression at a gene II amber codon upstream from the gene X start, the already modest level of gene II translation would have to be reduced by more than twofold to relieve all interference with internal initiation. Further downregulation of gene X expression proved to be required to maintain pX at levels relative to pII that are tolerated by the cell. Site-directed mutagenesis and nuclease mapping revealed that the gene X initiation site is sequestered in an extended RNA secondary structure that lowers gene X translation on the two mRNAs encoding it. The more general implications of the results for expression of in-frame overlapping genes are discussed.

Selection of genomic sequences that bind tightly to Ff gene 5 protein: primer-free genomic SELEX

Single-stranded DNA or RNA libraries used in SELEX experiments usually include primer-annealing sequences for PCR amplification. In genomic SELEX, these fixed sequences may form base pairs with the central genomic fragments and interfere with the binding of target molecules to the genomic sequences. In this study, a method has been developed to circumvent these artificial effects. Primer-annealing sequences are removed from the genomic library before selection with the target protein and are then regenerated to allow amplification of the selected genomic fragments. A key step in the regeneration of primer-annealing sequences is to employ thermal cycles of hybridization-extension, using the sequences from unselected pools as templates. The genomic library was derived from the bacteriophage fd, and the gene 5 protein (g5p) from the phage was used as a target protein. After four rounds of primer-free genomic SELEX, most cloned sequences overlapped at a segment within gene 6 of the viral genome. This sequence segment was pyrimidine-rich and contained no stable secondary structures. Compared with a neighboring genomic fragment, a representative sequence from the family of selected sequences had about 23-fold higher g5p-binding affinity. Results from primer-free genomic SELEX were compared with the results from two other genomic SELEX protocols.

Translation at higher than an optimal level interferes with coupling at an intercistronic junction

In pairs of adjacent genes co-transcribed on bacterial polycistronic mRNAs, translation of the first coding region frequently functions as a positive factor to couple translation to the distal coding region. Coupling efficiencies vary over a wide range, but synthesis of both gene products at similar levels is common. We report the results of characterizing an unusual gene pair, in which only about 1% of the translational activity from the upstream gene is transmitted to the distal gene. The inefficient coupling was unexpected because the upstream gene is highly translated, the distal initiation site has weak but intrinsic ability to bind ribosomes, and the AUG is only two nucleotides beyond the stop codon for the upstream gene. The genes are those in the filamentous phage IKe genome, which encode the abundant single-stranded DNA binding protein (gene V) and the minor coat protein that caps one tip of the phage (gene VII). Here, we have used chimeras between the related phage IKe and f1 sequences to localize the region responsible for inefficient coupling. It mapped upstream from the intercistronic region containing the gene V stop codon and the gene VII initiation site, indicating that low coupling efficiency is associated with gene V. The basis for inefficient coupling emerged when coupling efficiency was found to increase as gene V translation was decreased below the high wild-type level. This was achieved by lowering the rate of elongation and by decreasing the efficiency of suppression at an amber codon within the gene. Increasing the strength of the Shine-Dalgarno interaction with 16S rRNA at the gene VII start also increased coupling efficiency substantially. In this gene pair, upstream translation thus functions in an unprecedented way as a negative factor to limit downstream expression. We interpret the results as evidence that translation in excess of an optimal level in an upstream gene interferes with coupling in the intercistronic junction.

Preferential binding of fd gene 5 protein to tetraplex nucleic acid structures

The gene 5 protein of filamentous bacteriophage fd is a single-stranded DNA-binding protein that binds non-specifically to all single-stranded nucleic acid sequences, but in addition is capable of specific binding to the sequence d(GT(5)G(4)CT(4)C) and the RNA equivalent r(GU(5)G(4)CU(4)C), the latter interaction being important for translational repression. We show that this sequence preference arises from the formation of a tetraplex structure held together by a central block of G-quartets, the structure of which persists in the complex with gene 5 protein. Binding of gene 5 protein to the tetraplex leads to formation of a approximately 170 kDa nucleoprotein complex consisting of four oligonucleotide strands and eight gene 5 protein dimers, with a radius of gyration of 45 A and an overall maximum dimension of 120-130 A. A model of the complex is presented that is consistent with the data obtained. It is proposed that the G-quartet may act as a nucleation site for binding gene 5 protein to adjacent single-stranded regions, suggesting a novel mechanism for translational repression.

Appropriate expression of filamentous phage f1 DNA replication genes II and X requires RNase E-dependent processing and separate mRNAs

The products of in-frame overlapping genes II and X carried by the filamentous phage f1 genome are proteins with required but opposing functions in phage DNA replication. Their normal relative levels are important for continuous production of phage DNA without killing infected Escherichia coli hosts. Here we identify several factors responsible for determining the relative levels of pII and pX and that, if perturbed, alter the normal distribution of the phage DNA species in infected hosts. Translation of the two proteins is essentially relegated to separate mRNAs. The mRNAs encoding genes II and X are also differentially sensitive to cleavage dependent on rne, the gene encoding the only E. coli endo-RNase known to have a global role in mRNA stability. Whereas pII levels are limited at the level of mRNA stability, normal pX levels require transcription in sufficient amounts from the promoter for the smaller mRNA encoding only pX.

Translation limits synthesis of an assembly-initiating coat protein of filamentous phage IKe

Translation is shown to be downregulated sharply between genes V and VII of IKe, a filamentous bacteriophage classed with the Ff group (phages f1, M13, and fd) but having only 55% DNA sequence identity to it. Genes V and VII encode the following proteins which are used in very different amounts: pV, used to coat the large number of viral DNA molecules prior to assembly, and pVII, used to serve as a cap with pIX in 3 to 5 copies on the end of the phage particle that emerges first from Escherichia coli. The genes are immediately adjacent to each other and are represented in the same amounts on the Ff and IKe mRNAs. Ff gene VII has an initiation site that lacks detectable intrinsic activity yet through coupling is translated at a level 10-fold lower than that of upstream gene V. The experiments reported reveal that by contrast, the IKe gene VII initiation site had detectable activity but was coupled only marginally to upstream translation. The IKe gene V and VII initiation sites both showed higher activities than the Ff sites, but the drop in translation at the IKe V-VII junction was unexpectedly severe, approximately 75-fold. As a result, gene VII is translated at similarly low levels in IKe- and Ff-infected hosts, suggesting that selection to limit its expression has occurred.

Single-stranded DNA binding protein from bacteriophage cf: characterization, gene localization and protein-ssDNA complex

The single-stranded DNA binding protein from the filamentous bacteriophage cf has been purified and characterized. The first 12 amino acids, resulting from the N-terminal amino acid sequencing analysis of the protein, agree with an open reading frame (ORF) on the cf genome. The ORF contains 294 bp and codes for a 98 a.a. protein of molecular weight 10.8 kDa, consistent with the result from the denaturing protein gel analysis. The protein appears to be a homodimer as evident from the apparent molecular weight of about 22 kDa obtained from native protein gel analysis. The gene location of the protein has been identified as gene V of the cf single stranded genome, same as that from the M13 phage. The GVP of cf shows a strong sequence homology to the ssDNA binding proteins of Ff, IKe and Pf3 filamentous phages. The DNA binding wing of GVP, conserved among the filamentous phages, has been predicted for cf. To further characterize the protein, the GVP-ssDNA complex of cf has been purified from the infected host (Xanthomonas campestris pv. citri) by density gradient centrifugation. Transmission electron microscopy (TEM) images of the complex showed that it is about 1200 nm in length and 9 nm in diameter and it has a highly regular morphology with a central groove shadow running along the entire structure, but without any apparent helical pattern seen in the M13 complex. The GVP-ssDNA complex of cf seems more rigid than that of M13. Our computer modeling study suggested that this difference between the two complexes may be due to the additional 11 or 12 amino acids at the C-terminal end of the cf-GVP.

Direct measurement of oligonucleotide binding stoichiometry of gene V protein by mass spectrometry

The binding stoichiometry of gene V protein from bacteriophage f1 to several oligonucleotides was studied using electrospray ionization-mass spectrometry (ESI-MS). Using mild mass spectrometer interface conditions that preserve noncovalent associations in solution, gene V protein was observed as dimer ions from a 10 mM NH4OAc solution. Addition of oligonucleotides resulted in formation of protein-oligonucleotide complexes with stoichiometry of approximately four nucleotides (nt) per protein monomer. A 16-mer oligonucleotide gave predominantly a 4:1 (protein monomer: oligonucleotide) complex while oligonucleotides shorter than 15 nt showed stoichiometries of 2:1. Stoichiometries and relative binding constants for a mixture of oligonucleotides were readily measured using mass spectrometry. The binding stoichiometry of the protein with the 16-mer oligonucleotide was measured independently using size-exclusion chromatography and the results were consistent with the mass spectrometric data. These results demonstrate, for the first time, the observation and stoichiometric measurement of protein-oligonucleotide complexes using ESI-MS. The sensitivity and high resolution of ESI-MS should make it a useful too] in the study of protein-DNA interactions.

Site-directed mutagenesis of the M13 gene 5 protein: the role of Arg-21, Tyr-26 and Tyr-41

The gene 5 protein of bacteriophage M13 is a single stranded DNA binding protein essential for phage replication. We have generated the mutations R21A, Y26F and Y41A in the gene 5 protein and purified the mutant proteins for functional characterisation in vitro. The complex of Y26F with single-stranded DNA is disrupted at 0.8 M NaCl, the same salt concentration as that required to dissociate the native complex. However, the mutant proteins R21A and Y41A are considerably less stable and dissociate from single-stranded DNA at at 0.4 M NaCl. The fluorescence of the mutant proteins and the DNA-protein complexes they form has been compared with the wild-type protein to allow an assessment of the contribution from individual residues. We conclude that the fluorescence of Tyr-26 is 50% quenched in the complex with DNA, whereas that of Tyr-41 is fully quenched. Fluorescence titrations of the mutant proteins with poly(dT) show that all three mutant proteins can bind DNA but, in the case of Y41A, with a change of stoichiometry suggesting a loss of cooperativity. Gel retardation analysis of Y41A also shows anomalous behaviour in binding to oligonucleotides, consistent with the proposed involvement of Tyr-41 in dimer-dimer contacts in the nucleoprotein complex.

Structure of the gene V protein of bacteriophage f1 determined by multiwavelength x-ray diffraction on the selenomethionyl protein

The crystal structure of the dimeric gene V protein of bacteriophage f1 was determined using multiwavelength anomalous diffraction on the selenomethionine-containing wild-type and isoleucine-47-->methionine mutant proteins with x-ray diffraction data phased to 2.5 A resolution. The structure of the wild-type protein has been refined to an R factor of 19.2% using native data to 1.8 A resolution. The structure of the gene V protein was used to obtain a model for the protein portion of the gene V protein-single-stranded DNA complex.

Exploration of the single-stranded DNA-binding domains of the gene V proteins encoded by the filamentous bacteriophages IKe and M13 by means of spin-labeled oligonucleotide and lanthanide-chelate complexes

Scrutiny of NOE data available for the protein encoded by gene V of the filamentous phage IKe (IKe GVP), resulted in the elucidation of a beta-sheet structure which is partly five stranded. The DNA-binding domain of IKe GVP was investigated using a spin-labeled deoxytrinucleotide. The paramagnetic-relaxation effects observed in the 1H-NMR spectrum of IKe GVP, upon binding of this DNA fragment, could be visualized using two-dimensional difference spectroscopy. In this way, the residues present in the DNA-binding domain of IKe GVP can be located in the structure of the protein. They exhibit a high degree of identity with residues in the gene V protein encoded by the distantly related phage M13 (M13 GVP), for which similar spectral perturbations are induced by such a spin-labeled oligonucleotide. Binding studies with negatively charged lanthanide-1,4,7,10-tetraazacyclodecanetrayl-1,4,7-10- tetrakis(methylene)tetrakisphosphonic acid (DOTP) complexes, showed that these complexes bind to IKe and M13 GVP at two spatially remote sites whose affinities have different pH dependencies. Above pH 7, there is one high-affinity binding site for Gd(DOTP)5-/M13 GVP monomer, which coincides with the single-stranded DNA-binding domain as mapped with the aid of spin-labeled oligonucleotide fragments. The results show that single-stranded DNA binds to conserved (phosphate binding) electropositive clusters at the surface of M13 and IKe GVP. These positive patches are interspersed with conserved or conservatively replaced hydrophobic residues. At pH 5, a second Gd(DOTP)(5-)-binding site becomes apparent. The corresponding pattern of spectral perturbations indicates the accommodation of patches of conserved, or conservatively replaced, hydrophobic residues in the cores of the M13 and IKe dimers.

Reverse genetics of Drosophila RNA polymerase II: identification and characterization of RpII140, the genomic locus for the second-largest subunit

We have used a reverse genetics approach to isolate genes encoding two subunits of Drosophila melanogaster RNA polymerase II. RpII18 encodes the 18-kDa subunit and maps cytogenetically to polytene band region 83A. RpII140 encodes the 140-kDa subunit and maps to polytene band region 88A10:B1,2. Focusing on RpII140, we used in situ hybridization to map this gene to a small subinterval defined by the endpoints of a series of deficiencies impinging on the 88A/B region and showed that it does not represent a previously known genetic locus. Two recently defined complementation groups, A5 and Z6, reside in the same subinterval and thus were candidates for the RpII140 locus. Phenotypes of A5 mutants suggested that they affect RNA polymerase II, in that the lethal phase and the interaction with developmental loci such as Ubx resemble those of mutants in the gene for the largest subunit, RpII215. Indeed, we have achieved complete genetic rescue of representative recessive lethal mutations of A5 with a P-element construct containing a 9.1-kb genomic DNA fragment carrying RpII140. Interestingly, the initial construct also rescued lethal alleles in the neighboring complementation group, Z6, revealing that the 9.1-kb insert carries two genes. Deleting coding region sequences of RpII140, however, yielded a transformation vector that failed to rescue A5 alleles but continued to rescue Z6 alleles. These results strongly support the conclusion that the A5 complementation group is equivalent to the genomic RpII140 locus.

Cloning, expression and in vitro characterisation of the M13 gene 5 protein

The gene 5 protein encoded in the genome of bacteriophage M13 is a single stranded DNA binding protein essential for phage replication. We have cloned a fragment of the M13 genome containing gene 5, and investigated the effect of upstream elements on expression of the gene by means of Bal 31 deletion analysis. The gene was also expressed from the lac promoter of the phagemid vector pUC119, and the recombinant protein purified and characterised for DNA binding. The affinity of the recombinant protein for single-stranded DNA was shown to be essentially identical to that of wild type gene 5 protein. Wild type gene 5 protein has a glutamic acid residue at position 30 which, on the basis of the crystal structure, was believed to play a role in maintaining the tertiary structure of the protein through the formation of a salt bridge with arginine-80. We show that substitution of glutamic acid at position 30 by lysine does not impair DNA binding, suggesting that a salt bridge between glutamate-30 and arginine-80 is not essential for the structural integrity of the gene 5 protein as previously proposed.

Selection and characterization of randomly produced mutants of gene V protein of bacteriophage M13

Gene V protein of bacteriophage Ff (M13, f1, fd) is a master regulator of phage DNA replication and phage mRNA translation. It exerts these two functions by binding to single-stranded viral DNA or to specific sequences in the 5' ends of its target mRNAs, respectively. To study the structure/function relationship of gene V protein, M13 gene V was inserted in a phagemid expression vector and a library of missense and nonsense mutants was constructed by random chemical mutagenesis. Phagemids encoding gene V proteins with decreased biological activities were selected and the nucleotide sequences of their gene V fragments were determined. Furthermore, the mutant proteins were characterized both with respect to their ability to inhibit the production of phagemid DNA transducing particles and their ability to repress the translation of a chimeric lacZ reporter gene whose expression is controlled by the promoter and translational initiation signals of M13 gene II. From the data obtained, it can be deduced that the mechanism by which gene V protein binds to single-stranded DNA differs from the mechanism by which it binds to its target sequence in the gene II mRNA.

Assignment of the 1H NMR spectrum and secondary structure elucidation of the single-stranded DNA binding protein encoded by the filamentous bacteriophage IKe

By means of 2D NMR techniques, all backbone resonances in the 1H NMR spectrum of the single-stranded DNA binding protein encoded by gene V of the filamentous phage IKe have been assigned sequence specifically (at pH 4.6, T = 298 K). In addition, a major part of the side chain resonances could be assigned as well. Analysis of NOESY data permitted the elucidation of the secondary structure of IKe gene V protein. The major part of this secondary structure is present as an antiparallel beta-sheet, i.e., as two beta-loops which partly combine into a triple-stranded beta-sheet structure, one beta-loop and one triple-stranded beta-sheet structure. It is shown that a high degree of homology exists with the secondary structure of the single-stranded DNA binding protein encoded by gene V of the distantly related filamentous phage M13.

Gene V protein-mediated translational regulation of the synthesis of gene II protein of the filamentous bacteriophage M13: a dispensable function of the filamentous-phage genome

Introduction of a deletion in the genome of wild-type M13 bacteriophage that eliminates translational repression of M13 gene II by its cognate gene V protein had no effect on phage viability. Furthermore, it was noted that gene V protein of phage IKe, a distant relative of M13, does not function as a translational repressor of its cognate gene II protein. The data strongly indicate that the gene V protein-mediated control of gene II expression in bacteriophage M13 is an evolutionary relic of the ancestral filamentous-phage genome and thus dispensable for proper filamentous-phage replication.

Sequence-specific 1H-NMR assignment and secondary structure of the Tyr41----His mutant of the single-stranded DNA binding protein, gene V protein, encoded by the filamentous bacteriophage M13

Sequence-specific 1H-NMR assignments are reported for the Tyr41----His (Y41H) mutant of the single-stranded DNA binding protein, encoded by gene V of the filamentous bacteriophage M13 (GVP). The mutant protein was chosen for this purpose because it exhibits significantly improved solubility characteristics over wild-type GVP [Folkers et al. (1991) Eur. J. Biochem. 200, 139-148]. The secondary structure elements present in the protein are deduced from a qualitative interpretation of the nuclear Overhauser enhancement spectra and amide exchange data. The protein is entirely composed of antiparallel beta-structure. It is shown that identical structural elements are present in wild-type GVP. Previously, we have demonstrated that the secondary structure of the beta-loop, encompassing residues 13-31 which is present in GVP in solution, deviates from that proposed for the same amino acid sequence on the basis of X-ray diffraction data [van Duynhoven et al. (1990) FEBS Lett. 261, 1-4]. Now that we have arrived at a complete description of the secondary structure of the protein in solution, other deviations with respect to the crystallographically determined structure became apparent as well. The N-terminal part of the protein is, in solution, part of a triple-stranded beta-sheet while, in the crystal, it is an extended strand pointing away from the bulk of the protein dimer. One of the antiparallel beta-sheets in the protein which had been designated earlier as the complex loop has, in the solution structure, a different pairwise arrangement of the residues in its respective beta-ladders. Residues 30 and 48 are opposite to one another in the solution structure while in the crystal structure residues 32 and 48 are paired. A similar observation is made for the so-called dyad domain of the protein of which the beta-sheet in the solution structure is shifted by one residue with respect to that of the crystal structure.

Identification and nucleotide sequence analysis of an open reading frame involved in high-frequency conversion of turbid to clear plaque mutants of filamentous phage Cf1t

Clear plaque mutants (Cf1c) isolated from the temperate filamentous phage Cf1t occurred at a frequency of approximately 10(-3). The pahge yield from Cf1c-infected cells was higher than that from Cf1t-infected cells. Results of spot complementation tests implied that the turbid plaque phenotype is dominant. DNA fragment substitution studies indicated that a NcoI/KpnI fragment of 591 bp was responsible for the determination of plaque turbidity. Sequence data from four Cf1c isolates revealed base pair alterations and a deletion located in the upstream region of an open reading frame (ORFII) which might encode a 18.2-kDa protein. When the ORFII in Cf1t was disrupted by a frameshift mutation, this recombinant phage formed clear plaques. These observations suggest that ORFII may participate in the formation of turbid plaques. ORFII does not show significant homology with the sequence of f1 gpII, gpV, or other known phage proteins.

Approaches to predicting effects of single amino acid substitutions on the function of a protein

The relative activities of 313 mutants of the gene V protein of bacteriophage f1, assayed in vivo, have been used to evaluate two approaches to predicting the effects of single amino acid substitutions on the function of a protein. First, we tested methods that only depend on the properties of the wild-type and substituting amino acids. None of the properties or measures of the functional equivalence of amino acids we tested, including the frequency of exchange of amino acids among homologous proteins as well as changes in side-chain size, hydrophobicity, and charge, were found to be more than weakly correlated with the activities of mutants. The principal reason for this poor correlation was found to be that the effect of a particular substitution varies considerably from site to site. We then tested an approach using the activities of several mutants with substitutions at a site to predict the activity of another mutant, and we find that this is a relatively good indicator of whether the other mutant at that site will be functional. A predictive scheme was developed that combines the weak information from the models depending on the properties of the wild-type and substituting amino acids with the stronger information from the tolerance of a site to substitution. Although this scheme requires no knowledge of the structure of a mutant protein, it is useful in predicting the activities of mutants.

Regulation of expression of the genome of bacteriophage M13. Gene V protein regulated translation of the mRNAs encoded by genes I, III, V and X

With the aid of a binary plasmid in vivo testsystem it was demonstrated that the single-stranded DNA binding protein encoded by gene V of bacteriophage M13 not only regulates the synthesis of its cognate DNA replication proteins at the level of translation, but also of the assembly proteins and the coat proteins encoded by genes I and II, respectively. Furthermore, gene V protein functions as a translational autoregulator of its own synthesis. Comparison of the mRNA levels of genes I and X in the presence and absence of wild-type gene V protein indicated that gene V protein augments the physical stability of these mRNAs. The expression of the Escherichia coli beta-galactosidase gene and of a gene X mutant containing a deletion in the nontranslated mRNA leader sequence was not influenced by gene V protein, lending support to the conclusion that gene V protein exerts its regulatory effect via a specific nucleotide sequence in the leader sequences of the respective M13 mRNAs. We conclude that gene V protein functions as a master regulatory protein of the expression and replication of the M13 genome.

Isolation and in vitro characterization of temperature-sensitive mutants of the bacteriophage f1 gene V protein

In vivo selections were used to isolate 43 temperature-sensitive gene V mutants of the bacteriophage f1 from a collection of mutants constructed by saturation mutagenesis of the gene. The sites of temperature-sensitive substitutions are found in both the beta-sheets and the turns of the protein, and some sites are exposed to the solvent while others are not. Thirteen of the variant proteins were purified and characterized to evaluate their free energy changes upon unfolding and their affinities for single-stranded DNA, and eight were tested for their tendencies to aggregate at 42 degrees C. Each of the three temperature-sensitive mutants at buried sites and six of ten at surface sites had free energy changes of unfolding substantially lower (less stabilizing) than the wild-type at 25 degrees C. A seventh mutant at a surface site had a substantially altered unfolding transition and its free energy of unfolding was not estimated. The affinities of the mutant proteins for single-stranded DNA varied considerably, but two mutants at a surface site, Lys69, had much weaker binding to single-stranded DNA than any of the other mutants, while two mutants at another surface site, Glu30, had the highest DNA-binding affinities. The wild-type gene V protein is stable at 42 degrees C, but six of the eight mutants tested aggregated within a few minutes and the remaining two aggregated within 30 minutes at this temperature. Overall, each of the temperature-sensitive proteins tested had a tendency to aggregate at 42 degrees C, and most also had either a low free energy of unfolding (at 25 degrees C), or weak DNA binding. We suggest that any of these properties can lead to a temperature-sensitive gene V phenotype.

Reversible denaturation of the gene V protein of bacteriophage f1

The guanidine hydrochloride (GuHCl)-induced denaturation of the gene V protein of bacteriophage f1 has been studied, using the chemical reactivity of a cysteine residue that is buried in the folded protein and the circular dichroism (CD) at 211 and 229 nm as measures of the fraction of polypeptide chains in the folded form. It is found that this dimeric protein unfolds in a single cooperative transition from a folded dimer to two unfolded monomers. A folded, monomeric form of the gene V protein was not detected at equilibrium. The kinetics of unfolding of the gene V protein in 3 M GuHCl and the refolding in 2 M GuHCl are also consistent with a transition between a folded dimer and two unfolded monomers. The GuHCl concentration dependence of the rates of folding and unfolding suggests that the transition state for folding is near the folded conformation.

Circular dichroism and fluorescence analysis of the interaction of Pf1 gene 5 protein with poly(dT)

Circular dichroism (c.d.) and fluorescence spectroscopy have been used to investigate the interaction of the gene 5 protein of the filamentous bacteriophage Pf1 with single-stranded DNA. The c.d. spectrum of the Pf1 gene 5 protein is consistent with the absence of any significant alpha-helical content. The negative c.d. peak in the region of 210 nm, which arises from the protein, is diminished in the complex with poly(dT). Likewise, the c.d. peak at 265 nm arising from the poly(dT) decreases when the Pf1 gene 5 protein is bound, c.d. titrations of poly(dT) with Pf1 gene 5 protein indicate strong binding with a stoichiometry (n) of four nucleotides per protein subunit. In contrast, when the titrations were done using fluorescence anisotropy or fluorescence spectral shifts to follow binding, apparent stoichiometries between n = 2 and n = 4 were observed, often in the same experiment, depending on precise conditions. The results are interpreted in terms of two distinct modes of binding, in which either one or two subunits of the protein dimer are bound to the polynucleotide lattice, but still retaining the same local interaction with the DNA, with each binding site covering four nucleotides. The apparent stoichiometry of 2 results from the interaction of only one subunit of the dimer with the nucleic acid lattice, when protein is in excess. The second, unfilled, subunit of the dimer is nevertheless incorporated into the complex, resulting in the maximum possible fluorescence change when only half the sites are filled, since the fluorescence properties of the complex arise from protein-protein contacts associated with co-operative binding to the lattice. Further experiments in which the order of addition of components is changed, and the concentration of MgCl2 is varied, show that both of these factors are important in determining the dominant binding mode. In the absence of salt, dissociation and redistribution of the polynucleotide can occur following the addition of excess protein. This transition is suppressed in the presence of greater than 3 mM-MgCl2.

Complex between single-stranded DNA and gene 5 protein of bacteriophage M13 studied with linear dichroism and ultraviolet absorption

We have studied complexes between the gene 5 protein (gp5) of bacteriophage M13 and various polynucleotides, including single-stranded DNA, using ultraviolet absorption and linear dichroism. Upon complex formation the absorption spectra of both the protein and the polynucleotides change. The protein absorption changes indicate that for at least two of the five tyrosine residues per protein monomer the environment becomes less polar upon binding to the polynucleotides but also to the oligonucleotide p(dT)8. All gp5-polynucleotide complexes give rise to intense linear dichroism spectra. These spectra are dominated by negative contributions from the bases, but also a small positive dichroism of the protein can be discerned. The spectra can be explained by polynucleotide structures, which are the same in all complexes. The base orientations are characterized by a substantial inclination and propellor twist. The number of possible combinations of inclination and propeller twist values, which are in agreement with the linear dichroism results, is rather limited. The base orientations with respect to the complex axis are essentially different from those in the complex with the single-stranded DNA-binding protein gp32 of bacteriophage T4.

Translational regulation of M13 gene II protein by its cognate single-stranded DNA binding protein

To unravel the mechanism by which the single-stranded DNA binding protein encoded by gene V of the filamentous phage M13 regulates the synthesis of its cognate DNA replication protein encoded by gene II, an in vivo test system has been developed. The system consists of two recombinant plasmids with compatible replication origins. One plasmid contains M13 gene V under the control of the inducible araB promoter of Salmonella typhimurium. The other plasmid contains a fusion gene, whose expression is dependent upon the M13 gene-II-promoter and which consists of the 5' end of M13 gene II and the 5'-truncated beta-galactosidase gene of Escherichia coli. Induction of the synthesis of wild-type gene V protein by arabinose resulted in a specific reduction of both the beta-galactosidase activity and the amount of fusion protein produced. These specific inhibitory effects were not observed when the synthesis of the fusion protein was studied in the presence of an amber mutant of gene V. Comparison of the relative concentrations of the fusion protein mRNAs, as present in arabinose-induced and noninduced cells, provided solid and direct evidence for the conclusions made in earlier publications, that gene V protein exerts its regulatory effect at the level of translation. Since the transcript of the fusion gene only contains the first 74 nucleotides of gene II mRNA, it is furthermore concluded that these nucleotides are already sufficient for gene V protein to exert its regulatory effect.

Specificity of the binding of fd gene 5 protein to polydeoxyribonucleotides

The long-wavelength circular dichroism (CD) changes induced by binding of fd gene 5 protein to the alternating DNA sequences poly[d(A-C)] and poly[d(C-T)] were similar to those induced by the protein complexed with the homopolymers poly[d(A)], poly[d(C)], and poly[d(T)]. The fd gene 5 protein showed different binding affinities for the various polymers. The affinity for the alternating sequences was not compositionally weighted with respect to the affinities for the homopolymers, indicating that both base composition and base sequence of the template are important for the binding of fd gene 5 protein.

In vitro binding of the bacteriophage f1 gene V protein to the gene II RNA-operator and its DNA analog

We have investigated the binding of the f1 single-stranded DNA-binding protein (gene V protein) to DNA oligonucleotides and RNA synthesized in vitro. The first 16 nucleotides of the f1 gene II mRNA leader sequence were previously identified as the gene II RNA-operator; the target to which the gene V protein binds to repress gene II translation. Using a gel retardation assay, we find that the preferential binding of gene V protein to an RNA carrying the gene II RNA-operator sequence is affected by mutations which abolish gene II translational repression in vivo. In vitro, gene V protein also binds preferentially to a DNA oligonucleotide whose sequence is the DNA analog of the wild-type gene II RNA-operator. Therefore, the gene V protein recognizes the gene II mRNA operator sequence when present in either an RNA or DNA context.

Translation of phage f1 gene VII occurs from an inherently defective initiation site made functional by coupling

Expression of the filamentous phage f1 gene VII is shown to be translationally coupled to that of the upstream gene V. Fusions of the gene VII initiation site to the lacZ coding region were used to determine that initiation at the VII site is completely dependent on the process of translation having proceeded up to a stop codon immediately upstream from the VII site. Coupled expression from the VII site was found to be inefficient, proportional to the level of upstream translation, and very sensitive to the distance from the functional upstream stop codon. Independent expression from the VII site was not observed, even in a deletion series designed to remove potentially masking RNA structure. On the basis of the VII site's dissimilarity to ribosome binding site sequences and its properties overall, we suggest that it inherently lacks the features required for independent recognition by ribosomes, and acquires the ability to initiate synthesis of gene VII protein by virtue of the coupling process.

Translational repression in bacteriophage f1: characterization of the gene V protein target on the gene II mRNA

Previous studies have shown that the single-stranded DNA binding protein of bacteriophage f1 (gene V protein) represses the translation of the mRNA of the phage-encoded replication protein (gene II protein). We have characterized phage mutations in the repressor and in its target. Using a gene II-lacZ translational fusion, we have defined a 16-nucleotide-long region in the gene II mRNA sequence that is required in vivo for repression by the gene V protein. We have shown that in vitro the binding affinity of the gene V protein is at least 10-fold higher to an RNA carrying this sequence than to an RNA lacking it. We propose that this sequence constitutes the gene II mRNA operator.

Filamentous phage assembly: morphogenetically defective mutants that do not kill the host

The filamentous phage virion is assembled without killing the host, by extrusion of the DNA through the envelope and concomitant acquisition of coat proteins from the inner membrane. When assembly is blocked, however, intracellular phage DNA and gene products accumulate and the host is killed. This "cell killing" is largely absent in phage fd-tet, which carries a tetracycline-resistance determinant within the origin of minus-strand synthesis; as a result of the replication defect, phage DNA does not accumulate to high levels intracellularly when virion assembly is blocked. This allows morphogenetically defective mutants except those ablating gene V to be freely propagated in tetracycline-containing medium and studied in the absence of the confounding factor of cell morbidity. Because cultures can be initiated by transfection in the complete absence of input virions, extremely low levels of phage production can be assayed. Using this system, I show that genes III, VI, I, and IV are not required to form the complex between viral DNA and gene-V protein that is the intracellular precursor to mature virions; that genes I and/or IV are absolutely (or nearly absolutely) required for assembly; and that mos, a cis-acting sequence previously shown to enhance phage yield in some circumstances, is without such effect in others.

A genetic selection for temperature-sensitive variants of the gene V protein of bacteriophage f1

Complementary negative and positive genetic selections based on the activity of a plasmid-encoded bacteriophage f1 gene V are developed. The negative selection is based on an activity of the gene V protein in E. coli cells which markedly reduces the infection of those cells by f1-related viruses. In order to select against cells expressing active gene V protein, the cells are infected with the p'age R386, a derivative of f1 which confers resistance to chloramphenicol, and are plated in the presence of the antibiotic. Those cells which contain gene V protein are infrequently infected with the virus and are unable to grow in the presence of chloramphenicol; those which do not contain the gene V protein are readily infected and can grow in the presence of the antibiotic. The positive genetic selection consists of excising the gene V sequences from the plasmids and using them to replace the gene V of a bacteriophage f1 derivative containing an amber mutation in gene V. Only those genes which encode an active gene V protein can support phage growth and yield plaques. The two genetic selections can be combined in order to yield a substantial enrichment for genes encoding temperature-sensitive gene V proteins.

Regulation of bacteriophage f1 DNA replication. I. New functions for genes II and X

Gene II protein is required for all phases of filamentous phage DNA synthesis other than the conversion of the infecting single strand to the parental double-stranded molecule. It introduces a specific nick into the double-stranded replicative form DNA, is required for the initiation of (+) strand synthesis and is responsible for termination and ring closure of the (+) strand product. Here we show that the gene II protein also promotes minus strand synthesis later in infection. Over-expression of gene II protein can induce the conversion of all nascent single-stranded phage DNA to the double-stranded form, even in the presence of the single-stranded DNA-binding gene V protein that would normally sequester the newly synthesized single strands. We also present evidence that the gene X protein (separately translated from an initiator codon within gene II, and identical to the C-terminal one-third of the gene II protein) is a powerful inhibitor of phage-specific DNA synthesis in vivo.

Bacteriophage f1 DNA replication genes. II. The roles of gene V protein and gene II protein in complementary strand synthesis

Filamentous phage gene V, which encodes a single-stranded DNA binding protein, has been cloned and placed under control of the lac promoter. Cells bearing the clone are refractory to filamentous phage infection if the expression of the gene is induced with isopropyl-1-thio-beta-D-galactoside. The inhibition of infection is shown to occur at an early stage, and can be reversed if the cells express gene II in addition to gene V protein. These observations support the hypothesis that gene II protein, in addition to its role in nicking and facilitating the synthesis of phage viral (+) strand DNA, functions to prevent the gene V-mediated inhibition of complementary (-) strand synthesis. We proposed a model in which the absolute and relative concentrations of the products of genes II, X and V determine whether a single strand is to be exported as phage or incorporated into double-stranded replicative form DNA.

Filamentous phages as cloning vectors

The virtue of Ff vectors goes beyond the fact that they deliver a single strand in a convenient package for sequencing and oligonucleotide-directed mutagenesis. Of all vectors in common use they are the easiest to propagate and process. Their genomes can be easily manipulated, and the knowledge acquired over a quarter century of basic research makes their behavior reasonably predictable. For this reason I have emphasized the general properties of Ff phage in this review and dealt at some length with applications that are still not fully developed, I hope this review will inspire readers to continue the tradition of imaginative exploitation of this unique class of viruses.

Translational control of phage f1 gene expression by differential activities of the gene V, VII, IX and VIII initiation sites

Phage-specific transcription and subsequent RNA processing in Escherichia coli infected with the filamentous phage (f1, M13, fd) generate a pool of abundant and relatively long-lived phage mRNA species encoding the four adjacent genes V, VII, IX and VIII. Yet the products of gene V and gene VIII are synthesized at much higher levels than the gene VII and gene IX proteins. To ask if the translational initiation sites heading these genes show corresponding differences in activity and/or functional properties, we have purified a number of the phage mRNAs from cells infected with f1 and examined them in in vitro initiation reactions. The ribosome binding patterns obtained for the phage mRNA species and for smaller defined RNA fragments containing selected initiator regions reveal a large range in apparent ribosome binding strengths. The gene V and gene VIII sites are recognized efficiently in each mRNA species in which they are present. Gene IX site activity appears to be limited by local mRNA structure: the site has undetectable or low ribosome binding activity in all of the phage mRNA species, but is at least tenfold more active if the RNA sequences required to form a potential hairpin stem-and-loop 15 nucleotides upstream from the initiator AUG have been removed. The gene VII site shows no evidence of interaction with ribosomes in any phage mRNA or RNA fragment tested. The same striking differences in initiation activity were observed in vivo by cloning small f1 DNA fragments containing gene V or gene VII initiation site sequences to drive beta-galactosidase synthesis. High levels of a gene V-beta-galactosidase fusion protein are initiated at the V site, but no detectable synthesis occurs from the VII site. If the VII site is preceded by all of the information encoding the upstream gene V, however, modest amounts of a fusion protein initiated at the VII site are produced. The overall results, in accord with the observed yields of proteins in the phage-infected cell, provide strong evidence that the properties of these translational initiation sites determine in a significant way the differential expression of phage f1 genes V, VII, IX and VIII.

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.

A preliminary structure for the DNA binding protein from bacteriophage IKe

A modelling procedure has been utilized to obtain a preliminary three-dimensional structural model for the bacteriophage IKe DNA binding protein (IKe-DBP) based on the known high resolution X-ray diffraction structure of a functionally related protein (G5BP) from bacteriophage fd. The degree of structural homology observed is much higher than the 44% primary sequence identity between these proteins would indicate. These studies suggest IKe-DBP, like G5BP, is composed of a central three-stranded beta sheet from which protrude three extended beta loops. Furthermore, the IKe-DBP structural model can easily form, without conformational rearrangements, the compact dimer unit that is the functionally active species of G5BP. Structural comparisons show residues conserved in the primary sequence of both proteins tend to cluster in two regions. The first being essential for the maintenance of dimer association. The second about the two DNA binding channels which cross the face of each dimer. Based upon an earlier characterized G5BP-DNA complex, a model for DNA complexation to IKe-DBP is also presented.