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

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.

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.

Independent tyrosyl contributions to the CD of Ff gene 5 protein and the distinctive effects of Y41H and Y41F mutants on protein-protein cooperative interactions

The gene 5 protein (g5p) of the Ff virus contains five Tyr, individual mutants of which have now all been characterized by CD spectroscopy. The protein has a dominant tyrosyl 229-nm L(a) CD band that is shown to be approximately the sum of the five individual Tyr contributions. Tyr41 is particularly important in contributing to the high cooperativity with which the g5p binds to ssDNA, and Y41F and Y41H mutants are known to differ in dimer-dimer packing interactions in crystal structures. We compared the solution structures and binding properties of the Y41F and Y41H mutants using CD spectroscopy. Secondary structures of the mutants were similar by CD analyses and close to those derived from the crystal structures. However, there were significant differences in the binding properties of the two mutant proteins. The Y41H protein had an especially low binding affinity and perturbed the spectrum of poly[d(A)] in 2 mM Na(+) much less than did Y41F and the wild-type gene 5 proteins. Moreover, a change in the Tyr 229 nm band, assigned to the perturbation of Tyr34 at the dimer-dimer interface, was absent in titrations with the Y41H mutant under low salt conditions. In contrast, titrations with the Y41H mutant in 50 mM Na(+) exhibited typical CD changes of both the nucleic acid and the Tyr 229-nm band. Thus, protein-protein and g5p-ssDNA interactions appeared to be mutually influenced by ionic strength, indicative of correlated changes in the ssDNA binding and cooperativity loops of the protein or of indirect structural constraints.

Single-stranded DNA binding protein encoded by the filamentous bacteriophage M13: structural and functional characteristics

The single-stranded DNA binding protein, or gene V protein (gVp), encoded by gene V of the filamentous bacteriophage M13 is a multifunctional protein that not only regulates viral DNA replication but also gene expression at the level of mRNA translation. It furthermore is implicated as a scaffolding and/or chaperone protein during the phage assembly process at the hostcell membrane. The protein is 87 amino acids long and its biological functional entity is a homodimer. In this manuscript a short description of the life cycle of filamentous phages is presented and our current knowledge of the major functional and structural properties and characteristics of gene V protein are reviewed. In addition models of the superhelical complexes gVp forms with ssDNA are described and their (possible) biological meaning in the infection process are discussed. Finally it is described that the 'DNA binding loop' of gVp is a recurring motif in many ssDNA binding proteins and that the fold of gVp is shared by a large family of evolutionarily conserved gene regulatory proteins.

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.

Fluorescence studies of the binding of bacteriophage M13 gene V mutant proteins to polynucleotides

This investigation describes how the binding characteristics of the single-stranded DNA-binding protein encoded by gene V of bacteriophage M13, are affected by single-site amino acid substitutions. The series of mutant proteins tested includes mutations in the purported monomer-monomer interaction region as well as mutations in the DNA-binding domain at positions which are thought to be functionally involved in monomer-monomer interaction or single-stranded DNA binding. The characteristics of the binding of the mutant proteins to the homopolynucleotides poly(dA), poly(dU) and poly(dT), were studied by means of fluorescence-titration experiments. The binding stoichiometry and fluorescence quenching of the mutant proteins are equal to, or lower than, the wild-type gene V protein values. In addition, all proteins measured bind a more-or-less co-operative manner to single-stranded DNA. The binding affinities for poly(dA) decrease in the following order: Y61H greater than wild-type greater than F68L and R16H greater than Y41F and Y41H greater than F73L greater than R21C greater than Y34H greater than G18D/Y56H. Possible explanations for the observed differences are discussed. The conservation of binding affinity, also for mutations in the single-stranded DNA-binding domain, suggests that the binding to homopolynucleotides is largely non-specific.

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.

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.