Atomic Structure of the Degraded Procapsid Particle of the Bacteriophage G4: Induced Structural Changes in the Presence of Calcium Ions and Functional Implications

Bacteriophage G4 and φX174 are members of the Microviridae family. The degree of similarity of the structural proteins ranges from 66% identity of the F protein to 40% identity of the G protein. The atomic structure of the φX174 virion had previously been determined by X-ray crystallography. Bacteriophage G4 procapsids, consisting of the structural proteins F, G, D, B, H, and small traces of J but no DNA, were set up for crystallization. However, the resultant crystals were of degraded procapsid particles, which had lost the assembly scaffolding proteins D and B, resulting in particles that resembled empty virions.The structure of the degraded G4 procapsid has been determined to 3.0 Å resolution. The particles crystallized in the hexagonal space groupP6₃22 with unit cell dimensionsa=b=414.2(5) Å andc=263.0(3) Å. The diffraction data were collected at the Cornell High Energy Synchrotron Source (CHESS) on film and image plates using oscillation photography. Packing considerations indicated there were two particles per unit cell. A self-rotation function confirmed that the particles were positioned on 32 point group special positions in the unit cell. Initial phases were calculated to 6 Å resolution, based on the known φX174 virion model. Phase information was then extended in steps to 3.0 Å resolution by molecular replacement electron density modification and particle envelope generation.The resulting electron density map was readily interpretable in terms of the F and G polypeptides, as occur in the mature capsid of φX174. In a few regions of the electron density map there were inconsistencies between the density and the published amino acid sequence. Redetermining the amino acid sequence confirmed that the density was correct. The r.m.s. deviation between the C^αbackbone of the mature capsid of φX174 and the degraded G4 procapsid was 0.36 Å for the F protein and 1.38 Å for the G protein. This is consistent with the greater conservation of the F protein compared to the G protein sequences among members of the Microviridae family. Functionally important features between φX174 and G4 had greater conservation.Calcium ions (Ca^{2 +}) were shown to bind to G4 at a general site located near the icosahedral 3-fold axis on the F protein capsid, equivalent to sites found previously in φX174. Binding of Ca^{2 +}also caused the ordering of the conserved region of the DNA binding protein J, which was present in the degraded procapsid particle in the absence of DNA.     

Structure of the head-tail connector of bacteriophage φ29

The head-to-tail connecting region of bacteriophage φ29 has been studied by isolating neck-tail complexes from disrupted phage. These complexes can be isolated with appendages (from wild-type phage) or without appendages (from phage mutant sus12). Treatment of the neck-tail complex without appendages with urea or guanidinium hydrochloride releases the tail protein (p9) from the neck complex (proteins p10 and p11). Electron micrographs of φ29 necks show that they are composed of two collars and a thin axial tube. There is an internal hole along the longitudinal axis, from the upper collar to the thin tube.Image-processing analysis of electron micrographs of two-dimensional crystals of necks shows that the neck of phage φ29 consists of 12 external units and an internal area of apparent 6-fold symmetry, with a hole in the centre.     

Yeast-Expressed Bacteriophage-Like Particles for the Packaging of Nanomaterials

Virus-like particles (VLPs) generated by heterologous expression of viral structural genes have become powerful tools in vaccine development. Recently, we and others have reported on the assembly of VLPs of the RNA bacteriophages MS2, Qβ, and GA in yeast. Here, we investigate the formation of VLPs of five additional phages in the yeasts Saccharomyces cerevisiae and Pichia pastoris, namely, the coliphages SP and fr, Acinetobacter phage AP205, Pseudomonas phage PP7, and Caulobacter phage φCb5. In all cases except SP, particle formation was detected, although VLP outcome varied from 0.2 to 8 mg from 1 g of wet cells. We have found that phage φCb5 VLPs easily dissociate into coat protein dimers when applied to strong anion exchangers. Upon salt removal and the addition of nucleic acid or its mimics and calcium ions, the dimers re-assemble into VLPs with high efficiency. A variety of compounds, including RNA, DNA, and gold nanoparticles can be packaged inside φCb5 VLPs. The ease with which phage φCb5 coat protein dimers can be purified in high quantities and re-assembled into VLPs makes them attractive for downstream applications including the internal packaging of nanomaterials and the chemical coupling of peptides of interest on the surface.     

Directional Persistence of Cell Migration Coincides with Stability of Asymmetric Intracellular Signaling

Photosynthetic chromatophore vesicles found in some purple bacteria constitute one of the simplest light-harvesting systems in nature. The overall architecture of chromatophore vesicles and the structural integration of vesicle function remain poorly understood despite structural information being available on individual constituent proteins. An all-atom structural model for an entire chromatophore vesicle is presented, which improves upon earlier models by taking into account the stoichiometry of core and antenna complexes determined by the absorption spectrum of intact vesicles in Rhodobacter sphaeroides, as well as the well-established curvature-inducing properties of the dimeric core complex. The absorption spectrum of low-light-adapted vesicles is shown to correspond to a light-harvesting-complex 2 to reaction center ratio of 3:1. A structural model for a vesicle consistent with this stoichiometry is developed and used in the computation of excitonic properties. Considered also is the packing density of antenna and core complexes that is high enough for efficient energy transfer and low enough for quinone diffusion from reaction centers to cytochrome bc₁ complexes.     

Specificity determinants for bacteriophage lambda DNA replication: I. A chain of interactions that controls the initiation of replication

The genetic elements which control autonomous DNA replication differ in functional specificity among coliphage λ, the coliphages φ80 and 82, and the Salmonella phage P22. Hybrid phages derived by genetic recombination between λ and each of these related phages have been used to define and to localize specificity determinants for DNA replication.In λ-P22 hybrid phages (Hilliker & Botstein, 1976) the replication control elements segregate as an intact unit. By contrast, some viable λ-φ80 and λ.82 hybrid phages arise by recombination within the replication control region, in a small interval inside structural gene O. From the properties of such hybrid phages, we infer that the O gene product of λ and the functionally equivalent proteins of φ80 and 82 each interact with a specific nucleotide sequence in the cognate ori site, the DNA target for control of the origin of replication. With respect to this interaction, both the O products and the receptor sequences within ori show stringent type specificity. The donor and receptor specificity determinants for the ori-O interaction lie within an interval of less than 400 base-pairs.The O gene product also interacts with the product of replication gene P (Tomizawa, 1971). The O-P interaction displays limited type specificity; the P-like protein of φ80 can function together with the O protein of λ, but the P protein of λ cannot function with the O-like protein of φ80. The specificity determinants for the O-P interaction can be separated from those for the ori-O interaction.We propose that a chain of interactions between ori, O product, P product, and replication functions of the bacterial host, Escherichia coli, controls specific template selection and the assembly of the essential replication apparatus in the initiation of λ DNA replication.     

In vitro complex formation between bacteriophage φ29 terminal protein and deoxynucleotide

It has previously been shown that the 5′-terminal deoxyadenosine residue of each φ29 DNA strand is linked covalently to the 30,000 dalton terminal protein. When extracts prepared from φ29-infected$\text{Bacillus}\text{subtilis}$ cells are incubated with [α-³²p]dATP, complexes consisting of the nucleotide covalently linked to a 30,000 dalton protein can be detected. The formation of this complex requires the presence of φ29 DNA containing the bound 30,000 dalton terminal protein and Mg⁺⁺. When uninfected cell extracts were used, there was no complex formation. When [α-³²p]dCTP was used in place of [α-³²p]dATP, no complex was formed. DNA-protein templates prepared from φ29 related phages, φ15, Nf, M2Y and GA-1, also supported the complex formation in various degrees. These results support the hypothesis that the terminal protein serves as a primer for the initiation of φ29 DNA replication.     

Characterization of some low spin complexes of ferric hemeoctapeptide from cytochrome-c

Complexes of hemeoctapeptide, derived from bovine cytochrome c, show similar magnetic properties to those of low spin complexes of cytochrome c and hemoglobin. The electronic properties of hemeoctapeptide and cytochrome complexes are also similar while the Soret and beta bands of these analogs are generally blue shifted from those of corresponding complexes of hemoglobin due largely to the differences in the type of heme. Electron spin resonance calculations were carried out using Taylor's method to elucidate d orbital splittings and structural differences in hemeoctapeptide, hemoglobin, and cytochrome c. A correlation between V, the rhombicity, and the position of the beta band was found to exist and was dependent on protein type. However, neither the electronic not magnetic data was largely dependent on protein bulk. A large rhombic splitting caused shifts to the blue, and showed a dependence of the porphyrin pi orbitals on the placement of the metal relative to the porphyrin plane. A structural basis for the degree of rhombic splitting and thermodynamic parameters for ligand binding is proposed.     

Bacteriophage lambda FII gene protein: role in head assembly

The in vitro completion of bacteriophage lambda F_II^? heads to form phage can be used as an assay for the λ F_II gene protein. F_II protein activity is released from highly purified phage particles or phage heads by treatment with heat or denaturing agents. F_II protein was purified from isolated phage particles and from an extract of E^? infected cells in which it is not bound to any large structures. No differences in molecular weight (11,500), isoelectric point (4.75), electrophoretic mobility, or purification properties could be demonstrated between the F_II proteins from the two sources. Thus the polypeptide does not seem to be modified during assembly.Phage φ80 is closely related to λ. φ80 heads will join to φ80 tails in vitro but will not join to λ tails, though λ heads will join to either type of tail. Mixing experiments between F_II^? heads, tails, and F_II protein from λ or φ80 show that the specificity of head-tail joining is correlated with the source of the F_II protein and not with the source of the other head proteins. Thus, F_II protein is apparently responsible for this specificity of head-tail joining.     

Complete nucleotide sequence and molecular characterization of the temperate staphylococcal bacteriophage φPVL carrying Panton–Valentine leukocidin genes

The staphylococcal Panton–Valentine leukocidin (PVL) genes, [lukS-PV–lukF-PV], exist on the genome of a temperate bacteriophage φPVL isolated from mitomycin C-induced Staphylococcus aureus V8 (ATCC 49775) (Kaneko, J., Kimura, T., Kawakami, Y., Tomita, T., Kamio, Y., 1997b. Panton–Valentine leukocidin genes in phage-like particle isolated from mitomycin C-treated Staphylococcus aureus V8 (ATCC 49775). Biosci. Biotechnol. Biochem. 61, 1960–1962). In this study, the complete nucleotide sequence of the φPVL genome was analyzed, and the att sites (attL, attR, and attB) required for site-specific integration of φPVL into the host chromosome were also determined. The linear double-stranded φPVL genome comprised 41 401 bp with 3′ staggered cohesive ends (cos) of nine bases and contained 63 ORFs, among which the regulatory proteins involved in DNA replication, structural proteins, a holin, a lysin, an integrase, and dUTPase, were tentatively identified by the comparison of the deduced amino acid sequences and by the analysis of the proteins isolated from φPVL particles. The [lukS-PV–lukF-PV], attP, and int (integrase gene) of φPVL were all located very close to one another within a 4.0-kb segment on the genome in the order given, and this segment was located at the center from the left and the right cos sites. In addition, the attP region contained five direct repeat sequences that showed a high degree of homology with the recombinase-binding sites of some other S. aureus bacteriophages. The φPVL genome was found to integrate into an ORF encoding an unknown protein comprising 725 amino acid residues with two leucine zipper-like motifs.     

Construction of viable and lethal mutations in the origin of bacteriophage 'phi' X174 using synthetic oligodeoxyribonucleotides

Six different synthetic deoxyhexadecamers complementary to the origin of bacteriophage φX174, corresponding to nucleotides 4299 to 4314, except for one preselected nucleotide change were used as primers for DNA synthesis on wild-type φX² DNA as a template. DNA synthesis was performed with Escherichia coli DNA polymerase I (Klenow fragment) in the presence of DNA ligase. Heteroduplex RFIV DNA was isolated and, after limited digestion with DNAase I, complementary strands containing the mutant primers were isolated. The biological activity of these complementary strands was assayed in spheroplasts. Spheroplasts were made from E. coli K58 ung^? (uracil N-glycosylase) to prevent degradation of the complementary strands caused by uracil incorporation (Baas et al., 1980a).Using (5′-³²P) end-labeled primers, it was shown that all tested DNA polymerase preparations, including phage T4 DNA polymerase, contained variable amounts of 5′ → 3′ exonuclease activity. This nick translation activity may result in removal of the mutation in the primers, and therefore in isolation of wild-type complementary DNA instead of mutant complementary DNA.Restriction enzyme analysis of completed RFIV DNA showed that the primers can initiate DNA synthesis at more than one place on the φX174 genome. These complications result in a mixed population of complementary strand DNAs synthesized in vitro. Nevertheless, the desired mutants were picked up with high frequency using a selection test that is based on the difference in ultraviolet light sensitivity of homoduplex and heteroduplex φX174 RF DNA. Heteroduplex φX174 RF DNA is two to three times more sensitive to ultraviolet light irradiation than is homoduplex φX174 RF DNA (Baas &; Jansz, 1971,1972). Phage DNA derived from single plaque lysates of two of the six mutant complementary strand DNA preparations yielded, after annealing with wild-type complementary strand DNA, heteroduplex DNA with high frequency. DNA sequence analysis in the origin region of RF DNA obtained from these two phage preparations revealed the presence of the expected mutation. RFI DNA of these two origin mutants was nicked by φX174 gene A protein in the same way as wild-type φX174 RFI DNA.Phage DNA derived from single plaque lysates of the other four mutant complementary strand DNA preparations yielded exclusively homoduplex DNA after annealing with wild-type complementary strand DNA. It is concluded that priming with these deoxyhexadecamers resulted in the synthesis of complementary φX174 DNA with lethal mutations. The implications of these results, the construction of two silent, viable φX174 origin mutants and the failure to detect four others, for the initiation mechanism of φX174 RF DNA replication are discussed.     

Excision and duplication of su3+-transducing fragments carried by bacteriophage φ80: II. Red- or rec-dependent excision and duplication

During vegetative growth φ80)sus2psu3⁺ and φ80int3sus2psu3⁺ segregate su3^? progeny phages, which have lost suppressor activity, at high frequency, even in the absence of the host Rec system. DNA molecules of the su3^? segregants were equivalent to φ80 DNA, as determined by heteroduplex analysis. Loss of suppressor activity is ascribed either to unequal intermolecular crossing-over or to excision by internal recombination between two homologous regions of the phage genome which bracket the bacterial segment containing the su3⁺ gene. To investigate the recombination system acting on the segregation of su3^? phages, a fec^?int^? deletion derivative of φ80sus2psu3⁺, φ80Δ4sus2psu3⁺, has been isolated that is stable even after several cycles of growth in the absence of the host Rec system. However, segregation of su3^? phages from φ80Δ4sus2psu3⁺ was observed when it was complemented in vivo with the hybrid phage λatt⁸⁰imm⁸⁰ in the absence of the host Rec system. The Δ4 deletion is 12.4% of the φ80 genome, starting at a distance of 1.6% φ80 unit to the right from the φ80 crossover point, pp′, i.e. located between 54.6% and 67.0% φ80 unit, as measured from the left (0%) termini of the mature φ80 DNA molecules. By locating the regions of homology between the DNAs of λ and φ80 (Fiandt et al., 1971), the region deleted in φ80Δ4sus2psu3⁺ was assigned to the genes of the phage Red system and a part of the int gene. In the presence of the host Rec system, φ80Δ4-sus2psu3⁺ segregates both phages, φ80Δ4sus2 and φ80Δ4sus2p(su3⁺)₂, which were excised or duplicated for su3⁺-transducing fragments. The loss of the duplication in φ80Δ4sus2p(su3⁺)₂ is also promoted by the host Rec system. Either of two generalized recombination systems, viral Red system or host Rec system, can play a role in the production of the excisions and the duplications of transducing fragments.     

Bacteriophage phi 80-induced low molecular weight RNA

A species of low molecular weight RNA (M₃) which is produced in bacteriophage φ80-infected Escherichia coli has been isolated and characterized. M₃ appears immediately after infection and its synthesis continues until lysis. This RNA is unstable; its mean half-life is 13.5 min. The structural gene for M₃ is localized on the φ80 genome to the right of the exonuclease locus and to the left of gene Q.     

Insights into the diversity of φRSM phages infecting strains of the phytopathogen Ralstonia solanacearum complex: regulation and evolution

The filamentous φRSM phages (φRSM1 and φRSM3) have integration/excision capabilities in the phytopathogenic bacterium Ralstonia solanacearum. In the present study, we further investigated φRSM-like sequences present in the genomes of R. solanacearum strains belonging to the four major evolutionary lineages (phylotypes I–IV). Based on bioinformatics and comparative genomic analyses, we found that φRSM homologs are highly diverse in R. solanacearum complex strains. We detected an open reading frame (ORF)15 located upstream of the gene for φRSM integrase, which exhibited amino acid sequence similarity to phage repressor proteins. ORF15-encoded protein (a putative repressor) was found to encode a 104-residue polypeptide containing a DNA-binding (helix-turn-helix) domain and was expressed in R. solanacearum lysogenic strains. This suggested that φRSM3-ORF15 might be involved in the establishment and maintenance of a lysogenic state, as well as in phage immunity. Comparison of the putative repressor proteins and their binding sites within φRSM-related prophages provides insights into how these regulatory systems of filamentous phages have evolved and diverged in the R. solanacearum complex. In conclusion, φRSM phages represent a unique group of filamentous phages that are equipped with innate integration/excision (ORF14) and regulatory systems (ORF15).     

Structures and mechanisms of formation of liprotides

Many proteins form complexes called liprotides with oleic acid and other cis-fatty acids under conditions where the protein is partially unfolded. The complexes vary in structure depending on the ratio of protein and lipid, but the most common structural organization is the core-shell structure, in which a layer of dynamic, partially unfolded and extended proteins surrounds a micelle-like fatty acid core. This structure, first reported for α-lactalbumin together with OA, resembles complexes formed between proteins and anionic surfactants like SDS. Liprotides first rose to fame through their anti-carcinogenic properties which still remains promising for topical applications though not yet implemented in the clinic. In addition, liprotides show potential in drug delivery thanks to the ability of the micelle core to solubilize and stabilize hydrophobic compounds, though applications are challenged by their sensitivity to acidic pH and dynamic exchange of lipids which makes them easy prey for serum “hoovers” such as albumin. However, liprotides are also of fundamental interest as a generic “protein complex structure”, demonstrating the many and varied structural consequences of protein-lipid interactions. Here we provide an overview of the different types of liprotide complexes, ranging from quasi-native complexes via core-shell structures to multi-layer structures, and discuss the many conditions under which they form. Given the many variable types of complexes that can form, rigorous biophysical analysis (stoichiometry, shape and structure of the complexes) remains crucial for a complete understanding of the mechanisms of action of this fascinating group of protein-lipid complexes both in vitro and in vivo.     

Non-innocent ligand reservoirs for reducing or oxidizing equivalents in carbonylrhenium(I) complexes: 1,1′-Bis(diphenylphosphino)ferrocene (dppf) and bis-triazinyl-pyridine (BTP)

Organometallic complexes of Re(I) with ligands having opposite redox properties have been synthesized and structurally characterized. X-ray crystal structures of the complexes show typical fac-Re^I(CO)₃ coordination to the redox active ligands. Complete electrochemical and spectroelectrochemical studies on the ligands and the metal complexes were performed. The IR-spectroelectrochemical responses were monitored using the fac-Re(CO)₃ unit as a probe. The 15-20 cm⁻¹ hypsochromic or bathochromic shift of the ν_CO bands upon reduction or oxidation is attributed to ligand-centered processes.     

A Group 6 Late Embryogenesis Abundant Protein from Common Bean Is a Disordered Protein with Extended Helical Structure and Oligomer-forming Properties

Late embryogenesis-abundant proteins accumulate to high levels in dry seeds. Some of them also accumulate in response to water deficit in vegetative tissues, which leads to a remarkable association between their presence and low water availability conditions. A major sub-group of these proteins, also known as typical LEA proteins, shows high hydrophilicity and a high percentage of glycine and other small amino acid residues, distinctive physicochemical properties that predict a high content of structural disorder. Although all typical LEA proteins share these characteristics, seven groups can be distinguished by sequence similarity, indicating structural and functional diversity among them. Some of these groups have been extensively studied; however, others require a more detailed analysis to advance in their functional understanding. In this work, we report the structural characterization of a group 6 LEA protein from a common bean (Phaseolus vulgaris L.) (PvLEA6) by circular dichroism and nuclear magnetic resonance showing that it is a disordered protein in aqueous solution. Using the same techniques, we show that despite its unstructured nature, the addition of trifluoroethanol exhibited an intrinsic potential in this protein to gain helicity. This property was also promoted by high osmotic potentials or molecular crowding. Furthermore, we demonstrate that PvLEA6 protein is able to form soluble homo-oligomeric complexes that also show high levels of structural disorder. The association between PvLEA6 monomers to form dimers was shown to occur in plant cells by bimolecular fluorescence complementation, pointing to the in vivo functional relevance of this association.