YidC-driven membrane insertion of single fluorescent Pf3 coat proteins

The membrane insertion of single bacteriophage Pf3 coat proteins was observed by confocal fluorescence microscopy. Within seconds after addition of the purified and fluorescently labeled protein to liposomes or proteoliposomes containing the purified and reconstituted membrane insertase YidC of Escherichia coli, the translocation of the labeled residue was detected. The 50-amino-acid-long Pf3 coat protein was labeled with Atto520 and inserted into the proteoliposomes. Translocation of the dye into the proteoliposome was revealed by quenching the fluorescence outside of the vesicles. This allowed us to distinguish single Pf3 coat proteins that only bound to the surface of the liposomes from proteins that had inserted into the bilayer and translocated the dye into the lumen. The Pf3 coat protein required the presence of the YidC membrane insertase, whereas mutants that have a membrane-spanning region with an increased hydrophobicity were autonomously inserted into the liposomes without YidC.     

NMR-Based Simulation Studies of Pf1 Coat Protein in Explicit Membranes

As time- and ensemble-averaged measures, NMR observables contain information about both protein structure and dynamics. This work represents a computational study to extract such information for membrane proteins from orientation-dependent NMR observables: solid-state NMR chemical shift anisotropy and dipolar coupling, and solution NMR residual dipolar coupling. We have performed NMR-restrained molecular dynamics simulations to refine the structure of the membrane-bound form of Pf1 coat protein in explicit lipid bilayers using the recently measured chemical shift anisotropy, dipolar coupling, and residual dipolar coupling data. From the simulations, we have characterized detailed protein-lipid interactions and explored the dynamics. All simulations are stable and the NMR restraints are well satisfied. The C-terminal transmembrane (TM) domain of Pf1 finds its optimal position in the membrane quickly (within 6 ns), illustrating efficient solvation of TM domains in explicit bilayer environments. Such rapid convergence also leads to well-converged interaction patterns between the TM helix and the membrane, which clearly show the interactions of interfacial membrane-anchoring residues with the lipids. For the N-terminal periplasmic helix of Pf1, we identify a stable, albeit dynamic, helix orientation parallel to the membrane surface that satisfies the amphiphatic nature of the helix in an explicit lipid bilayer. Such detailed information cannot be obtained solely from NMR observables. Therefore, the present simulations illustrate the usefulness of NMR-restrained MD refinement of membrane protein structure in explicit membranes.     

NMR-Based Simulation Studies of Pf1 Coat Protein in Explicit Membranes

As time- and ensemble-averaged measures, NMR observables contain information about both protein structure and dynamics. This work represents a computational study to extract such information for membrane proteins from orientation-dependent NMR observables: solid-state NMR chemical shift anisotropy and dipolar coupling, and solution NMR residual dipolar coupling. We have performed NMR-restrained molecular dynamics simulations to refine the structure of the membrane-bound form of Pf1 coat protein in explicit lipid bilayers using the recently measured chemical shift anisotropy, dipolar coupling, and residual dipolar coupling data. From the simulations, we have characterized detailed protein-lipid interactions and explored the dynamics. All simulations are stable and the NMR restraints are well satisfied. The C-terminal transmembrane (TM) domain of Pf1 finds its optimal position in the membrane quickly (within 6 ns), illustrating efficient solvation of TM domains in explicit bilayer environments. Such rapid convergence also leads to well-converged interaction patterns between the TM helix and the membrane, which clearly show the interactions of interfacial membrane-anchoring residues with the lipids. For the N-terminal periplasmic helix of Pf1, we identify a stable, albeit dynamic, helix orientation parallel to the membrane surface that satisfies the amphiphatic nature of the helix in an explicit lipid bilayer. Such detailed information cannot be obtained solely from NMR observables. Therefore, the present simulations illustrate the usefulness of NMR-restrained MD refinement of membrane protein structure in explicit membranes.     

Dynamics of fd coat protein in the bacteriophage

The dynamics of the coat protein in fd bacteriophage are described with solid-state 15N and 2H NMR experiments. The virus particles and the coat protein subunits are immobile on the time scales of the 15N chemical shift anisotropy (10(3) Hz) and 2H quadrupole (10(6) Hz) interactions. Previously we have shown that the Trp-26 side chain is immobile, that the two Tyr and three Phe side chains undergo only rapid twofold jump motions about their C beta-C gamma bond axis [Gall, C. M., Cross, T. A., DiVerdi, J. A., & Opella, S. J. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 101-105], and that most of the backbone peptide linkages are highly constrained but do undergo rapid small amplitude motions [Cross, T. A., & Opella, S. J. (1982) J. Mol. Biol. 159, 543-549] in the coat protein subunits in the virus particles. In this paper, we demonstrate that the four N-terminal residues of the coat protein subunits are highly mobile, since both backbone and side-chain sites of these residues undergo large amplitude motions that are rapid on the time scales of the solid-state NMR experiments. In addition, the dynamics of the methyl-containing aliphatic residues Ala, Leu, Val, Thr, and Met are analyzed. Large amplitude jump motions are observed in nearly all of these side chains even though, with the exception of the N-terminal residue Ala-1, their backbone peptide linkages are highly constrained. The established information about the dynamics of the structural form of fd coat protein in the virus particle is summarized qualitatively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neutron diffraction studies of the structure of filamentous bacteriophage Pf1. Demonstration that the coat protein consists of a pair of alpha-helices with an intervening, non-helical surface loop

The structure of filamentous bacteriophage Pf1 has been studied using neutron diffraction from magnetically oriented gels of native and specifically deuterated phage. These methods have been used to determine the positions of the two methionine, two tyrosine and six isoleucine residues of the coat protein. Combined with the positions of the five valine residues previously determined, they represent one third (15 of 46) of the residues of the coat protein. These 15 amino acid residue positions have been used as the basis for constructing a model for the protein consisting of two alpha-helices with an intervening surface loop. The first helix extends from near the amino terminus to Ile12. The second helix extends from Lys20 to at least Met42, and may contain a bend between Ile32 and Val35. The two helices are tilted by about 15 degrees relative to one another, and are positioned in such a way that they appear to be bound end-to-end by main-chain hydrogen bonds. The intervening, non-helical loop, made up of Thr13 to Met19, connects the two helices without disrupting the pattern of main-chain hydrogen bonding, but does not result in a bend in the otherwise continuous helical structure. This model is used to predict the approximate positions of all amino acid residues in the Pf1 protein coat, providing a basis for further understanding of a number of viral properties including the symmetry transitions, the non-isomorphism of heavy-atom derivatives, and the protein-protein and protein-DNA interactions in the virion.     

Shuffling of structural elements in filamentous bacteriophages

All class II filamentous bacteriophage coat proteins contain a conserved, 12-amino acid sequence highly homologous to the loop portion of the EF-hand Ca²⁺-binding motif. The Pf3 coat protein contains two regions of homology to this sequence. The 12-amino acid sequence corresponds to a region of the Pf1 coat protein whose structure is controversial. In some models of the virus structure, this region is α-helical. In others, it forms a loop that folds back on itself. The similarity of this region to the loop in the helix-loop-helix Ca²⁺-binding motif suggests that it takes on a loop structure in the virion. Each filamentous phage lacks at least one residue normally involved in Ca²⁺-coordination, consistent with the relatively weak Ca²⁺ binding properties of the filamentous phages. Consideration of the structure of the coat protein in the membrane and in the virus particle indicates that the protein may be more effective in binding cations in its membrane-bound form than in the virus particle. This suggests that release of cations from this loop may be an obligate step during assembly of the proteins into the virus particle. Proteins 27:405–409, 1997. © 1997 Wiley-Liss, Inc.     

Involvement of SecDF and YidC in the membrane insertion of M13 procoat mutants

The M13 phage Procoat protein is one of the best characterized substrates for the novel YidC pathway. It inserts into the membrane independent of the SecYEG complex but requires the 60 kDa YidC protein. Mutant Procoat proteins with alterations in the periplasmic region had been found to require SecYEG and YidC. In this report, we show that the membrane insertion of these mutants also strongly depends on SecDF that bridges SecYEG to YidC. In a cold-sensitive mutant of YidC, the Sec-dependent function of YidC is strongly impaired. We find that specifically the SecDF-dependent mutants are inhibited in the cold-sensitive YidC strain. Finally, we find that subtle changes in the periplasmic loop such as the number and location of negatively charged residues and the length of the periplasmic loop can make the Procoat strictly Sec-dependent. In addition, we successfully converted Sec-independent Pf3 coat into a Sec-dependent protein by changing the location of a negatively charged residue in the periplasmic tail. Protease mapping of Pf3 coat shows that the insertion-arrested proteins that accumulate in the YidC- or in the SecDF-deficient strains are not translocated. Taken together, the data suggest that the Sec-dependent mutants insert at the interface of YidC and the translocon with SecDF assisting in the translocation step in vivo.     

Proton-decoupled 15N and 31P solid-state NMR investigations of the Pf3 coat protein in oriented phospholipid bilayers

The coat proteins of filamentous phage are first synthesized as transmembrane proteins and then assembled onto the extruding viral particles. We investigated the transmembrane conformation of the Pseudomonas aeruginosa Pf3 phage coat protein using proton-decoupled 15N and 31P solid-state NMR spectroscopy. The protein was either biochemically purified and uniformly labelled with 15N or synthesized chemically and labelled at specific sites. The proteins were then reconstituted into oriented phospholipid bilayers and the resulting samples analysed. The data suggest a model in which the protein adopts a tilted helix with an angle of approximately 30 degrees and an N-terminal 'swinging arm' at the membrane surface.     

Structure and dynamics of a membrane protein in micelles from three solution NMR experiments

Three solution NMR experiments on a uniformly ¹⁵N labeled membrane protein in micelles provide sufficient information to describe the structure, topology, and dynamics of its helices, as well as additional information that characterizes the principal features of residues in terminal and inter-helical loop regions. The backbone amide resonances are assigned with an HMQC-NOESY experiment and the backbone dynamics are characterized by a ¹H-¹⁵N heteronuclear NOE experiment, which clearly distinguishes between the structured helical residues and the more mobile residues in the terminal and interhelical loop regions of the protein. The structure and topology of the helices are described by Dipolar waves and PISA wheels derived from experimental measurements of residual dipolar couplings (RDCs) and residual chemical shift anisotropies (RCSAs). The results show that the membrane-bound form of Pf1 coat protein has a 20-residue trans-membrane hydrophobic helix with an orientation that differs by about 90° from that of an 8-residue amphipathic helix. This combination of three-experiments that yields Dipolar waves and PISA wheels has the potential to contribute to high-throughput structural characterizations of membrane proteins.     

Direct interaction of YidC with the Sec-independent Pf3 coat protein during its membrane protein insertion.

YidC is a newly defined translocase component that mediates the insertion of proteins into the membrane bilayer. How YidC functions in the insertion process is not known. In this study, we report that the Sec-independent Pf3 coat protein requires the YidC protein specifically for the membrane translocation step. Using photocrosslinking techniques and ribosome-bound Pf3 coat derivatives with an extended carboxyl-terminal region, we found that the transmembrane region of the Pf3 coat protein physically interacts with YidC and the bacterial signal recognition particle Ffh component. We also find that in the insertion pathway, Pf3 coat interacts strongly with YidC only after its transmembrane segment is fully exposed outside the ribosome tunnel. Interaction between Pf3 coat and YidC occurs even in the absence of the proton motive force and with a Pf3 coat mutant that is defective in transmembrane insertion. Our study demonstrates that YidC can directly interact with a Sec-independent membrane protein, and the role of YidC is at the stage of folding the Pf3 protein into a transmembrane configuration.     

Real Time Observation of Single Membrane Protein Insertion Events by the Escherichia coli Insertase YidC

Membrane protein translocation and insertion is a central issue in biology. Here we focus on a minimal system, the membrane insertase YidC of Escherichia coli that inserts small proteins into the cytoplasmic membrane. In a reconstituted system individual insertion processes were followed by single-pair fluorescence resonance energy transfer (FRET), with a pair of fluorophores on YidC and the substrate Pf3 coat protein. After addition of N-terminally labeled Pf3 coat protein a close contact to YidC at its cytoplasmic label was observed. This allowed to monitor the translocation of the N-terminal domain of Pf3 coat protein across the membrane in real time. Translocation occurred within milliseconds as the label on the N-terminal domain rapidly approached the fluorophore on the periplasmic domain of YidC at the trans side of the membrane. After the close contact, the two fluorophores separated, reflecting the release of the translocated Pf3 coat protein from YidC into the membrane bilayer. When the Pf3 coat protein was labeled C-terminally, no translocation of the label was observed although efficient binding to the cytoplasmic positions of YidC occurred.     

Structure of the coat protein in Pf1 bacteriophage determined by solid-state NMR spectroscopy

The atomic resolution structure of Pf1 coat protein determined by solid-state NMR spectroscopy of magnetically aligned filamentous bacteriophage particles in solution is compared to the structures previously determined by X-ray fiber and neutron diffraction, the structure of its membrane-bound form, and the structure of fd coat protein. These structural comparisons provide insights into several biological properties, differences between class I and class II filamentous bacteriophages, and the assembly process. The six N-terminal amino acid residues adopt an unusual "double hook" conformation on the outside of the bacteriophage particle. The solid-state NMR results indicate that at 30 degrees C, some of the coat protein subunits assume a single, fully structured conformation, and some have a few mobile residues that provide a break between two helical segments, in agreement with structural models from X-ray fiber and neutron diffraction, respectively. The atomic resolution structure determined by solid-state NMR for residues 7-14 and 18-46, which excludes the N-terminal double hook and the break between the helical segments, but encompasses more than 80% of the backbone including the distinct kink at residue 29, agrees with that determined by X-ray fiber diffraction with an RMSD value of 2.0 A. The symmetry and distance constraints determined by X-ray fiber and neutron diffraction enable the construction of an accurate model of the bacteriophage particle from the coordinates of the coat protein monomers.     

Sensitivity enhancement for membrane proteins reconstituted in parallel and perpendicular oriented bicelles obtained by using repetitive cross-polarization and membrane-incorporated free radicals

Multidimensional separated local-field and spin-exchange experiments employed by oriented-sample solid-state NMR are essential for structure determination and spectroscopic assignment of membrane proteins reconstituted in macroscopically aligned lipid bilayers. However, these experiments typically require a large number of scans in order to establish interspin correlations. Here we have shown that a combination of optimized repetitive cross polarization (REP-CP) and membrane-embedded free radicals allows one to enhance the signal-to-noise ratio by factors 2.4-3.0 in the case of Pf1 coat protein reconstituted in magnetically aligned bicelles with their normals being either parallel or perpendicular to the main magnetic field. Notably, spectral resolution is not affected at the 2:1 radical-to-protein ratio. Spectroscopic assignment of Pf1 coat protein in the parallel bicelles has been established as an illustration of the method. The proposed methodology will advance applications of oriented-sample NMR technique when applied to samples containing smaller quantities of proteins and three-dimensional experiments.     

The effect of proteolytic cleavage of potato virus X coat protein on its ability to self-assemble with RNA and viral infectivity

The process of proteolytic cleavage of potato virus X coat protein molecules inside the virions and in the dissociated state in the course of their purification and storage has been studied. In agreement with the previous reports, the intact form (Ps) of the coat protein in the viral particles was found to be gradually cleaved to three discrete lower molecular forms (Pi, Pf, Pu). During the storage of the dissociated coat protein preparations further cleavage was observed with formation of at least three additional lower molecular weight forms (Ppa, Ppb, Ppc). The location of proteolytic cleavage sites leading to formation of Ppa form was determined. The shortened forms Pi, Pf, Pu and Ppa (and possibly Ppc) were found to be incorporated into the viral particles in the course of reconstitution in vitro with the viral RNA. Infectivity of the virus containing only intact (Ps) form of the protein was found to be two to three folds higher than that of the virus containing only Pf form of the coat protein.     

The protein capsid of filamentous bacteriophage PH75 from Thermus thermophilus

The PH75 strain of filamentous bacteriophage (Inovirus) grows in the thermophilic bacterium Thermus thermophilus at 70 degrees C. We have characterized the viral DNA and determined the amino acid sequence of the major coat protein, p8. The p8 protein is synthesized without a leader sequence, like that of bacteriophage Pf3 but unlike that of bacteriophage Pf1, both of which grow in the mesophile Pseudomonas aeruginosa. X-ray diffraction patterns from ordered fibres of the PH75 virion are similar to those from bacteriophages Pf1 and Pf3, indicating that the protein capsid of the PH75 virion has the same helix symmetry and subunit shape, even though the primary structures of the major coat proteins are quite different and the virions assemble at very different temperatures. We have used this information to build a molecular model of the PH75 protein capsid based on that of Pf1, and refined the model by simulated annealing, using fibre diffraction data extending to 2.4 A resolution in the meridional direction and to 3.1 A resolution in the equatorial direction. The common design may reflect a fundamental motif of alpha-helix packing, although differences exist in the DNA packaging and in the means of insertion of the major coat protein of these filamentous bacteriophages into the membrane of the host bacterial cell. These may reflect differences in the assembly mechanisms of the virions.     

Conditional lethal mutations separate the M13 procoat and Pf3 coat functions of YidC: different YIDC structural requirements for membrane protein insertion

Conditional lethal YidC mutants have been isolated to decipher the role of YidC in the assembly of Sec-dependent and Sec-independent membrane proteins. We now show that the membrane insertion of the Sec-independent M13 procoat-lep protein is inhibited in a short time in a temperature-sensitive mutant when shifted to the nonpermissive temperature. This provides an additional line of evidence that YidC plays a direct role in the insertion of the Sec-independent M13 procoat protein. However, in the temperature-sensitive mutant, the insertion of the Sec-independent Pf3 phage coat protein and the Sec-dependent leader peptidase were not strongly inhibited at the restricted temperatures. Conversely, using a cold-sensitive YidC strain, we find that the membrane insertion of the Sec-independent Pf3 coat protein is blocked, and the Sec-dependent leader peptidase is inhibited at the nonpermissive temperature, whereas the insertion of the M13 procoat protein is nearly normal. These data show that the YidC function for procoat and its function for Pf3 coat and possibly leader peptidase are genetically separable and suggest that the YidC structural requirements are different for the Sec-independent M13 procoat and Pf3 coat phage proteins that insert by different mechanisms.     

Membrane assembly of the bacteriophage Pf3 major coat protein

The Pf3 major coat protein of the Pf3 bacteriophage is stored in the inner membrane of the infected cell during the reproductive cycle. The protein consists of 44 amino acids, and contains an acidic amphipathic N-terminal domain, a hydrophobic domain, and a short basic C-terminal domain. The mainly alpha-helical membrane-bound protein traverses the membrane once, leaving the C-terminus in the cytoplasm and the N-terminus in the periplasm. A cysteine-scanning approach was followed to measure which part of the membrane-bound Pf3 protein is inside or outside the membrane. In this approach, the fluorescence probe N-[(iodoacetyl)amino]ethyl-1-sulfonaphthylamine (IAEDANS) was attached to single-cysteine mutants of the Pf3 coat protein. The labeled mutant coat proteins were reconstituted into the phospholipid DOPC/DOPG (80/20 molar ratio) and DOPE/DOPG (80/20 molar ratio) model membranes. We subsequently studied the fluorescence characteristics at the different positions in the protein. We measured the local polarity of the environment of the probe, as well as the accessibility of the probe to the fluorescence quencher acrylamide. The results of this study show a single membrane-spanning protein with both the C- and N-termini remaining close to the surface of the membrane. A nearly identical result was seen previously for the membrane-bound M13 coat protein. On the basis of a comparison between the results from both studies, we suggest an "L-shaped" membrane-bound model for the Pf3 coat protein. DOPE-containing model membranes revealed a higher polarity, and quenching efficiency at the membrane/water interface. Furthermore, from the outside to the inside of the membrane, a steeper polarity gradient was measured at the PE/PG interface as compared to the PC/PG interface. These results suggest a thinner interface for DOPE/DOPG than for DOPC/DOPG membranes.     

Comparison of protein and deoxyribonucleic acid backbone structures in fd and Pf1 bacteriophages

The conformations of the protein and nucleic acid backbones in the filamentous viruses fd and Pf1 are characterized by one- and two-dimensional solid-state NMR experiments on oriented virus solutions. Striking differences are observed between fd and Pf1 in both their protein and DNA structures. The coat proteins of fd and Pf1 are almost entirely alpha helical and in both viruses most of the helix is oriented parallel to the filament axis. fd coat protein is one stretch of alpha helix that is slightly slued about the filament axis. In Pf1 coat protein two distinct sections of alpha helix are present, the smaller of which is tilted with respect to the filament axis by about 20 degrees. The DNA backbone structure of fd is completely disordered. By contrast, the DNA backbone of Pf1 is uniformly oriented such that all of the phosphodiester groups have the O-P-O plane of the nonesterified oxygens approximately perpendicular to the filament axis.     

Initial binding process of the membrane insertase YidC with its substrate Pf3 coat protein is reversible

The binding of the inner membrane insertase YidC from Escherichia coli to its substrate, the Pf3 coat protein, was examined in vitro by fluorescence spectroscopy. Purified YidC protein was solubilized with the lipid-like detergent n-dodecylphosphocholine and noncovalently labeled with 1-anilino-naphthalene-8-sulfonate (ANS), whereas the Pf3 coat protein was kept in solution by the addition of 10% (v/v) isopropanol to the buffer. The binding of Pf3 coat protein was analyzed by fluorescence quenching of ANS bound to YidC. All binding curves showed a strict hyperbolic form at pH values between 9.0 and 5.0, indicating a reversible and noncooperative binding between YidC and its substrate. Analysis of the data revealed a dissociation constant K D for the binding process in the range of 1 microM. The pH profile of the K D values suggests that the binding of the Pf3 coat protein is dominated by hydrophobic interactions. The titration experiments provide strong evidence for a conformational change of the insertase upon binding a Pf3 coat protein molecule.