Conformation of the antifreeze glycoprotein of polar fish

High-field proton and 13C NMR spectroscopy has been used to test and refine the recent proposal, based on vacuum uv circular dichroism results, of a threefold left-handed helical conformation for antifreeze glycoprotein (AFGP). Partial assignment of the protons of the glycotripeptide repeating unit has been made by comparison with spectra of model compounds, by selective decoupling, and by measurements of nuclear Overhauser effect (nOe). At 40 degrees C, AFGP fraction 8 (Mr 2600) shows 2-Hz linewidths which broaden at lower temperature. Neither 1H nor 13C chemical shifts depend strongly on temperature, suggesting no abrupt conformational transition. The nOe between alanine alpha and beta protons vary with temperature and with field strength, from small positive enhancements at 50 degrees C and 80 MHz to large negative effects at 3 degrees C and 300 MHz, indicating a substantial change of rotational correlation time with temperature. The higher-molecular-weight fraction 1-4 shows negative nOe at all temperatures. The CD spectra of fraction 1-4 show bands characteristic of the polyproline II structure at both 3 and 50 degrees C, while those bands in fraction 8 are weaker at 50 than 3 degrees C. The 1H nOe, the 13C T1, and CD data are interpreted as indicating that AFGP fraction 8 is an extended "rod-like" conformation at low temperature which becomes a flexible coil at high temperature, while fraction 1-4 is a flexible rod with sufficient segmental mobility to eliminate any long-range order.     

A model for fd phage penetration and assembly

Below 15 degrees C, chloroform causes fd phage to contract to I-forms, which are compact structures about 1/3 as long as the original phage. Above 15 degrees C, chloroform causes I-forms to contract to even more compact spheroidal S-forms. Here we show that the coat protein structure in I-forms is the same as the protein structure in the phage and the protein structure in S-forms is the same as the protein structure in bilayers. The conversions from fd----I-forms----S-forms are therefore suggested to mimic steps in fd penetration. The same conversions, in reverse order, are suggested to mimic steps in fd assembly.     

Laser Raman studies of lipid disordering by the B-protein of fd phage.

Complexes of the B-protein of fd phage with the model lipid dipalmitoyl phosphatidylcholine (DPPC) were made by sonication of the fd phage in the presence of dipalmitoyl phosphatidylcholine. Both laser Raman spectra and circular dichroism show the protein in the membrane to be almost entirely in the beta-sheet conformation. This beta-sheet conformation is found to be independent of the temperature between 10 degrees C and 50 degrees C. On the other hand, the protein has a very dramatic effect on the organization of the lipid bilayer. An aqueous dispersion of 1 : 1 lipid/protein mixture gives a broad conformational transition of DPPC which occurs between 10 degrees C and 30 degrees C. This contrasts markedly with simple aqueous DPPC dispersions which show a sharp transition at 41 degrees C. This appears to be the first reported example of the lowering of the conformational transition of a membrane bilayer by an intrinsic membrane protein.     

Initial structural and dynamic characterization of the M2 protein transmembrane and amphipathic helices in lipid bilayers

Amphipathic helices in membrane proteins that interact with the hydrophobic/hydrophilic interface of the lipid bilayer have been difficult to structurally characterize. Here, the backbone structure and orientation of an amphipathic helix in the full-length M2 protein from influenza A virus has been characterized. The protein has been studied in hydrated DMPC/DMPG lipid bilayers above the gel to liquid-crystalline phase transition temperature by solid-state NMR spectroscopy. Characteristic PISA (Polar Index Slant Angle) wheels reflecting helical wheels have been observed in uniformly aligned bilayer preparations of both uniformly 15N labeled and amino acid specific labeled M2 samples. Hydrogen/deuterium exchange studies have shown the very slow exchange of some residues in the amphipathic helix and more rapid exchange for the transmembrane helix. These latter results clearly suggest the presence of an aqueous pore. A variation in exchange rate about the transmembrane helical axis provides additional support for this claim and suggests that motions occur about the helical axes in this tetramer to expose the entire backbone to the pore.     

Deuterium/hydrogen exchange factors measured by solution nuclear magnetic resonance spectroscopy as indicators of the structure and topology of membrane proteins

Deuterium/hydrogen exchange factors (chi) were measured for the backbone amide sites of the membrane-bound forms of the 50-residue fd coat protein and the 23-residue magainin2 peptide in lipid micelles by solution nuclear magnetic resonance spectroscopy. By combining kinetic and thermodynamic effects, deuterium/hydrogen exchange factors overcome the principal limitations encountered in the measurements of kinetic protection factors and thermodynamic fractionation factors for membrane proteins. The magnitudes of the exchange factors can be correlated with the structure and topology of membrane-associated polypeptides. In fd coat protein, residues in the transmembrane helix have exchange factors that are substantially smaller than those in the amphipathic surface helix or the loop connecting the two helices. For the amphipathic helical peptide, magainin2, the exchange factors of residues exposed to the solvent are appreciably larger than those that face the hydrocarbon portion of membrane bilayers. These examples demonstrate that deuterium/hydrogen exchange factors can be measured by solution NMR spectroscopy and used to identify residues in transmembrane helices as well as to determine the polarity of amphipathic helices in membrane proteins.     

Effects of temperature and energy inhibitors on complex formation between Escherichia coli male cells and filamentous phage fd

The effect of temperature and various energy inhibitors on the formation of a complex between Escherichia coli male cells and filamentous phage fd was studied by a novel filtration method. Centrifuged male cells were observed by electron microscopy to have lost the majority of pili and to produce complexes with fd only above 25 degrees C. After preincubation of the cells at 37 degrees C without addition of the phage, nearly half the level of complex formation observed at 37 degrees C was detected at 0 degrees C and fd was at a minimum at about 20 degrees C. Several energy inhibitors and uncouplers drastically reduced complex formation at 37 degrees C, and also at 0 degrees C if the cells were briefly exposed to the reagents at the end of preincubation. Alteration of the cellular ATP concentration, either by shift-down of temperature or by the addition of the reagents, accompanied alteration in the ability of cells to form a complex with fd as well as alteration of the number of pili on the cell surface. In contrast to earlier reports, these results indicate that the complex formation between male cells and filamentous phage does not proceed either when pili disappear from the cell surface because of a decrease in the cellular energy level or when pili are removed by mechanical forces. The results also show that phage fd adsorption itself is not energy-dependent.     

Probing conserved helical modules of portal complexes by mass spectrometry-based hydrogen/deuterium exchange

The Double-stranded DNA bacteriophage P22 has a ring-shaped dodecameric complex composed of the 84 kDa portal protein subunit that forms the central channel of the phage DNA packaging motor. The overall morphology of the P22 portal complex is similar to that of the portal complexes of Phi29, SPP1, T3, T7 phages and herpes simplex virus. Secondary structure prediction of P22 portal protein and its threading onto the crystal structure of the Phi29 portal complexes suggested that the P22 portal protein complex shares conserved helical modules that were found in the dodecameric interfaces of the Phi29 portal complex. To identify the amino acids involved in intersubunit contacts in the P22 portal ring complexes and validate the threading model, we performed comparative hydrogen/deuterium exchange analysis of monomeric and in vitro assembled portal proteins of P22 and the dodecameric Phi29 portal. Hydrogen/deuterium exchange experiments provided evidence of intersubunit interactions in the P22 portal complex similar to those in the Phi29 portal that map to the regions predicted to be conserved helical modules.     

Raman markers of nonaromatic side chains in an alpha-helix assembly: Ala, Asp, Glu, Gly, Ile, Leu, Lys, Ser, and Val residues of phage fd subunits

The study of filamentous virus structure by Raman spectroscopy requires accurate band assignments. In previous work, site- and residue-specific isotope substitutions were implemented to elucidate definitive assignments for Raman bands arising from vibrational modes of the alpha-helical coat protein main chain and aromatic side chains in the class I filamentous phage, fd [Overman, S. A., and Thomas, G. J., Jr. (1995) Biochemistry 34, 5440-5451; Overman, S. A., and Thomas, G. J., Jr. (1998) Biochemistry 37, 5654-5665]. Here, we extend the previous methods and expand the assignment scheme to identify Raman markers of nonaromatic side chains of the coat protein in the native fd assembly. This has been accomplished by Raman analysis of 11 different fd isotopomers selectively incorporating deuterium at specific sites in either alanine, aspartic acid, glutamic acid, glycine, isoleucine, leucine, lysine, serine, or valine residues of the coat protein. Raman markers are also identified for the corresponding deuterated side chains. In combination with previous assignments, the results provide a comprehensive understanding of coat protein contributions to the Raman signature of the fd virion and validate Raman markers assigned to the packaged single-stranded DNA genome. The findings described here show that nonaromatic side chains contribute prolifically to the fd Raman signature, that marker bands for specific nonaromatics differ in general from those observed in corresponding polypeptides and amino acids, and that the frequencies and intensities of many nonaromatic markers are sensitive to secondary and higher-order structures. Nonaromatic markers within the 1200-1400 cm-1 interval also interfere seriously with the diagnostic Raman amide III band that is normally exploited in secondary structure analysis. Implications of these findings for the assessment of protein conformation by Raman spectroscopy are considered.     

Structural polymorphism correlated to surface charge in filamentous bacteriophages.

Fiber diffraction studies are used to demonstrate that changes in the helical symmetry of the protein coat of filamentous bacterial viruses fd and M13 are correlated with changes in the surface charge. Comparison of the structure of M13 and fd at pH 2 and 8 indicate that surface charge affects both the helical symmetry and flexibility of the virions. The changes in helical symmetry are similar in magnitude to that observed in the Pseudomanas phage Pf1 and probably reflect an inocuous side effect of the particle flexibility required for protection of the virus particles from damage due to shear. The magnitude of the observed changes in helical symmetry appears to be limited to that which can occur without repacking of the interfaces between the alpha-helices making up the viral protein coat.     

Investigation of secondary and tertiary structural changes of cytochrome c in complexes with anionic lipids using amide hydrogen exchange measurements: an FTIR study.

The structure of cytochrome c bound to anionic lipid membranes composed of dimyristoyl, dipalmitoyl, or dioleoyl phosphatidylglycerols, or of bovine heart cardiolipin, has been investigated by Fourier transform infrared spectroscopy. Only small changes in secondary structure, as registered by the amide I band of cytochrome c, were observed upon binding at temperatures below that of denaturation of the protein, and these were not coupled to the thermotropic phase transitions of the lipid. The denaturation temperature of the protein decreased by approximately 25-30 degrees upon binding, in a progression which correlated with that of the lipid phase transition temperatures, being approximately 7 degrees lower for complexes with dioleoyl than with dipalmitoyl phosphatidylglycerol. Large changes in the amide proton exchange characteristics, as monitored by the spectral shifts in the amide I band of the protein in D2O, were observed on binding cytochrome c to the lipid membranes. For the slowly exchanging population, the amide deuteration rates of the free protein were nearly independent of temperature, whereas those of the bound protein increased by up to two orders of magnitude over the temperature range from 10 to 40 degrees C. In addition, the extent of exchange differed between the bound and unbound protein. A structural transition in the bound protein was detected as a discontinuous step in Arrhenius plots of the deuterium exchange rates which occurred at a temperature in the region of 22 to 29 degrees C, depending on the lipid, far below that of denaturation. The temperature of this transition was determined by the physical state of the lipid, being 7 degrees lower for the lipids in the fluid state than for those in the gel state, and, for complexes with dimyristoyl phosphatidylglycerol, occurred at an intermediate temperature, being controlled by the lipid chain-melting transition at 27-28 degrees C. These results provide evidence for a coupling of the tertiary structure of the membrane-bound protein with the physical state of the membrane lipids.     

Peptide hydrogen exchange rates in Streptomyces subtilisin inhibitor.

The exchange reaction of the peptide NH protons of a microbial protease inhibitor (Streptomyces subtilisin inhibitor) with deuterium atoms in 2H2O (p2H 6.8) has been studied by proton magnetic resonance in the temperature range 56-71 degrees C. Both slowly and rapidly exchanging processes have been observed. The number of slowly exchanging protons is estimated to be 25 +/- 2 per subunit of the protein molecule. The decay of the slowly exchanging proton signals follows a single time-exponential function at each temperature. The observed first-order rate constants have been analyzed to give the denaturated fraction of the protein as a function of temperature with a consequent enthalpy (56 kcal/mol) and an entropy (137 cal/degree per mol) of denaturation. The results indicate the high conformational stability of this protein against heat denaturation.     

Infrared spectroscopic discrimination between the loop and alpha-helices and determination of the loop diffusion kinetics by temperature-jump time-resolved infrared spectroscopy for cytochrome c

The infrared (IR) absorption of the amide I band for the loop structure may overlap with that of the alpha-helices, which can lead to the misassignment of the protein secondary structures. A resolution-enhanced Fourier transform infrared (FTIR) spectroscopic method and temperature-jump (T-jump) time-resolved IR absorbance difference spectra were used to identify one specific loop absorption from the helical IR absorption bands of horse heart cytochrome c in D2O at a pD around 7.0. This small loop consists of residues 70-85 with Met-80 binding to the heme Fe(III). The FTIR spectra in amide I' region indicate that the loop and the helical absorption bands overlap at 1653 cm(-1) at room temperature. Thermal titration of the amide I' intensity at 1653 cm(-1) reveals that a transition in loop structural change occurs at lower temperature (Tm=45 degrees C), well before the global unfolding of the secondary structure (Tm approximately 82 degrees C). This loop structural change is assigned as being triggered by the Met-80 deligation from the heme Fe(III). T-jump time-resolved IR absorbance difference spectra reveal that a T-jump from 25 degrees C to 35 degrees C breaks the Fe-S bond between the Met-80 and the iron reversibly, which leads to a loop (1653 cm(-1), overlap with the helical absorption) to random coil (1645 cm(-1)) transition. The observed unfolding rate constant interpreted as the intrachain diffusion rate for this 16 residue loop was approximately 3.6x10(6) s(-1).     

Study of heat denaturation of collagen dispersions by a method of IR-spectroscopy]

Infrared spectroscopy was used to examine the kinetics of deuterium exchange in collagen films prepared from its 0.5% dispersions obtained from cattle tendons and healed at 25--100 degrees C for 30 min. The temperature relationships to the denaturation degree and time of deuterium exchange suggested that an almost complete heat denaturation of dispersions can be achieved at 31.5 degrees C. The temperature of semi-denaturation of dispersions was 28.5--29.0 degrees. The occurrence of intact supermolecular aggregates of collagen molecules in its dispersions had no effect on the system resistance to heat denaturation.     

Mechanism of conjugation and recombination in bacteria. XXI. Role of F factor genes in post-conjugational recombination in Escherichia coli K-12

Temperature sensitive dnaA recipient crossed at the restrictive temperature with HfrH, free from contaminating F+ cells, forms recombinants almost as proficiently as at the permissive temperature. The merozygotes are able to synthesize DNA at 42 degrees C, although the recipient and donor cells do not incorporate 3H-thymine. A substantial fraction of Lac+ recombinants, irrespective of the mating temperature, is temperature resistant (42 C-R); 15% from among those mated at 35 C and 30% from those mated at 42 C. The presence of dnaA mutation in these Lac+ 42 C-R recombinants was ascertained by co-transduction with ilv. Cell division at 42 C is inhibited in the Lac 42 C-R recombinants by acridine orange. The presence of F factor DNA in these recombinants was demonstrated directly by DNA: DNA hybridization. Suppression of dnaA mutation in Lac+ 42 degrees C-R recombinants and their sensitivity to acridine orange at 42 degrees C suggests that at least part of the F factor is integrated into the recombinant chromosome. A large fraction of the Lac+ 42 degrees C-R recombinants (up to 80%) is sensitive to male phage R17 and fertile. In crosses with HfrC there is a marked decrease of recombination frequency at 42 degrees C in the dnaA recipient. The fraction of Lac+ 42 degrees C-R recombinants is low (up to 10%) and the 42 degrees C-R recombinants are neither sensitive to male phage nor fertile. The results are discussed on the basis of the previously proposed model of post-conjugational recombination.     

Fourier transform infrared investigation of the Escherichia coli methionine aporepressor

This study represents the first physicochemical analysis of the recently cloned methionine repressor protein (Met aporepressor) from Escherichia coli. Infrared spectrometry was used to investigate the secondary structure and the hydrogen-deuterium exchange behavior of the E. coli Met aporepressor. The secondary structure of the native bacterial protein was derived by analysis of the amide I mode. The amide I band contour was found to consist of five major component bands (at 1625, 1639, 1653, 1665, and 1676 cm-1) which reflect the presence of various substructures. The relative areas of these component bands are consistent with a high alpha-helical content of the peptide chain secondary structure in solution (43%) and a small amount of beta-sheet structure (7%). The remaining substructure is assigned to turns (10%) and to unordered (or less ordered) structures (40%). The temperature dependence of the infrared spectra of native Met aporepressor in D2O medium over the temperature interval 20-80 degrees C indicates that there are two discrete thermal events: the first thermal event, centered at 42 degrees C, is associated with the hydrogen-deuterium exchange of the hard-to-exchange alpha-helical peptide bonds accompanied by a partial denaturation of the protein, while the second event, centered around 50 degrees C, represents the irreversible thermal denaturation of the protein.     

Solution structure and dynamics of a heat shock protein assembly probed by hydrogen exchange and mass spectrometry

The solution conformation and dynamics of the 16.9 kDa small heat shock protein from wheat have been studied using a combination of hydrogen/deuterium exchange, proteolytic digestion, and mass spectrometry. At room temperature, HSP16.9 exists as a dodecameric assembly. Regions of HSP16.9 that form extensive and essential intersubunit contacts in the assembly, including residues 1-40 and 131-151, show little or no protection against hydrogen/deuterium exchange after incubation in D(2)O for 5 s. The high levels of hydrogen/deuterium exchange indicate that these regions have experienced large conformational fluctuations in solution, breaking intersubunit contacts and exposing buried amide hydrogens to solvent. When HSP16.9 is pulse labeled for 10 ms, residues 1-40 and 131-151 are substantially more protected than they are after 5 s. Thus, the breaking of intersubunit contacts occurs on a time scale between 10 milliseconds and 5 s. At 42 degrees C, HSP16.9 exists in a suboligomeric form. When the intrinsic temperature dependence of hydrogen/deuterium exchange is taken into account, exchange patterns at 25 and 42 degrees C are identical within experimental error, suggesting that the conformation of individual HSP16.9 subunits is the same in both the dodecameric and subdodecameric forms. Significant protection is seen in regions that form the dimeric interface, suggesting that the stable suboligomeric form is a dimer. Taken together, these results suggest that heat activation of HSP16.9 occurs by shifting the dodecamer <--> dimer equilibrium in favor of free dimers. The conformation of the dimers themselves does not appear to be altered with an increase in temperature.     

Studies of synthetic helical peptides using circular dichroism and nuclear magnetic resonance

We have designed a set of 17-residue synthetic peptides to be monomeric helices in aqueous solution. Circular dichrosim experiments indicate the presence of helical structure in aqueous solution at low temperature and low pH. The two-dimensional nuclear magnetic resonance results for one of the peptides show a segment of ten residues which clearly meets all of the criteria for the existence of helical structure at both 5 degrees C and 15 degrees C. The first four residues of the peptide are in a largely extended conformation. Calculations suggest that residues 5 through 14 are significantly helical at 5 degrees C. When the temperature is increased, circular dichroism spectra indicate that the helical content decreases. At 15 degrees C, the 3JN alpha coupling constants increase in the helical region, indicating an increase in motion or conformational averaging in the helical segment. None of the peptides has pH titration behavior consistent with salt bridge stabilization of helical conformation. Our data lend themselves to interpretation with the helix dipole model and specific side-chain interactions. When the N and C termini charges are removed the helical content of the peptides increases. The amount of helicity increases as the pH is lowered, due to the ionization of His16. Much of the helical stabilization appears to be due to a specific side-chain interaction between His16 and Tyr12.     

Nuclear magnetic resonance of the filamentous bacteriophage fd.

The filamentous bacteriophage fd and its major coat protein are being studied by nuclear magnetic resonance (NMR) spectroscopy. 31P NMR shows that the chemical shielding tensor of the DNA phosphates of fd in solution is only slightly reduced in magnitude by motional averaging, indicating that DNA-protein interactions substantially immobilize the DNA packaged in the virus. There is no evidence of chemical interactions between the DNA backbone and the coat protein, since experiments on solid virus show the 31P resonances to have the same principle elements of its chemical shielding tensor as DNA. 1H and 13C NMR spectra of fd virus in solution indicate that the coat proteins are held rigidly in the structure except for some aliphatic side chains that undergo relatively rapid rotations. The presence of limited mobility in the viral coat proteins is substantiated by finding large quadrupole splittings in 2H NMR of deuterium labeled virions. The structure of the coat protein in a lipid environment differs significantly from that found for the assembled virus. Data from 1H and 13C NMR chemical shifts, amide proton exchange rates, and 13C relaxation measurements show that the coat protein in sodium dodecyl sulfate micelles has a native folded structure that varies from that of a typical globular protein or the coat protein in the virus by having a partially flexible backbone and some rapidly rotating aromatic rings.     

Laser raman studies of lipid disordering by the B-protein of fd phage

Complexes of the B-protein of fd phage with the model lipid dipalmitoyl phosphatidylcholine (DPPC) were made by sonication of the fd phage in the presence of dipalmitoyl phosphatidylcholine. Both laser Raman spectra and circular dichroism show the protein in the membrane to be almost entirely in the β-sheet conformation. This β-sheet conformation is found to be independent of the temperature between 10° C and 50° C. On the other hand, the protein has a very dramatic effect on the organization of the lipid bilayer. An aqueous dispersion of 1 : 1 lipid/protein mixture gives a broad conformational transition of DPPC which occurs between 10° C and 30° C. This contrasts markedly with simple aqueous DPPC dispersions which show a sharp transition at 41°C. This appears to be the first reported example of the lowering of the conformational transition of a membrane bilayer by an intrinsic membrane protein.     

The N-terminal propeptide of lung surfactant protein C is necessary for biosynthesis and prevents unfolding of a metastable alpha-helix

The lung surfactant-associated protein C (SP-C) consists mainly of a polyvaline alpha-helix, which is stable in a lipid membrane. However, in agreement with the predicted beta-strand conformation of a polyvaline segment, helical SP-C unfolds and transforms into beta-sheet aggregates and amyloid fibrils within a few days in aqueous organic solvents. SP-C fibril formation and aggregation have been associated with lung disease. Here, we show that in a recently isolated biosynthetic precursor of SP-C (SP-Ci), a 12 residue N-terminal propeptide locks the metastable polyvaline part in a helical conformation. The SP-Ci helix does not aggregate or unfold during several weeks of incubation, as judged by hydrogen/deuterium exchange and mass spectrometry. Hydrogen/deuterium exchange experiments further indicate that the propeptide reduces exchange in parts corresponding to mature SP-C. Finally, in an acidic environment, SP-Ci unfolds and aggregates into amyloid fibrils like SP-C. These data suggest a direct role of the N-terminal propeptide in SP-C biosynthesis.