Molecular and mesoscale structures in hydrophobically driven aqueous solutions

Since Kauzmann's seminal 1959 paper, the hydrophobic interaction has dominated thinking on the forces that control protein folding and stability. Despite its wide importance in chemistry and biology, our understanding of this interaction at the molecular level remains poor, with little experimental evidence to support the idea of water ordering close to a non-polar group that is at the centre of the standard model for the source of the entropic driving force. Developments over recent years in neutron techniques now enable us to see directly how a non-polar group actually affects the molecular structure of the water in its immediate neighbourhood. On the basis of such work on aqueous solutions of small alcohols, the generally accepted standard model is found to be wanting, and alternative sources of the entropic driving force are suggested. Moreover, the fact that we can now follow changes in hydrogen bonding as the alcohol concentration is varied gives us the possibility of explaining the concentration dependence of the enthalpy of mixing. Complementary studies of solute association on the mesoscopic scale show a rich concentration and temperature behaviour, which reflects a complex balance of polar and non-polar interactions. Unravelling the detailed nature of this balance in simple aqueous amphiphiles may lead to a better understanding of the forces that control biomolecular structural stability and interactions.

Neutron and X-ray scattering by ox corneal stroma differentially loaded with bound anions

Ox corneas at near physiological hydration were subjected to two variables: the amount of chloride ions bound to them and exposure of various mixtures of H(2)O/D(2)O as solvent. The preparations were then exposed to a neutron beam and the contrast match points, at which the collagen fibrils of the corneal stroma most nearly matched the scattering density of the various H(2)O/D(2)O mixtures, were measured. In both cases of high and low bound chloride, the contrast match points of the collagen fibril were equal, indicating that there were no significant changes in the water of electrostriction at the fibril surface when chloride ions bind to the stroma. The data suggest that the ligands which bind anions to corneal stroma are not located at the collagen fibril surface. When the chloride binding ligands were extracted from the corneal stroma there were significant changes in the structure of the fibrils. We suggest that the chloride binding ligands may be located within the collagen fibril.

Detergent organisation in crystals of monomeric outer membrane phospholipase A

The structure of the detergent in crystals of outer membrane phospholipase A (OMPLA) has been determined using neutron diffraction contrast variation. Large crystals were soaked in stabilising solutions, each containing a different H(2)O/D(2)O contrast. From the neutron diffraction at five contrasts, the 12 A resolution structure of the detergent micelle around the protein molecule was determined. The hydrophobic beta-barrel surfaces of the protein molecules are covered by rings of detergent. These detergent belts are fused to neighbouring detergent rings forming a continuous three-dimensional network throughout the crystal. The thickness of the detergent layer around the protein varies from 7-20 A. The enzyme's active site is positioned just outside the hydrophobic detergent zone and is thus in a proper location to catalyse the hydrolysis of phospholipids in a natural membrane. Although the dimerisation face of OMPLA is covered with detergent, the detergent density is weak near the exposed polar patch, suggesting that burying this patch in the enzyme's dimer interface may be energetically favourable. Furthermore, these results indicate a crucial role for detergent coalescence during crystal formation and contribute to the understanding of membrane protein crystallisation.

Hierarchical assembly of the Alu domain of the mammalian signal recognition particle

The mammalian signal recognition particle (SRP) catalytically promotes cotranslational translocation of signal sequence containing proteins across the endoplasmic reticulum membrane. While the S-domain of SRP binds the N-terminal signal sequence on the nascent polypeptide, the Alu domain of SRP temporarily interferes with the ribosomal elongation cycle until the translocation pore in the membrane is correctly engaged. Here we present biochemical and biophysical evidence for a hierarchical assembly pathway of the SRP Alu domain. The proteins SRP9 and SRP14 first heterodimerize and then initially bind to the Alu RNA 5' domain. This creates the binding site for the Alu RNA 3' domain. Alu RNA then undergoes a large conformational change with the flexibly linked 3' domain folding back by 180 degrees onto the 5' domain complex to form the final compact Alu ribonucleoprotein particle (Alu RNP). We discuss the possible mechanistic consequences of the likely reversibility of this final step with reference to translational regulation by the SRP Alu domain and with reference to the structurally similar Alu RNP retroposition intermediates derived from Alu elements in genomic DNA.

Effects of ligand binding on the association properties and conformation in solution of retinoic acid receptors RXR and RAR

In higher eukaryotes, vitamin A derived metabolites such as 9-cis and all-trans retinoic acid (RA), are involved in the regulation of several essential physiological processes. Their pleiotropic physiological effects are mediated through direct binding to cognate nuclear receptors RXRs and RARs that act as regulated transcription factors belonging to the superfamily of nuclear hormone receptors. Hormone binding to the structurally conserved ligand-binding domain (LBD) of these receptors triggers a conformational change that principally affects the conserved C-terminal transactivation helix H12 involved in transcriptional activation. We report an extensive biophysical solution study of RAR alpha, RXR alpha LBDs and their corresponding RXR alpha/RAR alpha LBD heterodimers combining analytical ultracentrifugation (AUC), small-angle X-ray and neutron scattering (SAXS and SANS) and ab initio three-dimensional shape reconstruction at low resolution. We show that the crystal structures of RXRs and RARs LBDs correlate well with the average conformations observed in solution. Furthermore we demonstrate the effects of 9-cisRA and all-transRA binding on the association properties and conformations of RXR alpha and RAR alpha LBDs in solution. The present study shows that in solution RAR alpha LBD behaves as a monomer in both unliganded and liganded forms. It confirms the existence in solution of a ligand-induced conformational change towards a more compact form of the LBD. It also confirms the stability of the predicted RXR alpha/RAR alpha LBD heterodimers in solution. SAS measurements performed on three different types of RXR alpha/RAR alpha LBD heterodimers (apo/apo, apo/holo and holo/holo) with respect to their ligand-binding site occupancy show the existence of three conformational states depending on the progressive binding of RA stereoisomers on RAR alpha and RXR alpha LBD subunits in the heterodimeric context. These results suggest that the subunits are structurally independent within the heterodimers. Our study also underlines the particular behaviour of RXR alpha LBD. In solution unliganded RXR alpha LBD is observed as two species that are unambiguously identified as homotetramers and homodimers. Molecular modelling combined with SAS data analysis allows us to propose a structural model for this autorepressed apo-tetramer. In contrast to the monomeric state observed in the crystal structure, our data show that in solution active holo-RXR alpha LBD bound to 9-cisRA is a homodimer regardless of the protein concentration. This study demonstrates the crucial role of ligands in the regulation of homodimeric versus heterodimeric association state of RXR in the NR signalling pathways.

Small angle neutron scattering and gel filtration analyses of neutrophil NADPH oxidase cytosolic factors highlight the role of the C-terminal end of p47phox in the association with p40phox

The NADPH oxidase of phagocytic cells is regulated by the cytosolic factors p47(phox), p67(phox), and p40(phox) as well as by the Rac1-Rho-GDI heterodimer. The regulation is a consequence of protein-protein interactions involving a variety of protein domains that are well characterized in signal transduction. We have studied the behavior of the NADPH oxidase cytosolic factors in solution using small angle neutron scattering and gel filtration. p47(phox), two truncated forms of p47(phox), namely, p47(phox) without its C-terminal end (residues 1-358) and p47(phox) without its N-terminal end (residues 147-390), and p40(phox) were found to be monomeric in solution. The dimeric form of p67(phox) previously observed by gel filtration experiments was confirmed. Our small angle neutron scattering experiments show that p40(phox) binds to the full-length p47(phox) in solution in the absence of phosphorylation. We demonstrated that the C-terminal end of p47(phox) is essential in this interaction. From the comparison of the presence or absence of interaction with various truncated forms of the proteins, we confirmed that the SH3 domain of p40(phox) interacts with the C-terminal proline rich region of p47(phox). The radii of gyration observed for p47(phox) and the truncated forms of p47(phox) (without the C-terminal end or without the N-terminal end) show that all these molecules are elongated and that the N-terminal end of p47(phox) is globular. These results suggest that the role of amphiphiles such as SDS or arachidonic acid or of p47(phox) phosphorylation in the elicitation of NADPH oxidase activation could be to disrupt the p40(phox)-p47(phox) complex rather than to break an intramolecular interaction in p47(phox).

Studies on the structure and mechanism of a bacterial protein toxin by analytical ultracentrifugation and small-angle neutron scattering

Pneumolysin, an important virulence factor of the human pathogen Streptococcus pneumoniae, is a pore-forming toxin which also possesses the ability to activate the complement system directly. Pneumolysin binds to cholesterol in cell membrane surfaces as a prelude to pore formation, which involves the oligomerization of the protein. Two important aspects of the pore-forming activity of pneumolysin are therefore the effect of the toxin on bilayer membrane structure and the nature of the self-association into oligomers undergone by it. We have used analytical ultracentrifugation (AUC) to investigate oligomerization and small-angle neutron scattering (SANS) to investigate the changes in membrane structure accompanying pore formation. Pneumolysin self-associates in solution to form oligomeric structures apparently similar to those which appear on the membrane coincident with pore formation. It has previously been demonstrated by us using site-specific chemical derivatization of the protein that the self-interaction preceding oligomerization involves its C-terminal domain. The AUC experiments described here involved pneumolysin toxoids harbouring mutations in different domains, and support our previous conclusions that self-interaction via the C-terminal domain leads to oligomerization and that this may be related to the mechanism by which pneumolysin activates the complement system.SANS data at a variety of neutron contrasts were obtained from liposomes used as model cell membranes in the absence of pneumolysin, and following the addition of toxin at a number of concentrations. These experiments were designed to allow visualization of the effect that pneumolysin has on bilayer membrane structure resulting from oligomerization into a pore-forming complex. The structure of the liposomal membrane alone and following addition of pneumolysin was calculated by the fitting of scattering equations directly to the scattering curves. The fitting equations describe scattering from simple three-dimensional scattering volume models for the structures present in the sample, whose dimensions were varied iteratively within the fitting program. The overall trend was a thinning of the liposome surface on toxin attack, which was countered by the formation of localized structures thicker than the liposome bilayer itself, in a manner dependent on pneumolysin concentration. At the neutron contrast match point of the liposomes, pneumolysin oligomers were observed. Inactive toxin appeared to bind to the liposome but not to cause membrane alteration; subsequent activation of pneumolysin in situ brought about changes in liposome structure similar to those seen in the presence of active toxin. We propose that the changes in membrane structure on toxin attack which we have observed are related to the mechanism by which pneumolysin forms pores and provide an important perspective on protein/membrane interactions in general. We discuss these results in the light of published data concerning the interaction of gramicidin with bilayers and the hydrophobic mismatch effect.

Depletion interaction of casein micelles and an exocellular polysaccharide

Casein micelles become mutually attractive when an exocellular polysaccharide produced by Lactococcus lactis subsp. cremoris NIZO B40 (hereafter called EPS) is added to skim milk. The attraction can be explained as a depletion interaction between the casein micelles induced by the nonadsorbing EPS. We used three scattering techniques (small-angle neutron scattering, turbidity measurements, and dynamic light scattering) to measure the attraction. In order to connect the theory of depletion interaction with experiment, we calculated structure factors of hard spheres interacting by a depletion pair potential. Theoretical predictions and all the experiments showed that casein micelles became more attractive upon increasing the EPS concentration.

The effect of regulatory Ca2+ on the in situ structures of troponin C and troponin I: a neutron scattering study

The effects of regulatory amounts of Ca2+ on the in situ structures of troponin C (TnC) and troponin I (TnI) in whole troponin have been investigated by neutron scattering. In separate difference experiments, 97% deuterated TnC and TnI within whole troponin were studied +/-Ca2+ in 41.6% 2H2O buffers in which protonated subunits were rendered "invisible". We found that the radius of gyration (Rg) of TnI decreased by approximately 10% upon addition of regulatory Ca2+ indicating that it was significantly more compact in the presence of Ca2+. The apparent cross-sectional radius of gyration (Rc) of TnI increased by about 9% when regulatory Ca2+ was bound to TnC. Modeling studies showed that the high-Q scattering patterns of TnI could be fit by a TnI which consisted of two subdomains: one, a highly oblate ellipsoid of revolution containing about 65% of the mass and the other, a highly prolate ellipsoid of revolution consisting of about 35% of the mass. No other fits could be found with this class of models. Best fits were achieved when the axes of revolution of these ellipsoids were steeply inclined with respect to each other. Ca2+ addition decreased the center of mass separation by about 1.5 nm. The Rg of TnI, its high-Q scattering pattern, and the resultant structure were different from previous results on neutron scattering by TnI in the (+Ca2+) TnC.TnI complex. The Rg of TnC indicated that it was elongate in situ. The Rg of TnC was not sensitive to the Ca2+ occupancy of its regulatory sites. However, Rc increased upon Ca2+ addition in concert with expectations from NMR and crystallography of isolated TnC. The present observations indicate that TnI acts like a molecular switch which is controlled by smaller Ca2+-induced changes in TnC.

Detergent binding in trigonal crystals of OmpF porin from Escherichia coli

The structure of the detergent, ocytyl hydroxyethylsufoxide (C8(HE)SO), bound to the OmpF porin from E coli (in the trigonal crystal form) has been determined by neutron crystallography. Due to a dynamic exchange of detergent molecules with their environment they are not ordered on an atomic scale. The structure reported here is therefore at a resolution of approximately 16 A. The X-ray crystallographically determined structure of the protein provides a starting point for the neutron analysis in which the detergent is visualized primarily thanks to its high contrast against D2O. The structure shows the detergent to be located mainly in two areas. It forms toroidal annuli around each OmpF trimer, these annuli fusing to form a detergent belt surrounding a solvent filled column traversing the crystal. Those areas of the protein to which the detergent binds are formed almost exclusively of hydrophobic residues and form a band about 30 A high around the trimer. Its upper and lower bounds are defined by two bands of aromatic residues, tyrosines pointing away from the detergent belt and interacting with the polar headgroups while phenylalanines point inwards. This strongly suggests that the same areas define, in vivo, the location at which protein interacts with lipid. The hydrophobic moiety of detergent is also found mediating the hydrophobic protein-protein interactions at the interface between two trimers on the crystallographic two-fold axis.

A core-shell model of calcium phosphate nanoclusters stabilized by beta-casein phosphopeptides, derived from sedimentation equilibrium and small-angle X-ray and neutron-scattering measurements

Calcium phosphate nanoclusters were prepared under standardised conditions using 10 mg ml(-1) of the 25-amino-acid N-terminal tryptic phosphopeptide of bovine beta-casein as a stabilising agent. The Mr determined by sedimentation equilibrium was 197,600+/-13,700 and the apparent radius of gyration determined by X-ray scattering was 2.80+/-0.05 nm. A small-angle neutron scattering contrast variation study in 1H2O/2H2O mixtures was performed and gave radii of gyration at the calculated match points for the calcium phosphate (88.2% 2H2O) and phosphopeptide (41.3% 2H2O) of 3.39+/-0.08 nm and 1.85+/-0.05 nm, respectively. Measurements at larger scattering wave vector showed a subsidiary maximum at about Q = 1.6 nm(-1). The results are consistent with a model of the nanoclusters comprising a spherical core of 355+/-20 CaHPO4 x 2 H2O units, density 2.31 g ml(-1) and radius 2.30+/-0.05 nm surrounded by 49+/-4 peptide chains with a partial specific volume of 0.7 cm3 g(-1), forming a tightly packed shell with an outer radius of 4.04+/-0.15 nm. This model suggests that the phosphopeptide is able to arrest the process of growth of the precipitating phase of calcium phosphate at its earliest stages. A similar role for whole casein could be vital to the normal functioning of the mammary gland during milk secretion.

Protein-detergent interactions in single crystals of membrane proteins studied by neutron crystallography

The detergent micelles surrounding membrane protein molecules in single crystals can be investigated using neutron crystallography combined with H2O/D2O contrast variation. If the protein structure is known then the contrast variation method allows phases to be determined at a contrast where the detergent dominates the scattering. The application of various constraints allows the resulting scattering length density map to be realistically modeled. The method has been applied to two different forms of the membrane protein porin. In one case both hydrogenated and partially deuterated protein were used, allowing the head group and tail to be distinguished.

Detergent structure in tetragonal crystals of OmpF porin

BACKGROUND

The high-resolution structures of five porins have been solved by X-ray crystallography including the trigonal crystal form of the trimeric OmpF porin from Escherichia coli. In an accompanying article, the structure of the tetragonal form of OmpF porin is presented. In contrast to the trigonal crystal form, the protein surfaces normally in contact with lipids in the membrane are exposed and interact with amphiphiles in the tetragonal crystal. Thus, the tetragonal form can be used to investigate protein-detergent interactions.

RESULTS

Using single-crystal neutron diffraction studies and two different detergents (one of them deuterated in its hydrophobic moiety), details of the amphiphile-protein interactions are revealed. Detergent molecules bind to the so-called hydrophobic zone that surrounds the OmpF porin trimer and which is exposed to lipid in the native environment. The aromatic rings on both sides of the hydrophobic zone coincide with the boundary between non-polar and polar moieties of the detergents.

CONCLUSIONS

In the tetragonal crystal form of OmpF porin, the membrane-exposed area is accessible from the aqueous solution. It is coated by a film of detergent molecules, which presumably mimics the interactions of the protein with lipids in the biological membrane. In the trigonal form, protein-protein interactions predominate in the hydrophobic zone. These may reflect the tight interactions between trimers that are observed in the biological membrane.

The three-dimensional distribution of RNA and protein in the interior of tomato bushy stunt virus: a neutron low-resolution single-crystal diffraction study

BACKGROUND

The published high-resolution model of the isometric T = 3 plant virus tomato bushy stunt virus (TBSV) shows the packing in three different environments (A, B, C) of the 180 coat protein subunits of the capsid. It does not, however, account for the localization of either the viral RNA or approximately 25% of the amino acids of the protein subunits, although at least the RNA is rigidly linked to the viral capsid. Solution studies have shown that most of the missing protein is located in an inner shell, and that most of the RNA is sandwiched between the two protein shells.

RESULTS

We have determined the organization of TBSV at 16 A resolution, using neutron single-crystal diffraction. Connections between the two protein shells are confined to the 20 three-fold axes of the virion, where three C-type subunits meet. Much more RNA density is located under the 30 C-C dimers than under the 60 A-B dimers, where we could even identify lagoons of solvent.

CONCLUSIONS

Our results emphasize the importance of the amino termini of the 60 C-type protein subunits not only in the RNA-protein interactions but also in the organization of the coat protein, and, probably, in the assembly of the virion. The lack of equivalence between subunits of classes A or B and subunits of class C is even more pronounced in the interior of the virion than in the outer shell, which possesses icosahedral symmetry.

Membrane-bound form of the pore-forming domain of colicin A. A neutron scattering study

The ion-channel forming C-terminal fragment of colicin A binds to negatively charged lipid vesicles and provides an example of the insertion of a soluble protein into a lipid bilayer. The soluble structure is known and consists of a ten-helix bundle containing a hydrophobic helical hairpin. This fragment forms a well-defined complex with dimyristoylphosphatidyl-glycerol which is thus amenable to neutron scattering studies. Neutron scattering experiments in the Guinier range (low angles) provided the mass and the stoichiometry of the complex (290,000 (+/- 10,000) M(r), 8.2 (+/- 0.5)), in fair agreement with previous determinations. By varying the neutron scattering length density of the solvent with 2H2O/H2O mixtures and therefore the contrast of the different components, the radial distribution of the protein and of the lipids was determined. Finally, an attempt was made to fit various models to the wider angle scattering data. This study suggests that the pore-forming fragment of colicin A lies mostly at the surface of the membrane, with the lipids arranged in a bilayer organization.

Organization of turnip yellow mosaic virus investigated by neutron small angle scattering at 80 K: an intermediate state preceding decapsidation of the virion?

The organization of turnip yellow mosaic virus has been investigated by neutron small angle scattering at 300 K and 80 K in buffers containing various amounts of D2O. We confirm that in native virions, no substantial part of the RNA is located at a radius larger than ca. 100-110 A, i.e., that there is very little interpretation of the RNA into the capsid. At 80 K, scattering curves do not depend much upon contrast, from 40% D2O to 100% D2O buffers, but are strongly affected by interparticle interference. We could, however, show that it is not the case for the subsidiary intensity maximum at q approximately 0.06 A-1. From the position of this maximum, we conclude that upon freezing, the radius of the capsid expands by c.a. 3.5% and the RNA penetrates deeply into the protein shell. Biological implications of this conformational change immediately preceding decapsidation are discussed.

Activation of recA protein. The open helix model for LexA cleavage

RecA protein is induced by the binding of DNA and ATP to become active in the hydrolysis of ATP and the cleavage of repressors. These reactions appear to depend on the structural state of the protein polymerized along the DNA, i.e. a helical coat of six RecA per turn of 95 to 100 A pitch. In support of this model of the active conformation, it was shown that high concentrations of salt also induce this helical polymerized state as well as the enzymatic activities. Here, we describe that, in vitro and with the non-hydrolyzable analogue ATP gamma S, RNA and heparin can also induce both the structural transition and the enzymatic activation of RecA to LexA cleavage in accordance with the model. RNA and heparin do not support the reaction in the presence of ATP, and they do not induce the hydrolysis of ATP either, suggesting that, in contrast to ATP gamma S, the nucleotide is not bound stably enough, and that the combined affinities of polynucleotide and ATP actually modulate the discrimination of RecA for the various possible inducers in vivo.

In vitro decapsidation of turnip yellow mosaic virus investigated by cryo-electron microscopy: a model for the decapsidation of a small isometric virus

The in vitro decapsidation of a small isometric plant virus, turnip yellow mosaic virus (TYMV), was investigated by cryo-electron microscopy. Cryo-electron micrographs of TYMV and empty shells show that rapidly frozen virions still contain their RNA. Images of vitrified virions resemble closely those previously obtained by negative staining. Rapidly frozen virions decapsidate upon thawing although they remain well dispersed on the grid. The escape of the RNA through a hole at the periphery of the capsid could be visualized. The results suggest a model for the in situ decapsidation of small icosahedral viruses.

The location of bound lipid in the lipovitellin complex

The location of the bound lipid in the soluble lipoprotein lipovitellin has been determined by neutron crystallographic techniques. With the use of the contrast variation method, whereby the crystals are soaked in different H2O-D2O mixtures, the lipid has been found to occupy a large cavity in the protein whose structure had previously been determined by x-ray crystallography. The lipid appears to be bound in the form of a bilayer with the major protein-lipid interactions being hydrophobic and with the lipid headgroups projecting into the bulk solvent and into a solvent-filled space in the cavity.

Structure and RNA content of the prosomes

Duck erythroblasts prosomes were analysed by small angle neutron scattering (SANS), dynamic light scattering and (cryo-)electron microscopy. A molecular weight of approximately 720,000 +/- 50,000, a radius of gyration of 64 +/- 2 A and a hydrodynamic radius of approximately 86 A were obtained. Electron micrographs show a hollow cylinder-like particle with a diameter of 120 A, a height of 170 A and a diameter of 40 A for the cavity, built of four discs, the two outer ones being more pronounced than those in the center. Results from SANS indicate less then 5% of RNA in the purified prosomes, but nuclease protection assays confirm its presence.

Symmetry, flexibility and permeability in the structure of yeast retrotransposon virus-like particles

The virus-like particles (VLPs) of the yeast retrotransposon Ty are genetically, structurally and functionally analogous to retroviral nucleocapsids or cores. Like retroviral cores Ty-VLPs package and possibly promote the enzyme activities for reverse transcription and integration, as well as encapsulating the RNA that is the intermediate in retrotransposition. Here we show that Ty-VLPs assemble into symmetrical structures across a broad distribution of particle sizes. This spread of sizes violates the principle of quasi-equivalent packing. In addition, RNase accessibility experiments suggest that these particles form an open structure that does not protect the encapsulated RNA. These features distinguish Ty-VLPs from typical spherical viral capsids in both structure and function.

The influence of heptane-1,2,3-triol on the size and shape of LDAO micelles. Implications for the crystallisation of membrane proteins

The presence of small amphiphiles has been found to be necessary in the crystallization of several membrane-protein/surfactant complexes. It has been suggested that the role of the small amphiphile may be to reduce the size of the surfactant belt around the protein, making the formation of crystals easier. Thus far it was not known if this would involve changes in micellar size in general or whether the small amphiphile would merely replace LDAO during crystal growth. In the present study we have used small angle neutron scattering to study mixed micelles of lauryldimethyl amine oxide (LDAO; hydrogenated and deuterated) and heptane-1,2,3-triol (HP). Our results show that with increasing overall HP concentrations mixed LDAO/HP micelles of decreasing mass and radius are formed. The composition of these micelles has been determined. HP thus may decrease the size of the surfactant belt around a protein before crystallisation by insertion into a host micelle. As HP is a 'small amphiphile' compared to the surfactants used for solubilization of membrane proteins, the curvature of the host micelle will be increased by its insertion.

Human adenovirus serotype 3 fiber protein. Comparison of native and recombinant proteins

We were able to isolate viral fiber and penton from Ad3-infected KB cells using for their detection antibodies obtained against recombinant Ad3 fiber. The native material was examined by electron microscopy and the characteristic fiber shape of a shaft terminated by a globular head was observed. The native fiber was compared with two recombinant fibers synthesized in Escherichia coli cells. One, the Ad3 fiber protein expressed in E. coli with a 14-amino acid NH2-terminal fusion peptide, under the control of the T7 promoter has been described previously. The second is a recombinant Ad3 fiber without the fusion peptide (recAd3fib), expressed in the same system. As with the fusion protein recAd3fib was found to be insoluble upon expression. It was solubilized in 6 M urea and the gradual removal of urea during the purification cycle led to a soluble preparation. Biochemical and biophysical studies show that, similarly to fusion fiber, recAd3fib self-assembles as trimers in prokaryotic cells. Electron microscopy shows that, whereas the fusion fiber consists of a population of heterogeneous particles, recAd3fib has the characteristic morphology and size of the Ad3 trimeric native fiber. Small angle neutron scattering gives a molecular weight consistent with a trimeric fiber and a radius of gyration consistent with the dimensions derived from electron microscopy. These results suggest that the fusion peptide at the NH2 terminus prevents correct protein folding. They also indicate that after solubilization with urea and subsequent renaturation a correctly folded eukaryotic oligomeric protein can be produced in E. coli.

The solution structure of recA filaments by small angle neutron scattering

The technique of small angle neutron scattering has been applied to study the structure in solution of recA self-polymers and various recA-DNA complexes. These results are compared with those recently obtained by other physical techniques.

Complexes of RecA protein in solution. A study by small angle neutron scattering

RecA complexes on DNA and self-polymers were analysed by small-angle neutron scattering in solution. By Guinier analysis at small angles and by model analysis of a subsidiary peak at wider angles, we find that the filaments fall into two groups: the DNA complex in the presence of ATP gamma S, an open helix with pitch 95 A, a cross-sectional radius of gyration of 33 A and a mass per length of about six RecA units per turn, which corresponds to the state of active enzyme; and the compact form (bound to single-stranded DNA in the absence of ATP, or binding ATP gamma S in the absence of DNA, or just the protein on its own), a helical structure with pitch 70 A, cross-sectional radius of gyration 40 A and mass per length about five RecA units per turn, which corresponds to the conditions of inactive enzyme. The results are discussed in the perspective of unifying previous conflicting structural results obtained by electron microscopy.

Activation of recA protein: the salt-induced structural transition

Purified recA protein is induced by high salt concentrations to hydrolyse ATP even in the absence of DNA. By small angle neutron scattering we show that this salt activation results from a structural transition of the protein filament in the presence of ATP gamma S from the inactive, compact form (a helical polymer of pitch 70 A and cross-sectional radius of gyration Rc 40 A) to the open form (a helical filament of pitch 95 A and Rc 35 A, which are the same structural parameters as in the ATPase active complex with DNA and ATP), without detectable change in the degree of association. We conclude that activation of recA is due to the same structural change whether induced by the binding of DNA or by salt. Indeed, the other enzymatic activity of recA, the proteolytic cleavage of the lexA repressor, is found to be inducible by the same salt concentrations as those of the structural transition.

Molecular weight determination of an active photosystem I preparation from a thermophilic cyanobacterium, Synechococcus elongatus

An active photosystem I (PSI) complex was isolated from the thermophilic cyanobacterium Synechococcus elongatus by a procedure consisting of three steps: First, extraction of photosystem II from the thylakoids by a sulfobetaine detergent yields PSI-enriched membranes. Second, the latter are treated with Triton X-100 to extract PSI particles, which are further purified by preparative isoelectric focusing. Third, anion-exchange chromatography is used to remove contaminating phycobilisome polypeptides. The purified particles show three major bands in sodium dodecyl sulfate gel electrophoresis of apparent molecular mass of 110, 15, and 10 kDa. Charge separation was monitored by the kinetics of flash-induced absorption changes at 820 nm. A chlorophyll/P700 ratio of 60 was found. When the particles are stored at 4 degrees C, charge separation was stable for weeks. The molecular mass of the PSI particles, determined by measurement of zero-angle neutron scattering intensity, was 217,000 Da. The PSI particles thus consist of one heterodimer of the 60-80-kDa polypeptides and presumably one copy of the 15- and 10-kDa polypeptides, respectively.

The location of DNA in complexes of recA protein with double-stranded DNA. A neutron scattering study

Purified recA protein is found as rodlike homopolymers, and it forms filamentous complexes with double-stranded DNA that are stable in the presence of ATP gamma S, a nonhydrolyzable analogue of ATP. The structure of these filaments has been described in some detail by electron microscopy. Here we confirm the mass per length of 6.5 recA/100 A in solution by small-angle neutron scattering and extend the analysis to homopolymers of recA protein, finding a mass per length of about 7 recA/100 A and a radial mass distribution (cross-sectional radius of gyration) significantly different for the two filaments. The models proposed so far for the structure of the complex have placed the DNA in the center of the filament. Here we verify this assumption using small-angle neutron scattering to locate the DNA in the complexes, exploiting the contrast variation method in D2O/H2O mixtures. Model calculations show that the natural contrast difference between DNA and protein is not sufficient to locate the DNA (which accounts for only 4.7% of the mass in the complex). When deuterated DNA is used, the contrast difference is enhanced, and model calculations and experiment then converge, indicating that the DNA is indeed near the axis of the complex.

An elongated model of the Xenopus laevis transcription factor IIIA-5S ribosomal RNA complex derived from neutron scattering and hydrodynamic measurements

The precise molecular composition of the Xenopus laevis TFIIIA-5S ribosomal RNA complex (7S particle) has been established from small angle neutron and dynamic light scattering. The molecular weight of the particle was found to be 95,700 +/- 10,000 and 86,700 +/- 9000 daltons from these two methods respectively. The observed match point of 54.4% D2O obtained from contrast variation experiments indicates a 1:1 molar ratio. It is concluded that only a single molecule of TFIIIA, a zinc-finger protein, and of 5S RNA are present in this complex. At high neutron scattering contrast radius of gyration of 42.3 +/- 2 A was found for the 7S particle. In addition a diffusion coefficient of 4.4 x 10(-11) [m2 s-1] and a sedimentation coefficient of 6.2S were determined. The hydrodynamic radius obtained for the 7S particle is 48 +/- 5 A. A simple elongated cylindrical model with dimensions of 140 A length and 59 A diameter is compatible with the neutron results. A globular model can be excluded by the shallow nature of the neutron scattering curves. It is proposed that the observed difference of 15 A in length between the 7S particle and isolated 5S RNA most likely indicates that part(s) of the protein protrudes from the end(s) of the RNA molecule. There is no biochemical evidence for any gross alteration in 5S RNA conformation upon binding to TFIIIA.

Molecular weight and shape of angiotensin-I converting enzyme. A neutron scattering study

The molecular weight of angiotensin-I converting enzyme from pig lung has been determined to be 112000 (+/- 6000) by neutron scattering. This is somewhat lower than the value determined by SDS-PAGE and than previous estimates which, however, show a very wide range of values. A quantitative analysis of the amino acid and carbohydrate content was made in order to determine the enzyme concentration. The small angle neutron scattering technique also gives information on the molecular shape, yielding a radius of gyration of 44.5 +/- 1.5 A which, for the observed molecular weight, indicates that the angiotensin converting enzyme molecule is clearly elongated in aqueous solution. Dynamic light scattering experiments confirm this conclusion.

Crystal packing and stoichiometry of the fibre protein of adenovirus type 2

Crystals of the fibre protein of adenovirus type 2 have been grown and studied by electron microscopy and X-ray powder diffraction. The molecular packing and density of the crystals suggest that the fibre is dimeric.

Structural studies of adenovirus type 2 by neutron and X-ray scattering

Small-angle neutron and X-ray scattering have been used to investigate various aspects of the structural organization of adenovirus type 2. Neutron scattering allows the determination of the radial distribution of DNA and protein, which because of the highly icosahedral form of the virus allows it to be described in terms of three icosahedral shells. X-ray scattering shows that the distance between the major coat proteins (hexons) in the capsid is 100 +/- A. Evidence was also observed for an organization in the nucleoprotein core that gives rise to a maximum in the X-ray scattering at 1/29 A-1.

Structure of collagen in cartilage of intervertebral disk

Small-angle x-ray and neutron diffraction patterns have been obtained from the annulus fibrosus of porcine intervertebral disk. These show that the collagen in this tissue is modified compared with that in tendon.

Bone water

A short review is given of the water in bone. Various analyses of bone water content are discussed, and its possible location is considered in relation to the behaviour of water in isolated components of bone. Some of the difficulties encountered in examining such microscopic phenomena as water structure in a heterogeneous system such as bone are also discussed.

Collagen-mineral axial relationship in calcified turkey leg tendon by X-ray and neutron diffraction

The axial relationship between the collagen and mineral componetns in calcified turkey leg tendon was investigated using low-angle X-ray and neutron diffraction. The results indicate that the mineral is arranged with the same axial periodicity as the collagen and occupies the gap region of the collagen structure.