Two-dimensional crystallization of a membrane protein on a detergent-resistant lipid monolayer.

Two-dimensional crystals of a membrane protein, the proton ATPase from plant plasma membranes, have been obtained by a new strategy based on the use of functionalized, fluorinated lipids spread at the air-water interface. Monolayers of the fluorinated lipids are stable even in the presence of high concentrations of various detergents as was established by ellipsometry measurements. A nickel functionalized fluorinated lipid was spread into a monolayer at the air-water interface. The overexpressed His-tagged ATPase solubilized by detergents was added to the subphase. 2D crystals of the membrane protein, embedded in a lipid bilayer, formed as the detergent was removed by adsorption. Electron microscopy indicated that the 2D crystals were single layers with dimensions of 10 microm or more. Image processing yielded a projection map at 9 A resolution, showing three well-separated domains of the membrane-embedded proton ATPase.

Copper refolding of prion protein.

We have shown previously that normal mouse prion protein (MoPrP) binds copper ions during protein refolding and acquires antioxidant activity. In this report, we probe the structure of the copper refolded form of MoPrP to determine how copper binding alters the secondary and tertiary features of the protein. Circular dichroism showed that recombinant MoPrP prepared in the presence of copper (as Cu(++)) showed an increased signal in the 210-220 nm range of the spectrum. Changes in protein conformation were localised to the N-terminal region of MoPrP using a panel of antibodies to assess epitope accessibility. The copper refolded recombinant prion protein had reduced proteinase K (PK) sensitivity when compared to the non-copper liganded form. Reduced PK sensitivity was not due to aggregation however as high resolution electron microscopy showed a homogenous preparation with little aggregate when compared to the non-copper form. Finally, disruption of the single disulphide linkage in MoPrP significantly diminished the antioxidant activity of the copper refolded form suggesting that activity was not solely dependent on bound copper but also on a conformation enabled by the formation of the disulphide bond.

Synchrotron radiation diffraction from two-dimensional protein crystals at the air/water interface.

Protein structure determination by classical x-ray crystallography requires three-dimensional crystals that are difficult to obtain for most proteins and especially for membrane proteins. An alternative is to grow two-dimensional (2D) crystals by adsorbing proteins to ligand-lipid monolayers at the surface of water. This confined geometry requires only small amounts of material and offers numerous advantages: self-assembly and ordering over micrometer scales is easier to obtain in two dimensions; although fully hydrated, the crystals are sufficiently rigid to be investigated by various techniques, such as electron crystallography or micromechanical measurements. Here we report structural studies, using grazing incidence synchrotron x-ray diffraction, of three different 2D protein crystals at the air-water interface, namely streptavidine, annexin V, and the transcription factor HupR. Using a set-up of high angular resolution, we observe narrow Bragg reflections showing long-range crystalline order in two dimensions. In the case of streptavidin the angular range of the observed diffraction corresponds to a resolution of 10 A in plane and 14 A normal to the plane. We show that this approach is complementary to electron crystallography but without the need for transfer of the monolayer onto a grid. Moreover, as the 2D crystals are accessible from the buffer solution, the formation and structure of protein complexes can be investigated in situ.

Functional and structural differences between the prion protein from two alleles prnp(a) and prnp(b) of mouse.

The prion protein is a glycoprotein expressed by neurones and other cells. In its holo-form it binds copper and exhibits superoxide dismutase activity. Studies in mice have led to the description of two distinct alleles. Differences in these alleles are linked to long and short incubation times following infection with scrapie. We studied recombinant mouse protein corresponding to the products of either allele and two intermediates carrying single amino-acid residue substitutions. The different forms of the prion protein exhibited differences in superoxide dismutase (SOD) activity and conformation. Intermediates with single substitutions were less stable than either allelic product. The findings provide insight into the differences between the two alleles and might have consequences for understanding differences in susceptibility to prion disease.

Projection structure of a transcriptional regulator, HupR, determined by electron cryo-microscopy.

Large, well-ordered two-dimensional crystals of the histidine-tagged-HupR protein, a transcriptional regulator from the photosynthetic bacterium Rhodobacter capsulatus, were obtained by specific interaction with a Ni(2+)-chelated lipid monolayer. HupR is a response regulator of the NtrC subfamily; it activates the transcription of the structural genes hupSLC, of [NiFe]hydrogenase. A projection map of the full-length protein at 9 A resolution was obtained by electron cryo-microscopy and image analysis of frozen-hydrated two-dimensional crystals. The crystals have a p6 plane group with unit cell dimensions of a=b=111.6(+/-1.0) A, gamma=120.4(+/-0.5) degrees. The structure of the N-terminal domain of NtrC, the family to which HupR belongs, had been determined previously by NMR. The atomic coordinates of the N-terminal domain of NtrC, were compared to the structure obtained by cryo-electron microscope techniques of the whole HupR. These results provide the first structure at medium resolution of a whole transcription factor, HupR from the NtrC family.

Surface-induced polymerization of actin.

Living cells contain a very large amount of membrane surface area, which potentially influences the direction, the kinetics, and the localization of biochemical reactions. This paper quantitatively evaluates the possibility that a lipid monolayer can adsorb actin from a nonpolymerizing solution, induce its polymerization, and form a 2D network of individual actin filaments, in conditions that forbid bulk polymerization. G- and F-actin solutions were studied beneath saturated Langmuir monolayers containing phosphatidylcholine (PC, neutral) and stearylamine (SA, a positively charged surfactant) at PC:SA = 3:1 molar ratio. Ellipsometry, tensiometry, shear elastic measurements, electron microscopy, and dark-field light microscopy were used to characterize the adsorption kinetics and the interfacial polymerization of actin. In all cases studied, actin follows a monoexponential reaction-limited adsorption with similar time constants (approximately 10(3) s). At a longer time scale the shear elasticity of the monomeric actin adsorbate increases only in the presence of lipids, to a 2D shear elastic modulus of mu approximately 30 mN/m, indicating the formation of a structure coupled to the monolayer. Electron microscopy shows the formation of a 2D network of actin filaments at the PC:SA surface, and several arguments strongly suggest that this network is indeed causing the observed elasticity. Adsorption of F-actin to PC:SA leads more quickly to a slightly more rigid interface with a modulus of mu approximately 50 mN/m.

Characterization of the growth of 2D protein crystals on a lipid monolayer by ellipsometry and rigidity measurements coupled to electron microscopy.

We present here some sensitive optical and mechanical experiments for monitoring the process of formation and growth of two-dimensional (2D) crystals of proteins on a lipid monolayer at an air-water interface. The adsorption of proteins on the lipid monolayer was monitored by ellipsometry measurements. An instrument was developed to measure the shear elastic constant (in plane rigidity) of the monolayer. These experiments have been done using cholera toxin B subunit (CTB) and annexin V as model proteins interacting with a monosialoganglioside (GM1) and dioleoylphosphatidylserine (DOPS), respectively. Electron microscopy observations of the protein-lipid layer transferred to grids were systematically used as a control. We found a good correlation between the measured in-plane rigidity of the monolayer and the presence of large crystalline domains observed by electron microscopy grids. Our interpretation of these data is that the crystallization process of proteins on a lipid monolayer passes through at least three successive stages: 1) molecular recognition between protein and lipid-ligand, i.e., adsorption of the protein on the lipid layer; 2) nucleation and growth of crystalline patches whose percolation is detected by the appearance of a non-zero in-plane rigidity; and 3) annealing of the layer producing a slower increase of the lateral or in-plane rigidity.

Dual function C-terminal domain of dynamin-1: modulation of self-assembly by interaction of the assembly site with SH3 domains.

Impairment of endocytosis by mutational targeting of dynamin-1 GTPases can result in paralysis and embryonic lethality. Dynamin-1 assembles at coated pits where it functions to cleave vesicles from donor membranes. Receptor endocytosis is modulated by SH3 (src homology 3) domain proteins, which directly bind to dynamin C-terminal proline motif sequences, affecting both the dynamin GTPase activity and its recruitment to coated pits. We have determined that dynamin-dynamin interactions, which are required for dynamin helix formation, involve these same SH3 domain-binding C-terminal proline motif sequences. Consequently, SH3 domain proteins induce the in vitro disassembly of dynamin helices. Our results therefore suggest the the dual function of the dynamin C-terminus (involving amino acids 800-840) permits direct regulation of dynamin assembly and function through interaction with SH3 domain proteins. Additionally, the N-terminal GTPase domain plays an important role in assembly. Finally, we show that the central PH (pleckstrin homology) domain exerts a strong inhibitory effect on the capacity for dynamin-1 self-assembly.

Structural study of the response regulator HupR from Rhodobacter capsulatus. Electron microscopy of two-dimensional crystals on a nickel-chelating lipid.

Two-dimensional crystals of the histidine-tagged-HupR protein, a transcriptional regulator from the photosynthetic bacterium Rhodobacter capsulatus, were obtained upon specific interaction with a Ni2+-chelated lipid monolayer. HupR is a response regulator of the NtrC family; it activates the transcription of the structural genes, hupSLC, of the [NiFe]hydrogenase. The lipid (Ni-NTA-DOGA) uses the metal chelator nitrilotriacetic group as the hydrophilic headgroup and contains unsaturated oleyl tails to provide the fluidity necessary for two-dimensional protein crystallization. A projection map of the full-length protein at 18 A resolution was generated by analysing electron microscopy micrographs of negatively stained crystals. The HupR protein appeared to be dimeric and revealed a characteristic "propeller-like" motif. Each monomer forms an L-shaped structure.

Effect of the C-terminal proline repeats on ordered packing of squid rhodopsin and its mobility in membranes.

Negative stain electron microscopy and saturation transfer electron spin resonance spectroscopy have been used to compare the lattice ordering and in-plane membrane mobility of full-length and C-terminally cleaved squid rhodopsin. The C-terminus of squid rhodopsin contains a negatively charged region followed by 9-10 repeats of a proline-rich sequence, not found in rhodopsins other than those of cephalopod invertebrates, but similar proline repeats are found in other, unrelated membrane proteins. We find that the proline repeats cluster the rhodopsins into small groups, interfering with two-dimensional crystallization and maintaining their mobility in the membrane.

The organization of the spike complex of Semliki Forest virus.

Semliki Forest virus (SFV) is an enveloped animal virus comprising an icosahedral nucleocapsid surrounded by a membrane containing 80 transmembrane, trimeric spikes. SFV was treated with the non-ionic detergent n-octyl beta-D-glucopyranoside (octylglucoside) and analysed by cryo-electron microscopy and image reconstruction to explore the interaction between the spikes and the capsid. Comparison of the structure of detergent treated SFV (DSFV) with SFV by three-dimensional image reconstruction from cryoelectron micrographs showed that one fourth of the spikes, those on the 3-fold axis, were selectively removed by detergent treatment. Quantitative immunoblotting of gently detergent treated virus showed that polypeptide E1 was selectively removed from the trimeric spike complex (E1, E2, E3)3. Difference imaging between DSFV and SFV in combination with comparison to the previously established structure of Sindbis virus, which lacks the E3 protein, leads to a model for the position of E1, E2 and E3 in the spike. If the trimeric spike is represented as a triangle, E2 extends from the centre to the vertices and E1 fills in between the ridges of E2 to form the edges of the triangle while E3 is at the distal end of the spike, interacting primarily with E2.