Specific recognition of macroscopic objects by the cell surface: evidence for a receptor density threshold revealed by micrometric particle binding characteristics

The establishment of specific molecular bonds between a cell and a facing surface is involved in many physiological and technological situations. Using micrometric magnetic particles, we have explored the formation of specific molecular bonds between the cell and surfaces bearing complementary ligands under passive conditions. Streptavidin-coated particles were targeted to the cell surface of a B-cell line through a specific biotinylated antibody against the CD19 receptor. Flow cytometry, optical microscopy, and micropipette experimental techniques have been used. Main findings have been that cell surface receptor density acted like a switch for particle capture with a threshold value found here equal to 1.6 x 10(3) receptor/ microm(2). This led to exclusion from binding of the cells of lowest receptor density. The density threshold was modulated by the length of the binding link and the physics of the cell/particle collision. We suggest that the shear stress is one of the main determinants of the characteristics of binding. We also show that several thousand receptors were involved in the cell particle contact at the end of the binding process, although only eight bonds are required for the initial capture of a particle. A passive binding inhibition process due to link concentration by the initial contact was proposed to account for the small number of particles per cell.     

Interactions between protein-gold complexes and cell surfaces: a method for precise quantitation

We have developed a rapid and precise electron microscope technique for the quantitation of gold particles in suspension using latex microspheres as a reference (EM latex technique). This technique allowed us to determine the specific absorption of colloidal gold at its absorption maximum (520 nm) and the average number of ligands ([125I]IgG) bound to one gold particle. On the basis of these values important binding characteristics of protein-gold complexes to cell surfaces were analyzed in a model system consisting of Staphylococcus aureus with protein A on the cell wall as a specific binding site for IgG-Au. Our observations showed that the number of binding sites represented by one IgG-gold complex depended primarily on the particle size, with one 20-nm IgG-Au corresponding to 15 and one 6-nm IgG-Au to 2.5 binding sites. Hence, the efficiency of binding of IgG-Au complexes increased with decreasing gold particle size. Saturation of binding sites, however, was not achieved. The technique also made possible the determination of the affinity between IgG-Au complexes and the cell surface; this affinity can either be regarded as a characteristic of the ligand IgG or of the gold particle. We observed that the affinity of IgG decreased with the size of the gold particles to which IgG was bound, whereas the affinity of the entire gold particle increased with particle size. The EM latex technique for quantitation of gold particles extends the general use of protein-gold complexes to the quantitative characterization of their interaction with cell surface constituents.     

Electron Landau damping in toroidal plasma with Solov’ev equilibrium

The contribution of untrapped and two groups of trapped particles to the longitudinal (with respect to the magnetic field) elements of the dielectric susceptibility is determined by solving the drift-kinetic equations for such particles in axisymmetric tokamaks with Solov’ev equilibrium. The obtained dielectric characteristics are applicable for studying linear wave processes in the frequency range of Alfvén and fast magnetosonic waves in small- and large-aspect-ratio tokamaks with circular, elliptical, and D-shaped cross sections of magnetic surfaces. The high-frequency power absorbed in plasma via electron Landau damping is estimated by summing up terms containing the imaginary parts of both diagonal and non-diagonal elements of the longitudinal susceptibility. The imaginary part of the longitudinal susceptibility is calculated numerically for spherical tokamaks in a wide range of wave frequencies and magnetic surface radii.     

On-chip bioanalysis with magnetic particles

Magnetic particles can combine two very selective processes in bioanalysis: the specific binding of analytes to the particle surface based on molecular recognition and the specific isolation of magnetic objects from complex sample mixtures. They have found numerous applications including cell isolation, immunoassays or DNA extraction. In this review recent trends in the use of magnetic particles are presented. Integrated sample-in-answer-out lab-on-a-chip systems often employ magnetic particles for at least one of the reaction steps. Several groups have shown on-particle processing in continuous flow for assays and DNA extractions. Other researchers have demonstrated the manoeuvring and splitting of magnetically functionalised droplets for various bioapplications. Improvements in magnet configuration now allow for sorting of magnetically labelled cells within mL volumes in minutes.     

Lectin-recognizable colloidal dispersions stabilized by n-dodecyl beta-D-maltoside: particle-particle and particle-surface interactions

Recently, we reported that it is possible to utilize sugars as stabilizing agents for colloidal particles. This study shows that when n-dodecyl beta-D-maltoside (DDM) is utilized as a dispersing and stabilizing agent in the synthesis and stabilization of poly[methyl methacrylate-co-(n-butyl acrylate)] (p-MMA/nBA) colloidal particles, stable colloidal dispersions can be formed. Since understanding of sugar-protein interactions have numerous practical and scientific implications, these studies examine DDM-stabilized p-MMA/nBA colloidal particles and their specific binding properties with concanavalin A (Con A). By use of spectroscopic analysis, unique binding characteristics that are a function of DDM concentration, time, and the concentration of Con A are detected. When DDM-stabilized p-MMA/nBA particles are allowed to coalesce, DDM is released from the particle surfaces and, under suitable conditions, selectively stratifies in the areas of the excess of interfacial energy near the film-air (F-A) interface, thus providing sites for attracting Con A via alpha-glucose-OH hydrogen bonding. Consequently, adsorption of Con A at the F-A interfaces occur and the degree of adsorption is controlled by the amount of DDM at the F-A interface.     

The light-harvesting chlorpohyll-protein complex of photosystem II. Its location in the photosynthetic membrane

We have investigated the structure of the photosynthetic membrane in a mutant of barley known to lack a chlorophyll-binding protein. This protein is thought to channel excitation energy to photosystem II, and is known as the "light-harvesting chlorophyll-protein complex." Extensive stacking of thylakoids into grana occurs in both mutant and wild-type chloroplasts. Examination of membrane internal structure by freeze-fracturing indicates that only slight differences exist between the fracture faces of mutant and wild-type membranes. These differences are slight reductions in the size of particles visible on the EFs fracture face, and in the number of particles seen on the PFs fracture face. No differences can be detected between mutant and wild-type on the etched out surface of the membrane. In contrast, tetrameric particles visible on the etched inner surface of wild-type thylakoids are extremely difficult to recognize on similar surfaces of the mutant. These particles can be recognized on inner surfaces of the mutant membranes when they are organized into regular lattices, but these lattices show a much closer particle-to-particle spacing than similar lattices in wild-type membranes. Although several interpretations of these data are possible, these observations are consistent with the proposal that the light-harvesting chlorophyll-protein complex of photosystem II is bound to the tetramer (which is visible on the EFs face as a single particle) near the inner surface of the membrane. The large tetramer, which other studies have shown to span the thylakoid membrane, may represent an assembly of protein, lipid, and pigment comprising all the elements of the photosystem II reaction. A scheme is presented which illustrates one possibility for the light reaction across the photosynthetic membrane.     

Three-dimensional EM structure of the ectodomain of integrin {alpha}V{beta}3 in a complex with fibronectin

Integrins are alphabeta heterodimeric cell surface receptors that mediate transmembrane signaling by binding extracellular and cytoplasmic ligands. The ectodomain of integrin alphaVbeta3 crystallizes in a bent, genuflexed conformation considered to be inactive (unable to bind physiological ligands in solution) unless it is fully extended by activating stimuli. We generated a stable, soluble complex of the Mn(2+)-bound alphaVbeta3 ectodomain with a fragment of fibronectin (FN) containing type III domains 7 to 10 and the EDB domain (FN7-EDB-10). Transmission electron microscopy and single particle image analysis were used to determine the three-dimensional structure of this complex. Most alphaVbeta3 particles, whether unliganded or FN-bound, displayed compact, triangular shapes. A difference map comparing ligand-free and FN-bound alphaVbeta3 revealed density that could accommodate the RGD-containing FN10 in proximity to the ligand-binding site of beta3, with FN9 just adjacent to the synergy site binding region of alphaV. We conclude that the ectodomain of alphaVbeta3 manifests a bent conformation that is capable of stably binding a physiological ligand in solution.     

Initial Binding of Murine Leukemia Virus Particles to Cells Does Not Require Specific Env-Receptor Interaction

The initial step of virus-cell interaction was studied by immunofluorescence microscopy. Single particles of murine leukemia virus (MLV) vectors and human immunodeficiency virus (HIV) were visualized by immunofluorescence. Fluorescent dots representing single virions could be localized by staining of capsid proteins (CA) or surface envelope proteins (SU) after fixation of virus supernatants. This technique can be used to determine particle concentration in viral supernatants and also to study virus-cell interaction. We investigated the role of the Env-receptor interaction for the initial binding event between the cell and the viral particles. Ecotropic MLV vector particles were shown to bind to human cells which do not express the specific viral receptor. In addition, MLV particles defective for Env were shown to bind the cells similarly to infectious MLV. Time course experiments of virus-cell binding and dissociation showed identical profiles for infectious and Env-defective MLV particles and suggested that MLV Env is not involved in the early phases of attachment of virus to cells. The possible implication of cellular factors in enhancing viral binding and infectivity is discussed.     

Exposure of binding sites for vitronectin on platelets following stimulation

Vitronectin is a glycoprotein that mediates cell adhesion and spreading in a number of cell culture systems. Liposomes containing platelet glycoproteins IIb-IIIa complex have been shown to bind vitronectin-coated surfaces through an Arg-Gly-Asp cell attachment mechanism. We examined the expression of the binding sites for vitronectin on the surface of intact, resting platelets and following stimulation. 125I-Labeled vitronectin bound specifically in a saturable manner to platelets treated with physiological concentrations of thrombin. The binding reached saturation at 100 nM concentration, and, at saturation, approximately 5000 specific binding sites were detected per platelet. The binding was divalent cation-dependent and only partially reversible after complete saturation. A synthetic hexapeptide containing the Arg-Gly-Asp sequence inhibited vitronectin binding to platelets. A monoclonal antibody against platelet glycoprotein IIb-IIIa complex also inhibited the binding of vitronectin to stimulated platelets. These data suggest that platelets possess an inducible divalent cation-dependent receptor for vitronectin and that the glycoprotein IIb-IIIa complex is involved in the expression of the vitronectin receptor.     

Arraying prostate specific antigen PSA and Fab anti-PSA using light-assisted molecular immobilization technology

We here report for the first time the creation of prostate specific antigen (PSA) and Fab anti‐PSA biosensor arrays using UV light‐assisted molecular immobilization (LAMI), aiming at the detection and quantification of PSA, a cancer marker. The technology involves formation of free, reactive thiol groups upon UV excitation of protein aromatic residues located in spatial proximity of disulphide bridges, a conserved structural feature in both PSA and Fab molecules. The created thiol groups bind onto thiol reactive surfaces leading to oriented covalent protein immobilization. Protein activity was confirmed carrying out immunoassays: immobilized PSA was recognized by Fab anti‐PSA in solution and immobilized Fab anti‐PSA cross‐reacted with PSA in solution. LAMI technology proved successful in immobilizing biomedically relevant molecules while preserving their activity, highlighting that insight into how light interacts with biomolecules may lead to new biophotonic technologies. Our work focused on the application of our new engineering principles to the design, analysis, construction, and manipulation of biological systems, and on the discovery and application of new engineering principles inspired by the properties of biological systems.     

Interaction of 3-[3H]-2-n-nonyl-4-hydroxyquinoline-N-oxide with submitochondrial particles of beef heart. II. Determination of the binding sites

The binding of 3H-NQNO in submitochondrial particles was determined by measuring the radioactivity in the supernatants as well as in the sediments after centrifugation of particles suspensions containing different amounts of 3H-NQNO. From the binding data Scatchard plots were constructed showing a large amount of aspecific binding depending on the particles preparation and concentration. In the presence of saturating concentrations of either antimycin or unlabelled NQNO (2-n-Nonyl-4-hydroxy-quinolinee-N-oxide) that remove or prevent the specific binding of 3H-NQNO, it is possible to evaluate the aspecific component of 3H-NQNO binding and to subtracte it from the experimental binding data by graphyc correction according to (3). The straight line from the corrected points gives the specific binding parameters: number of specific binding sites: about 0,5 moles 3H-NQNO/ moles cytochrome b and KD= 50 nM.     

A mixed-phase immunoassay based on simultaneous binding of fluorescently tagged and PNA-conjugated peptide epitopes on antibodies: quantification on PNA-coated microparticles

A mixed-phase immunoassay based on simultaneous binding of an antibody to its fluorescently tagged peptide epitope and a PNA conjugate of the same peptide has been developed. As a fluorescent marker, a europium(III) chelate allowing time-resolved measurement from a single particle has been employed. The ternary complex formed in solution is immobilized by Watson-Crick base-pairing to a microparticle bearing a PNA sequence complementary to that present in the complex. The concentration of the antibody in the sample may then be determined by a single particle measurement. Accordingly, different antibodies may in principle be addressed by sequence-specific hybridization to different categorized microparticles.     

Scanning two-photon fluctuation correlation spectroscopy: particle counting measurements for detection of molecular aggregation.

Scanning fluctuation correlation spectroscopy (FCS) is an experimental technique capable of measuring particle number concentrations by monitoring spontaneous equilibrium fluctuations in the local concentration of a fluorescent species in a small (femtoliter) subvolume of a sample. The method can be used to detect molecular aggregation for dilute, submicromolar samples by directly "counting particles". We introduce the application of two-photon excitation to scanning FCS and discuss its important advantages for this technique. We demonstrate the capability of measuring particle number concentrations in solution, first with dilute samples of monodisperse 7-nm and 15-nm radius latex spheres, and then with B phycoerythrin. The detection of multiple species in a single sample is shown, using mixtures containing both sphere sizes. The method is then applied to study protein aggregation in solution. We monitor the concentration-dependent association/ dissociation equilibrium for glycogen phosphorylase A and malate dehydrogenase. The measured dissociation constants, 430 nM and 144 nM respectively, are in good agreement with previously published values. In addition, oligomer dissociation induced by pH titration from pH 8 to pH 5.0 is detectable for the enyme phosphofructokinase. The possibility of measuring dissociation kinetics by scanning two-photon FCS is also demonstrated using phosphofructokinase.     

The use of aurovertin to determine the F1 content of submitochondrial particles and the ATPase complex

(1) The concentration of aurovertin-binding sites calculated from fluorimetric titrations of submitochondrial particles is equal to the F₁ concentration, calculated from the concentration of F₁-binding sites in stripped particles.(2) Direct binding experiments show that the fluorescence enhancement of aurovertin bound to submitochondrial particles and the isolated ATPase complex is less (or absent) at higher concentrations than at lower concentrations. The binding data can be described by ‘specific’ and ‘non-specific’ binding. The concentration of the ‘specific’ sites is twice that derived from fluorimetric titrations.(3) After dissociation of the bound F₁ with LiCl, fluorimetric titrations with aurovertin yield linear Scatchard plots. The fluorescence enhancement and K_D are equal to those of the β-subunit-aurovertin complex. The concentration of β-subunits is double the concentration of F₁.(4) It is concluded that both for submitochondrial particles and the isolated ATPase complex the most reliable and simple way to determine the F₁ content is to dissociate the F₁ with LiCl, spin down the insoluble material and titrate the supernatant (containing free β-subunit) with aurovertin.     

Particle confinement in axisymmetric poloidal magnetic field configurations with zeros of B: Methodological note

Collisionless particle confinement in axisymmetric configurations with magnetic field nulls is analyzed. The existence of an invariant of motion—the generalized azimuthal momentum—makes it possible to determine in which of the spatial regions separated by magnetic separatrices passing through the magnetic null lines the particle occurs after it leaves the vicinity of a magnetic null line. In particular, it is possible to formulate a sufficient condition for the particle not to escape through the separatrix from the confinement region to the external region. In the configuration under analysis, the particles can be lost from a separatrix layer with a thickness on the order of the Larmor radius because of the nonconservation of the magnetic moment μ. In this case, the variations in μ are easier to describe in a coordinate system associated with the magnetic surfaces. An analysis is made of the applicability of expressions for the single-pass change Δμ in the magnetic moment that were obtained in different magnetic field models for a confinement system with a divertor (such that there is a circular null line).     

Monoclonal antibodies conjugated with superparamagnetic iron oxide particles allow magnetic resonance imaging detection of lymphocytes in the mouse brain

We investigated the potential of antibody-vectorialized superparamagnetic iron oxide (SPIO) particles as cellular specific magnetic resonance contrast agents to image lymphocyte populations within the central nervous system (CNS), with the final goal of obtaining a reliable tool for noninvasively detecting and tracking specific cellular populations in vivo. We used superparamagnetic particles bound to a monoclonal antibody. The particle is the contrast agent, by means of its T?* relaxation properties; the antibody is the targeting vector, responsible for homing the particle to target a surface antigen. To investigate the efficiency of particle vectorialization by these antibodies, we compared two types of antibody-vectorialized CD3-specific particles in vivo. We successfully employed vectorialized SPIO particles to image B220? cells in a murine model of B-cell lymphoma. Likewise, we were able to identify CD3? infiltrates in a murine model of multiple sclerosis. The specificity of the technique was confirmed by immunohistochemistry and electron microscopy of corresponding sections. Our findings suggest that indirect binding of the antibody to a streptavidinated particle allows for enhanced particle vectorialization compared to covalent binding of the antibody to the particle.     

Early steps in the assembly of light-harvesting chlorophyll a/b complex: time-resolved fluorescence measurements

The light-harvesting chlorophyll a/b complex (LHCIIb) spontaneously assembles from its pigment and protein components in detergent solution. The formation of functional LHCIIb can be detected in time-resolved experiments by monitoring the establishment of excitation energy transfer from protein-bound chlorophyll b to chlorophyll a. To detect the possible initial steps of chlorophyll binding that may not yet give rise to chlorophyll b-to-a energy transfer, we have monitored LHCIIb assembly by measuring excitation energy transfer from a fluorescent dye, covalently bound to the protein, to the chlorophylls. In order to exclude interference of the dye with protein folding or pigment binding, the experiments were repeated with the dye bound to four different positions in the protein. Initial chlorophyll binding occurs at roughly the same rate as the establishment of chlorophyll b-to-a energy transfer, in the range of 10 s. However, under limiting chlorophyll concentrations, the binding of chlorophyll a clearly precedes that of chlorophyll b. The complex containing the apoprotein, carotenoids, and chlorophyll a but no chlorophyll b is biochemically unstable and therefore cannot be isolated. However, chlorophyll a binding into this weak complex is specific, as it does not occur with a C-terminal deletion mutant of Lhcb1 which still contains most chlorophyll-ligating amino acids but is unable to fold and assemble into functional LHCIIb. As a scenario for LHCIIb assembly in the thylakoid, we propose the initial formation of a labile Lhcb1-chlorophyll a-carotenoid complex that then becomes stabilized by the binding (or formation in situ) of chlorophyll b.     

A Microfluidic-based Hydrodynamic Trap for Single Particles

The ability to confine and manipulate single particles in free solution is a key enabling technology for fundamental and applied science. Methods for particle trapping based on optical, magnetic, electrokinetic, and acoustic techniques have led to major advancements in physics and biology ranging from the molecular to cellular level. In this article, we introduce a new microfluidic-based technique for particle trapping and manipulation based solely on hydrodynamic fluid flow. Using this method, we demonstrate trapping of micro- and nano-scale particles in aqueous solutions for long time scales. The hydrodynamic trap consists of an integrated microfluidic device with a cross-slot channel geometry where two opposing laminar streams converge, thereby generating a planar extensional flow with a fluid stagnation point (zero-velocity point). In this device, particles are confined at the trap center by active control of the flow field to maintain particle position at the fluid stagnation point. In this manner, particles are effectively trapped in free solution using a feedback control algorithm implemented with a custom-built LabVIEW code. The control algorithm consists of image acquisition for a particle in the microfluidic device, followed by particle tracking, determination of particle centroid position, and active adjustment of fluid flow by regulating the pressure applied to an on-chip pneumatic valve using a pressure regulator. In this way, the on-chip dynamic metering valve functions to regulate the relative flow rates in the outlet channels, thereby enabling fine-scale control of stagnation point position and particle trapping. The microfluidic-based hydrodynamic trap exhibits several advantages as a method for particle trapping. Hydrodynamic trapping is possible for any arbitrary particle without specific requirements on the physical or chemical properties of the trapped object. In addition, hydrodynamic trapping enables confinement of a "single" target object in concentrated or crowded particle suspensions, which is difficult using alternative force field-based trapping methods. The hydrodynamic trap is user-friendly, straightforward to implement and may be added to existing microfluidic devices to facilitate trapping and long-time analysis of particles. Overall, the hydrodynamic trap is a new platform for confinement, micromanipulation, and observation of particles without surface immobilization and eliminates the need for potentially perturbative optical, magnetic, and electric fields in the free-solution trapping of small particles.Download video file.^{(62M, mov)}     

Characterization of the 2:1 complex between the class I MHC-related Fc receptor and its Fc ligand in solution.

The neonatal Fc receptor (FcRn) facilitates the transfer of maternal immunoglobulin G (IgG) to offspring and prolongs the half-life of serum IgG. FcRn binds IgG in acidic intracellular vesicles and releases IgG upon exposure to the basic pH of the bloodstream. The crystal structure of an FcRn/Fc complex revealed FcRn dimers bridged by homodimeric Fc molecules to create an oligomeric array with two receptors per Fc [Burmeister et al. (1994) Nature 372, 379-383], consistent with the 2:1 FcRn:Fc stoichiometry observed in solution [Huber et al. (1993) J. Mol. Biol. 230, 1077-1083; Sánchez et al. (1999) Biochemistry 38, 9471-9476]. Two distinct 2:1 FcRn/Fc complexes were present in the cocrystal structure: a complex containing an FcRn dimer interacting with an Fc and a complex in which single FcRn molecules are bound to both sides of the Fc homodimer. To determine which of the two possible 2:1 FcRn/Fc complexes exists in solution, we generated recombinant Fc molecules with zero, one, and two FcRn binding sites and studied their interactions with a soluble form of rat FcRn. The wild-type Fc with two FcRn binding sites binds two FcRn molecules under all assay conditions, and the nonbinding Fc with no FcRn binding sites shows no specific binding. The heterodimeric Fc with one FcRn binding site binds one FcRn molecule, suggesting that the 2:1 FcRn/wild-type Fc complex formed in solution consists of single FcRn molecules binding to both sides of Fc rather than an FcRn dimer binding to a single site on Fc.