Polyglutaraldehyde: a new reagent for coupling proteins to microspheres and for labeling cell-surface receptors

High-Purity Corundum as Support for Affinity Extractions from Complex Samples

Nonporous corundum powder, known as an abrasive material in the industry, was functionalized covalently with protein binders to isolate and enrich specific proteins from complex matrices. The materials based on corundum were characterized by TEM, ESEM, BET, DLS, EDS, and zeta potential measurements. The strong Al-O-P bonds between the corundum surface and amino phosphonic acids were used to introduce functional groups for further conjugations. The common crosslinker glutaraldehyde was compared with a hyperbranched polyglycerol (PG) of around 10 kDa. The latter was oxidized with periodate to generate aldehyde groups that can covalently react with the amines of the surface and the amino groups from the protein via a reductive amination process. The amount of bound protein was quantified via aromatic amino acid analysis (AAAA). This work shows that oxidized polyglycerol can be used as an alternative to glutaraldehyde. With polyglycerol, more of the model protein bovine serum albumin (BSA) could be attached to the surface under the same conditions, and lower non-specific binding (NSB) was observed. As a proof of concept, IgG was extracted with protein A from crude human plasma. The purity of the product was examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). A binding capacity of 1.8 mg IgG per gram of corundum powder was achieved. The advantages of corundum include the very low price, extremely high physical and chemical stability, pressure resistance, favorable binding kinetics, convenient handling, and flexible application.

Influence of Glutaraldehyde's Molecular Transformations on Spectroscopic Investigations of Its Conjugation with Amine-Modified Fe3O4 Microparticles in the Reaction Medium

Glutaraldehyde (GA) is a widely used cross-linking agent in biological research due to its superior characteristics, such as high reactivity toward proteins, high stability, and cost-effectiveness. In this regard, analyzing spectral changes initiated by various molecular forms and transformations of GA in a reaction medium and its reaction with surface functional-modified solid spheres is vital for a successful bioconjugation process targeting the biomolecules of interest. In this work, we present Fourier transform-infrared (FT-IR), Raman, and UV-visible spectroscopic analyses of glutaraldehyde-modified Fe₃O₄ microparticles (magnetic beads) to confirm the conjugation between GA and magnetic beads. We also studied the molecular transformations of glutaraldehyde during the reaction with amine-modified magnetic beads via investigating the reaction medium of the glutaraldehyde solution. Our FT-IR and Raman studies confirmed that glutaraldehyde was successfully coupled on the magnetic beads. Furthermore, FT-IR and UV-vis studies on the glutaraldehyde solution revealed the multiple molecular forms of GA in an aqueous medium, and they also confirmed that glutaraldehyde transforms into other molecular forms while the reaction occurs with the magnetic beads.

Mapping aldehydic load in vivo by positron emission tomography with [18F]NA3BF3

A new radiotracer, [¹⁸F]NA₃BF₃, capable of rapid, stable, and catalyst-free complexation of aldehydes in vivo is reported. [¹⁸F]NA₃BF₃ was shown to bind aldehydes in live subjects using locally administered aldehyde-presenting microparticles, and was then applied to mapping aldehydic load in a mouse model of sepsis. [¹⁸F]NA₃BF₃ may enable the direct investigation of the chemical biology of aldehydes in living subjects, and may open avenues for the adoption of endogenous aldehydic load as an imaging biomarker of inflammatory pathology.

Stages in ELISA

This chapter gives general information on essential practical features of ELISAs. These can be summarized as follows: 1. Adsorption of antigen or antibody to the plastic solid phase. 2. Addition of the test sample and subsequent reagents. 3. Incubation of reactants. 4. Separation of bound and free reactants by washing. 5. Addition of enzyme-labeled reagent. 6. Addition of enzyme detection system (color development). 7. Visual or spectrophotometric reading of the assay.

Glutaraldehyde: behavior in aqueous solution, reaction with proteins, and application to enzyme crosslinking

Glutaraldehyde possesses unique characteristics that render it one of the most effective protein crosslinking reagents. It can be present in at least 13 different forms depending on solution conditions such as pH, concentration, temperature, etc. Substantial literature is found concerning the use of glutaraldehyde for protein immobilization, yet there is no agreement about the main reactive species that participates in the crosslinking process because monomeric and polymeric forms are in equilibrium. Glutaraldehyde may react with proteins by several means such as aldol condensation or Michael-type addition, and we show here 8 different reactions for various aqueous forms of this reagent. As a result of these discrepancies and the unique characteristics of each enzyme, crosslinking procedures using glutaraldehyde are largely developed through empirical observation. The choice of the enzyme-glutaraldehyde ratio, as well as their final concentration, is critical because insolubilization of the enzyme must result in minimal distortion of its structure in order to retain catalytic activity. The purpose of this paper is to give an overview of glutaraldehyde as a crosslinking reagent by describing its structure and chemical properties in aqueous solution in an attempt to explain its high reactivity toward proteins, particularly as applied to the production of insoluble enzymes.

A monoclonal antibody against bovine thrombin reacting to the C-terminal side of thrombin

We succeeded in producing a monoclonal antibody (MAb) against bovine thrombin. The MAb belonged to mouse IgG(1), and its light chain consisted of kappa-chain. The MAb reacted with bovine and human thrombins, which were coated by coupling to poly-lysine-coated wells with glutaraldehyde, but did not react with the thrombin-like enzyme, habutobin. Furthermore, the MAb did not react with thrombin which was coated to plates without poly-lysine and glutaraldehyde. The concentration of thrombin in ovalbumin solution (10 mg/mL) could be measured by means of the enzyme-linked immunosorbent assay (ELISA) double sandwich method using the MAb and polyclonal antibody. Thrombin added to defibrinated plasma could not be detected by means of the ELISA double sandwich method using the present MAb, and this may be due to the AT-III activity in the defibrinated plasma. Postclotting thrombin could be detected by means of the ELISA-double sandwich method using the MAb. It is suggested, from the results of our experiments, that the MAb obtained reacted in a limited fashion to the C-terminal of bovine thrombin.

Time and force dependence of the rupture of glycoprotein IIb-IIIa-fibrinogen bonds between latex spheres

We studied the shear-induced breakup of doublets of aldehyde/sulfate (A/S) latex spheres covalently linked with purified platelet GPIIb-IIIa receptor, and cross-linked by fibrinogen. Flow cytometry with fluorescein isothiocyanate-fibrinogen showed than an average of 22,500 molecules of active GPIIb-IIIa were captured per sphere, with a mean K(d) = 56 nM for fibrinogen binding. The spheres, suspended in buffered 19% Ficoll 400 containing 120 or 240 pM fibrinogen, were subjected to Couette flow in a counter-rotating cone-plate rheoscope. Doublets, formed by two-body collisions at low shear rate (G = 8 s(-1)) for < or =15 min, were subjected to shear stress from 0.6 to 2.9 Nm(-2), their rotations recorded until they broke up or were lost to view. Although breakup was time dependent, occurring mostly in the first 2 rotations after the onset of shear, the percentage of doublets broken up after 10 rotations were almost independent of normal hydrodynamic force, F(n): at 240 pN, 15.6, 16.0, and 17.0% broke up in the force range 70-150 pN, 150-230 pN, and 230-310 pN. Unexpectedly, at both [fibrinogen], the initial rate of breakup was highest in the lowest force range, and computer simulation using a stochastic model of breakup was unable to simulate the time course of breakup. When pre-sheared at low G for >15 min, no doublets broke up within 10 rotations at 70 < F(n) < 310 pN; it required >3 min shear (>1110 rotations) at F(n) = 210 pN for significant breakup to occur. Other published work has shown that binding of fibrinogen to GPIIb-IIIa immobilized on plane surfaces exhibits an initial fast reversible process with relative low affinity succeeded by transformation of GPIIb-IIIa to a stable high-affinity complex. We postulate that most doublet breakups observed within 10 rotations were from a population of young doublets having low numbers of bonds, by dissociation of the initial receptor complex relatively unresponsive to force. The remaining, older doublets with GPIIb-IIIa in the high-affinity complex were not broken up in the time or range of forces studied.

Kinetics and locus of failure of receptor-ligand-mediated adhesion between latex spheres. II. Protein-protein bond

In an extension of the previous paper, we describe the force dependence of break-up of doublets of latex spheres cross-linked by protein G-IgG bonds via the Fc region of the antibody. The receptor, the monoclonal Bear-1 antibody, was either covalently linked to 4.75-microns aldehyde/sulfate (A/S) latex spheres in a one-step reaction, or physically adsorbed to the 4.63-microns carboxyl-modified latex spheres used in Part I of this paper. The spheres were suspended in 19% buffered Dextran 40 containing the ligand, the bivalent recombinant protein G (Gamma-Bind G), and observed in the counter-rotating cone and plate Rheoscope. Break-up of doublets, tracked individually under the microscope, as well as in populations of 50-150 particles, was studied over a range of normal force from 20 to 260 pN. In individual particle studies, the fraction of doublets of spheres with covalently linked IgG breaking up in the first 10 rotations, increased from 16% in the low-force to 63% in the high-force range. In population studies, the fraction broken up increased with duration and magnitude of the applied force, and decreased with increasing ligand concentration. Moreover, doublets of physically adsorbed IgG spheres required significantly lower force than doublets of covalently linked IgG spheres for the same degree of break-up, possibly because of surface detachment of IgG molecules rather than rupture of receptor-ligand bonds. Computer simulation, using the Bell stochastic model of break-up and a Poisson distribution for the number of bonds, described in Part I, showed that the parameters of the protein-protein bond differed significantly from those of the carbohydrate-protein bond studied in Part I of this paper, the former being much more responsive to force than the latter.

Fluorescent staphylococci as microbeads

Fixed bacteria of the protein A-rich Cowan I Staphylococcus strain were labelled with fluorescein isothiocyanate and used as the second-step reagent in an indirect immunofluorescent assay of specific cell-surface antigen expression. The results are documented with fluorescence microscopy and flow cytometry.

Affinity separation with polyaldehyde microsphere beads

Agarose polyaldehyde microsphere beads were prepared by encapsulating polyaldehyde microspheres of various diameters, e.g., polyacrolein or polyglutaraldehyde microspheres, within agarose beads. Amino ligands such as proteins or drugs can be bound covalently to the beads in a single step at physiological pH. The binding capacity of the beads towards various amino ligands is inversely related to the diameter of the microspheres encapsulated in the agarose matrix. Different reagents, e.g., bovine serum albumin, ethanolamine and hydroxylamine, were studied as blocking reagents of the free aldehyde groups. Blocking the remaining aldehyde groups after coupling the amino ligands to the beads is essential for increasing or retaining the reactivity of the ligands conjugated to the beads. Among the reagent studied, hydroxylamine was found to be the most suitable blocking reagent of the free aldehyde groups of beads conjugated with proteins. The extent of leakage of amino ligands bound to the agarose-polyaldehyde microsphere beads was studied as a function of the pH of aqueous solutions of the beads. At physiological pH the leakage was negligible. At acid pH, leakage of ligands containing several primary amine groups, e.g., proteins, was insignificant. However, significant leakage was detected for ligands containing a single amino group. The leakage of proteins bound to the agarose-polyaldehyde microsphere beads was found to be much less than the leakage of the same proteins bound to agarose beads through the cyanogen bromide activation method.

The influence of immune complexes, steric effects, and antigen-antigen interactions on the sensitivity of enzyme-linked immunosorbent assays

Serum from mice hyperimmunized with 2,4,6-trinitrophenylated bovine gamma globulin (TNP-BGG) or keyhole limpet hemocyanin have been shown to have enhanced binding to several ligands unrelated to the antigen used for immunization. Addition of the immunizing antigen to the serum can result in increased binding to unrelated ligands and to the polyvinyl chloride surface of microtiter wells in solid-phase enzyme-linked immunosorbent assays. In a competitive binding assay using TNP-BGG-hyperimmune serum adsorbed to the microtiter well followed by an alkaline phosphatase conjugate of BGG in the presence or absence of TNP-BSA, substantial inhibition of BGG binding is seen. Steric hindrance appears to be the major cause of such inhibition since addition of hapten alone has little effect on BGG binding. An antigen-antigen interaction between KLH and TNP is also detectable. Immune complex formation, steric effects, and antigen-antigen interactions potentially have substantial influences on ELISA sensitivity and must be considered as possible sources of artifact in these assays.

Optimized synthesis of polyglutaraldehyde nanoparticles using central composite design

A central composite design was applied to the optimization of the synthesis of polyglutaraldehyde nanoparticles (PGNP). The effects of monomer concentration, surfactant concentration, pH, oxygen level, and stirring rate on the particle size, polydispersity, surface carboxyl group concentration, and yield of PGNP were investigated. The optimal conditions for the synthesis of PGNP were found to be: 7% (w/v) glutaraldehyde, 2.5% (w/v) dextran, pH 12, 70% (v/v) oxygen, and a stirring rate of 1080 rpm. Under these conditions, the values of the dependent variables adequately resembled those predicted by the model. The usefulness of these particles in the targeted delivery of cytotoxic drugs is discussed.

Interaction forces between red cells agglutinated by antibody. III. Micromanipulation

In the flow studies described in two previous papers (Tha, S. P., and H. L. Goldsmith, 1986, Biophys. J. 50:1109-1116; Tha, S. P., J. Shuster, and H. L. Goldsmith, 1986, Biophys. J. 50:1117-1126), hydrodynamic forces of the order of 10(-11) N (mu dyn) were applied to measure the force of separation of doublets of hardened, sphered human red blood cells cross-linked by anti-B antibody. The same cell preparation and hyperimmune antiserum has here been used to carry out experiments with micropipet aspiration techniques. One cell of a doublet was aspirated onto a holding pipet, and a second aspiration pipet was brought into proximity of the other cell so that the two pipets and the doublet were colinear. Suction was then raised until the two cells separated. Some doublets were assembled by aspiration of a singlet, bringing a second singlet into apposition with the first, and releasing it from the pipet which was then withdrawn. Cells could be repeatedly assembled and separated. At 3.56% vol/vol antiserum, the mean normal force of separation was 0.45 +/- 0.11 nN in phosphate-buffered saline suspensions containing 2.5 x 10(4) cells/microliter; at 1.22% vol/vol antiserum, the value was 0.22 +/- 0.11 nN. The above values of the force were approximately 2.5 x greater than those from the flow studies. The data could be fitted to a Poisson distribution with 0.05 nN as the force needed to break a single cross-bridge (c.f. 0.024 nN from the previous hydrodynamic data). The forces of separation of randomly assembled doublets were lower than those of preexisting doublets. Repeated assembly and separation of doublets showed that the cell surfaces are nonuniform in adhesion strength both over the local scale less than 0.25 micron2 and the cell population.

Polymer microbeads in immunology

Synthetic polymer microbeads have been studied extensively and the required properties, including monodispersity and size range 0.05-10 microns can best be achieved by radiation polymerization based on methacrylate derivatives. Fluorochrome-conjugated beads can be used for cell surface markers and simultaneously to study phagocytosis. The paper reviews some of these applications. Cell separation techniques are also described. Future possibilities for immunological and cell biology studies are discussed.

Magnetic albumin/protein A immunomicrospheres. I. Preparation, antibody binding capacity and chemical stability

We describe a method of preparing small magnetic microspheres of albumin/protein A, uniform in size, at 200, 300 or 500 nm. It is shown that, independent of size, the microspheres always carry iron peripherally in their matrix and are thus magnetically responsive. A quantitative antibody binding capacity of 82 micrograms/mg microspheres was established for the 500 nm microspheres. The microspheres are stable in most commonly used buffers over a pH range of 2.5-9.2, but are appreciably unstable in such concentrated denaturing agents as 3 M TCN-, 6 M guanidine, or 8 M urea (loss of antibody binding capacity, 30% for TCN- and 70% for urea).

The effect of antigen cross-linking on the sensitivity of the enzyme-linked immunosorbent assay

To investigate the effects of antigen cross-linking on ELISA results, we assayed antibodies to several purified antigens, using microtitration trays coated with antigens in their native and cross-linked forms. Cross-linking was achieved by a carbodiimide promoted condensation reaction. For several antigens an increase in sensitivity of the ELISA was obtained after cross-linking. The results of a double antibody sandwich assay using the same cross-linked antigens, showed that the affinity for antibodies remained unchanged after limited cross-linking. Therefore, the higher sensitivity of the ELISA is most likely due to a higher affinity of the cross-linked antigens for the plastic carrier. Cross-linking of proteins in a complex antigen preparation obtained from Schistosoma mansoni led to a large increase in sensitivity.

Polymeric microspheres for immunoresearch

New microspheres having functional aldehyde groups have been prepared by radiation polymerization of acrolein solution containing hydroxyethyl methacrylate and glutalardehyde. The size distribution in the microspheres was narrow and average particle diameter was 1 - 2 micron. The binding ability of the microspheres to antigen increased by increasing the concentration of glutalardehyde. The preparation procedure of the microspheres is simple. The microspheres can be used for immunoresearch.

Cell separation using positive immunoselective techniques

Positive immunoselection is the direct selection and recovery of cells which express a given specificity from among a heterogeneous group of contaminating cells. A variety of methods are available to effect such separations. The principles of affinity chromatography, using solid-phase matrices or cellular immunoadsorbents, are extensively used. Liquid-phase positive immunoselection can also be performed using either a fluorescence-activated cell sorter or by using 'cellular engineering' to protect a cell from an otherwise noxious environment. The enzyme catalase coupled to specific antibody has been used for this purpose and renders cells resistant to hydrogen peroxide. The various positive immunoselection techniques available are reviewed and evaluated in the following report.

The selective detection of cell surface determinants by means of antibodies and acetylated avidin attached to highly fluorescent polymer microspheres

Procedures are described for the synthesis of 500 A-diameter polymer microspheres containing a novel fluorescent cross-linking agent. These microspheres have very high fluorophore concentration without quenching of the fluorescence and show very low nonspecific interaction with cells. When monoclonal anti-Thy-1.2 is attached to the fluorescent microspheres, specific binding results in 10(4) spheres being attached per thymocyte while non-specific binding is less than 1%. Similar values are obtained for an indirect staining procedure. The high non-specific binding of cationic avidin to negative cell surfaces is shown to be decreased to negligible levels by acetylation of the amine groups of the protein without decreasing its high-affinity binding to biotin. The use of acetyl-avidin (pI = 6.7) directly, or when attached to fluorescent microspheres, resulted in a highly selective detection of biotinyl groups on the erythrocyte or lymphocyte cell surface. Attachment of biotinyl groups to the hinge carbohydrates of antibodies did not affect their specificity. It allowed their detection by means of microspheres-acetyl-avidin conjugates.

A new immunoadsorbent for hemoperfusion: agarose-polyacrolein microspheres beads. I. In vitro studies

The development and properties of a novel adsorbent system consisting of polyacrolein microspheres encapsulated in agarose is described. In the model system, the microspheres contain covalently bound bovine serum albumin. In practice any protein or ligands with primary amino groups may be covalently bound. Circulating antibovine serum albumin antibodies were adsorbed from whole blood or serum of rabbits or goats onto the microspheres. The capacity of this batch is 10 mg antibody adsorbed/gm wet weight beads. When the column is operated at less than capacity, 50%, 70%, 90% and 95% of the anti BSA is adsorbed in 30, 60, 120 and 180 min, respectively. Thus, relatively short periods of hemoperfusion may be used. The beads are biocompatible. There are negligible decreases of RBC; up to a 10% decrease of WBC and up to a 20% decrease of platelets in 3 hrs. The beads are stable; neither breakdown nor leakage was observed over a period of 3 months. High flow rates were readily obtained. The mean diameter of the microspheres is 0.2 mu; the mean diameter of the agarose polyacrolein microspheres beads (APAMB) is 1.0 mm. We can produce monodisperse beads of any given diameter ranging from 200 mu to 1 cm.

Simultaneous analysis of cell surface antigens and cell morphology using monoclonal antibodies conjugated to fluorescent microspheres

A new method for simultaneous analysis of cell surface antigens and cell morphology using monoclonal antibodies conjugated to fluorescent microspheres ('immunospheres') is described. Wright's staining was performed on cells after reaction with immunospheres, and a direct correlation of cell surface antigen expression and cell morphology was made. Mild formalin fixation of cells inhibited phagocytosis of microspheres, which is a potential source of confusion in the analysis of cell surface binding. Rapid, accurate analysis of cell surface antigen expression in single cell suspensions of heterogeneous human hematopoietic and lymphoid cell populations was facilitated by this method.

Immunomicrospheres: reagents for cell labeling and separation

Immunomicrospheres are specially designed microscopic particles that have antibodies or similar molecules chemically bound to their surfaces. The antibody-coated microspheres react in a highly specific way with target cells, viruses, or other antigenic agents. Immunomicropheres may be synthesized so that they incorporate compounds that are highly radioactive, intensely fluorescent, magnetic, electron opaque, highly colored, or pharmacologically active. These various types of microspheres may be coated with pure, highly specific monoclonal antibodies obtained by the new hybridoma cell cloning techniques or with conventional antibody preparations. Some of the many present and potential applications for these new reagents are (i) new types of radioimmune or immunofluorescent assays, (ii) improved fluorescence microscopy, (iii) separation of cells on the basis of the fluorescent, electrophoretic, or magnetic properties of bound immunomicrospheres, (iv) markers for use in several types of electron or standard light microscopy, and (v) delivery of lethal compounds to specific undesirable living cells. The combination of the various new types of synthetic microspheres and the newly available homogeneous antibodies offers new opportunities in research, diagnosis, and therapy.

Polyglutaraldehyde: a new reagent for coupling proteins to microspheres and for labeling cell-surface receptions. II. Simplified labeling method by means of non-magnetic and magnetic polyglutaraldehyde microspheres

Procedures were developed for the synthesis of a new immunoreagent in form of polyglutaraldehyde (PGL) microspheres in sizes ranging from about 50 nm to 1.5 micron. Addition of fluorochromes during synthesis yielded microspheres of high fluorescence intensity. By carrying out the polymerization of glutaraldehyde in presence of iron oxide, magnetic PGL microspheres were produced. Antibody conjugates obtained by interaction of PGL microspheres with immunoglobulins were used to label human red blood cells (RBC) and lymphocytes. A simple method for the separation of magnetically labeled human RBC from unlabeled cells was demonstrated.