Immune complex receptors on cell surface. I. Ultrastructural demonstration of macrophages.

A method is described for ultrastructural localization of immune complex receptors on the surface of viable peritoneal exudate cells. The technique entails incubation with a soluble complex of horseradish peroxidase (HRP) and specific antibody to HRP at 4 degrees C followed by exposure to diaminobenzidine and processing for electron microscopy. The bound immune complexes were evident as focal deposits of HRP reaction product, adhering closely to the external surface of macrophages with an uninterrupted periodicity varying between 30 and 120 nm. Following incubation with an insoluble immune complex containing a higher proportion of antibody, receptor sites stained frequently, but large aggregates adhered to the cells. Rinsing cells after staining with soluble complexes partially displaced the bound immune complexes. Fixation prior to exposure to immune complexes largely eliminated the binding capacity of the immune complex receptors.     

Enhanced chemiluminescence reaction applied to the study of horseradish peroxidase stability in the course of p-iodophenol oxidation

The enhanced chemiluminescence reaction (ECL) was applied to the study of horseradish peroxidase (HRP) inactivation during the oxidation of p-iodophenol. Enzyme inactivation was shown to be the main reason for light decay in the course of the reaction. No individual effect of luminol and p-iodophenol as enhancer on HRP activity towards 2,2′-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid) (ABTS) was detected, enzymatic activity loss was detected only in the course of the ECL reaction. HRP activity towards ABTS (a colorimetric substrate) fell in a similar manner to the decay in light emission. The reactive radical species formed during enhancer oxidation were suggested as the main inactivating agents. The similarity of changes in light intensity and enzymatic activity allows one to apply the ECL reaction for testing potential stabilizers of HRP. The loss of enzyme activity can be partially explained by non-specific interaction of radical species with protein globule. The addition of bovine serum albumin provided almost complete protection of peroxidase from inactivation. This confirms the non-specific inactivation with highly reactive endogenous intermediates through the modification of a protein globule. © 1997 John Wiley & Sons, Ltd.     

基于“酶-邻氨基苯酚”体系的电化学免疫传感方法及其应用

本研究建立了一种新的电化学免疫传感方法,并将其应用于实际样本的检测。采用辣根过氧化物酶(horseradish peroxidase,HRP)的新型底物邻-氨基苯酚(O-aminophenol,O-AP)构建了基于"酶-邻氨基苯酚"体系的电化学免疫传感方法,并用于血吸虫抗体检测。邻-氨基苯酚在辣根过氧化物酶催化双氧水(H2O2)时被氧化,生成的产物3-氨基吩噁嗪能通过电化学方法检测。实验结果验证了基于"酶-邻氨基苯酚"的新型蛋白检测体系用于检测人血清中血吸虫抗体的可操作性,实现了实际样本的检测。并且,采用方波伏安法作为最终检测方法,具有更高的灵敏性。     

Biocatalytic properties of recombinant tobacco peroxidase in chemiluminescent reaction

The wild-type anionic tobacco peroxidase and its Glu141Phe mutant have been expressed in Escherichia coli, and reactivated to yield active enzymes. A Glu141Phe substitution was made with the tobacco anionic peroxidase (TOP) to mimic neutral plant peroxidases, such as horseradish peroxidase (HRP). Both recombinant forms of tobacco peroxidase show extremely high activity in luminol oxidation with hydrogen peroxide, and thus, preserve the unique property of the native tobacco peroxidase, a superior chemiluminescent reagent. The chemiluminescent signal intensity for both recombinant forms of TOP is orders of magnitude higher than that for wild-type recombinant HRP. The substitution slightly increases TOP activity and stability in the reaction course, but has almost no effect on the optimal parameters of the reaction (pH, luminol and hydrogen peroxide concentrations) and calibration plot. Comparison of substrate specificity profiles for recombinant TOP and HRP demonstrates that Glu141 has no principal effect on the enzyme activity. It is not the presence of the negative charge at the haem edge, but the high redox potential of TOP Compounds I and II that provides high activity towards aromatic amines and aminophenols, and luminol in particular.     

Protein heteroconjugation by the peroxidase-catalyzed tyrosine coupling reaction

Combining different proteins can integrate the functions of each protein to produce novel protein conjugates with wider ranges of applications. We have previously introduced a peptide containing tyrosine residues (Y-tag) at the C-terminus of Escherichia coli alkaline phosphatase (BAP). The tyrosine residues in the Y-tag were efficiently recognized by horseradish peroxidase (HRP) and were site-specifically cross-linked with each other to yield BAP homoconjugates. In this study, the HRP-catalyzed tyrosine coupling reaction was used for protein heteroconjugation. Streptavidin (SA) was selected as the conjugation partner for BAP. The Y-tag (GGGGY) was genetically introduced to the C-terminus of SA. Prior to heteroconjugation, the reactivity of the Y-tagged SA was examined. The Y-tagged SA cross-linked to form an SA homoconjugate upon HRP treatment, whereas wild-type SA remained essentially intact. In the heteroconjugation reaction of BAP and SA, the Y-tagged BAP and SA were efficiently cross-linked with each other upon HRP treatment. The functions of the BAP-SA conjugates were evaluated by measuring the BAP enzymatic activity on a biotin-coated plate. The BAP-SA conjugate tethered to the plate showed BAP enzymatic activity, indicating that both BAP and SA retained their functions following heteroconjugation. The BAP-SA conjugate prepared from both Y-tagged BAP and SA showed the highest enzymatic activity on the biotin-coated plates. This result illustrates the advantage of the protein conjugation reaction in which multiple numbers of proteins can be conjugated at the same time.     

Biocatalytic properties of recombinant tobacco peroxidase in chemiluminescent reaction

The wild-type anionic tobacco peroxidase and its Glu141Phe mutant have been expressed in Escherichia coli, and reactivated to yield active enzymes. A Glu141Phe substitution was made with the tobacco anionic peroxidase (TOP) to mimic neutral plant peroxidases, such as horseradish peroxidase (HRP). Both recombinant forms of tobacco peroxidase show extremely high activity in luminol oxidation with hydrogen peroxide, and thus, preserve the unique property of the native tobacco peroxidase, a superior chemiluminescent reagent. The chemiluminescent signal intensity for both recombinant forms of TOP is orders of magnitude higher than that for wild-type recombinant HRP. The substitution slightly increases TOP activity and stability in the reaction course, but has almost no effect on the optimal parameters of the reaction (pH, luminol and hydrogen peroxide concentrations) and calibration plot. Comparison of substrate specificity profiles for recombinant TOP and HRP demonstrates that Glu141 has no principal effect on the enzyme activity. It is not the presence of the negative charge at the haem edge, but the high redox potential of TOP Compounds I and II that provides high activity towards aromatic amines and aminophenols, and luminol in particular.     

Tomato peroxidase: purification, characterization, and catalytic properties

A major peroxidase has been found in the tomato pericarp (Lycopersicon esculentum var. Tropic) of the ripe and green fruit. A purification scheme yielding this enzyme approximately 85% pure has been developed. The tomato enzyme resembles horseradish peroxidase (HRP) in a standard peroxidase assay and in its ability to be reduced to ferroperoxidase, to be converted to oxyferroperoxidase (compound III), and to form peroxidase complexes with hydrogen peroxide (compounds I and II). In contrast to the HRP, the tomato peroxidase fails to catalyze the aerobic oxidation of indole-3-acetic acid in the presence of 2,4-dichlorophenol and manganese. The tomato peroxidase can be resolved into two nonidentical subunits in the presence of dithiothreitol while HRP remains as a single polypeptide chain after such treatment. Dithiothreitol is oxidized in the presence of tomato or horseradish peroxidase with the enzymes accumulating in their oxyferroperoxidase forms during the oxidation reaction. Whereas HRP returns to its free ferric form at the end of the reaction, the tomato enzyme is converted into a form that absorbs at 442 nanometers.     

Oxidation of 2,4-dichlorophenol catalyzed by horseradish peroxidase: characterization of the reaction mechanism by UV-visible spectroscopy and mass spectrometry

The hydrogen peroxide-oxidation of 2,4-dichlorophenol catalyzed by horseradish peroxidase has been studied by means of UV-visible spectroscopy and mass spectrometry in order to clarify the reaction mechanism. The dimerization of 2,4-dichlorophenol to 2,4-dichloro-6-(2,4-dichlorophenoxy)-phenol and its subsequent oxidation to 2-chloro-6-(2,4-dichlorophenoxy)-1,4-benzoquinone together with chloride release were observed. The reaction rate was found to be pH-dependent and to be influenced by the pK(a) value of 2,4-dichlorophenol. The dissociation constants of the 2,4-dichlorophenol/horseradish peroxidase (HRP) adduct at pH 5.5 and 8.5 were also determined: their values indicate the unusual stability of the adduct at pH 5.5 with respect to several adducts of HRP with substituted phenols.     

Possible involvement of transglutaminase in endocytosis and antigen presentation

Experiments were carried out to determine as to whether or not internalization of antigen is necessary for subsequent antigen presentation by accessory cells using monoamines which are known as transglutaminase (TGase) inhibitors. It was found that endocytosis for immune complexes via Fc receptors such as sheep erythrocytes coated with IgG class antibody (EA) was different from receptor-independent endocytosis for soluble protein such as horse radish peroxidase (HRP) in the sensitivity to monoamines; methylamine inhibited the receptor-dependent endocytosis of immune complexes at a concentration of over 20 mM and the receptor-independent endocytosis of HRP at 2 mM, while dansylcadaverine (DC) inhibited both at a concentration of 100 microM. It was noteworthy that antigen-specific T cell proliferation to splenic adherent cells pulsed with DNP9.6-ovalbumin (DNP9.6-OVA) was blocked strongly by DC as well, but weakly by methylamine. These results suggest the possibility that antigen presentation requires internalization of antigen by a mechanism such as receptor-dependent endocytosis for the subsequent reexpression of antigen on membranes. Furthermore, it was confirmed that TGase activity is high in peritoneal exudate and spleen adherent cells, both of which have accessory cell activities for lymphocytes, suggesting the possibility that TGase might be involved intimately in receptor-dependent endocytosis and subsequent antigen presentation.     

A trinitrophenyl(TNP)-poly-L-lysine-horseradish peroxidase conjugate for the detection of anti-TNP antibodies in vivo

A new conjugate for the detection of anti-trinitrophenyl(TNP) antibodies was developed to study the localization pattern of specific antibody containing cells and extracellular antibody in vivo. By means of a bridging molecule, poly-L-lysine, nine TNP groups and six horseradish peroxidase (HRP) groups were joined in one conjugate. Thus a higher specificity (more hapten) was united with a higher staining intensity (more enzyme) in the same conjugate. This conjugate made possible the simultaneous detection of anti-TNP antibody containing cells and establishment of their class (immunoglobulin M (IgM) and IgG). It was also used for the demonstration of anti-TNP antibodies in tissues where a TNP-alkaline phosphate (AP) conjugate could not be used due to high AP (endogenous) background staining. Thus we demonstrated anti-TNP antibody containing cells in gut associated lymphoid tissue and anti-TNP-(TNP-ovalbumin) immune complexes in the glomeruli of the kidney. We suggest that poly-L-lysine is a suitable bridging molecule for the preparation of hapten-HRP conjugates.     

THE INTERACTION OF PARTICULATE HORSERADISH PEROXIDASE (HRP)-ANTI HRP IMMUNE COMPLEXES WITH MOUSE PERITONEAL MACROPHAGES IN VITRO

The uptake, distribution, and fate of particulate horseradish peroxidase (HRP)-anti HRP aggregates has been studied in homogeneous monolayers of mouse macrophages in vitro. Macrophages rapidly interiorize the immune complexes after binding to the cell surface. The rate of interiorization is maximal for complexes formed in a broad zone of 4-fold antibody excess to equivalence and corresponds to a rate of 10% of the administered load/10⁶ cells per hour. This rate is 4000-fold greater than the uptake of soluble HRP. The binding and endocytosis of HRP-anti HRP by macrophages is mediated by the trypsin insensitive F_c receptor. Cytochemically, intracellular HRP is localized within membrane bound vacuoles. After uptake of HRP, the enzymatic activity is degraded exponentially with a half-life of 14–18 hr until enzyme is no longer detectable. This half-life is twice as long as that previously observed for soluble uncomplexed HRP and is related to the combination of HRP with anti-HRP rather than the absolute amounts of enzyme or antibody ingested. The half-life of HRP-¹²⁵I was 30 hr. Exocytosis of cell associated enzyme or TCA precipitable counts was not detected, nor were persistent surface complexes demonstrable. The extensive capacity of macrophages to interiorize and destroy large amounts of antigen after the formation of antibody illustrates a role of this cell in the efferent limb of the immune response.     

Distribution of horseradish peroxidase (HRP)-anti-HRP immune complexes in mouse spleen with special reference to follicular dendritic cells

The distribution of immune complexes has been studied in mouse spleen stimulated to contain many germinal centers (GC's). Horseradish peroxidase (HRP)-anti-HRP complexes were used as an appropriately precise and sensitive model. We were primarily interested in the relative abilities of three cell types to interact with complexes: lymphocytes, macrophages, and follicular dendritic cells (FDC's). The latter are distinctive, nonendocytic, stellate cells located primarily at the transition of mantle and GC zones of 2 degrees lymphoid follicles (Chen, L. L., J. C. Adams, and R. M. Steinman, 1978, J. Cell Biol. 77:148). Binding of immune complexes to lymphocytes could not be visualized in situ. Macrophages avidly interiorized complexes into lysosomes, but did not retain them extracellularly. In contrast, FDC's could retain HRP-anti-HRP extracellularly under appropriate conditions, but did not endocytose them. Cytochemical reactivity accumulated progressively on FDC's 1--6 h after administration of complexes i.v., remained stable in amount and location for 1 day, and then was progressively lost over a 1- to 5-day period. Several variables in the association of complexes with macrophages and FDC's were pursued. Only 1 microgram of complexed HRP had to be administered to visualize binding to both cell types. Macrophages interiorized complexes formed in a wide range of HRP/anti-HRP ratios, while FDC's associated with complexes formed in HRP excess only. Quantitative studies with [125I]HRP-anti-HRP demonstrated that 20% of the splenic load of HRP associated with FDC's. Complexes formed with an F(ab')2 anti-HRP were distributed primarily in macrophages. When the levels of the third component of serum complement were depleted by prior treatment with cobra venom factor, uptake of complexes by macrophages was reduced some 50% whereas association with FDC's was abolished. The fact that antigen excess complexes are retained extracellularly strengthens the idea that they are immunogenic. Finally, the association of complexes with FDC's seems to retard the entry of antigen into the GC proper.     

Histology of the bone marrow antibody response

The histology of the specific and non-specific antibody response in mouse and rat bone marrow was studied after subcutaneous priming and intravenous boosting with horseradish peroxidase (HRP). Cells producing specific antibody against HRP were found only occasionally in the bone marrow after subcutaneous priming. After the intravenous boost injection their number gradually increased. These anti-HRP forming cells were found as single cells, randomly dispersed throughout the bone marrow. Such a random distribution was also found for cytoplasmic (non-specific) immunoglobulin containing cells. At no time point after immunization could lymphoid aggregates or trapping of immune complexes be observed in the bone marrow of either species. On the basis of these observations it is concluded that the bone marrow forms a suitable microenvironment for immigrating antibody-forming cells but does not contribute actively to the induction of the immune response.     

The kinetics of the diffusion-controlled reaction of the binding of carbon monoxide to hemoglobin in glycerol-water mixtures of high viscosity

The kinetics of the binding of carbon monoxide to human hemoglobin and to ferrous horseradish peroxidase (HRP) have been studied by flash photolysis in mixtures of glycerol and water over a wide range of temperature and solvent viscosities. This was done in order that the influence of diffusion-control on the association rates could be determined. The binding of CO to HRP which is much slower than binding to Hb was devoid of diffusion effects. By contrast, the fast and slow phases of binding to Hb in the high viscosity solvents both displayed curved Arrhenius plots, consistent with a change from a chemical activationcontrolled process in the high temperature region to a diffusion-controlled process in the low temperature region. Analyses of the curved Arrhenius plots indicated that in the low temperature diffusion-controlled region, the activation enthalpy is similar to the activation energy of viscosity of the solvent, as might be expected for a diffusion-controlled reaction.Curve fitting of rate-temperature-viscosity data, assuming simultaneous chemical activation and diffusion-control, yielded factors by which the diffusion rate constants differ from that for reaction between uniformly reactive spheres of equal radii. For the fast Hb reaction, observed upon partial photolysis, this factor varies from 0.02 to 1.1, depending upon the solvent composition. For the slow Hb reaction, observed upon higher degrees of photolysis, this factor was 0.03 and 0.04. These factors were rationalized in terms of fractional surface reactivities and of a maximum allowable solid angle of entry of reactant to the binding site. It was concluded that the steric hindrance of T-state Hb (slow reaction) is much greater than R-state Hb (fast reaction).     

Simultaneous ultrastructural demonstration of retrogradely transported horseradish peroxidase and choline acetyltransferase immunoreactivity

In order to study the synaptic connections of neurons identified by their projection target and neurotransmitter content, we have adapted a method of combining retrograde tracing of horseradish peroxidase (HRP) and immunocytochemistry at the electron microscopic level. HRP was injected into the rat amygdala. Sections from the rostral forebrain were processed according to the 3,3'-diaminobenzidine/glucose oxidase reaction followed by choline acetyltransferase (ChAT) localization. Neurons in the ventral pallidum which contained both the diffuse immunoperoxidase reaction product (ChAT) and large electron dense bodies characteristic of retrogradely transported HRP were defined as double labeled, i.e. cholinergic neurons that project to the amygdaloid body.     

Competition between glycoprotein hormones and horseradish peroxidase for mannose-specific binding sites in cells of endocrine organs

Mannose-specific binding sites for horseradish peroxidase (HRP) were studied in paraformaldehyde-fixed, frozen sections of endocrine organs by a cytochemical method reported previously. In the testis, HRP was bound to interstitial cells, probably macrophages, and to sites extending along the surface of spermatozoa in the seminiferous tubules. In the epididymis, cells in the connective tissue, probably fibroblasts or macrophages, showed the specific reaction. In the ovaries, the reaction for lectin-bound HRP was observed in connective tissue cells of the theca externa, and in the mucosa of the uterus, binding of HRP occurred to many fibroblasts. The glycoprotein was also bound to cells in the connective tissue of the thyroid, probably mast cells, as well as to endothelial cells in the adrenal medulla and cortex. In all cases, the binding reaction required Ca2+ and was suppressed by mannose or mannan. Partially purified and highly purified preparations of glycoprotein hormones [ovine follicle-stimulating hormone, ovine luteinizing hormone, bovine thyroid-stimulating hormone, and human chorionic gonadotropin] as well as bovine thyroglobulin and yeast invertase competed with the binding of HRP to all the cells mentioned thus showing that the hormones were bound to the same sites as HRP. When 1 microM HRP was present in the incubation medium, the addition of 15-25 microM of highly purified hormones almost suppressed the reaction for lectin-bound HRP and competitive effects could be observed at even lower concentrations of the hormones.     

Direct immunocytochemistry with a horseradish peroxidase-conjugated monoclonal antibody against substance P

The procedure for the isolation and conjugation of the anti-substance P monoclonal antibody NC1/34 with the enzyme horseradish peroxidase (HRP) is described. This resulted in a molecular complex of monoclonal antibody/HRP of 1:1. This conjugate was of approximately 400,000 daltons, as estimated by gel chromatography. Practically all the isolated antibody was coupled to HRP. The conjugate was tested both in a model system where CNBr-activated Sepharose beads were coupled to substance P and on fixed tissue preparations from the rat spinal cord and medulla oblongata. The conjugate revealed staining in nerve fibers in areas known to contain substance P. The best immunohistochemical results were obtained by prolonged incubations at 12 degrees C in the presence of 0.1% Triton X-100. The preabsorption of the conjugate with substance P obliterated the reaction.     

Uptake and fate of luminally administered horseradish peroxidase in resting and isoproterenol-stimulated rat parotid acinar cells

The formation and fate of apical endocytic vesicles in resting and isoproterenol-stimulated rat parotid acinar cells were studied using luminally administered horseradish peroxidase (HRP) to mark the vesicles. The tracer was taken up from the lumen by endocytosis in small, smooth-surfaces "c"- or ring-shaped vesicles. About 1 h after HRP administration the vesicles could be found adjacent to the Golgi apparatus. At later times HRP reaction product was localized in multivesicular bodies and lysosomes; in isoproterenol-stimulated cells it was also present in autophagic vacuoles. HRP reaction product was never localized in any structure associated with secretory granule formation. These results suggest that the apical endocytic vesicles play a role in membrane recovery, but that they are degraded and not reutilized directly in secretory granule formation. Additionally, it was found that when isoproterenol was injected before HRP administration, the apical junctional complexes became permeable to the tracer, allowing it to gain access to the lateral and basal intercellular spaces. This permeability may provide an additional route whereby substances in the extracellular fluid could reach the saliva.     

Site-specific protein cross-linking by peroxidase-catalyzed activation of a tyrosine-containing peptide tag

Protein modification methods represent fundamental techniques that are applicable in many fields. In this study, a site-specific protein cross-linking based on the oxidative tyrosine coupling reaction was demonstrated. In the presence of horseradish peroxidase (HRP) and H(2)O(2), tyrosine residues undergo one-electron oxidation reactions and form radicals in their phenolic moieties, and these species subsequently react with each other to form dimers or further react to generate polymers. Here, a peptide-tag containing a tyrosine residue(s) (Y-tag, of which the amino acid sequences were either GGGGY or GGYYY) was genetically introduced at the C-terminus of a model protein, Escherichia coli alkaline phosphatase (BAP). Following the incubation of recombinant BAPs with HRP and H(2)O(2), Y-tagged BAPs were efficiently cross-linked with each other, whereas wild-type BAP did not undergo cross-linking, indicating that the tyrosine residues in the Y-tags were recognized by HRP as the substrates. To determine the site-specificity of the cross-linking reaction, the Y-tag was selectively removed by thrombin digestion. The resultant BAP without the Y-tag showed no reactivity in the presence of HRP and H(2)O(2). Conversely, Y-tagged BAPs cross-linked by HRP treatment were almost completely digested into monomeric BAP units following incubation with the protease. Moreover, cross-linked Y-tagged BAPs retained ～95% of their native enzymatic activity. These results show that HRP catalyzed the site-specific cross-linking of BAPs through tyrosine residues positioned in the C-terminal Y-tag. The site-selective enzymatic oxidative tyrosine coupling reaction should offer a practical option for site-specific and covalent protein modifications.     

Glucose oxidase as label in histological immunoassays with enzyme-amplification in a two-step technique: coimmobilized horseradish peroxidase as secondary system enzyme for chromogen oxidation

A sensitive staining procedure for glucose oxidase (GOD) as marker in immunohistology is described. The cytochemical procedure involves a two-step enzyme method in which GOD and horseradish peroxidase (HRP) are coimmobilized onto the same cellular sites by immunological bridging or by the principle of avidin-biotin interaction. In this coupled enzyme technique, H2O2 generated during GOD reaction is the substrate for HRP and is utilized for the oxidation of chromogens such as 3,3'-diaminobenzidine or 3-amino-9-ethylcarbazole. Due to the immobilization of the capture enzyme HRP in close proximity to the marker enzyme (GOD), more intense and specific staining is produced than can be obtained with soluble HRP as coupling enzyme in the substrate medium. Indirect antibody labelled and antibody bridge techniques including the avidin (streptavidin)-biotin principle have proven the usefulness of this GOD labelling procedure for antigen localization in paraffin sections. Antigens such as IgA in tonsil, alpha-fetoprotein in liver and tissue polypeptide antigen in mammary gland served as models. The immobilized two-step enzyme procedures have the same order of sensitivity and specificity as comparable immunoperoxidase methods. The coupled GOD-HRP principle can be superior to conventional immunoperoxidase labelling for the localization of biomolecules in tissue preparations rich in endogenous peroxidase activities.