New immunolatex spheres: visual markers of antigens on lymphocytes for scanning electron microscopy

New immunochemical reagents consisting of antibodies bound to small latex spheres were used as visual markers for the detection and localization of cell surface antigens by scanning electron microscopy. Cross-linked latex spheres of various sizes from 300 to 3,4000 A in diameter were synthesized by aqueous emulsion copolymerization of methacrylate derivatives containing hydroxyl and carboxyl functional groups. Proteins and other molecules containing primary amino groups were covalently bonded to the acrylic spheres under a variety of mild conditions by the aqueous carbodiimide, cyanogen bromide, and glutaraldehyde methods. For use in the indirect immunochemical-labeling technique, goat antibodies directed against rabbit immunoglobulins were bonded to the spheres. These immunolatex reagents were shown to bind only to cells (red blood and lymphocytes) which had previously been sensitized with rabbit antibodies against cell surface antigens. Mouse spleen lymphocytes with exposed immunoglobulins on their surface (B cells) were labeled with these spheres and distinguished from unlabeled or T lymphocytes by scanning electron microscopy. The distribution of Ig receptors on lymphocytes was also studied using the spheres as visual markers. When lymphocytes were fixed with glutaraldehyde and subsequently labeled with the immunolatex reagents, a random distribution was observed by scanning electron microscopy; a patchy distribution was observed when unfixed lymphocytes were used. These results are consistent with studies using ferritin-labeled antibodies (S. De Petris and M. Raff. 1973. Nature [Lond.]. 241:257.) and support the view that Ig receptors on lymphocytes undergo translational diffusion. In addition to serving as visual markers for scanning electron microscopy, these latex spheres tagged with fluorescent or radioactive molecules have applications as highly sensitive markers for fluorescent microscopy and as reagents for quantitative studies of cell surface antigens and other receptors.     

Immunocytochemistry: its evolution and criteria for its application in the study of epon-embedded cells and tissue

The word immunocytochemistry is currently used to describe a number of methods that can be employed to localize antigens within cells by means of antigen-specific antibodies. In this article we will review a number of these methods, including immunofluorescence, immunoperoxidase, avidin-biotin, and colloidal-gold techniques. The advantages and disadvantages of the various methods are discussed, special attention being focused upon immunocytochemical staining of plastic-embedded tissue. Studies on the light microscope level show that embedding tissue in plastic prior to immunoperoxidase staining not only improves visualization of antigen-specific staining but also provides an accurate and efficient means of prescreening tissue for antigen prior to immunocytochemical staining on the electron microscope level. Varying section thickness between 1 and 3 microns does not significantly influence staining, whereas the fixative used to preserve the tissue under study does. On the electron microscope level, the colloidal gold technique appears superior to immunoperoxidase staining. It is both esthetically more pleasing and highly sensitive. Of five different colloidal gold methods tested, the most sensitive is the two-step technique that employs an antigen-specific primary antibody followed by a gold-labeled secondary antibody. Throughout this article, special emphasis is placed on the use of proper controls, both on the light and electron microscope levels. Where possible, such controls should include substitution of specific antiserum with normal serum; the use of antigen-adsorbed antiserum; the use of antisera with specificities for antigens not present in the tissue being studied; the use of tissue previously shown to be stainable for the antigen; and if cultured cells are being studied, the use of a number of cell types that do not contain the antigen.     

Negative staining in the detection of viruses in clinical specimens

Viruses have unique morphology and are therefore good candidates for negative staining. Negative staining with phosphotungstic acid (PTA) or uranyl acetate has facilitated the detection of many viruses in clinical specimens. Enhancement procedures have included the use of centrifugation and agar diffusion for concentrating virus particles, the use of solid phase capture reagents to trap virus particles and the use of secondary antibodies and electron dense markers to help visualize them. Techniques currently in use and employing negative staining include direct EM, immune electron microscopy (IEM), solid phase immune electron microscopy (SPIEM), colloidal gold-labeled protein A (PAG), solid phase IEM employing a second decorator antibody (SPIEMDAT), and solid phase IEM using colloided gold-labeled secondary antibodies (SPEIMDAGT). IEM methods assist with the detection of small viruses or viruses present in low numbers while PAG offers increased sensitivity over direct EM and IEM. In our experience the serum-in-agar (SIA) method is the most sensitive of the PAG IEM techniques for detection of rotavirus particles in clinical specimens. SPIEMDAT enhances the detection of small viruses which are often missed by other techniques due to background staining in specimens. SPEIMDAGT employing colloidal gold-labeled secondary antibody has increased sensitivity and offers the advantage of detecting viral antigen when whole virus particles are not visible. IEM techniques have recently been used for typing viruses using either monospecific antisera or monoclonal antibodies and colloidal gold-labeled secondary antibody.     

An immunogold-silver staining method for detection of cell-surface antigens in light microscopy

An immunogold-silver staining technique for detection of cell-surface antigens in cell suspensions was developed. Leukocyte cell suspensions were first incubated with monoclonal antibodies directed against cell-surface antigens and then with colloidal gold-labeled goat anti-mouse antibodies. Cytocentrifuge preparations of the cell suspensions were immersed in a physical developer containing silver lactate and hydroquinone as reducing substance. The preparations were then counterstained and mounted. In light microscopy, cells reacting with the monoclonal antibodies showed dark granules on their surface membrane. An optimal morphology, as revealed by a May-Grünwald-Giemsa counterstain, permitted accurate cell identification. The labeling was influenced by the gold particle diameter and the concentration of the gold reagents, by the duration of incubation in the physical developer, and by the composition and temperature of this medium. The T-cell subsets enumerated with this method in the peripheral blood of normal adults were identical to those found with other methods. The sensitivity of the technique was comparable with that of immunofluorescence microscopy. This immunogold-silver staining procedure proved to be a reliable tool for detection of cell-surface antigens in light microscopy.     

Immunogold-silver staining and epipolarized light microscopic detection of phosphoenolpyruvate carboxykinase and glycogen phosphorylase in rat liver

The subcellular distribution of enzymes related to carbohydrate metabolism was determined in sections of paraformaldehyde fixed and polyethylene glycol-1540-embedded rat liver and in cryostat sections. For this purpose, goat anti-rat phosphoenolpyruvate carboxykinase (PEPCK) serum and rabbit anti-rat glycogen phosphorylase (GP) serum were used as primary antibodies to localize the corresponding antigens. The primary antibodies were localized by 5 nm colloidal gold labeled secondary antibodies (either rabbit anti-goat IgG for PEPCK or goat anti-rabbit IgG for GP), and the gold particles were enhanced by silver staining using appropriate development reagents. The silver enhanced gold particles were detected by epipolarized light microscopy. PEPCK and GP immunoreactive molecules were found only in glycogen-containing areas of the cytosome of hepatocytes, and not in other cells. No immunocytochemical staining of hepatocytes was found when normal serum replaced the primary antibody in the procedures. Visio-Bond semithin (0.35–1.0 m) sections provided higher resolution for subcellular immunostaining of PEPCK and GP than cryosections of 10 m. Epipolarized light microscopy provided detection at high sensitivity of the gold-labeled antibody, and combined with transmitted light, allowed simultaneous visualization of the tissue morphology.     

Integrated microfluidic magnetic immunosensor for quantification of human serum IgG antibodies to Helicobacter pylori

In this paper, we have developed and characterized a microfluidic magnetic immunosensor coupled to a gold electrode for the rapid and sensitive quantification of human serum IgG antibodies to Helicobacter pylori. This microorganism cause peptic ulcers and chronic gastritis, affecting around the 10% of the world population. The sensor was completely automated and the antibodies detection in serum samples was carried out using a non-competitive immunoassay based on the use of purified H. pylori antigens that are immobilized on magnetic microspheres 3-aminopropyl-modified. The magnetic microbeads were injected into microchannel devices and manipulated for an external removable magnet. The IgG antibodies in human serum sample are allowed to react immunologically with the immobilized antigens, and the bounded antibodies are quantified by alkaline phosphatase (AP) enzyme-labeled second antibodies specific to human IgG. The p-aminophenyl phosphate (p-APP) was converted to p-aminophenol (p-AP) by AP and an electroactive product was detected on gold layer electrode at 0.250 V. The response current obtained from the product of enzymatic reaction is directly proportional to the activity of the enzyme and, consequently, to the amount of IgG antibodies to H. pylori in serum samples. The electrochemical detection can be done within 1 min and total assay time was 25 min. The calculated detection limits for electrochemical detection and the ELISA procedure were 0.37 and 2.1 U mL⁻¹, respectively, and the within- and between-assay coefficients of variation were below 5%. Our results indicate the potential usefulness of our fabricated microbiochip for the early assessment of human serum immunoglobulin G (IgG) antibodies to H. pylori.     

Some applications of microspheres in flow cytometry

Microspheres of latex ranging from 0.1 to 10 microns in diameter are nowadays commercially available. Labelled with different fluorochromes, they are good standards to check the optical path and to calibrate flow cytometers. The kits available contain microspheres highly selected with a precise size and a narrow distribution, so as to allow an easy alignment of instruments. Mixed with the cell preparations, microspheres may be used as an internal standard, in order to compare samples from day to day. Phagocytic activity has been investigated after incubation of cells with fluorescent microspheres. Covalently bound to ligands such as antibodies, microspheres become a powerful and specific reagent to label cell surface antigens. The positive signal is enhanced, allowing the detection of poorly represented epitopes. This paper reviews some examples of these applications published in the flow cytometry field.     

金抗体替代ELISA中的天然抗体用于溶菌酶检测

目的 酶联免疫吸附测定(ELISA)被广泛用于抗体或抗原的检测,并被视为临床实践中的金标准,可提供相对可靠、灵敏和特异的检测结果.ELISA的本质是抗原与相应抗体之间的特异性相互作用.然而,天然抗体固有的不稳定性是ELISA的一个难以克服的弱点,并可能导致检测结果的重现性差甚至错误的诊断结果.本课题组先前应用构象工程方...     

Immunogold staining method for the light microscopic detection of leukocyte cell surface antigens with monoclonal antibodies: its application to the enumeration of lymphocyte subpopulations

Colloidal gold was used as a marker for the light microscopic detection of lymphocyte cell surface antigens with monoclonal antibodies. Suspensions of peripheral blood leukocytes were first incubated with monoclonal mouse antibodies and then with colloidal gold-labeled goat anti-mouse antibodies. The cells were fixed and cytocentrifuge preparations or smears were made. Granulocytes and monocytes were then labeled by the cytochemical staining of their endogenous peroxidase activity. Lymphocytes reacting with the monoclonal antibody had numerous dark granules around the surface membrane. With electron microscopy, these granules appeared as patches of gold particles. This immunogold staining method proved to be a reliable tool for the enumeration of T-lymphocyte subpopulations in peripheral blood. The results were almost identical to those obtained with immunofluorescence microscopy. The procedure can also be applied on small volumes of capillary blood. This constitutes a good microtechnique for the determination of lymphocyte subsets in children.     

Immunohistochemical localization of barley stripe mosaic virions in infected wheat cells

Barley stripe mosaic virus particles were localized in ultrathin sections with colloidal gold-labeled specific IgG or antiserum followed by gold-labeled goat anti-rabbit IgG. On the average, 1.5 gold particles were attached per virus rod. A statistical analysis of counts of gold and virus particles showed that the staining procedure was highly reproducible from experiment to experiment and after several independently prepared colloidal gold solutions. The procedure should be useful for the intracellular localization of any protein to which an antibody can be prepared.     

Flow microsphere immunoassay-based method of virus quantitation.

A sensitive assay for adenovirus quantitation in vitro was developed using the flow microsphere immunoassay (FMIA) approach. Polystyrene microspheres were covalently coated with purified anti-adenoviral antibodies and incubated with virus-containing samples. After incubation, the samples were stained with DNA-specific fluorescent dyes, and microsphere-associated fluorescence was quantitated with a flow cytometer. The adsorption of virus to microspheres was examined under different experimental conditions. The flow cytometric assay was determined to be as accurate in detecting adenovirus as titering on 293 cells. The proposed method can be used to quantify virus in viral stocks and in biological samples.     

Detection and Assay of Avian Tumor Virus Group-Specific Antigen and Antibody by the Paired Radioiodine-Labeled Antibody Technique

The paired radioiodine-labeled antibody technique (PRILAT) was applied to the detection and quantitation of avian tumor virus group-specific (gs) antigens and antibody. The technique proved to be specific, repeatable, and appreciably more sensitive than the microcomplement-fixation test for avian leukosis (COFAL). The PRILAT facilitated direct measurement of comparative antigen content of several types of transformed, neoplastic, or virus-infected cells and the magnitude of nonspecific antibody binding by appropriate control cells. The versatility of the technique was illustrated by application to the detection and quantitation of gs antibody content of chicken, turkey, pigeon, and hamster sera. Antibodies were detected in COFAL-negative sera from hamsters bearing tumors induced by the Schmidt-Ruppin strain of Rous sarcoma virus. Sera from chickens bearing similar tumors were not positive for gs antibodies, although sera from turkeys and chickens immunized with avian leukosis virus did contain gs antibodies.     

研究报告：金抗体替代ELISA中的天然抗体用于溶菌酶检测

目的酶联免疫吸附测定(ELISA)被广泛用于抗体或抗原的检测,并被视为临床实践中的金标准,可提供相对可靠、灵敏和特异的检测结果。ELISA的本质是抗原与相应抗体之间的特异性相互作用。然而,天然抗体固有的不稳定性是ELISA的一个难以克服的弱点,并可能导致检测结果的重现性差甚至错误的诊断结果。本课题组先前应用构象工程方法开发了一种基于金纳米粒子的人工抗体(简称金抗体)。金抗体可以像天然抗体一样特异性地与抗原相互作用,并且具备远优于天然抗体的稳定性。出色的稳定性使金抗体可能成为天然抗体更好的替代物,用于ELISA中。方法经过必要的优化并与辣根过氧化物酶(HRP)耦联后,制得酶标金抗体10HRP-(Au-400P1),然后用酶标金抗体代替天然酶标抗体用于ELISA检测中。结果通过一系列的实验证明,抗溶菌酶金抗体可用于ELISA特异性检测1～16 mg/L范围内的鸡蛋清溶菌酶(HEWL)样品。结论金抗体可以替代天然抗体用于ELISA检测,并具有优于传统ELISA法的检测准确性和一致性。     

Colloidal gold labeling of intracellular ligands in dorsal root sensory neurons, visualized by scanning electron microscopy

We report a novel technique that combines high-resolution scanning electron microscopy (SEM) of intracellular structures with backscattered electron imaging (BEI) of colloidal gold-labeled intracellular ligands. Murine dorsal root ganglia were immersion-fixed, freeze-cleaved, labeled with gold complexes, and critical point-dried. Specimens were carbon-coated and viewed by BEI. They were then minimally sputter-coated with gold and previously identified cells relocated by secondary electron imaging (SEI). This permitted increased resolution of intracellular detail while gold particles remained detectable by BEI. Incubation with RNAse-gold and DNAse-gold complexes resulted in specific labeling of cytoplasm and nucleus, respectively. Immunolabeling of neurofilament (NF) and small nuclear ribonucleoproteins (snRNP) resulted in selective labeling of intracellular antigens. Nonspecific binding was abolished by use of 1% skin milk. Specifically, incubation with monoclonal anti-NF68 resulted in labeling of cytoplasm in 66% of neurons, notably of the large cells known to contain large amounts of NF. Satellite cells, which lack NF, showed low levels of background label. Human autoimmune anti-Sm serum recognizes snRNP particles, with the exception of the nucleolar U3 snRNP. Labeling with this serum resulted in specific labeling of 92% of nuclei, with only background labeling over nucleoli and cytoplasm. The results show that it is feasible to employ high-resolution SEM in conjunction with colloidal gold labeling to localize intracellular ligands in situ.     

Dual-peak long period fiber grating coated with graphene oxide for label-free and specific assays of H5N1 virus

Avian influenza is an acute infectious disease caused by the avian influenza virus (AIV), which has caused enormous economic losses and posed considerable threats to public health. This study aimed to demonstrate an immunosensor based on dispersion turning point long-period fiber grating (DTP-LPFG) integrated with graphene oxide (GO) for the specific detection of a type of AIV H5N1 virus. LPFG was designed to work at DTP, whose dual-peak spacing was very high sensitive to a refractive index. Anti-H5N1 monoclonal antibodies were covalently bonded with the GO film on the fiber surface, thus constructing an immunosensor for the label-free and specific detection of the H5N1 virus. The proposed method was capable of the reliable detection of H5N1 virus with the limit of detection as low as ~1.05 ng/ml within the large range of 1 ng/mL to 25 µg/mL. More importantly, immunoassays of the whole H5N1 virus in clinical samples further confirmed that the GO-integrated DTP-LPFG immunosensor showed very high specificity to the H5N1 virus and demonstrated great potential for clinical use.     

Hapten-sandwich labeling. II. Immunospecific attachment of cell surface markers suitable for scanning electron microscopy

A hapten-sandwich procedure has been used for immunospecific labeling of cell surface antigens with markers visible by scanning electron microscopy. Antihapten antibody was used to link hapten-modified tobacco mosaic virus, bushy stunt virus, or hemocyanin to hapten-modified human erythrocytes. The antihapten antibody bridge was also used to link the hapten-virus marker to hapten-modified antibodies against mammary tumor virus on mouse mammary tumor cells, or against immunoglobulin receptors on mouse splenic lymphocytes. In all cases, labeling was highly specific. With this technique, it is possible to (a) compare morphological features of cells bearing differing cell surface antigens, and (b) examine the arrangement of specific antigenic sites on a cell surface or their distribution relative to membrane structures such as microvilli.     

Endocytosis in Trypanosoma cruzi (Euglenozoa: Kinetoplastea) epimastigotes: Visualization of ingested transferrin-gold nanoparticle complexes by confocal laser microscopy

Here we describe the visualization by confocal microscopy of ingested gold (15nm)-labeled transferrin in epimastigote forms of the protozoan Trypanosoma cruzi. Intracellular gold labeling was evident at two sites, which represent the bottom of the cytopharynx and the reservosomes. The gold tracer was best observed by confocal microscopy by using the 633nm excitation wavelength. Intracellular gold clusters larger than 60nm could be visualized by either gold reflection (light scattering) or photoluminescence modes. The gold reflection mode, the gold photoluminescence mode and the anti-transferrin immunofluorescence image of gold-labeled transferrin showed co-localization, thus demonstrating that the gold visualization modes did not represent artifacts or mislocalization of the biomarker. Visualization of protein-gold nanoparticle complexes by confocal microscopy thus emerges as a promising imaging tool to explore the endocytic pathway in trypanosomes and other cell types, as well as to perform immunolocalization studies using gold-labeled secondary antibodies.     

一种快速检测甲型流感病毒的方法

目的 开发一种快速、简便的基于胶体金免疫层析法（GICA）的试剂盒,以用于对甲型流感病毒的检测。方法以柠檬酸三钠还原法制备胶体金颗粒,标记抗甲型流感病毒内部抗原的单克隆抗体。硝酸纤维素膜上包被两种抗甲型流感病毒单克隆抗体的混合液,制成免疫层析试纸。待测样品中的甲型流感病毒首先与胶体金标记抗体结合,后移动至硝酸纤维素上与固定的单克隆抗体发生反应,形成肉眼可见的红色带。结果GICA试纸条与甲1型和甲3型流感病毒共16种毒株均能发生特异性反应,与乙型流感病毒、副流感病毒、腺病毒和呼吸道合胞病毒无交叉反应。用三种不同甲型流感病毒毒株的不同浓度标本与美国同类经过FDA批准的产品比较,灵敏度相同。结论GICA试纸条灵敏度能够达到临床使用的要求,并具有简便快速、无需特殊仪器设备等优点,对甲型流感的诊断和流行病学调查具有十分重要的应用价值。     

Immunoenzyme analysis of adenovirus hexon. Determination of antibodies from hyperimmunized chickens

We have elaborated three systems of enzyme-linked immunosorbent assay (ELISA) for detection of chicken IgG antibodies specific for hexon antigens of three immunologically distinct adenovirus groups: those of mammalian adenoviruses (Mastadenovira), typical avian adenoviruses (Aviadenovira) and of egg-drop syndrome-76 (EDS-76) virus. In each system the antibodies against respective hexons were specifically detected. In mammalian adenovirus hexons the ELISA detects primarily the type-specific (epsilon) and genus-specific (alpha) antigenic determinants. The time course of anti-hexon antibodies content was followed during immunization. The level of anti-hexon antibodies in egg yolk reflects adequately their content in blood serum. The technique is suitable for serological diagnosis of chicken adenoviral infections as well as for characterization of egg-yolk antibodies obtained by preparative hyperimmunization of hens.     

Development of a Fluorescent Based Immunosensor for the Serodiagnosis of Canine Leishmaniasis Combining Immunomagnetic Separation and Flow Cytometry

Background

An accurate diagnosis is essential for the control of infectious diseases. In the search for effective and efficient tests, biosensors have increasingly been exploited for the development of new and highly sensitive diagnostic methods. Here, we describe a new fluorescent based immunosensor comprising magnetic polymer microspheres coated with recombinant antigens to improve the detection of specific antibodies generated during an infectious disease. As a challenging model, we used canine leishmaniasis due to the unsatisfactory sensitivity associated with the detection of infection in asymptomatic animals where the levels of pathogen-specific antibodies are scarce.

Methodology

Ni-NTA magnetic microspheres with 1,7 µm and 8,07 µm were coated with the Leishmania recombinant proteins LicTXNPx and rK39, respectively. A mixture of equal proportions of both recombinant protein-coated microspheres was used to recognize and specifically bind anti-rK39 and anti-LicTNXPx antibodies present in serum samples of infected dogs. The microspheres were recovered by magnetic separation and the percentage of fluorescent positive microspheres was quantified by flow cytometry.

Principal Findings

A clinical evaluation carried out with 129 dog serum samples using the antigen combination demonstrated a sensitivity of 98,8% with a specificity of 94,4%. rK39 antigen alone demonstrated a higher sensitivity for symptomatic dogs (96,9%), while LicTXNPx antigen showed a higher sensitivity for asymptomatic (94,4%).

Conclusions

Overall, our results demonstrated the potential of a magnetic microsphere associated flow cytometry methodology as a viable tool for highly sensitive laboratorial serodiagnosis of both clinical and subclinical forms of canine leishmaniasis.