Monoclonal antibody against the glutaraldehyde-conjugated polyamine,spermine

We developed a mouse monoclonal antibody (ASPM-29, mAb) against spermine (Spm) conjugated to human serum albumin (HSA) using glutaraldehyde-sodium borohydride, for applications in immunocytochemistry (ICC). The antibody specificity was evaluated by an enzyme-linked immunosorbent assay (ELISA) binding test, simulating the ICC of tissue sections. ASPM-29 showed an almost equal immunoreactivity to Spm and spermidine (Spd) but no reactivity to any of the other polyamine (PA)-related compounds tested. By use of this antibody, indirect immunoperoxidase staining was observed in different tissues fixed with glutaraldehyde in combination with borohydride reduction. In contrast, immunoreactivity was quite low in tissues fixed only with glutaraldehyde. Absorption controls indicated that the immunostaining could be completely inhibited by 50 g/ml of Spm or Spd and partially inhibited by N-acetylspermine (Ac-Spm), N¹-acetylspermidine (N¹-Ac-Spd), or N⁸-acetylspermidine (N⁸-Ac-Spd), but was hardly inhibited at all by other PA-related compounds or amino acids. The reactivity of the antibody with Spm conjugated on wells in an ELISA plate was inhibited by micromolar concentrations of Spm, Spd, Ac-Spm, N¹-Ac-Spd, or N⁸-Ac-Spd, in decreasing order, but not by other small molecules. Dense ICC staining was observed in the paranuclear and basal cytoplasm of acinar cells of rat pancreas, submandibular gland and paratid gland, these results being in complete agreement with our recent ICC methods using other mAbs produced against N-(-male-imidobutyryloxy) succinimide-conjugated Spm.     

Immunocytochemistry of glutamate at the synaptic level

High concentrations of glutaraldehyde (2-5%) were found optimal for fixation of glutamate. In the absence of glutaraldehyde, (para)formaldehyde does not permanently retain L-[3H]-glutamate or D-[3H]-aspartate previously taken up into brain slices. Rats were fixed by rapid transcardial perfusion with 2.5% glutaraldehyde/1% (para)formaldehyde, and brain samples osmicated, embedded in epoxy resin, sectioned, and exposed to specific antisera to glutamate (conjugated to carrier protein by glutaraldehyde), followed by colloidal gold-labeled second antibody. The gold particle density was higher over putative glutamatergic nerve terminals than over any other tissue elements (two to three times tissue average in cerebellum and hippocampus). Calibration by test conjugates containing known concentrations of fixed glutamate processed in the same fluid drops as the tissue sections indicated that the concentration of fixed glutamate in putative glutamatergic terminals in hippocampus CA1 was c. 20 mmol/liter. The grain density over the parent cell bodies was only slightly higher than the tissue average. (Grain densities over test conjugates of other amino acids, aldehyde-fixed to brain macromolecules, were similar to that over empty resin. Labeling was blocked by glutamate-glutaraldehyde but not by other glutaraldehyde-treated amino acids.) In other experiments, brain slices were incubated in oxygenated artificial cerebrospinal fluid (CSF) and then immersion-fixed and processed as above. Here, the ration of grain densities in putative glutamatergic terminals vs other tissue elements was greater than in perfusion-fixed material. Comparison of intra-terminal areas poor and rich in synaptic vesicles suggested that in this preparation vesicles contained at least three times the glutamate concentration of cytosol. In the glutamatergic synapses of the giant reticulospinal axons in lamprey the ratio was over 30. Prolonged K+ depolarization of hippocampal and cerebellar slices reduced the nerve terminal glutamate immunoreactivity in a Ca2(+)-dependent manner. The results suggest that glutamate is released by exocytosis at excitatory synapses and show that immunocytochemistry can be used to study the cellular processing of small molecules.     

Monoclonal antibodies against glutaraldehyde-conjugated histamine: application to immunocytochemistry

 We have developed mouse monoclonal antibodies (AHA-1–5, all IgG₁ sub-isotype mAbs) against histamine (HA) conjugated to bovine serum albumin using glutaraldehyde-NaBH₄. Among these, AHA-1 mAb was found to be the most useful for HA immunocytochemistry (ICC) in terms of specificity and sensitivity without non-specific immunobinding. AHA-1 was demonstrated to be specific to HA with an enzyme-linked immunosorbent assay (ELISA) binding test, simulating the ICC of tissue sections, and not reactive to any of the other amino acids and peptides with N-terminal histidine tested. By use of this antibody, indirect immunoperoxidase staining was observed in rat stomach fixed with glutaraldehyde (GA) in combination with NaBH₄ reduction. In contrast, no immunoreactivity was seen in tissue fixed only with GA. Absorption controls indicated that the immunostaining could be completely inhibited by GA-conjugated HA, which was consistent with the results of an ELISA inhibition test. No cross-reactivity occurred with other GA-conjugated amino acids. ICC staining was dense in the cytoplasm of gastric enterochromaffin-like cells and very weak in mast cells. A new finding was that staining was noticed in some cell bands of the intermediate layer between the stratum lucidum and the stratum corneum of the stratified squamous epithelium of the gastric cardia, esophagus, tongue, and skin in rats. The results strongly suggest that the monoclonal antibody allowed highly specific detection of HA in animal tis- sues. Accepted: 27 August 1996     

Monoclonal Anti-Conjugated Acetylcholine Antibody and Immunohistochemical Applications in Rat Nervous System

Acetylcholine (ACh) conjugates were injected into AKR and DBA mice over a period of 10 weeks. The polyclonal antisera were tested at various immunization times for affinity and specificity using an enzyme-linked immunosorbent assay (ELISA). The most immunoreactive compound was found to be choline-glutaryl-bovine serum albumin (or conjugated ACh). The AKR and DBA mice yielding the highest apparent affinity were killed, and the spleen cells were fused with X63 or SP2/O/Ag mouse myeloma cells. Supernatants of confluent cultures were tested for the presence of anti-conjugated ACh antibodies using the same ELISA method. The best results were obtained with the hybridomas from AKR spleen cells and X63 mouse myeloma cells. Monoclonal antibody affinity and specificity were then evaluated by a radioimmunological procedure using iodinated monoclonal anti-conjugated ACh antibody. From competition experiments, the most immunoreactive compound was choline-glutaryl-protein. The other related compounds were recognized either poorly or not at all. The high affinity and specificity of our monoclonal antibody enabled us to visualize ACh molecules on fixed rat brain sections. ACh was fixed with a mixture of nitrobenzyl alcohol and glutaraldehyde. Many ACh-immunoreactive cell bodies and fibers were seen on sections from the basal forebrain and spinal cord. Preadsorption and other immunohistochemical tests demonstrated that the ACh staining was highly specific.     

Antibodies to keyhole limpet hemocyanin cross-react with an epitope on the polysaccharide capsule of Cryptococcus neoformans and other carbohydrates: implications for vaccine development

Cryptococcus neoformans causes a life-threatening meningoencephalitis in AIDS patients. Mice immunized with a glycoconjugate vaccine composed of the glucuronoxylomannan (GXM) component of the cryptococcal capsular polysaccharide conjugated to tetanus toxoid produce Abs that can be either protective or nonprotective. Because nonprotective Abs block the efficacy of protective Abs, an effective vaccine must focus the Ab response on a protective epitope. Mice immunized with peptide mimetics of GXM conjugated to keyhole limpet hemocyanin (KLH) with glutaraldehyde developed Abs to GXM. However, control peptides P315 and P24 conjugated to KLH also elicited Abs to GXM. GXM-binding Abs from mice immunized with P315-KLH were inhibited by KLH treated with glutaraldehyde (KLH-g), but not by P315. Furthermore, KLH-g inhibited binding of GXM by serum of mice immunized with GXM-TT, indicating that glutaraldehyde treatment of KLH reveals an epitope(s) that cross-reacts with GXM. Vaccination with KLH-g or unmodified KLH elicited Abs to GXM, but did not confer protection against C. neoformans, suggesting the cross-reactive epitope on KLH was not protective. This was supported by the finding that 4H3, a nonprotective mAb, cross-reacted strongly with KLH-g. Sera from mice immunized with either native KLH or KLH-g cross-reacted with several other carbohydrate Ags, many of which have been conjugated to KLH for vaccine development. This study illustrates how mAbs can be used to determine the efficacy of potential vaccines, in addition to describing the complexity of using KLH and glutaraldehyde in the development of vaccines to carbohydrate Ags.     

Binding properties and esterase activity of monoclonal antibodies elicited against sucrose 6-heptylphosphonate

Various sugar phosphonates were prepared by a Mitsunobu condensation between phosphonic diacids and properly protected carbohydrates. 6'-O-p-Aminophenylsucrose 6-heptylphosphonate was coupled to Bovine Serum Albumin (BSA) and Keyhole Limpet Hemocyanin (KLH) and the KLH conjugate was used for generation of monoclonal antibodies. Binding properties of these antibodies were screened by competitive enzyme-linked immunosorbent assay (ELISA) using the BSA conjugate. A monoclonal antibody with good binding properties showed a regioselective esterase activity toward 6-octanoylsucrose compared with 6'-octanoylsucrose.     

Evaluation of the immunocytochemical method for amino acids

Free amino acids can be coupled to proteins by glutaraldehyde. Rabbits immunised with a bovine serum albumin-glutaraldehyde-amino acid conjugate form antibodies that recognise similar conjugates with brain proteins in glutaraldehyde-fixed tissue. Antisera raised against conjugated GABA (gamma-aminobutyrate), glutamate, aspartate, taurine, glutamine, or glycine were tested against a variety of small molecular compounds that had been fixed by glutaraldehyde to brain protein and immobilised on cellulose ester filters for processing together with the brain sections. This system permitted closely similar conditions for testing and immunocytochemistry. After removing antibodies against the carrier used for immunisation and against cross reacting amino acid conjugates the antisera showed a high specificity. The specific nature of the antisera was corroborated by solid phase adsorption to the homologous antigens and by inhibition experiments with free amino acids and amino acid-glutaraldehyde fixation complexes. After transection of the striatonigral pathway the ipsilateral substantia nigra was almost depleted of GABA-like immunoreactivity; this observation lends additional support to the selectivity of the GABA antiserum. A semiquantitative relation was established between the concentration of amino acid before fixation in a model system and the subsequent intensity of immunostaining. Similar model experiments suggested that the conjugation of an amino acid to brain protein with glutaraldehyde, and the immunoreactivity of the conjugates, may be significantly inhibited in the presence of high concentrations of other amino compounds.     

A monoclonal antibody to aflatoxin B1: detection of the mycotoxin by enzyme immunoassay

A monoclonal antibody (McAb) was produced after fusion of mouse (X63.Ag8.6.5.3) myeloma cells with spleen cells isolated from female Balb-c/NZB F1 hybrid mice immunized with aflatoxin B₁ (oxine)-keyhole limpet haemocyanin conjugate. The hybridoma cell line producing antibody specific for aflatoxin B₁ (AFB₁) was grown in tissue culture and as an ascites tumour. The ascitic fluid gave suitably high dilution titres (1:800 000) by enzyme immunoassay and was conjugated to horseradish peroxidase by a two-step procedure with glutaraldehyde. The conjugate was used to develop a direct competitive enzyme-linked immunosorbent (ELISA) assay for AFB₁. The sensitivity of the ELISA was 0–2 ng/ml with a working range up to 10 ng/ml for AFB₁. The specificity of the McAb was determined and it was shown not to cross-react significantly with any of the metabolites tested. This McAb and the direct competitive ELISA described may prove of use in the detection of AFB₁ in foods and feeds.     

Production of monomeric antigen-enzyme conjugate to study requirements for follicular immune complex trapping

Summary Studies concerning the localization of immune complexes in lymphoid follicles and the involvement of these trapped immune complexes in the regulation of the immune response have thus far been performed with poorly defined complexes in terms of size and composition. For that reason, the minimum requirements for trapping in terms of number of antigen- and antibody molecules present in immune complexes could not be determined. We here describe the production and in vivo use of a monomeric HSA-HRP antigen-enzyme conjugate, readily demonstrable in cryostat sections and ELISA. This conjugate was obtained by combining the glutaraldehyde coupling-method with chromatography to fractionate monomeric and multimeric constituents.SDS-PAGE analysis showed that the conjugate consisted of a single molecular species of 109 kDa, whereas the often used periodate oxidation coupling method yielded a heterogeneous population of multimeric, oligomeric and monomeric molecules.We investigated the minimal size requirements for the composition of immune complexes to be trapped in murine spleen follicles using three different conjugates (monomeric HSA-HRP, multimeric HSA-HRP and multimeric HSA-HRP-Penicillin) and a panel of anti-HSA and anti-Penicillin monoclonal antibodies. We demonstrate that the smallest immune complexes, consisting of one antibody and two conjugate molecules, do not localize in splenic follicles. Immune complexes prepared with a single monoclonal antibody localize in follicles only if the epitope recognized occurs repeatedly on the antigen.The relevance of these results for physiological follicular trapping of protein antigens is discussed. The described method for the production of monomeric enzyme-labelled protein applicable in histochemistry and ELISA should prove useful to prepare other conjugates of defined size for studies of trapping and other applications.Abbreviations FDC follicular dendritic cell - HRP horseradish peroxidase - HSA human serum albumin - HY anti-HSA hyperimmune serum - MAb monoclonal antibody - Pen penicillin     

Monoclonal antibodies to queuine

Monoclonal antibodies specific for queuine have been prepared. Synthetic 9-(5-carboxypentyl)queuine (cp9Q) was conjugated with bovine serum albumin (BSA) or keyhole limpet hemocyanin (KLH), and the conjugate was used to immunize BALB/c mice by intraperitoneal and subcutaneous injection. Monoclonal antibodies were subsequently obtained by fusion of spleen cells and the mouse myeloma cell line X63Ag8U1. An enzyme-linked immunoabsorbent assay (ELISA) using o-phenylenediamine as peroxidase substrate was used for screening of clones and characterization of antibodies. Inhibition experiments with various homologous nucleosides revealed that the monoclonal antibody designated as 2D8E6 has no cross-reactivity with guanosine, adenosine or 7-methylguanosine.     

Characterization of antisera to glutamate and aspartate

Antisera were raised in rabbits against glutamate (Glu) and aspartate (Asp) conjugated to the invertebrate carrier protein hemocyanin (HC) with glutaraldehyde (GA). The antisera were characterized by testing their immunocytochemical staining properties on sections cut at the level of the ventral cochlear nucleus (VCN) from fixed brains of normal rats after absorption with conjugates of compounds structurally similar and biologically relevant to Glu and Asp. Optimal staining with Glu antiserum was obtained at a dilution of 1:10,000 and was completely blocked by 303 micrograms/ml of the Glu-HC conjugate. No crossreactivity with any of 11 compounds tested was observed. Optimal staining with the Asp antiserum was obtained at 1:8000 dilution and was completely blocked by 225 micrograms/ml of the Asp-HC conjugate. Of 10 compounds tested for crossreactivity, only L-asparagine demonstrated a measurable (about 10%) crossreactivity with the Asp antiserum. The specificity of the two antisera was also tested by immunoblot analysis against 11 compounds conjugated to HC with GA. Listed in order of staining intensity, from greatest to least, conjugates that reacted with the Glu antiserum were Glu greater than Gly-Glu greater than Asp-Glu = Asp greater than N-carbamyl (NC)-Glu greater than Asn = Gln = GABA. Conjugates that reacted with the Asp antiserum, in order of decreasing staining intensity, were Asp greater than Glu-Asp = Asn greater than Gly-Asp greater than Glu. No other compounds tested for crossreactivity reacted with the two antisera in the immunoblot analysis. Glu-like immunoreactivity in rat dorsal root ganglia and somatosensory cortex, and the comparative distribution of Glu- and Asp-like immunoreactivities in the latter tissue, are presented as examples of staining patterns obtained with the two antisera.     

Comparison of antigen constructs and carrier molecules for augmenting the immunogenicity of the monosaccharide epithelial cancer antigen Tn

We have demonstrated previously that the optimal method for inducing an antibody response against defined cancer antigens is covalent conjugation of the antigen to keyhole limpet hemocyanin (KLH) and use of the potent saponin adjuvant QS-21. Single molecules of glycolipids (tetrasaccharides, pentasaccharides, or hexasaccharides) and MUC1 peptides (containing between one and five MUC1 tandem repeats) conjugated to KLH have proven sufficient for antibody recognition and vaccine construction. However, cancer specificity of monoclonal antibodies against the monosaccharide Tn and disaccharide sTn comes largely from recognition of clusters (c) of these molecules on the cell surface. Tn consists of a monosaccharide (GalNAc) O-linked to serine or threonine on epithelial cancer mucins which are uniquely rich in serines and threonines. We test here several Tn constructs: Tn monosaccharide, Tn(c) prepared on a triple threonine backbone, and Tn prepared on a partially or fully glycosylated MUC1 backbone. We determine that Tn(c) is more effective than Tn, and conjugation to KLH is more effective than conjugation to BSA or polystyrene beads for inducing ELISA reactivity against Tn, and FACS reactivity against Tn-positive tumor cells. Surprisingly, MUC1 glycosylated with Tn at three or five sites per 20 amino acid MUC1 tandem repeat and conjugated to KLH, induced the strongest antibody response against Tn and tumor cells expressing Tn, and had the additional advantage of inducing antibodies against MUC1.     

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.     

Production of monomeric antigen-enzyme conjugate to study requirements for follicular immune complex trapping.

Studies concerning the localization of immune complexes in lymphoid follicles and the involvement of these trapped immune complexes in the regulation of the immune response have thus far been performed with poorly defined complexes in terms of size and composition. For that reason, the minimum requirements for trapping in terms of number of antigen- and antibody molecules present in immune complexes could not be determined. We here describe the production and in vivo use of a monomeric HSA-HRP antigen-enzyme conjugate, readily demonstrable in cryostat sections and ELISA. This conjugate was obtained by combining the glutaraldehyde coupling-method with chromatography to fractionate monomeric and multimeric constituents. SDS-PAGE analysis showed that the conjugate consisted of a single molecular species of 109 kDa, whereas the often used periodate oxidation coupling method yielded a heterogeneous population of multimeric, oligomeric and monomeric molecules. We investigated the minimal size requirements for the composition of immune complexes to be trapped in murine spleen follicles using three different conjugates (monomeric HSA-HRP, multimeric HSA-HRP and multimeric HSA-HRP-Penicillin) and a panel of anti-HSA and anti-Penicillin monoclonal antibodies. We demonstrate that the smallest immune complexes, consisting of one antibody and two conjugate molecules, do not localize in splenic follicles. Immune complexes prepared with a single monoclonal antibody localize in follicles only if the epitope recognized occurs repeatedly on the antigen. The relevance of these results for physiological follicular trapping of protein antigens is discussed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Production of Monoclonal Antibody to 2'',3''-Cyclic Nucleotide 3''-Phosphodiesterase from Bovine Cerebral White Matter

Lewis rats were immunized with partially purified 2',3'-cyclic nucleotide 3'-phosphodiesterase (CNPase) from bovine cerebral white matter and the spleen cells were fused with cell of a mouse myeloma cell line (SP-2). The production of monoclonal antibody was detected by enzyme-linked immunoadsorbent assay, immunohistochemical staining of bovine cerebrum, Western blotting analysis, and CNPase binding assay. Monoclonal antibody that specifically binds CNPase molecules was obtained. However, the antibody did not suppress the enzyme activity. Western blotting analysis demonstrated that the monoclonal antibody binds both CNa (Wla) and CNb (Wlb). The monoclonal antibody was identified as being of the IgG2c subclass. Immunohistochemical examination revealed that the myelin sheath in the CNS was heavily stained with the monoclonal antibody in several species (bovine, mouse, rat, and human). In contrast, peripheral nervous system myelin was not stained even in bovine tissue. These results suggest that the monoclonal antibody obtained in the present study specifically recognizes the CNPase molecules in the CNS.     

Loss of antibody binding to prefixed cells: Fixation parameters for immunocytochemistry

Summary The denaturing effects of various types of fixative solutions on 5 cell surface antigens on mouse T-lymphocytes (Thy-1, T-200, Lyt-1, Lyt-2, and Th-B) were studied. For this purpose, cells were fixed with paraformaldehyde, glutaraldehyde, acrolein and osmium tetroxide at various concentrations. Fixed cells were then incubated with monoclonal antibodies and appropriate second stage antibodies or conjugates. The degree of antibody binding to these cells was determined quantitatively using flow-cytometry with a fluorescence-activated cell sorter or with a semi-automatic micro-ELISA system. The data obtained indicate that paraformaldehyde and glutaraldehyde preserve all five tested antigen molecules, whereas antibody binding to cells fixed in acrolein and osmium tetroxide is rapidly reduced at increasing concentrations of the fixative. The optimal concentration of paraformaldehyde is in the range 0.5–1%, whereas glutaraldehyde should be used at concentrations between. 0.05 and 0.1%. Cells fixed with 0.5% paraformaldehyde or with 0.05% glutaraldehyde are stable and can be stored for at least one week prior to incubation with antibodies.     

A monoclonal antibody against the glutaraldehyde-conjugated polyamine, putrescine: application to immunocytochemistry

We developed a mouse monoclonal antibody (mAb; APUT-32, IgG1 subisotype mAb) against putrescine (Put) conjugated to bovine serum albumin using a glutaraldehyde (GA)-sodium borohydride procedure, for applications in immunocytochemistry (ICC). The antibody specificity was evaluated by an ELISA binding test, simulating the ICC of tissue sections. APUT-32 mAb was highly specific to Put, and distinguished alterations in the chemical structure of other polyamine (PA) analogs, showing 3.8% crossreaction with cadaverine, 3.3% with spermidine (Spd), and 2.3% with 1,3-diaminopropane. Comparable results in immunoreactivity of APUT-32 mAb were obtained with the ELISA inhibition test. By the indirect immunoperoxidase method using the APUT-32 mAb, Put-like immunoreactivities were observed in the cytoplasm of HeLa and MCF-7 cell lines fixed with GA in combination with NaBH4 reduction, but almost no immunoreaction was seen in the cytoplasm of the human melanoma BD cell line. On the other hand, the same method but using a previously prepared ASPM-29 mAb, specific for spermine (Spm) and Spd, produced intense immunostaining in the cytoplasm of all the three cell types. The Put-like immunoreaction was completely abolished by absorption of the APUT-32 mAb with 10 microg/ml Put-human serum albumin conjugate prepared using GA and NaBH4. HPLC analysis was also performed for the levels of each of the PAs in the three types of cell, showing that the levels of Put detected were much lower than those of Spm and Spd, and were strikingly different in the three cell lines among which the human melanoma BD cell line contained the lowest levels of Put. These results strongly suggest that APUT-32 mAb reacts specifically with Put in the tumor cells and therefore has the potential as a new tool for elucidating the biological roles of Put in cells and tissues.     

Immunohistochemical application of monoclonal antibodies against myelin basic protein and neurofilament triple protein subunits: advantages over antisera and technical limitations

Four monoclonal antibodies against guinea pig myelin basic protein (MBP), and four against subunits of bovine neurofilament triplet proteins (NF) were produced and their activity determined by enzyme-linked immunosorbant assay. The specificity and cross-reactivity of these eight monoclonal antibodies and one heterologous antiserum against each of the two central nervous system (CNS) antigens were examined in a histological study using the immunoperoxidase, antibody sandwich technique in rat and human brain tissue. Tissue sections were prepared from paraffin-embedded or fresh brain tissue that had been fixed with one of five different fixatives. The resulting immunoperoxidase labeling was then graded for intensity and examined for artifacts. One monoclonal antibody against MBP and one against NF resulted in labeling that was superior to that given by each of the antisera against their respective antigens. Of the five fixatives tested, a mercuric chloride-formalin solution gave the best preservation of these two antigens in rat and human brain tissue. The mercuric chloride-formalin solution was found to be superior to the other fixatives when immersion fixation was used, and was especially optimal when brains were perfused fixed. Three artifacts were encountered among the various antibody-fixative combinations that produced erroneous, but seemingly specific staining of Purkinje cells, neurons and axons, or astrocytes.     

Use of monoclonal antibodies in immunoenzyme analysis for demonstrating antigenic monovalency

To prove the monovalence of the antigen a method has been developed consisting of ELISA with the use of monoclonal antibodies in combination with the antibody neutralization test. Yersinia pestis capsular antigen was disintegrated by heating at 100 degrees C for a short time and subsequently passed through a column packed with Sephadex G-50. The portions of the eluate, showing high activity in the antibody neutralization test and low activity in ELISA (the double antibody sandwich scheme), contained mainly the monovalent antigen. This antigen was replaced by the polyvalent antigen from the antibody complex, but if such complex had been previously fixed by treatment with glutaraldehyde, no replacement of the monovalent antigen by the polyvalent one occurred.     

Immunoelectron microscopy study of polyamines using a newly prepared monoclonal antibody against spermidine: use of a mixture of glutaraldehyde and paraformaldehyde as a cross-linking agent in the preparation of the antigen

We developed a mouse monoclonal antibody (ASPD-19, IgG3 sub-isotype mAb) against spermidine (Spd) conjugated to bovine serum albumin (BSA) using a mixture of glutaraldehyde (GA) and paraformaldehyde (PFA)-sodium borohydride for applications in immunoelectron microscopic studies. The antibody specificity was evaluated by an ELISA binding test simulating the immunocytochemistry (ICC) of tissue sections. The ASPD-19 mAb is highly specific for Spd and Spm, almost the same degree to each, and can distinguish alterations in the chemical structure of other polyamine (PA) analogs, showing less than 3.2% cross-reaction with N(1)-acetylspermidine, acetylspermine, or N(8)-acetylspermidine. By an indirect immunoperoxidase method using the ASPD-19 mAb, PA-like immunoreactivities were observed in different tissues fixed with Karnovsky fixative (a mixture of GA and PFA) in combination with borohydride reduction. In contrast, immunoreactivity was very low in tissues when the borohydride reduction step was omitted. The PA-like immunoreaction was completely abolished by the adsorption of the ASPD-19 mAb with 100 microg/ml of Spd or Spm, but was inhibited little or none by other PA-related compounds or amino acids. A light microscopic ICC method using ASPD-19 produced immunostaining of PAs in certain cells in rat tissues with high biosynthetic activities (small intestine, pancreas and spinal cord). A pre-embedding immunoelectron microscopic study using rat spinal cord showed PA immunoreactivity located predominantly on free (polysomes) and attached ribosomes of the rough endoplasmic reticulum (Nissl bodies) in the cytoplasm of motor neurons. These results are in complete agreement with the results obtained by our recent ICC method using another mAb (ASPM-29) produced against GA-conjugated Spm.