Metachromasia of 3-amino-9-ethylcarbazole (AEC) and its prevention in immunoperoxidase techniques

3-Amino-9-ethylcarbazole (AEC) used as chromogen in immunoperoxidase techniques normally has an intense, red colour. However, as an inconstant phenomenon, a pale yellowish-green reaction product severely impairing the evaluation can be observed. In order to circumvent this undesired effect, factors such as tissue fixative, proteolytic digestion, antibody concentrations and incubation time of the primary antibody were analyzed. The most important factor inducing a change in colour is probably the inadequately high local peroxidase concentration arising as the consequence of high amounts of bound primary antibody. This high enzyme concentration might cause metachromasia of AEC by producing the yellowish-green quinone-di-imine form of the substrate. As could be shown by spectrophotometry in test tube experiments, AEC metachromasia was proven to be enzyme dependent. Thus, the best way to trigger the local enzyme concentration on a tissue section to adequate levels appears to be the dilution of the primary antibody.     

A microfluorometric study of masked metachromasia in cells of the endocrine polypeptide (APUD) series

Synopsis Masked metachromasia can be demonstrated by staining with a metachromatic basis dye after a Feulgen-type hydrolysis of suitably fixed tissue, and is believed to be indicative of polypeptides with a high concentration of side-chain acidic groups and a random-coil conformation. In this investigation, the metachromatic fluorochrome Coriphosphine O was used. After staining, the degree of metachromasia under various conditions and in several tissues was assessed by microspectrofluorometric measurements of the ratio of metachromatic fluorescence (red) to orthochromatic fluorescence (green). This technique was employed, in the first instance, to determine the optimum staining conditions; details of the final staining method are presented. Measurements of metachromasia in different tissues under standardized conditions showed that the degree of metachromasia varied between different cell types in the APUD series.     

Effects of Ethanol on the Metachromatic Reaction of Toluidine Blue O

Ethanol abolishes the metachromatic reaction of toluidine blue O with un-combined chromotropes but not when they are in association with protein. The green colour obtained in metachromatic regions is established as not due to any green impurity of the dye by chromatographic analysis but due to the fluid dehydrants combining with the dye as dye-organic solvent mixture showed green. The loss of metachromasia is not due to a dehydration effect of ethanol alone for the following reasons: (i) Stained samples of chromotropes dried in vacuuo continued to retain the metachromatic colour, (ii) Although other dehydrating agents likewise abolished the metachromasia, alcohols which have very slight affinity to water also abolished it, (iii) Ethanol does not abolish metachromasia produced in an acid mucopolysaccharide-protein complex. This has been suggested as due to the inability of ethanol to separate the dye from such compounds and to bring about a shift to green.     

ADEPT and related concepts

Antibody-based therapy has attracted interest because of its potential to improve selectivity. But the limitations of antibodies as delivery systems are well known and the objective of restricting action to tumor sites requires additional means. The ADEPT concept introduced two components, enzyme and prodrug, that have the advantage that they can be secondarily manipulated to augment the selectivity of the primary delivery systems. An antibody-enzyme conjugate (AEC) is no more selective as a delivery system than antibody itself and total catalytic capacity in tumor, plasma, and nontumor tissues is a function not only of concentration but also of volume. It is pointless giving a prodrug that is promptly activated by enzyme in blood. The ability to inactivate or clear plasma enzyme (PENCIL) by an antibody directed at its active site and modified to have low potential to penetrate the tumor is one of several ways of improving partition of enzyme between tumor and nontumor. A second opportunity for manipulation arises from structural differences between prodrug and active drug and the potential of enzymes to exploit that difference. However effective the enzyme delivery system, some leakage of active drug into plasma is likely and active drug access to hemopoietic tissues is dose limiting. An enzyme for which the active drug, but not the prodrug, is substrate, and which is conjugated to a macromolecule, is proposed. Some thymidylate synthetase inhibitors suggest themselves as ready agents for use in this intravascular inactivation of active drug (IVIAD). This approach is an alternative to inactivation of plasma enzyme.     

Storage granules of thyroid C cells in the dog: a cytochemical and ultrastructural study, in relation to the masked metachromasia reaction.

Masked metachromasia can be demonstrated in thyroid C cells, and other cells of the APUD series, by staining with a metachromatic basic dye after hydrolysis of suitably fixed tissue. The reaction is thought to be due to the presence of polypeptides with a high concentration of side-chain acidic groups. Since most APUD cells possess storage granules, presumed to contain a polypeptide hormone, it has been assumed that the masked metachromasia reaction gives information concerning the contents of these granules. However, there has been an increasing suspicion that the reaction might actually be due to the membrane bounding these granules, rather than to the contents. We have examined, cytochemically and ultrastructurally, dog thyroid tissue which has been subjected to fixation and hydrolysis as in the usual method for masked metachromasia. We found that the membrane surrounding the C cell granules is removed by hydrolysis, confirming the hypothesis that the reaction is due to the contents (hormone and/or matrix)rather than to the membrane. Tissues were fixed in an aqueous mixture containing glutaraldehyde (6 25% v/v), picric acid (three-quarters saturation) and sodium acetate (I% W/V)adjusted to PH 7 with sodium hydroxide. This was found to be a very satisfactory fixative for electron microscopy Some morphological details of C cells were noted, such as the richness of desmosomes between C cells in this species, and frequent direct contact with the colloid.     

Intensification of 3,3′-diaminobenzidine precipitation using the ferric ferricyanide reaction,and its application in the double-immunoperoxidase technique

Summary As in double-immunoperoxidase methods, colour mixing usually indicates unwanted interactions between reagents of the first and second sequences, it is desirable to prevent such superimposition of colours by eliciting adequate colour intensity in the first immunoperoxidase sequence. The brown oxidation product of 3,3-diaminobenzidine (DAB) in the first immunoperoxidase sequence can be intensified by applying the ferric ferricyanide reaction, resulting in intense greenish-blue staining. When the primary antibody is used at a sufficient concentration, cells labelled in the first sequence do not cross-react with the red chromogen, 3-amino-9-ethylcarbazole (AEC), used in the second sequence. Thus, this double-immunoperoxidase method results in different cell populations being clearly labelled in contrasting colours. Primary antibodies from the same species and the same type of link antibodies can be used in the two separate immunoperoxidase sequences. When primary antibodies raised in different species and two types of link antibodies are used, the method can, without loss of sensitivity, be shortened by performing the first two incubation steps simultaneously.     

Multi-colour brightfield in situ hybridisation on tissue sections

 We describe the brightfield microscopical detection of multiple DNA target sequences in cell and tissue preparations. For this purpose, chromosome-specific DNA probes labelled with biotin, digoxigenin or fluorescein were simultaneously hybridised and detected by enzyme cytochemistry using two horseradish peroxidase (PO) reactions and one alkaline phosphatase (APase) reaction. For triple-colour detection on single cell preparations, the combination of the enzyme precipitates PO/diaminobenzidine (DAB, brown colour), APase/fast red (FR, red colour) and PO/tetramethylbenzidine (TMB, green colour) resulted in an accurate detection of DNA targets. Embedding of the preparations in a thin cross-linked protein layer further stabilised the enzyme reaction products. For in situ hybridisation on tissue sections, however, this detection procedure showed some limitations with respect to both the stability of the APase/FR and PO/TMB precipitates, and the sequence of immunochemical layers in multiple-target procedures. For this reason, the APase/FR reaction was replaced by the APase/new fuchsin (NF, red colour) reaction and the washing steps after the PO/TMB reaction were restricted to the use of phosphate buffer pH 6.0. Furthermore, to improve the efficiency of the ISH reaction, APase/NF was applied in an avidin-biotin complex detection system and, to avoid target shielding in the triple-target ISH, the third primary antibody was applied prior to the second enzyme cytochemical reaction. These adaptations resulted in stable, well contrasting brown, red and green coloured precipitates. After quick haematoxylin counterstaining, the tissue preparations were directly mounted in phosphate buffer and, optionally, embedded in the cross-linked protein layer. Accepted: 27 June 1997     

黄曲霉素对裸鼹鼠肺泡上皮Ⅱ型细胞基因表达的影响

目的:观察不同浓度黄曲霉素对裸鼹鼠肺泡上皮Ⅱ型细胞(AEC II)相关因子m RNA表达的影响,探讨裸鼹鼠抵御肺癌的分子机制。方法:通过酶消化法分离裸鼹鼠肺组织细胞并用免疫黏附法进行纯化得到裸鼹鼠肺泡上皮Ⅱ型细胞进行原代培养,40小时后,实验组分别给予不同浓度(0.25、0.5、1.0、2.0和4.0 mg/L)的黄曲霉素处理,溶剂对照组给予DMSO(0.4 m L/L)处理。黄曲霉素作用48小时后收集细胞,用实时定量PCR技术检测裸鼹鼠AECII细胞中的SP-C基因及TNF-α、IL-1、IL-6、IL-8、IL-12等炎症因子的m RNA表达变化。结果:原代分离的裸鼹鼠AEC II细胞纯度70%,活性90%,可用于体外实验。定量PCR结果显示黄曲霉素使裸鼹鼠AEC II细胞SP-C表达水平显著下降,TNF-α、IL-1、IL-6、IL-8、IL-12等炎症因子的表达水平在黄曲霉低于2 mg/L浓度的条件下没有显著变化。结论:裸鼹鼠AEC II细胞在黄曲霉素导致细胞受损的情况下,仍然保持较低水平的炎症因子表达,这可能是其抵抗肺癌的机制之一。     

大鼠肺泡Ⅱ型上皮细胞的原代分离

目的建立大鼠肺泡Ⅱ型上皮细胞(alveolar epithelial cells typeⅡ,AECⅡ)分离、纯化、原代培养及鉴定的方法。方法用4.2U/ml的弹性蛋白酶通过气管插管注入肺泡内,消化分离AECⅡ。把细胞悬液接种到包被有大鼠IgG的塑料平皿中纯化细胞。用电镜、碱性磷酸酶显色法、改良巴氏染色法、单宁酸染色法、免疫组化染色法鉴定AECⅡ。结果细胞纯度达到90%以上,倒置显微镜下可见细胞呈岛屿状生长。电镜下可见细胞内有大量板层小体,包膜上有绒毛结构。碱性磷酸酶染色法(BCIP/NBT)可见胞浆内有蓝色颗粒。改良巴氏染色法、单宁酸染色法可见胞浆内有黑色颗粒。抗大鼠肺泡表面活性蛋白A(surfactant protein A,SP-A)免疫组化染色呈阳性反应。结论弹性蛋白酶作用温和,不损伤胞膜,分离所得细胞活力好;IgG免疫粘附纯化法操作简单,纯化效率高。电镜、BCIP/NBT、巴氏染色、单宁酸染色及免疫组化染色等鉴定方法稳定可靠,特异性高。     

Dietary vitamin A can improve immune function in heat-stressed broilers

This experiment was undertaken to evaluate the effect of dietary vitamin A on the performance and immune competence of broilers under heat stress (HS). A total of 180 birds, at 22 days of age, were randomly assigned to be reared either at 24°C (thermoneutral, TN, 24°C, constant) or 24°C to 38°C (heat stress, HS, cycling) until the age of 42 days. Birds were then supplemented with vitamin A at 750, 1500, 15 000 IU/kg. Each of the 2 × 3 factorially arranged treatments were replicated in six cages, each containing five birds. Humoral immunity was assessed by intravenous injection of 7% sheep red blood cells (SRBC) followed by evaluation of serum for antibody titers in primary and secondary responses. Cell-mediated immunity was assessed by using a Sephadax stimulation method to recruit abdominal exudate cells (AEC) to evaluate macrophage phagocytic ability. Body weight (BW) and feed conversion were significantly affected by dietary vitamin A (P < 0.05). HS significantly reduced BW, feed intake and feed conversion (P < 0.05). Numbers of AEC, percentage of macrophages in AEC, phagocytic macrophages, internalized opsonized and unopsonized SRBC were increased by dietary vitamin A (P < 0.05). Both primary and secondary antibody responses were characterized by increasing titers of antibody to SRBC by dietary vitamin A when birds were exposed to HS (P < 0.05). Lymphoid organ weights, antibody responses, incidence of macrophages in AEC and phagocytic ability of macrophages were all significantly reduced under HS. These results indicated that HS severely reduced performance and immunocompetence of broilers, whereas the immune response of broilers improved by dietary vitamin A supplementation under HS.     

Peroxiredoxin 6 as an antioxidant enzyme: protection of lung alveolar epithelial type II cells from H2O2-induced oxidative stress

We evaluated the antioxidant role of peroxiredoxin 6 (Prdx6) in primary lung alveolar epithelial type II cells (AEC II) that were isolated from wild type (WT), Prdx6-/-, or Prdx6 transgenic (Tg) overexpressing mice and exposed to H(2)O(2) at 50-500 microM for 1-24 h. Expression of Prdx6 in Tg AEC II was sevenfold greater than WT. Prdx6 null AEC II exposed to H(2)O(2) showed concentration-dependent cytotoxicity indicated by decreased "live/dead" cell ratio, increased propidium iodide (PI) staining, increased annexin V binding, increased DNA fragmentation by TUNEL assay, and increased lipid peroxidation by diphenylpyrenylphosphine (DPPP) fluorescence. Compared to Prdx6 null cells, oxidant-mediated damage was significantly less in WT AEC II and was least in Prdx6 Tg cells. Thus, Prdx6 functions as an antioxidant enzyme in mouse AEC II. Prdx6 has been shown previously to reduce phospholipid hydroperoxides and we postulate that this activity is a major mechanism for the effectiveness of Prdx6 as an antioxidant enzyme.     

Intensification of 3,3'-diaminobenzidine precipitation using the ferric ferricyanide reaction, and its application in the double-immunoperoxidase technique

As in double-immunoperoxidase methods, colour mixing usually indicates unwanted interactions between reagents of the first and second sequences, it is desirable to prevent such superimposition of colours by eliciting adequate colour intensity in the first immunoperoxidase sequence. The brown oxidation product of 3,3'-diaminobenzidine (DAB) in the first immunoperoxidase sequence can be intensified by applying the ferric ferricyanide reaction, resulting in intense greenish-blue staining. When the primary antibody is used at a sufficient concentration, cells labelled in the first sequence do not cross-react with the red chromogen, 3-amino-9-ethylcarbazole (AEC), used in the second sequence. Thus, this double-immunoperoxidase method results in different cell populations being clearly labelled in contrasting colours. Primary antibodies from the same species and the same type of link antibodies can be used in the two separate immunoperoxidase sequences. When primary antibodies raised in different species and two types of link antibodies are used, the method can, without loss of sensitivity, be shortened by performing the first two incubation steps simultaneously.     

Antibodies against neuroactive amino acids and neuropeptides. II. Simultaneous immunoenzymatic double staining with labeled primary antibodies of the same species and a combination of the ABC method and the hapten-anti-hapten bridge (HAB) technique.

In the present study we developed an immunoenzymatic double staining technique allowing the simultaneous detection of two neuroactive substances with primary antibodies of the same species and their simultaneous visualization in semithin sections of epoxy-embedded material. For this purpose, primary antibodies against glutamate, GABA, and serotonin were either biotinylated or labeled with the trinitrophenyl (TNP) group. The latter was visualized by a detection system here referred to as the hapten-anti-hapten bridge (HAB) technique. The HAB technique consists of anti-TNP antibodies, serving as bridges between the TNP-ylated primary antibody, and a TNP-ylated marker enzyme, such as alkaline phosphatase. The single components of the HAB technique were optimized by use of a dot-blot assay and an "artificial tissue" system. The optimal staining sequence consisted of TNP-ylated primary antibody with a molar TNP:antibody ratio of 12:1, followed by anti-TNP antibody and TNP-ylated alkaline phosphatase (molar TNP:enzyme ratio of 20:1). No further improvement of detection sensitivity could be obtained when soluble immunocomplexes between anti-TNP antibody and TNP-ylated alkaline phosphatase on the side of phosphatase excess were prepared and used instead of simple TNP-ylated alkaline phosphatase. When compared with other established procedures, such as avidin-conjugated alkaline phosphatase or the ABC method, the HAB technique revealed a similar detection sensitivity. The TNP-ylated primary antibody, however, had to be used at higher concentration than the corresponding unlabeled primary antibody. The suitability of the HAB technique in combination with a modified three-step ABC technique for the simultaneous demonstration of glutamate-like and GABA-like immunoreactivity in the rat brain was demonstrated. The advantages of the new technique in comparison with existing double staining methods are discussed.     

Double autoimmunostaining with glycine treatment.

Double autoimmunostaining by a sequential twice-repeated enzyme-labeled polymer method was examined on archival paraffin sections of formalin-fixed human tissue using an autoimmunostaining apparatus to determine optimal conditions for glycine treatment, to select the best combination of dyes for the horseradish peroxidase-hydrogen peroxide reaction, and to investigate mounting methods for preparing permanent specimens. The optimal glycine treatment determined by changing the incubation time in 0.1 M glycine hydrochloride buffer, pH 2.2, was glycine buffer washing three times for 1 min each, with suppression of nonspecific binding of the primary antibody by protein blocking. Combinations of DAB and AEC, SG and AEC with Ultramount, and DAB and VIP or NovaRED and SG with the VectaMount were found usable for the double autoimmunostaining, based on color analysis of the dyes. Pairs of primary antibodies, CD68 and anti-fascin antibodies CD3 and CD79a, and anti-Ki-67 antigen and anti-p53 antibodies were applicable in double autoimmunostaining with appropriate antigen retrieval for each pair of primary antibodies. Consequently, good sequential double autoimmunostaining should include masking the nonspecific binding of primary antibodies, optimal glycine treatment, and selection of adequate dyes and mounting methods.     

Apoptosis of lung epithelial cells in response to TNF-alpha requires angiotensin II generation de novo

Recent work from this laboratory demonstrated that apoptosis of pulmonary alveolar epithelial cells (AEC) in response to Fas requires angiotensin II (ANGII) generation de novo and binding to its receptor (Wang et al., 1999b, Am J Physiol Lung Cell Mol Physiol 277:L1245-L1250). These findings led us to hypothesize that a similar mechanism might be involved in the induction of AEC apoptosis by TNF-alpha. Apoptosis was detected by assessment of nuclear and chromatin morphology, increased activity of caspase 3, binding of annexin V, and by net cell loss inhibitable by the caspase inhibitor ZVAD-fmk. Purified human TNF-alpha induced dose-dependent apoptosis in primary type II pneumocytes isolated from rats or in the AEC-derived human lung carcinoma cell line A549. Apoptosis in response to TNF-alpha was inhibited in a dose-dependent manner by the nonselective ANGII receptor antagonist saralasin or by the nonthiol ACE inhibitor lisinopril; the inhibition of TNF-induced apoptosis was maximal at 50 microgram/ml saralasin (101% inhibition) and at 0.5 microgram/ml lisinopril (86% inhibition). In both cell culture models, purified TNF-alpha caused a significant increase in the mRNA for angiotensinogen (ANGEN), which was not expressed in unactivated cells. Transfection of primary cultures of rat AEC with antisense oligonucleotides against ANGEN mRNA inhibited the subsequent induction of TNF-stimulated apoptosis by 72% (P < 0.01). Exposure to TNF-alpha increased the concentration of ANGII in the serum-free extracellular medium by fivefold in A549 cell cultures and by 40-fold in primary AEC preparations; further, exposure to TNF-alpha for 40 h caused a net cell loss of 70%, which was completely abrogated by either the caspase inhibitor ZVAD-fmk, lisinopril, or saralasin. Apoptosis in response to TNF-alpha was also completely inhibited by neutralizing antibodies specific for ANGII (P < 0.01), but isotype-matched nonimmune immunoglobulins had no significant effect. These data indicate that the induction of AEC apoptosis by TNF-alpha requires a functional renin/angiotensin system (RAS) in the target cell. They also suggest that therapeutic control of AEC apoptosis in response to TNF-alpha is feasible through pharmacologic manipulation of the local RAS.     

Repeated immunostaining of the same tissue section using alkaline phosphatase as a reporter

One can determine the best dilution of a primary antibody for immunohistochemistry that uses horseradish peroxidase conjugated to a secondary antibody by testing increasing concentrations sequentially on the same tissue section. When the same tissue section is incubated repeatedly with increasing concentrations of primary antibodies to epithelial membrane antigen, smooth muscle α-actin, or vimentin using alkaline phosphatase conjugated to a secondary antibody as the reporter, the best staining was obtained with a less concentrated primary antibody than was optimal for a single staining test. The best concentration of primary antibody for single run staining using an alkaline phosphatase reporting system is usually four times the best concentration for staining with multiple runs. The optimal concentration can be determined by denaturing the residual alkaline phosphatase and extracting residual stain by incubating the section in 4:1 diglyme:phosphate buffered saline for 20 min at 80^o C between tests of primary antibody concentrations. I tested the method for four chromogens from one supplier and one chromogen from a different supplier.     

Efficiency and sensitivity of indirect immunoperoxidase methods

The peroxidase-antiperoxidase (PAP) complex method has repeatedly been claimed to be more sensitive and antibody efficient than the indirect peroxidase labeled antibody method. However, most studies comparing these methods used tissue sections as the test material. However, test systems with known amounts of antigen will allow more reliable comparison of these methods and quantitative evaluation of method sensitivity. We therefore compared the antibody efficiency and sensitivity of these methods for the detection of human chorionic gonadotropin in an enzyme linked immunosorbent assay (ELISA), an antigen spot test (AST) and tissue sections of choriocarcinoma. In the PAP technique rabbit PAP and goat anti-rabbit antibody were applied. The same antibody was peroxidase-labeled with the periodate technique and used in the labeled antibody method. In the ELISA the PAP method resulted in slightly higher antibody efficiency than the labeled antibody method. At low primary antibody dilutions the intensity of the reaction decreased with the PAP method but remained high with the labeled antibody method, in the ELISA as well as on tissue sections. In the AST the labeled antibody method and the PAP method appeared to be equally sensitive.     

Simultaneous demonstration of lectin-binding sites and antigens detected by monoclonal antibodies in a parallelized double-staining technique: a highly discriminative and quickly developing technique for frozen sections

A sensitive immunoenzymatic double-staining technique is presented for the simultaneous visualization of lectin-binding sites and antigenic structures detected by monoclonal antibodies. The lectin is demonstrated by an extended unlabeled peroxidase-antiperoxidase (PAP) technique and the monoclonal antibody by an alkaline phosphatase-antialkaline phosphatase (APAAP) method, which corresponds to the standard PAP technique. 3-amino-9-ethylcarbazole (AEC) and fast blue BB salt serve as substrates for the peroxidase and the alkaline phosphatase, respectively. The antisera and the enzyme complexes raised in different animals enable the performance of three parallel incubation steps. The staining procedure requires three and a half hours altogether. This method proved to be highly discriminative and rather insensitive to interference by various artifacts.     

Identification of two novel markers for alveolar epithelial type I and II cells

Alveolar epithelial type I and type II cells (AEC I and II) are closely aligned in alveolar surface. There is much interest in the precise identification of AEC I and II in order to separate and evaluate functional and other properties of these two cells. This study aims to identify specific AEC I and AEC II cell markers by DNA microarray using the in vitro trans-differentiation of AEC II into AEC I-like cells as a model. Quantitative real-time PCR confirmed five AEC I genes: fibroblast growth factor receptor-activating protein 1, aquaporin 5, purinergic receptor P2X 7 (P2X7), interferon-induced protein, and Bcl2-associated protein, and one AEC II gene: gamma-aminobutyric acid receptor pi subunit (GABRP). Immunostaining on cultured cells and rat lung tissue indicated that GABRP and P2X7 proteins were specifically expressed in AEC II and AEC I, respectively. In situ hybridization of rat lung tissue confirmed the localization of GABRP mRNA in type II cells. P2X7 and GABRP identified in this study could be used as potential AEC I and AEC II markers for studying lung epithelial cell biology and monitoring lung injury.     

The labeled antigen method of immunoenzymatic staining.

A two stage immunohistological technique (the "labeled antigen" procedure) has been assessed for the detection of a variety of human and animal cytoplasmic constituents in tissue sections. In this method specific antiserum is followed by antigen complexed to horseradish peroxidase or to alkaline phosphatase. The primary antibody acts bivalently, linking the labeled antigen to antigen in the tissue section. The major advantage of this technique is that nonantigen specific antibody in the primary antiserum cannot cause nonspecific staining since it has no affinity for the antigen:enzyme complex. Consequently the specificity of the reaction is assured, background staining is minimized and the total staining time (from wax section to mounted slide) can be reduced to as little as 30 min. Further advantages include the possibility of labeling Ig allotypes and the high efficiency of enzyme utilization. Covalent human IgG:horseradish peroxidase complexes can also be used in a triple sandwich in conjunction with human anti-viral or autoimmune antibodies.