Modified Whipf's Polychrome: A Connective Tissue Stain with Special Application for Demonstrating Leishmania

A polychrome stain procedure was developed to demonstrate amastigotes of the protozoan parasite Leishmania braziliensis as well as cytoplasmic and other tissue components in cutaneous lesions of infected animals. The procedure is as follows: stain nuclei for 10 minutes with an iron hematoxylin containing 0.5% hematoxylin and 0.75% ferric ammonium sulfate dissolved in 1:1 0.6 N H₂SO₄:95% ethanol; rinse 4 minutes in distilled water. Cytoplasmic staining is achieved by exposing tissues for 10 minutes to a solution containing 0.25% Biebrich scarlet, 0.45% orange G, 0.5% phosphomolybdic acid and 0.5% phosphotungstic acid in 1% aqueous acetic acid. These first two solutions are modified from Whipf's polychrome stain. Sections are differentiated for 10 seconds in 50% ethanol, rinsed in water, stained 3 minutes in 0.1% aniline blue WS in saturated aqueous picric acid, rinsed in water and differentiated for 1 minute in absolute ethanol containing 0.05% acetic acid. Mordanting overnight in 6% picric acid in 95% ethanol produced optimal results.

This procedure was applied to sectioned material from experimental animals with various protozoa. Trypanosoma cruzi, Besnoitia Jellisoni, Toxoplasma gondii and especially Leishmania braziliensis were well demonstrated. Combining cytoplasmic dyes and phosphomolybdic-phosphotungstic acids into one solution afforded differential staining of tissues by Biebrich scarlet and orange G; connective tissues were stained by this solution. Substantially improved definition of connective tissues resulted after counterstaining. This procedure differs from the Massou sequence in which connective tissues are first stained by cytoplasmic dyes along with other tissues and then destained prior to specific counter-staining. in comparing dyes structurally related to Biebrich scarlet, it was found that Crocein scarlet MOO, but not Poncenu S, was an acceptable substitute. Sirius supra blue GL and Sirius red FSBA were not useful as replacements for aniline blue WS in this procedure.     

Reduced Methylene Blue as a Stain for Crustacean Nerves

Effective in situ staining of crustacean nerves was achieved with leuco methylene blue reduced with either ascorbic acid or sodium hydrosulfite (Na₂S₂O₄). A stock solution of methylene blue, 0.4% (ca. 0.001 M), and the reductants, ascorbic acid or sodium hydrosulfite (0.01 M), were prepared in van Harreveld's crayfish physiological solution. Methylene blue stock solution was mixed with either of the reductants in the approximate ratio of 1:10, v/v, and titrated to the end point. Ascorbic acid reduction is light catalyzed and requires intense illumination during titration. The cleared or leucomethylene blue stock solution is suitable for immediate use as a working nerve stain. With either reductant, the working solution oxidizes on standing in air, but can be titrated repeatedly without loss of staining properties. Dissected nerve trunks or tissue were immersed in the working stain for 20 min at room temperature and the staining process observed until suitable contrast developed. Excess dye was decanted and the tissues flooded with crayfish physiological solution. Contrast could sometimes be enhanced by flooding the stained area with 1% hydrogen peroxide in van Harreveld's solution. When permanent mounts were prepared, tissues were dehydrated with tertiary butyl alcohol in preference to ethyl alcohol series. For anatomical and neurophysiological studies of nerve distribution in crustaceans, the alternative use of either ascorbic acid or sodium hydrosulfite, as reductants for methylene blue, was preferable to the more complicated rongalit-technique and characterization of neural elements was fully as satisfactory.     

Chlorazol Fast Pink as an in Vivo Stain for Unmineralized Bone and Tooth Matrix

The present investigation was carried out with the intention of using in vivo injections of chlorazol fast pink to mark the beginnings of bone formation in experimental skeletal fluorosis. Experiments show, however, that any uncalcified osteoid stains red, irrespective of whether it has been recently laid down or not. The staining is acid fast and hard tissues can be decalcified without loss of the dye. In vivo staining of the matrix by chlorazol fast pink does not appear to affect the growth of the tissue or its subsequent calcification and, therefore, provides a means of labelling bone surfaces at any stage during a continued experiment. Chlorazol fast pink is readily released from bone matrix by the β toxin of Clostridium histolyticum but not by other proteinases, which suggests that the dye is attached to collagen. The matrix of dentine differs from that of bone in that it is attacked both by the β toxin and the γ toxin of Clostridium histolyticum. No explanation of this difference between bone and dentine can be given.     

Unmasking of Proteins by in Vitro Methylation of Rat Liver Rna During Azo Dye Carcinogenesis

In liver parenchyma of rats fed the azo dye 4-dimethylaminoazobenzene cytoplasmic ribonucleic acid (RNA) stains intensely with toluidine blue in sites of neoplastic transformation and hepatomas. With the mercury-bromphenol blue method, the staining intensity of proteins was found to be much weaker in these areas than in surrounding tissue. A 4 hr treatment at 60 C in a mixture of methanol and HCI completely abolished the increased staining of RNA with toluidine blue, but restored protein stainability with bromphenol blue in preneoplastic foci and tumors; the staining intensity of proteins was then comparable to that in surrounding liver. These results suggest that proteins were masked by the RNA responsible for hyperbasophilia, and that in vitro addition of methyl groups to such RNA is equal in effect to RNase extraction which was previously found to unmask cytoplasmic proteins.     

An Evaluation of the Metachromasy of Anionic Dyes. I. Visual Observations on Tissue Sections

Thirteen dyes of the azo (benzopurpurin, Congo red, trypan blue, chromotrope 2R, orange G), indigoid (indigocarmine), triphenylmethane (acid fuchsin, aniline blue, light green, methyl blue), and xanthene (eosin B, eosin Y, erythrosin B) groups were applied under standard conditions to a variety of human, rabbit, rat, mouse and frog tissues in paraffin sections. Sections were examined for color changes which might indicate metachromatic reactions analogous to the metachromasy of cationic dyes. Disazo and xanthene dyes showed shifts in hue, with some qualification on the shifts of xanthenes. Metachromatic shifts of anionic dyes were generally of low order compared to those of cationic dyes. Nuclei, erythrocytes, inner elastic laminae of arteries, keratinous structures, and certain areas in the ground substance of connective tissue most often elicited metachromasy. It is suggested that basic proteins are responsible for the metachromatic reactions. Equally interesting areas were those staining poorly (cartilage matrix, most types of mucus), since these are sites of highly acidic substances capable of binding proteins.     

Hoechst 33342 Staining Coupled with Conventional Histological Technique

Hoechst 33342 was injected either intravenously or intraperitoneally into mice which were killed 1 or 24 hr or 7, 14 or 28 days later. Various organs were fixed and paraffin embedded. Visual inspection showed that independently of the route of dye administration or survival time, distinct fluorescence of nuclei was observed in organs other than cerebral cortex. Even formic acid decalcification of bone failed to abolish the fluorescence of osteocytes. In vivo staining with Hoechst 33342 is proposed as an alternative for staining after sectioning. Cells from spleens of Hoechst 33342-injected mice or stained in vitro were injected intramuscularly into mice. Hoechst 33342-stained splenocytes could be found in deparaffinized sections at the site of injection 24 hr later.     

Vital Staining of Newly Formed Areas of Compact Bone with Chlorazol Fast Pink

The dense connective tissues of the mouse and cat are selectively stained following the vital introduction of chlorazol fast pink. In addition, the newly formed areas of bone and of cartilage are intensely stained, while other areas of these two tissues are unstained. The staining reactions of this dye parallel that of trypan blue, vitally as well as in vitro.     

Alizarin Red S and Toluidine Blue for Differentiating Adult or Embryonic Bone and Cartilage

This technic has been successfully employed by the author for staining, in toto, the bones and cartilage of mature specimens of Urodela and the developing bone and cartilage of the embryonic human, cat, pig and rat. The differential staining is accomplished by using a modification of Dawson's method of staining bone with alizarin red S following a toluidine blue solution specific for cartilage. Specimens are fixed in 10% formalin, stained one week in a solution of .25 g. of toluidine blue in 100 cc. of 70% alcohol, macerated 5 to 7 days in a 2% KOH solution, counterstained for 24 hours in a 0.001% solution of alizarin red S in 2% aqueous KOH, dehydrated in cellosolve and cleared in methyl salicylate. In the adult and embryonic forms thus treated the soft tissues are cleared while the osseous tissue is stained red, the cartilage blue.     

Supravital Uptake of Methylene Blue by Dendritic Cells within Stratified Squamous Epithelia: a Light and Electron Microscope Study

Electron microscopic data on methylene blue staining of dendritic cells in the epithelia of the soft palate and skin of the moose after supravital dye injection are presented. The ultrastructural details were compared with corresponding light microscopic findings. Methylene blue stained tissue was fixed by immersion in a paraformaldehyde-glutaraldehyde solution containing phosphomolybdic acid. The ensuing dye precipitate was stabilized by ammonium heptamolybdate. The light microscopic investigation revealed that selective staining of dendritic cells depended on the presence of ambient oxygen. In addition, delicate morphological characteristics, like spinous structures of the dendrites, were visible. Some cells also showed terminal enlargements of the dendrites close to the surface of the epithelium. In general, visualization of morphological detail was superior to that obtained by conventional histological and immunohistochemlcal procedures. Nerve fibers were also stained within the epithelium as well as the subepithelial connective tissue. At the electron microscopic level, the dye was clearly identified as an electron dense precipitate that accumulated primarily within the cytoplasm near the plasma membrane. Furthermore, it was bound to the chromatin of the nuclei. No significant staining of mitochondria or other organelles was seen, within the cytoplasm, the oxygen-dependent binding sites may be associated with heme proteins that attract both the dye in its reduced lipophilic leuco form and oxygen, followed by generation of oxygen radicals and a reoxldation of the leuco form to the cationic blue dye. Because of its selectivity for intraepithelial dendritic cells, the method described here supplements immunocytochemical procedures at both the light and electron microscopic levels.     

A Suction Device for Easy Handling of Glass Coverslips

Electron microscopic data on methylene blue staining of dendritic cells in the epithelia of the soft palate and skin of the moose after supravital dye injection are presented. The ultrastructural details were compared with corresponding light microscopic findings. Methylene blue stained tissue was fixed by immersion in a paraformaldehyde-glutaraldehyde solution containing phosphomolybdic acid. The ensuing dye precipitate was stabilized by ammonium heptamolybdate. The light microscopic investigation revealed that selective staining of dendritic cells depended on the presence of ambient oxygen. In addition, delicate morphological characteristics, like spinous structures of the dendrites, were visible. Some cells also showed terminal enlargements of the dendrites close to the surface of the epithelium. In general, visualization of morphological detail was superior to that obtained by conventional histological and immunohistochemlcal procedures. Nerve fibers were also stained within the epithelium as well as the subepithelial connective tissue. At the electron microscopic level, the dye was clearly identified as an electron dense precipitate that accumulated primarily within the cytoplasm near the plasma membrane. Furthermore, it was bound to the chromatin of the nuclei. No significant staining of mitochondria or other organelles was seen, within the cytoplasm, the oxygen-dependent binding sites may be associated with heme proteins that attract both the dye in its reduced lipophilic leuco form and oxygen, followed by generation of oxygen radicals and a reoxldation of the leuco form to the cationic blue dye. Because of its selectivity for intraepithelial dendritic cells, the method described here supplements immunocytochemical procedures at both the light and electron microscopic levels.     

A Method for Injecting Insect Tracheae Permanently

By the use of an alcohol insoluble dye (trypan blue), acetic acid, and a detergent (“Santomerse No. 3”), a resulting dye solution is obtained which will completely penetrate the tracheal system of an insect. The dye is injected by the use of a vacuum and by the pressure produced when the air is allowed to re-enter the dye vessel. The dye itself is permanently fixed in the tracheae by means of a fixing solution containing alcohol, acetic acid and barium chloride as its components. The material must be properly preserved after staining. It may be stored indefinitely in 70% alcohol, xylol, cedar oil or clove oil, depending on whether the material is to be used for sectioning or for whole mounts. Injected material may be sectioned in either celloidin or paraffin, or may be cleared and mounted in toto.     

Basic Two-Dye Stains for Epoxy-Embedded 0.3-1 μ Sections

Dyes used in the 3 methods recommended are: I, thionin and acridine orange (T-AO); II, Janus green and Darrow red (JG-DR); III, methyl green and methyl violet (MG-MV). The first 2 methods were two-solution stains, applied in sequence; the third, required only one solution since methyl violet is present in commercial methyl green. Staining solution and timing was as follows: Method I. 0.1% thionin in a 45% ethanolic solution of 0.01 N NaOH, 5 min at 70 C; rinsing in water and followed by 1 min in a 1% aqueous solution of acridine orange made up in 0.02 N NaOH, also at 70 C, then washed, and dried on slides. Method II. 0.5% Janus green in aqueous 0.05 N NaOH, 5 min at 70 C; rinsing in water then into 0.5% Darrow red in 0.05 N NaOH (aq.), 2 min at 70 C., washing, and drying on slides. Method III. 1% methyl green (commercial, unpurified) in 1% aqueous borax for 15-20 min at 20-25 C, washing and attaching to slides. All staining was performed by floating the sections on the staining solutions, all drying at 70 C, and mounting in a resinous medium. T-AO gave blue to violet cytoplasmic structures, darker nuclei which contrasted strongly with yellow connective tissue and the secretion of goblet cells. JG-DR resembled a hematoxylineosin stain, but by shortening the staining time in DR to 0.5-1 min, collagenous and elastic tissue retained more of the green dye. MG-MV gave dark green nuclei in light green cytoplasm, with collagenous and elastic tissues in blue to violet. As with most methods for staining ultrathin sections, thicknesses of less than 1 μ required longer staining times.     

In Vivo Staining by Dis and Trisazo Dyes, Especially of Bone and Elastic Tissue

The localization and retention of dis and trisazo dyes in connective tissues and bone was studied in rats and rabbits. Chlorazol fast pink, 5% in 0.9% NaCl. was injected intraperitoneally, 25 mg/kg each day for 2 days in newborn, growing, mature and 17-18 day pregnant rats, and up to 5 days in young rabbits. The dye was also injected at different time intervals during the development of strontium-induced rickets in growing rats, and in animals with abscess walls following subcutaneous injection of 0.1 ml turpentine. Animals were killed at-intervals thereafter, and comparison of in vivo staining of 5% solutions of chlorazol fast pink, chlorantine fast red, chlorazol black E, chlorazol sky blue, chlorazol sky pink, chlorazol green, chlorazol violet, pontamine green and pontamine sky blue was made by intraperitoneal injection in rats. Soft and hard tissue specimens were embedded in polyester resin or in paraffin wax and sectioned at 5-7 μ. Chlorazol fast pink stained some connective tissues and growing bones. The main intensity of staining occurred within 24 hr and gradually decreased but was still detectable after 6 mo in elastic tissues. In thin plastic sections, colouration was brilliant, not in osteoid tissue, but at calcifying bone margins and in elastic fibres. Dye localized at calcifying bone margins was incorporated within calcified tissues and then subsequently lost through remodelling. Such staining was not seen in paraffin-embedded material. Dye uptake was greatly reduced in rachitic rats, and wide osteoid seams were coloured faint pink, but where calcification was still occurring, colouration was brilliant. Similarly collagenous tissue in abscess walls was only lightly stained, in contrast to brilliant colouration of elastic tissues and macrophages. Of the 9 dyes tested, only chlorazol fast pink and chlorazol sky blue stained bone and elastic tissue in vivo. This prolonged retention and staining by these 2 dyes, unlike the others, was associated with their presence in the proximal convoluted tubules of the kidney.     

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.     

Monitoring of Epoxy Block Trimming by the Use of a Laterally Mounted Mirror

Mounting a small mirror on the side of the knife holder of an ultramicrotome permits the monitoring of selected areas during epoxy block trimming without removing the block from the chuck. This technique is particularly useful for trimming toward preselected areas of in situ embedded cell cultures for subsequent sectioning. When the visibility of the embedded cells is improved by staining with Paragon-1301 or toluidine blue before embedment, such mirror monitoring can be carried out at magnifications up to 40 times during the trimming procedure.     

A Method for Preparing and Staining Histological Sections Containing Titanium Implants for Light Microscopy

An improved method for preparing and staining ground tissue-implant sections for light microscopy is presented. Undecalcified tissue blocks with titanium implants were dehydrated in an ascending series of ethanol and stained in toto with basic fuchsin. Specimens were infiltrated and embedded in methyl methacrylate and sections were prepared using a cutting-grinding-system. The polished surface was counterstained with light green or anilin blue. Light polymerizing resin was used as slide mounting medium and for mounting the coverglass. The sections obtained were 10-15 μm thick with tissue architecture which clearly differentiated structures at the tissue-implant interface. The method was very useful for computer assisted morphometric analysis.     

Insight into generation of induced mesenchymal stem cells from induced pluripotent cells

Mesenchymal stem cells(MSCs)have the potential for use in cell-based regenerative therapies.Currently,hundreds of clinical trials are using MSCs for the treatment of various diseases.However,MSCs are low in number in adult tissues;they show heterogeneity depending upon the cell source and exhibit limited proliferative potential and early senescence in in vitro cultures.These factors negatively impact the regenerative potential of MSCs and therefore restrict their use for clinical applications.As a result,novel methods to generate induced MSCs(iMSCs)from induced pluripotent stem cells have been explored.The development and optimization of protocols for generation of iMSCs from induced pluripotent stem cells is necessary to evaluate their regenerative potential in vivo and in vitro.In addition,it is important to compare iMSCs with primary MSCs(isolated from adult tissues)in terms of their safety and efficacy.Careful investigation of the properties of iMSCs in vitro and their long term behavior in animals is important for their translation from bench to bedside.     

The role of phosphotungstic and phosphomolybdic acids in connective tissue staining I. Histochemical studies

Synopsis An investigation of the role of phosphotungstic and phosphomolybdic acids in Mallory-like trichrome methods showed unexpectedly that, rather than acting as mordants to anionic dyes, these polyacids selectively blocked staining of all tissue components other than connective tissue fibres to Aniline Blue and other similar fibrereactive dyes. Connective tissue components were found to contain residues resembling histidine that are easily accessible to anionic dyes. Blocking towards typical anionic dyes for demonstrating plasma proteins, such as Biebrich Scarlet, was also demonstrated but was less complete. The blockade of both types of dye was labile if the staining times were extended; plasma dyes were more sensitive than fibre dyes in this respect. Histochemical reactions for tyrosine residues were blocked. In connective tissue, phosphotungstic acid did not block histidine residues demonstrable by the coupled tetrazonium reaction with previous iodination. Thus it is postulated that differential trichrome staining occurs by binding of Aniline Blue to basic residues in the connective tissue not blocked by phosphotungstic acid and subsequent replacement of the blocking agent by an anionic dye. The binding of phosphotungstic acid to both epithelium and connective tissue was demonstrated by the quenching of autofluorescence in these regions and by the reduction of the bound PTA to blue coloured products with titanium trichloride.     

毛木耳对孔雀石绿染料降解条件的优化

随着我国印染工业的发展,废水对生态环境的危害日趋严重,亟需开发一种脱色明显且成本低廉的降解方法。本研究发现毛木耳Auricularia cornea菌株AC5对不同结构的染料均具有一定的降解作用,尤其是三苯甲烷类染料。利用26℃、160r/min振荡培养7d的粗酶液对染料（75.0mg/L）进行12h降解,结果显示三苯甲烷染料孔雀石绿、结晶紫,蒽醌染料活性蓝19和偶氮染料活性蓝222的降解效率分别为83.27%、71.77%、67.81%和63.92%。染料降解实验和酶活力测定结果表明,毛木耳对孔雀石绿的降解率达到最高时漆酶活性最高,为321.0U/mL,木质素过氧化物酶和锰过氧化物酶活性较低。因此,推测在降解过程中漆酶起到主要作用。研究表明利用毛木耳菌丝发酵液降解染料废水成本低且操作方便,为染料废水的降解研究提供了前期基础。     

中华蜜蜂酪胺受体基因克隆及表达分析

酪胺(tyramine)属于生物多聚胺类,是昆虫中枢神经系统内重要的神经递质、神经调质和神经激素,参与调控昆虫的多种行为和生理过程,如酪胺受体基因参与调控动物的学习与记忆。本研究首次克隆获得中华蜜蜂(Apis cerana cerana)酪胺受体基因Actyr1和Actyr2的全长cDNA序列,利用qRT-PCR方法鉴定了Actyr1和Actyr2在中华蜜蜂不同组织器官中的表达谱,采用地高辛原位杂交技术对Actyr1和Actyr2在大脑中的表达进行了定位。中华蜜蜂Actyr1、Actyr2的cDNA全长序列分别为1241 bp(GenBank登录号：KC814693)和1270 bp(GenBank登录号：KC814694),分别编码297、399个氨基酸残基。qRT-PCR分析结果表明,Actyr1和Actyr2在不同组织中的表达量为头部最高,其次是腹部表皮,触角和胸部肌肉的表达量最低,并且头部的表达量显著高于其他组织的表达量;原位杂交结果显示,Acytr1和Actyr2在中华蜜蜂大脑蘑菇体的凯尼恩细胞、触角叶周围的细胞处均有较强阳性着色。这些研究表明,Acytr1和Actyr2基因可能参与了蜜蜂的学习记忆,并且在相同的细胞中互相作用,共同调控蜜蜂的生物学功能。