Bisbenzimide: a fluorescent counterstain for tissue autoradiography

Interpretation of the data from experiments using autoradiography (e.g. using in situ hybridization histochemistry, receptor binding, neuronal tract-tracing etc.) is aided when the autoradiographic grains can be seen in the context of cellular boundaries. Studies making use of autoradiography in the central nervous system have sometimes used tinctorial stains, such as cresyl violet, as counterstains to visualize the labeling. Tinctorial stains are excellent Nissl stains however, under bright-field illumination such dyes tend to obscure autoradiographic grains. In addition, dark-field illumination provides a common means of visualizing autoradiographic grains but tictorial stains are not optimally visible under these conditions. In an effort to find a counterstain that would be compatible with dark-field illumination, we have investigated the use of fluorescent dyes. Of the fluorescent dyes tested, bisbenzimide (Hoechst 33258) in pH 2.0 buffer was found to be optimal. Bisbenzimide counterstaining gave good resolution of cellular boundaries and appeared not to interfere with the ability to visualize autoradiographic grains. Furthermore, the illumination of bisbenzimide and of the autoradiographic grains could be controlled independently, making it easy to visualize or photograph the bisbenzimide Nissl staining and the autoradiographic grains simultaneously. Thus bisbenzimide is well suited for use as a fluorescent counterstain in autoradiographic studies.     

Photoconversion of DAPI and Hoechst dyes to green and red-emitting forms after exposure to UV excitation

The fluorescent dye 4′-6-Diamidino-2-phenylindole (DAPI) is frequently used in fluorescence microscopy as a chromosome and nuclear stain because of its high specificity for DNA. Normally, DAPI bound to DNA is maximally excited by ultraviolet (UV) light at 358 nm, and emits maximally in the blue range, at 461 nm. Hoechst dyes 33258 and 33342 have similar excitation and emission spectra and are also used to stain nuclei and chromosomes. It has been reported that exposure to UV can convert DAPI and Hoechst dyes to forms that are excited by blue light and emit green fluorescence, potentially confusing the interpretation of experiments that use more than one fluorochrome. The work reported here shows that these dyes can also be converted to forms that are excited by green light and emit red fluorescence. This was observed both in whole tissues and in mitotic chromosome spreads, and could be seen with less than 10-s exposure to UV. In most cases, the red form of fluorescence was more intense than the green form. Therefore, appropriate care should be exercised when examining tissues, capturing images, or interpreting images in experiments that use these dyes in combination with other fluorochromes.     

Ethidium bromide: a nucleic acid stain for tissue section

The phenanthridinium dye, ethidium bromide (EB), selectively intercalates into double-stranded regions of nucleic acids with a large and specific increase in fluorescence. When used for the staining of fixed tissue sections, the dye stains cellular nuclei with excellent resolution of microscopic detail. In some fixed tissues, particularly pancreatic acini, cytoplasm stains intensely and this staining can be abolished by digestion with trypsin and ribonuclease. The orange fluorescence of EB can be easily distinguished from the green fluorescence of fluorescein and EB is thus an excellent counterstain for immunofluorescence. Ethidium bromide is a useful and practical stain for the fluorescence microscopy of tissue sections and, in combination with enzymatic digestion of RNA, provides a simple way to differentially localize DNA and RNA.     

Safranine fluorescent staining of wood cell walls

Safranine is an azo dye commonly used for plant microscopy, especially as a stain for lignified tissues such as xylem. Safranine fluorescently labels the wood cell wall, producing green/yellow fluorescence in the secondary cell wall and red/orange fluorescence in the middle lamella (ML) region. We examined the fluorescence behavior of safranine under blue light excitation using a variety of wood- and fiber-based samples of known composition to interpret the observed color differentiation of different cell wall types. We also examined the basis for the differences in fluorescence emission using spectral confocal microscopy to examine lignin-rich and cellulose-rich cell walls including reaction wood and decayed wood compared to normal wood. Our results indicate that lignin-rich cell walls, such as the ML of tracheids, the secondary wall of compression wood tracheids, and wood decayed by brown rot, tend to fluoresce red or orange, while cellulose-rich cell walls such as resin canals, wood decayed by white rot, cotton fibers and the G-layer of tension wood fibers, tend to fluoresce green/yellow. This variation in fluorescence emission seems to be due to factors including an emission shift toward red wavelengths combined with dye quenching at shorter wavelengths in regions with high lignin content. Safranine fluorescence provides a useful way to differentiate lignin-rich and cellulose-rich cell walls without counterstaining as required for bright field microscopy.     

Tracing of sensory neurones and spinal motoneurones of the pigeon by injection of fluorescent dyes into peripheral nerves

The projection of peripheral sensory and motor nerves was investigated in the pigeon (Columba livia) by means of retrogradely transported fluorescent dyes. Two combinations of fluorescent tracers were used that could be identified within the same cell when excited by light of 405 nm: 1) Propidium iodide and Bisbenzimide, which label the cytoplasm orange and the nucleus blue, respectively; 2) Fast Blue, which labels the cytoplasm blue, and Nuclear Yellow, which labels the nucleus (especially the nucleolar ring) yellow. The presence of the tracers in a given cell was confirmed microspectrophotometrically. Following injection of the tracers into peripheral nerves, labelled sensory neurones were seen in the dorsal root ganglia and motoneurones of the spinal cord. The peroneal and tibial nerves projected to L2-L5 and L2-L7, respectively, whereas the median and ulnar nerves projected to C12-Th2 and C13-Th1. Double-labelled sensory neurones were observed when both peroneal and tibial, or median and ulnar nerves were injected with different tracers. This indicates that some sensory neurones possess peripheral processes that dichotomize to pass down two different peripheral nerves. Double labelling was never seen in motoneurones, or in sensory neurones after tracer injection into the sciatic and femoral nerves.     

Zinc-Specific N-(6-Methoxy-8-Quinolyl)-Para-Toluenesulfonamide as a Selective Nontoxic Fluorescence Stain for Pancreatic Islets

Separation of the endocrine from the exocrine pancreatic tissue by fluorescence activated sorting has been limited by the lack of an ideal fluorescent label for islet tissue. Our studies indicates the zinc-specific stain N-(6-methoxy-8-quinolyl)-para-toluenesulfonamide (TSQ), has characteristics ideal for use as a fluorescent label for islet tissue. Dispersed rat pancreas cells stained with TSQ produced bright blue fluorescence when excited by UV light [peak emission wavelength at 480 nm. maximal excitation at 365 nm). The fluorescence was specific for islet tissue as confirmed by counterstaining with the islet-specific stain dithizone and there was minimal background staining of exocrine tissue. Stained tissue remained brightly fluorescent for 2 hr. with some fading by 4 hr. Injection of TSQ into rats at a concentration sufficient to produce staining of islets produced no toxicity discernible at 4 months. The viability of isolated rat islets stained with TSQ was maintained as shown by supravital staining, in vitro secretion of insulin, and reversal of diabetes after transplantation of stained islets into diabetic syngeneic recipients.     

Newer Applications of the Histological Stain Prepared from Pterocarpus Santalinus

A histological stain prepared from the heartwood of Pterocarpus santalinus Linn, has been found to be an excellent nuclear stain for various cells of animal and plant origin. As an elastic tissue stain, the results are comparable to standard elastic tissue stains. The striations of voluntary muscle fibers are well shown. The Nissl granules and fibers of cranial nerves in the pons are visualized. When counterstained with light green, it differentially stains muscle and fibrous tissue. The stain can be used as counterstain with certain histochemical procedures with satisfactory results. The preparation and use of this versatile stain are described.     

Newer applications of the histological stain prepared from Pterocarpus santalinus

A histological stain prepared from the heartwood of Pterocarpus santalinus Linn. has been found to be an excellent nuclear stain for various cells of animal and plant origin. As an elastic tissue stain, the results are comparable to standard elastic tissue stains. The striations of voluntary muscle fibers are well shown. The Nissl granules and fibers of cranial nerves in the pons are visualized. When counterstained with light green, it differentially stains muscle and fibrous tissue. The stain can be used as counterstain with certain histochemical procedures with satisfactory results. The preparation and use of this versatile stain are described.     

Gallocyanin-chrome alum counterstaining of Golgi-Kopsch impregnations

A simple technique is described for counterstaining Golgi-Kopsch impregnations. The sections are first stabilized by the method of Geisert and Updyke and then stained in 0.15% gallocyanin and 5% chromium potassium sulfate for 45 minutes at 55-60 C. The sections are then rinsed, dehydrated to 70% ethanol, cleared in terpineol, mounted and coverslipped. This procedure results in a light to medium blue stain of those cells not impregnated by the silver chromate. The major advantages of this procedure over earlier methods are: (1) the counterstain does not fade and (2) since no differentiation is required, many sections may be stained simultaneously.     

Staining of Nuclei in Fungi by Ethidium Bromide

Ethidium bromide, (0.1% solution in ethanol-water, 1:3, v/v) was used to stain nuclei in mycelia and spores of different fungi. Nuclei looked bright brick red under green excitation. This method is very efficient, specific, reproducible and cost-effective.     

Tissue Molds for Cryostat Embedding

Ethidium bromide, (0.1% solution in ethanol-water, 1:3, v/v) was used to stain nuclei in mycelia and spores of different fungi. Nuclei looked bright brick red under green excitation. This method is very efficient, specific, reproducible and cost-effective.     

Gallocyanin-Chrome Alum Counterstaining of Golgi-Kopsch Impregnations

A simple technique is described for counterstaining Golgi-Kopsch impregnations. The sections are first stabilized by the method of Geisert and Updyke and then stained in 0.15% gallocyanin and 5% chromium potassium sulfate for 45 minutes at 55-60 C. The sections are then rinsed, dehydrated to 70% ethanol, cleared in terpineol, mounted and coverslipped. This procedure results in a light to medium blue stain of those cells not impregnated by the silver chromate. The major advantages of this procedure over earlier methods are: (1) the counterstain does not fade and (2) since no differentiation is required, many sections may be stained simultaneously.     

Effect of light and phosphate on conidiation in the fungus Verticillium agaricinum

Verticillium agaricinum (Link) Corda, grown in a yeast extract-sucrose medium, conidiated abundantly in darkness after irradiation with near ultraviolet (290–400 nm) for 15 min or blue light (400–550 nm) for 60 min. Few conidia were formed in total darkness. Exposure to 30 min of near ultraviolet light suppressed conidiation. Conidiation was also suppressed by phosphate in excess of 10⁻⁴ M irrespective of light condition. After irradiation with near ultraviolet light for more than 30 min, there was a cessation of growth and a change in colony color from yellow to reddish. The color does not appear to be due to a carotenoid because the colonies turned from red to yellow when covered with acid. At pH lower than 6.0 the pigment has an absorption maximum around 390 nm, whereas at higher pH it is around 540 nm. Thus, it appears that irradiation of V. agaricinum with near ultraviolet may cause an increase in pH, which in turn produces the change of colony color from yellow to reddish.     

ACCLIMATION OF THE PHOTOSYNTHETIC APPARATUS OF PALMARIA PALMATA (RHODOPHYTA) TO LIGHT QUALITIES THAT PREFERENTIALLY EXCITE PHOTOSYSTEM I OR PHOTOSYSTEM II1

Acclimation of the photosynthetic apparatus to light absorbed primarily by phycobilisomes (which transfer energy predominantly to photosystem II) or absorbed by chlorophyll a (mainly present in the antenna of photosystem I) was studied in the macroalga Palmaria palmata L. In addition, the influence of blue and yellow light, exciting chlorophyll a and phycobilisomes, respectively, ivas investigated. All results were compared to a white light control. Complementary chromatic adaptation in terms of an enhanced ratio of phycoerythrin to phycocyanin under green light conditions was observed. Red light (mainly absorbed by chlorophyll a) and green light (mainly absorbed by phycobilisomes) caused an increase of the antenna system, which was not preferentially excited. Yellow and blue light led to intermediate states comparable to each other and white light. Growth was reduced under all light qualities in comparison to white light, especially under conditions preferably exciting phycobilisomes (green light-adapted algae had a 58% lower growth rate compared to white light-adapted algae). Red and blue light-adapted algae showed maximal photosynthetic capacity with white light excitation and significantly lower values with green light excitation. In contrast, green and yellow light-adapted algae exhibited comparable photosynthetic capacities at all excitation wavelengths. Low-temperature fluorescence emission analysis showed an increase of photosystem II emission in red light-adapted algae and a decrease in green light-adapted algae. A small increase of photosystem I emission teas also found in green light-adapted algae, but this was much less than the photosystem II emission increase observed in red light-adapted algae (both compared to phycobilisome emission). Efficiency of energy transfer from phycobilisomes to photosystem II was higher in red than in green light-adapted algae. The opposite was found for the energy transfer efficiency from phycobilisomes to photosystem I. Zeaxanthin content increased in green and blue light-adapted algae compared to red, white, and yellow light-adapted algae. Results are discussed in comparison to published data on unicellular red algae and cyanobacteria.     

LED光质对番茄幼苗生长及内源性GA和IAA含量的影响

采用发光二极管调制光谱能量分布,以荧光灯为对照,研究不同光质(红光、蓝光、黄光、绿光)下番茄幼苗生理特性及内源性GA和IAA水平与其生长的关系。结果表明:(1)红光和蓝光有利于番茄幼苗茎的伸长和叶面积的增加。(2)除蓝光处理下可溶性糖含量和SOD活性与对照无显著性差异外,各单色光质处理下番茄幼苗根系活力、色素含量、可溶性蛋白和可溶性糖含量、SOD活性较对照均显著降低。(3)与对照相比,各单色光质处理下番茄幼苗叶片中GA含量显著降低,IAA含量在红光下显著升高,在黄光和绿光下显著降低,且叶面积与IAA含量呈显著正相关关系。(4)番茄幼苗茎中GA和IAA含量在红光和蓝光处理下显著高于对照和黄、绿光处理,且株高与茎中GA和IAA含量呈正相关关系。     

光强与光质对银杏光合作用及黄酮苷与萜类内酯含量的影响

对2年生银杏（Ginkgo biloba L.)苗进行遮荫和光膜处理,测定光合速率及碳水化合物,银杏黄酮苷与萜类内酯的含量。光合速率在自然光下测定时从大到小依次为：黄膜＞蓝膜和红膜＞绿膜＞紫膜和白膜,在光膜下测定时为：黄膜＞红膜＞蓝膜、紫膜和白膜＞绿膜。光强和光质对碳水化合物含量有显著影响。光质对萜类内酯的生物合成和积累有影响,紫膜处理的银杏萜类内酯含量最高,为3.89mg/g,比白膜（对照） 高85．23％,其次是绿膜,为2．80mg/g。覆膜和蔗荫显著减少银杏黄酮苷含量,这可能与紫外辐射强度减弱有关。     

Development of transgenic fish for ornamental and bioreactor by strong expression of fluorescent proteins in the skeletal muscle

In the present study, new applications of the transgenic technology in developing novel varieties of ornamental fish and bioreactor fish were explored in a model fish, the zebrafish (Danio rerio). Three "living color" fluorescent proteins, green fluorescent protein (GFP), yellow fluorescent protein (YFP), and red fluorescent protein (RFP or dsRed), were expressed under a strong muscle-specific mylz2 promoter in stable lines of transgenic zebrafish. These transgenic zebrafish display vivid fluorescent colors (green, red, yellow, or orange) visible to unaided eyes under both daylight and ultraviolet light in the dark. The level of foreign protein expression is estimated between 3% and 17% of total muscle proteins, equivalent to 4.8-27.2mg/g wet muscle tissue. Thus, the fish muscle may be explored as another useful bioreactor system for production of recombinant proteins. In spite of the high level of foreign protein expression, the expression of endogenous mylz2 mRNAs was not negatively affected. Furthermore, compared to the wild-type fish, these fluorescent transgenic fish have no advantage in survival and reproduction.     

Photoperiodic and light spectral conditions which inhibit circulating concentrations of thyroxine in the male hamster

Adult male Syrian hamsters were exposed daily for 12 weeks to 11 h/day of cool white fluorescent light (350 +/- 50 microW/cm2) followed by an additional 3 h of near ultraviolet (339-317 nm), blue (435-500 nm), green (515-550 nm), yellow (558-636 nm) or red (653-668 nm) light at an irradiance of 0.2 microW/cm2 or to total darkness. Animals exposed to the wavelengths between 558-668 nm (yellow or red half peak bandwidths) or those receiving a total of 13 h of darkness/day had suppressed circulating levels of thyroxine (T4), a depressed free T4 index (FT4I) and a higher T3/T4 ratio compared to animals receiving a total of 14 h of white light (350 +/- 50 microW/cm2). These results suggest that specific wavelengths of light can affect the neuroendocrine-thyroid axis.     

Use of eriochrome cyanine R in routine histology and histopathology: is it time to say goodbye to hematoxylin?

Abstract

Eriochrome cyanine R (ECR) is a synthetic anionic dye that forms complexes with cations such as iron. We found that an iron-ECR (Fe-ECR) mixture provided either nuclear or myelin staining depending on the differentiator used. Selective nuclear staining was obtained by differentiation in an aqueous HCl solution, pH 0.95, followed by a wash in slightly alkaline tap water; the pH difference facilitated control of differentiation. When used with an eosin B counterstain, results were nearly indistinguishable from standard hematoxylin and eosin (H & E) staining. Nuclear staining with Fe-ECR provides tinctorial features similar to regressive aluminum-hemateins as well as resistance to acidic solutions such as those of iron hemateins. Fe-ECR also stained selectively intestinal cells of the diffuse neuroendocrine system (DNES). In addition to its use as an H & E substitute, acid differentiated Fe-ECR produced acid-resistant and selective nuclear counterstaining in combination with Alcian blue, and in the Papanicolaou and van Gieson techniques. With alkali differentiation, Fe-ECR produced selective myelin staining, which was compatible with neutral red counterstaining. Myelin sheaths were stained aqua blue. Fe-ECR could be used for both cytological and histological samples, and was suitable for use in automated tissue stainers. ECR also is less expensive than hematoxylin. Hematoxylin still may be preferred as a nuclear counterstain for some immunostaining methods for which Fe-ECR mixtures probably are too acidic.