A Staining Sequence for A, B and D Cells of Pancreatic Islets

Recent investigations strongly suggest the elaboration of a third pancreatic hormone by the D cell and the existence of cells which show the staining properties of both B and D cells. Demonstration of these and all other islet cells in a single section is possible by the following staining sequence: (1) of D cells by silver or toluidine blue, (2) of B cells by pseudoisocyanin, and (3) empirical staining of all islet cells together by aldehyde fuchsin, ponceau de xylidine, acid fuchsin and light green. Difficulties in embedding compact pancreatic tissue can be overcome by dehydrating to 80% ethanol, followed by tetrahydrofurane as the intermediate fluid to paraffin infiltration.     

Differentiation of Cells in the Hypophysis and in Pancreatic Islets

Deparaffinized, 3-5μ, sections are brought to water, oxidized 3.5 min in an equal-parts mixture of 0.3% H₂SO₄ and 0.3% KMnO₄, and decolorized with 4% K₂S₂O₅. Nuclei are stained with Gomori's (1939) chromium-hematoxylin, and cell granules with Cason's (1950) mixture. The eosinophilic cells of the hypophysis and the alpha cells of pancreatic islets (of Langerhans) stain carmine red; basophilic and beta cells stain dark blue. Heidenhain's _susa is the most suitable fixative for hypophysis, Bouin's fluid for pancreas; but a satisfactory result is obtainable after formalin-sublimate or plain formalin. Besides studying the ratio of the cell types in the hypophysis or in pancreatic islets, it is possible to estimate the granule content of the cells. The method works on human autopsy material provided fixation of hypophysis occurs within 24 hr, and. pancreas, 12 hr post mortem, and it is suitable also for quite fresh organs.     

Differentiation of Cells in the Hypophysis and in Pancreatic Islets

Deparaffinized, 3-5μ, sections are brought to water, oxidized 3.5 min in an equal-parts mixture of 0.3% H₂SO₄ and 0.3% KMnO₄, and decolorized with 4% K₂S₂O₅. Nuclei are stained with Gomori's (1939) chromium-hematoxylin, and cell granules with Cason's (1950) mixture. The eosinophilic cells of the hypophysis and the alpha cells of pancreatic islets (of Langerhans) stain carmine red; basophilic and beta cells stain dark blue. Heidenhain's _susa is the most suitable fixative for hypophysis, Bouin's fluid for pancreas; but a satisfactory result is obtainable after formalin-sublimate or plain formalin. Besides studying the ratio of the cell types in the hypophysis or in pancreatic islets, it is possible to estimate the granule content of the cells. The method works on human autopsy material provided fixation of hypophysis occurs within 24 hr, and. pancreas, 12 hr post mortem, and it is suitable also for quite fresh organs.     

Differential Staining of Gastric Glandular Cells

Fundus of stomach is fixed in 10% formalin (aqueous), Bouin's fluid or 5% trichloracetic acid (aqueous). It is embedded in paraffin, and 7μ sections are cut, mounted, deparaffinized and passed to 70% alcohol and then stained as follows: Mordant 3 min. in saturated Bismarck brown in 70% alcohol. Rinse in 70% alcohol, pass to distilled water, then overstain (2 hr.) in aniline blue, 0.5% solution in 2.5% acetic acid (aqueous). Precipitate the anilin blue with 0.5 ml. of 0.1% methyl violet solution (aqueous) dropped on die slide. Leave on 2 min. or less. Wash and differentiate in 70% alcohol. (Parietal cells dark blue). Stain 30 min. in a mixture of hematein, 0.10g.; A1C13 cryst., 0.05g.; and 70% alcohol 50 ml., prepared just before use and not filtered. Rinse in 70% alcohol and differentiate with an alcoholic extract of saffron (2 g. saffron pistils in 100 ml. 90% alcohol at 60°C. for 6 hr.) while observing the progress of differentiation microscopically. Dehydrate by dropping a 0.1 % solution of acetic acid in absolute alcohol on the section for 30 sec., followed by pure absolute alcohol, xylene, and covering in balsam.     

Differential Staining of Gastric Glandular Cells

Fundus of stomach is fixed in 10% formalin (aqueous), Bouin's fluid or 5% trichloracetic acid (aqueous). It is embedded in paraffin, and 7μ sections are cut, mounted, deparaffinized and passed to 70% alcohol and then stained as follows: Mordant 3 min. in saturated Bismarck brown in 70% alcohol. Rinse in 70% alcohol, pass to distilled water, then overstain (2 hr.) in aniline blue, 0.5% solution in 2.5% acetic acid (aqueous). Precipitate the anilin blue with 0.5 ml. of 0.1% methyl violet solution (aqueous) dropped on die slide. Leave on 2 min. or less. Wash and differentiate in 70% alcohol. (Parietal cells dark blue). Stain 30 min. in a mixture of hematein, 0.10g.; A1C13 cryst., 0.05g.; and 70% alcohol 50 ml., prepared just before use and not filtered. Rinse in 70% alcohol and differentiate with an alcoholic extract of saffron (2 g. saffron pistils in 100 ml. 90% alcohol at 60°C. for 6 hr.) while observing the progress of differentiation microscopically. Dehydrate by dropping a 0.1 % solution of acetic acid in absolute alcohol on the section for 30 sec., followed by pure absolute alcohol, xylene, and covering in balsam.     

The Demonstration of Beta Cells in Pancreatic Islets and Their Tumors

The stain is applied routinely to tissues fixed in 10% buffered formalin (pH near 7.0) or in Bouin's fluid. Bring paraffin section to water as usual and mordant 72 hr in 5% CrCl₃ dissolved in 5% acetic acid. Wash in water and in 70% alcohol and stain 6 hr. Formula of staining solution: new fuchsin, 1% in 70% alcohol, 100 ml; HCl, conc., 2 ml and paraldehyde, 2 ml, mixed together and added to the dye solution; let stand 24 hr before use. After staining, wash in running tap water 5-10 min, rinse in distilled water and counterstain if desired. Dehydration in alcohol, clearing and covering completes the process. When the paraldehyde is obtained from a freshly opened bottle, standardized staining times can be used and thus eliminate the necessity of differentiating individual slides. The granules of beta cells stained deep blue to purple and were demonstrated in the pancreatic islet of man, dog, mouse, frog, guinea pig and rabbit.     

A Historical Perspective on the Identification of Cell Types in Pancreatic Islets of Langerhans by Staining and Histochemical Techniques

Before the middle of the previous century, cell types of the pancreatic islets of Langerhans were identified primarily on the basis of their color reactions with histological dyes. At that time, the chemical basis for the staining properties of islet cells in relation to the identity, chemistry and structure of their hormones was not fully understood. Nevertheless, the definitive islet cell types that secrete glucagon, insulin, and somatostatin (A, B, and D cells, respectively) could reliably be differentiated from each other with staining protocols that involved variations of one or more tinctorial techniques, such as the Mallory-Heidenhain azan trichrome, chromium hematoxylin and phloxine, aldehyde fuchsin, and silver impregnation methods, which were popularly used until supplanted by immunohistochemical techniques. Before antibody-based staining methods, the most bona fide histochemical techniques for the identification of islet B cells were based on the detection of sulfhydryl and disulfide groups of insulin. The application of the classical islet tinctorial staining methods for pathophysiological studies and physiological experiments was fundamental to our understanding of islet architecture and the physiological roles of A and B cells in glucose regulation and diabetes.     

Optimizing Conditions for Rat Pancreatic Islets Isolation

Many procedures have been described for rat pancreatic islet isolation. Several factors contribute to the pancreatic islet isolation outcome. One of the main problems in islet isolation procedure is the formation of a viscouse, gellike structure during collagenase digestion which entraps the free islets and decrease islet yield after density gradient purification. This issue has not been addressed in most techniques described for rat islet isolation. We examined effect of various factors to eliminate formation of gellike material and improve the islets yields. Islet isolation was performed on 26 adult male Wistar Albino rats weighing between 280 and 350 g. We have observed that several factors affect pancreatic islet isolation. Optimum Collagenase enzyme concentration, maintaining pH range between 7.7 and 7.9 in digestion solution, incubation temperature at 38±1 °C and addition of Calcium ion decreased the formation of gellike materials and increased islet yield. Addition of Glycerol as a gelatin solvent has also been helpful in the reduction or complete elimination of gellike material. Precise optimization of rat islet isolation procedure is useful to improve the islet yield in islet transplantation studies.     

大鼠胰岛分离条件的优化

目的:优化大鼠胰岛分离纯化的条件,为胰岛移植实验奠定基础。方法:通过胆总管灌注胶原酶P来消化大鼠胰腺,分离胰岛,采用不连续密度梯度Ficoll离心法纯化胰岛,观察胶原酶浓度、消化时间以及大鼠体重对胰岛分离结果的影响。双硫腙染色鉴定胰岛,丫啶橙/碘丙啶染色鉴定胰岛细胞活率,糖刺激胰岛素释放试验评价胰岛功能。结果:胶原酶浓度、消化时间以及大鼠体重对胰岛分离结果有重要影响。1mg/ml胶原酶P在37℃静止消化45分钟条件下,胰岛分离效果最佳,效果较其他酶浓度和消化时间条件下好(P＜0．05)。体重350g的大鼠的胰岛收获量778．33±80．21IEQ/胰腺,而体重250g的大鼠的胰岛收获量655．00±56．56 IEQ/胰腺(P＜0．05)。优化条件下分离的胰岛其纯度＞90%,胰岛细胞活率＞90%,低糖(2．8mmol/L)、高糖(16．7mmol/L)刺激胰岛素释放分别为(5．40±1．75)mIU/L/30IEQ,(12．27±2．55)mIU/L/30IEQ(P＜0．05),刺激指数为2．33±0．29。结论:胶原酶浓度、消化时间以及大鼠体重影响胰岛分离结果,优化分离条件可改善大鼠胰岛分离结果。     

A Differential Staining Technique for Simultaneous Visualization of Mitotic Spindle and Chromosomes in Mammalian Cells

A new technique has been devised for staining the mitotic spindle in mammalian cells while preserving spindle structure and chromosome number. The cells are trypsinized and fixed with a 3:1 methanobacetic acid solution containing 4 mM MgCl₂ and 1.5 mM CaCl₂ at room temperature. The cells are then placed on slides and treated with 5% perchloric acid before staining with a 10% acetic acid solution containing safranin O and brilliant blue R. The preserved spindles appear dark blue against a light cytoplasmic background with chromosomes stained bright red. Individual chromosomes and chromatids are clearly visible. Positioning of the chromosomes relative to the spindle apparatus is readily ascertained allowing easy study of mitotic spindle and chromosome behavior.     

Differential Staining of Tannin in Sections of Epoxy-Embedded Plant Cells

A staining procedure is described for the light microscopic localization of ergastic tannins in epoxy sections of plant cells embedded for study by transmission electron microscopy. Callus and cell suspensions of Pseudotsuga menziesii and Pinus taeda fixed in glutaraldehyde:acrolein and then OsO₄, followed by epoxy embedding, were sectioned 0.5 μn thick, stained on a glass slide with ethanolic Sudan black B at 60 C as described by Bronner, and then mounted in Karo syrup. Tannin deposits stained brownish-orange and were easily distinguished from lipid bodies of similar size, which stained dark blue to black, and from starch grains, which were unstained. The significance of this differential polychromasia was confirmed by transmission electron microscopy. This staining proadure should prove valuable in the cytoplasmic evaluation of the plant cell ergastics (especially tannins) via light microscopy whether or not electron microscopic examination is intended.     

Basic Fuchsin-Crystal Violet; A Rapid Staining Sequence for Juxtaglomerular Granular Cells Embedded in Epoxy Resin

A basic fuchsin-crystal violet staining sequence for demonstration of juxtaglomerular granular cells in epoxy-embedded tissues is rapid and results in slides with excellent contrast and intensity. Procedure: Cut sections 0.3-0.6 μ thick. Hydrate through xylene and alcohol to water. Stain in modified Goodpasture's stain (basic fuchsin, 1; aniline, 1; phenol, 1; 30% alcohol, 100) for 20-30 sec; rinse in tap water; stain in modified Stirling's (crystal violet, 5; alcohol, 10; aniline, 2; water, 88) for 20-30 sec; rinse in tap water and dry on a hotplate; mount in a synthetic resin. Granular cells of the juxtaglomerular apparatus are stained an intense dark blue by the crystal violet. Arterial elastic membranes and collagen are pale blue. Other structures are shades of red.     

The Pancreatic Islets of Bony Fishes

The biology of the fish endocrine pancreas is discussed fromviewpoints of cytology, peripheral physiology, and control ofislet secretion. The clear cell often described in Brockmannbodies is probably not a real entity, but the islets of manyfish species probably contain a fourth granular cell type inaddition to the usual population of A-, B-, and D-cells. Numerousstudies employing islet cytotoxins and exogenous hormone treatmentshave been reported, but a unified concept of islet functionin any fish species still does not exist. Recent data indicatethat metabolic parameters other than blood sugar must be measuredin order to obtain a more accurate assessment of islet function.The direct relationship of the nervous system to islet endocrinecells also raises questions regarding the control of islet secretionand necessitates consideration of laboratory conditions andseasonal or diurnal variation as probable influencing factorsof islet activity.     

Comparative Histophysiology of the Pancreatic Islets

The embryological origin of the islet tissue from a common entodermalanlage with the exocrine pancreas has been questioned recently.The islet tissue may be of. neural crest origin, and the ancestralislet cells may have been "taste cells in the gut." Whether the separation of exocrine and endocrine tissue in thecyclostomes is an original one or not remains an open phylogenetickey question. One or more islet hormones affect the exocrine pancreas tissue.However, the islet topography in various groups shows that intrapancreaticislet dissemination is not a general prerequisite for the normalfunction of the exocrine tissue. The D-cell is now generally recognized as the source of a thirdislet hormone. A fourth granular cell type (X-cell) may wellsecrete a fourth islet hormone. The significance of the amphiphilislet cells, found in various species, and of the "light" cellsof the cyclostomes requires further studies. The islet function in lower vertebrates is largely unknown.So far, neither the islet cytology nor the known effects ofpancreatectomy allow far-reaching conclusions. The evolutionof the islet functions may be only understood when their interactionswith the pituitary functions become clear.     

Differential Staining of Yeast for Purified Cell Walls, Broken Cells, And Whole Cells

Intact yeast cells are Gram positive but broken or disrupted cells are Gram negative. A counterstain with methyl green provides differential staining between cell wall and cytoplasm. The cells and cell fragments are dried on a slide and stained by a standard Gram stain. The preparation is then treated for 5 min with 1% phosphomolybdic acid, washed, and stained 0.5 min with 1% aqueous methyl green (unpurified by CHCl₃ extraction). Under these conditions whole, intact cells are dark purple or black, walls of broken cells and purified walls are light green, and the exposed cytoplasm stains light purple. All fractions can be easily differentiated.     

A Mathematical Study of the Differential Effects of Two SERCA Isoforms on Ca2+ Oscillations in Pancreatic Islets

Cytosolic Ca²⁺ dynamics are important in the regulation of insulin secretion from the pancreatic β-cells within islets of Langerhans. These dynamics are sculpted by the endoplasmic reticulum (ER), which takes up Ca²⁺ when cytosolic levels are high and releases it when cytosolic levels are low. Calcium uptake into the ER is through sarcoendoplasmic reticulum Ca²⁺-ATPases, or SERCA pumps. Two SERCA isoforms are expressed in the β-cell: the high Ca²⁺ affinity SERCA2b pump and the low affinity SERCA3 pump. Recent experiments with islets from SERCA3 knockout mice have shown that the cytosolic Ca²⁺ oscillations from the knockout islets are characteristically different from those of wild type islets. While the wild type islets often exhibit compound Ca²⁺ oscillations, composed of fast oscillations superimposed on much slower oscillations, the knockout islets rarely exhibit compound oscillations, but produce slow (single component) oscillations instead. Using mathematical modeling, we provide an explanation for this difference. We also investigate the effect that SERCA2b inhibition has on the model β-cell. Unlike SERCA3 inhibition, we demonstrate that SERCA2b inhibition has no long-term effect on cytosolic Ca²⁺ oscillations unless a store-operated current is activated.     

Foregut Mesenchyme Contributes Cells to Islets during Pancreatic Development in a 3-Dimensional Avian Model

Current interest in the potential use of pancreatic stem-cells in the treatment of insulin dependent diabetes mellitus has led to increased research into normal pancreatic development. Pancreatic organogenesis involves branching morphogenesis of undifferentiated epithelium within surrounding mesenchyme. Current understanding is that the pancreatic islets develop exclusively from the epithelium of the embryonic buds. However, a cellular contribution to islets by mesenchyme has not been conclusively excluded. We present evidence that the mesenchyme of both the dorsal pancreatic bud and stomach rudiment make a substantial contribution of cells to islets during development in a three-dimensional avian model. These data suggest that mesenchyme can be a source not only of signals but also of cells for the definitive epithelia, making pancreatic organogenesis more akin to that of the kidney than to other endodermal organs. This raises the possibility for the use of mesenchymal cells as stem-or progenitor-cells for islet transplantation.Key Words: islets, stem-cells, development, epithelium, mesenchyme, pancreas, stomach, chick-quail, 3-dimensional, endocrine     

Foregut Mesenchyme Contributes Cells to Islets during Pancreatic Development in a 3-Dimensional Avian Model

Current interest in the potential use of pancreatic stem-cells in the treatment of insulin dependent diabetes mellitus has led to increased research into normal pancreatic development. Pancreatic organogenesis involves branching morphogenesis of undifferentiated epithelium within surrounding mesenchyme. Current understanding is that the pancreatic islets develop exclusively from the epithelium of the embryonic buds. However, a cellular contribution to islets by mesenchyme has not been conclusively excluded. We present evidence that the mesenchyme of both the dorsal pancreatic bud and stomach rudiment make a substantial contribution of cells to islets during development in a three-dimensional avian model. These data suggest that mesenchyme can be a source not only of signals but also of cells for the definitive epithelia, making pancreatic organogenesis more akin to that of the kidney than to other endodermal organs. This raises the possibility for the use of mesenchymal cells as stem- or progenitor- cells for islet transplantation.