An electron microscopic analysis of notochordal and mesenchymal cell abnormalities in embryos of Danforth’s short-tail (Sd) mice

Abnormalities of notochordal cells and of mesenchymal cells in embryos of Danforth's short-tail (Sd) and C57BL mice were examined by means of electron microscopy and cytochemical staining at 11.0 and 11.5 days of gestation. In abnormal (Sd/+; Sd/Sd) embryos, the notochordal cells were markedly deficient in bundles of filaments and lacked surface protrusions, and the notochordal basal lamina was continuous; in contrast, notochordal cells of normal (+/+) littermates and of C57BL embryos contained numerous bundles of filaments and showed fingerlike surface protrusions and discontinuous basal laminae. The pathologic notochordal cells also lacked the accumulations of glycogen revealed in the normals by means of thiocarbohydrazide cytochemical staining at the electron microscopic level. The mesenchymal cells of abnormals also were deficient in filaments but did stain for glycogen, though less prominently than did normal mesenchymal cells.     

Ultrastructure of the neural basal lamina in loop-tail mice

Ultrastructural features of the neural basal lamina were studied by means of the tannic acid and ruthenium red techniques in normal and abnormal dysraphic loop-tail mice at 9-11 days of gestation. With ruthenium red, the configuration of the neural basal lamina is similar in both normal and abnormal embryos at 9-11 days. However, differences were detected in the abnormal 9-day embryos processed with tannic acid, as compared with normal littermates. These include irregularities in the lamina rara externa, as well as differences in the staining pattern of the neuroepithelial cell plasma membrane. By 11 days of gestation, the lamina rara externa of the normal embryos shows features similar to those observed in the 9-day abnormal embryos.     

Ultrastructural analysis of basal neuroepithelial cells in dysraphic mice

Ultrastructural aspects of the cellular pathology in the basal neuroepithelium of the hindbrain and spinal cord were analyzed in dysraphic loop-tail mice at nine days of gestation. Whereas the basal cytoplasm of the neuroepithelium in normal littermates showed a consistent electron density, the neuroepithelium in abnormal embryos was characterized by "light" and "dark" cells scattered randomly along the basal aspect of the hindbrain and spinal cord. In the abnormals, gaps occurred in the neural basal lamina, and the neuroepithelial cells often were in direct contact with cytoplasmic processes from mesenchymal cells and from notochordal cells; in normal littermates, contact was observed only between the intact and continuous neural basal lamina and mesenchymal cells and notochordal cells. Thus, it is possible that the pathological features observed ultrastructurally in the basal neuroepithelium in dysraphic embryos may represent faulty tissue interaction with adjacent notochordal and mesenchymal cells.     

Abnormal elevation of the neural folds in the loop-tail mutant mouse.

The processes of elevation and convergence of the spinal neural folds were analyzed in normal (+/+; Lp/+) and abnormal (Lp/Lp) embryos of the loop-tail mutant mouse in order to determine possible mechanisms underlying the dysraphic defect characterized by a failure of the neural fold to close in this mutant. The results indicate that the neural folds are already defective during very early phases of elevation, with greater distances between the apical points of the paired walls of the neural groove, larger ventral angles and higher ratios of luminal/basal linear distances occurring in the abnormal embryos relative to those in normal embryos. The cross-sectional area of the neuroepithelium is also greater in abnormals, suggesting that faulty elongation of the neuraxis may contribute to the dysraphic condition.     

Ultrastructural analysis of the midaxial extracellular matrix in spinal dysraphism.

Ultrastructural aspects of the extracellular matrix (ECM) in the midaxial region of dysraphic embryos of the loop-tail (Lp) mutant mouse were analyzed by means of electron microscopy. In 17-23 somite embryos, ultrastructural differences in the ECM occurred with respect to the presence of a pair of long trailing basal laminar strands extending continuously from the ventral notochordal cells to the gut in abnormal (Lp/Lp) embryos, in contrast to short, ragged, discontinuous strands in normal (+/+; Lp/+) embryos. The ultrastructural localization and configuration of fibronectin (FN) and laminin (L) associated with these strands, however, were similar in normals and abnormals. In addition, FN occurred over interstitial bodies, fibrils, and sporadically along the basal laminae of the neural tube (or folds), notochord, gut, and vessels, whereas L was largely confined to the basal laminae. The results indicate that although the ultrastructural pattern of FN and L reactivity are similar in normal and abnormal embryos, a disturbance in the manner whereby the notochord detaches from the gut in dysraphic embryos may be of causal significance in the etiology of dysraphism in this mutant.     

The extracellular matrix between the optic vesicle and presumptive lens during lens morphogenesis in an anophthalmic strain of mice

Extracellular matrix material present during early lens morphogenesis in anophthalmic strain ZRDCT-Ch mice was studied histochemically by the Alcian blue 8GX pH 2.5, Alcian blue 8GX pH 2.5/periodic acid-Schiff combined, high iron diamine, and Van Gieson methods. Observed staining patterns were compared with results from an analysis of a normal strain of mice (E.H. Webster, Jr., A.F. Silver, and N.I. Gonsalves, 1983, Develop. Biol. 100, 147-157). No differences in constituents were found between the strains in staining patterns of the ectodermal basal lamina. However, the optic vesicle basal lamina in the anophthalmic strain was found to have a relatively lower staining intensity for sulfated glycosaminoglycan associated with it than was observed in the normal strain, although these mutant optic vesicles were morphologically normal. Results from this and the earlier study on normal mice indicate that one function of sulfated glycosaminoglycan in early lens morphogenesis may be to serve as a cementing medium between the optic and lens rudiments. This sulfated glycosaminoglycan deficiency on the anophthalmic optic vesicle basal lamina is temporally correlated with and may be causally related to precocious lens cup formation and frequently observed separation of the normally adherent eye rudiments. Conclusions drawn from this study are consistent with the speculation of H.B. Chase and E.B. Chase (1941, J. Morphol. 68, 279-301) that there may be abnormal contact between the optic vesicle and presumptive lens ectoderm in the mutant strain, although there is a differing view on the cause of the abnormal contact.     

The fine structure of ventricular cells in the brains of mouse embryos homozygous for the loop-tail gene

The neural tube in normal (+/+), heterozygous (Lp/+), and abnormal (Lp/Lp) mutant mouse embryos ranging in age from 10 to 12 days of gestation was studied by means of transmission electron microscopy. In the abnormal embryos, ventricular cells in defective regions of the brain show distortions and crowding together of internal cellular processes and a decrease in blebs and bulbous projections, as compared with their normal counterparts. At 12 days' gestation the abnormal brains show a scarcity of the T-shaped internal cellular processes characteristic of normal brains. The abnormal brains also show increased amounts of intercellular space and extensive gaps between the cells, particularly in basal regions. There are no striking differences between the normal and abnormal brains at 10 to 12 days' gestation with respect to the appearance and distribution of cilia, microfilaments, microtubules, tight junctions, and ribosomes.     

Ultrastructural analysis of the midaxial extracellular matrix in spinal dysraphism

Ultrastructural aspects of the extracellular matrix (ECM) in the midaxial region of dysraphic embryos of the loop-tail (Lp) mutant mouse were analyzed by means of electron microscopy. In 17–23 somite embryos, ultrastructural differences in the ECM occurred with respect to the presence of a pair of long trailing basal laminar strands extending continuously from the ventral notochordal cells to the gut in abnormal (Lp/Lp) embryos, in contrast to short, ragged, discontinuous strands in normal (+ /+;Lpj +) embryos. The ultrastructural localization and configuration of fibronectin (FN) and laminin (L) associated with these strands, however, were similar in normals and abnormals. In addition, FN occurred over interstitial bodies, fibrils, and sporadically along the basal laminae of the neural tube (or folds), notochord, gut, and vessels, whereas L was largely confined to the basal laminae. The results indicate that although the ultrastructural pattern of FN and L reactivity are similar in normal and abnormal embryos, a disturbance in the manner whereby the notochord detaches from the gut in dysraphic embryos may be of causal significance in the etiology of dysraphism in this mutant.     

Strongyloides ratti and Trichinella spiralis: net charge of epicuticle

The intact epicuticles of Strongyloides ratti stage-3 larvae and Trichinella spiralis stage-1 larvae were found to have a surface net negative charge. Ultrastructural studies on S. ratti using cationized ferritin and ruthenium red showed the negative charge to be dense and uniformly distributed over the epicuticular surface. Staining with acetic acid-ferric oxide hydrosol occurred at pH 1.65 and suggests that amino acid carboxyl groups were not responsible for the negative charge property. Alcian blue staining occurred at pH 0.5 and at a critical electrolyte concentration (CEC) of 0.9 M MgCl2, a property similar to that of highly sulfated mucopolysaccharides such as the proteoglycan keratan sulfate. In contrast, T. spiralis larvae failed to stain with alcian blue below pH 5.0 or at a CEC of 0.1 M, suggesting its negative charge is associated with dissociated amino acid carboxyl groups. Attempts to remove the negative charge-bearing components in the epicuticle of S. ratti by detergents, organic solvents, denaturing agents, proteases, uronidases, neuraminidases, and lipases were unsuccessful. The presence of elastin in the S. ratti larval outer cortical layer was indicated by its vulnerability to elastase and its reaction to aldehyde fuchsin-alcian blue stain. These results show that the epicuticle of S. ratti is not a typical cell membrane, although it appears to have ultrastructural similarities. It is suggested that the association of highly sulfated mucopolysaccharides with the epicuticular surface of free-living nematodes such as S. ratti L3 may reflect a greater need to protect against surface desiccation. It is also postulated that the highly negatively charged surface may have anticomplementary and anticoagulation effects.     

Alcian Blue Pyridine Variant-a Superior Alternative to Alcian Blue 8GX: Staining Performance and Stability

We compared the staining performance, dye content, solubility, and visual absorption maximum of two batches of alcian blue pyridine variant and of five batches of alcian blue 8GX (C.I. 74240). Whenever possible, we also compared results to those obtained with the same dye batches produced at an earlier date to provide information concerning dye stability. Both alcian blue pyridine variant batches were of high dye content, stable, of satisfactory solubility, and performed well in both the routine Mowry mucin stain and in the critical electrolyte concentration (CEC) stain. Of the five alcian blue 8GX samples, some were also of appropriate dye content, were sufficiently stable, and gave good staining in the two procedures. Two batches, however, were unstable, and three batches were unsatisfactory in staining performance and solubility in the CEC stain. Consequently alcian blue pyridine variant is a superior substitute for alcian blue 8GX.     

Alcian Blue Pyridine Variant–a Superior Alternative to Alcian Blue 8GX: Staining Performance and Stability

We compared the staining performance, dye content, solubility, and visual absorption maximum of two batches of alcian blue pyridine variant and of five batches of alcian blue 8GX (C.I. 74240). Whenever possible, we also compared results to those obtained with the same dye batches produced at an earlier date to provide information concerning dye stability. Both alcian blue pyridine variant batches were of high dye content, stable, of satisfactory solubility, and performed well in both the routine Mowry mucin stain and in the critical electrolyte concentration (CEC) stain. Of the five alcian blue 8GX samples, some were also of appropriate dye content, were sufficiently stable, and gave good staining in the two procedures. Two batches, however, were unstable, and three batches were unsatisfactory in staining performance and solubility in the CEC stain. Consequently alcian blue pyridine variant is a superior substitute for alcian blue 8GX.     

Cranial effects of retinoic acid in the loop-tail (Lp) mutant mouse

The effects of retinoic acid (RA) on the manifestation and nature of neural tube defects (NTD) in heterozygous embryos of mutant mice carrying the gene loop-tail (Lp) and in normal (+/+) littermates and embryos from normal homozygous matings were compared with NTD that occur in untreated abnormal homozygous (Lp/Lp) embryos. A single intraperitoneal dose (5 mg/kg) of RA administered at 9 AM or 3 PM on day 8 of gestation induced NTD in +/+ as well as Lp/+ embryos removed on day 12 of gestation. All of the NTD were confined to the brain and consisted of exencephaly involving the diencephalon, mesencephalon, and metencephalon. In neither phenotype (Lp/+; +/+) was the massive exencephaly and myeloschisis characteristic of untreated Lp/Lp embryos produced; thus, it is possible that the teratogenic mechanisms of RA-induced defects and of Lp-induced defects may differ.     

发育中人胎儿肥大细胞的组织化学研究

用组织化学技术,对５０例不同胎龄胎儿颊部和食管肥大细胞进行了研究。我们发现：幼稚的肥大细胞颗粒ＴＢ染色呈淡紫色。ＡＢ·Ｓ染色呈蓝色,ＣＥＣ值偏低,颗粒的糖胺多糖硫酸化程度偏低;成熟的肥大细胞颗粒ＴＢ染色呈深紫色,ＡＢ·Ｓ染色呈红色,ＣＥＣ值偏高,颗粒的糖胺多硫酸化程度偏高,含肝素。颊部、食管的肥大细胞在出现的时间、ＡＢ·Ｓ组化染色、ＣＥＣ值与肝素含量等存在不同。结果说明发育中胎儿肥大细胞颗粒的组化性质发生了改变,不同部位肥大细胞的发育是不同步的,这些是发育中胎儿肥大细胞异质性的表现。本文对这些现象进行了讨论。     

Histochemical evaluation of glycosaminoglycan deposition in the skin

Histologic demonstration of glycosaminoglycan (GAG) deposition in the skin has been based on the use of either colloidal iron or alcian blue. To define the best technique for the determination of skin GAG content we undertook a prospective study comparing the two stains and evaluating the use of cetylpyridinium chloride (CPC) to enhance fixation. Slides were prepared from skin biopsies obtained from five patients with cutaneous mucinoses. The preparations were coded and examined by three observers. Colloidal iron staining gave a higher intensity for GAG deposits in papillary and reticular dermis. Digestion by specific enzymes identified similar GAGs with either colloidal iron, or alcian blue; however, colloidal iron made GAGs more obvious, partly due to the contrast afforded by the yellow background stain. The addition of CPC to the fixative appreciably enhanced GAG fixation without interfering with the action of enzymes. Experimentally, we confirmed this effect of CPC by determining a pronounced decrease in GAG leakage into the fixative from CPC treated human umbilical cord. We conclude that the combination of CPC fixation and colloidal iron staining gives the best definition of skin GAGs in clinical specimens.     

35S]autoradiographic study of sulfated GAG accumulation and turnover in embryonic mouse tooth germs

The accumulation of sulfated GAG in embryonic mouse molars before, during, and after terminal differentiation of odontoblasts was localized by [35S]autoradiography combined with the use of chondroitin ABC lyase. Much more sulfated GAG were accumulated in the dental papilla than in the dental epithelium. High incorporation of [35S]sulfate occurred at the epithelio-mesenchymal junction, which is the site of dental basement membrane and predentin. Before terminal differentiation of odontoblasts, the distribution of sulfated GAG was uniform at the basement membrane. After the onset of terminal differentiation of odontoblasts, much more sulfated GAG accumulated at the tip of principal cusps than at the apical (inferior) parts of cusps, and sulfated GAG were then found to be degraded more rapidly at the epithelio-mesenchymal junction than at other parts of the tooth germ. Thus regional variation in the rate of degradation of GAG exists in the tooth germs. Trypsin-isolated dental epithelia cultured in vitro synthesized a new basement membrane that could be labeled with [3H]glucosamine but not with 35SO4(-2). The epithelial-derived basal lamina contains little or no sulfatated GAG.     

A method for the identification of sulfated glycopeptide by two-dimensional electrophoresis on cellulose acetate membrane

Two-dimensional electrophoresis on cellulose acetate membrane permits the clean separation of sulfated glycopeptide in a mixture of acidic glycans (glycosaminoglycans and acidic glycopeptides). Two systems were used. In system 1, 0.1 M pyridine-0.47 M formic acid buffer (pH 3.0) was used in the first and 0.1 M barium acetate (pH 8.0) in the second dimension. In system 2, 0.1 M pyridine-0.47 M formic acid buffer (pH 3.0) was used in the first and 0.1 M HCl in the second dimension. All of the acidic glycans on electrophoretogram were stained with alcian blue in 70% ethanol. On the other hand, sulfated glycans alone were made visible with alcian blue in 0.1 M HCl. Alcian blue in 70% ethanol or 0.1 M HCl, when combined with periodic acid-Schiff's reagent identified sulfated glycopeptides on cellulose acetate membrane.     

Staining properties of duodenal mast cells in 48/80-treated rats

Summary Mast cells in the tongue, mesentery and lamina propria of the duodenal mucosa in normal and 48/80-treated rats were observed at different time intervals. The tissues were studied comparatively after staining with toluidine blue, acridine orange or alcian bluesafranin. Under the experimental conditions used, the mast cells in the tongue and mesentery showed constant positive reactions to toluidine blue and acridine orange, both of which failed to demonstrate the presence of mast cells in the lamina propria of the duodenal mucosa. The combined alcian blue-safranin stain elicited a safranin-positive reaction in the mast cells of the tongue and mesentery and an alcian blue reaction in those of the lamina propria of the duodenal mucosa. This alcianophilia of the duodenal mast cells was not affected by compound 48/80. On the other hand, the safranin stain of the tongue and mesentery mast cells was altered to alcian blue by the drug. The results are discussed in the light of recent developments in mast cell research.This work was supported by grant MA-2236 of the Medical Research Council of Canada.     

Histochemical analysis of extracellular matrix material in embryonic mouse lens morphogenesis

Extracellular matrix material (ECM) present during mouse lens morphogenesis was studied histologically by the periodic acid-Schiff, Alcian blue 8GX, pH 2.5, high iron diamine, and Van Gieson methods, and enzymatically with bovine testicular hyaluronidase, Streptomyces hyaluronidase, malt diastase, and collagenase. The basal lamina of the optic vesicle prior to lens placode formation was found to be higher in glycosaminoglycan (GAG) content than was the ectodermal basal lamina. Upon apposition of the optic vesicle and presumptive lens ectoderm, the ECM plus basal laminae appeared as the equivalent of adding both optic vesicle-associated and ectodermal-associated basal lamina. The proposal is made that the initial triggering mechanism of lens morphogenesis consists of a cross-linking and polymerization of optic vesicle-associated GAG to ectodermal-associated glycoproteins resulting in a firm attachment between the structures. Basal lamina associated with the presumptive pigmented retina and also the more ventral part of the interface matrix were found to change from predominantly GAG in early stages to collagen deposits in more advanced stages, temporally coinciding with the appearance of differentiative markers in each structure. This pattern of GAG turnover and replacement by collagen during the course of development is also seen in mouse salivary gland morphogenesis (M. R. Bernfield, S. D. Banerjee, and R. H. Cohn (1972). J. Cell Biol. 52, 674-686.).     

Ultrastructure of the basal lamina and its relationship to extracellular matrix of embryos of the starfish Pisaster ochraceus as revealed by anionic dyes

The ultrastructure of the 51/2–6-day-old embryonic asteroid basal lamina (BL) was studied by transmission electron microscopy (TEM) and scanning electron microscopy (SEM) and after treatment with anionic dyes. Conventional fixation in glutaraldehyde and osmium reveals a BL consisting of a lamina densa separated from the basal cell surface by a lamina lucida. Little or no reticular lamina is present. Material similar in appearance to the basal lamina extends into the blastocoel, forming an extracellular matrix (ECM). Following fixation in the presence of the dye ruthenium red, proteoglycan (PG) granules are visible in the lamina lucida and immediately beneath the lamina densa. The ECM consists of granules of a similar appearance, which are associated with fibers of an intermediate electron density resembling invertebrate collagen. After fixation in the presence of alcian blue under polyanionic conditions, all aspects of the basal lamina and the ECM stain very densely. The use of alcian blue in 0.3 M MgCl₂ (monoanionic condition) or in low concentrations reveals a lamina densa consisting of a fine feltwork and tubule-like structures. A meshwork composed of thick, densely stained and thinner, intermediately stained strands is embedded in the inner aspect (that adjacent to the blastocoel) of the ectodermal lamina densa. Similar elements are present in the endodermal BL, but the dense material is represented by short regions that do not form a meshwork. The dense and intermediate strands of both basal laminae also extend into the blastocoel as ECM. The tubule-like structures extend from the dense material of the inner meshwork into the lamina densa. They also cross both the lamina densa and lucida to associatee with the basal cell membranes. The fact that the basal cell surfaces are often puckered outward at the points of contact suggests that this configuration might be providing a means whereby forces can be transferred from the ECM through the basal lamina to the cells.     

The basal lamina of the postnatal mammary epithelium contains glycosaminoglycans in a precise ultrastructural organization

The mammary epithelium was investigated to determine whether glycosaminoglycans (GAG) are components of the basal lamina of epithelia undergoing postnatal morphogenesis. Isolated epithelial tissues from midpregnant mice produce substantial amounts of GAG, consisting predominantly of hyaluronic acid and heparan sulfate. The basal surfaces of mammary epithelia at various postnatal developmental stages show GAG, as demonstrated by histochemistry and by autoradiography coupled with enzyme susceptibility. Electron microscopy using ruthenium red staining reveals polyanionic components, presumably GAG, within the epithelial basal lamina. Detailed ultrastructural analyses of tannic acid-treated and ruthenium red-stained material demonstrate that the lamina contains a two-dimensional symmetrical array of tetragonally ordered components colsely associated with the basal plasma membrane. This array is similar to that found in the hyaluronate-containing lamina of embryonic epithelia. A structurally ordered complex of GAG-containing macromolecules may characterize the basal lamina of all epithelia which undergo morphogenetic changes in cell shape.