ELECTRON MICROSCOPIC STUDIES OF INDUCED CARTILAGE DEVELOPMENT AND CALCIFICATION

Cultured, human, amniotic cells (FL strain) injected into the thigh muscles of cortisone-conditioned mice proliferated to form discrete colonies which, over a period of 5 days, became invested by numerous fibroblasts. Cartilage cells and matrix appeared within the fibroblastic zones during the succeeding 2–4 days. Cartilage matrix calcified within 12 days following FL-cell injection. Cartilage cells closely resembled fibroblasts from which they appeared to be derived, and were readily distinguished from FL cells by their prominent ergastoplasm and Golgi complexes. Cartilage matrix was composed of a distinctive feltwork of randomly arranged, collagen fibrils (~600 A axial period and ~250 A width) from which small electron-opaque, leaflike matrix particles extended. Matrix calcification occurred with the deposition of radially arranged needle-like structures resembling hydroxyapatite. Dense centers were often identified within these clusters. Examination of heavily calcified areas revealed confluent masses of apatite-like material. In general, the fine structure of induced cartilage formation and calcification resembled that of cartilage development and calcification as previously described in the normal epiphysis.     

MUCOPOLYSACCHARIDES SYNTHESIZED BY CULTURED GLIAL CELLS DERIVED FROM A PATIENT WITH SANFILIPPO A SYNDROME

—Glial cells were cultured from brain tissue obtained at autopsy of a patient with Sanfilippo A syndrome. Mucopolysaccharides were labeled by culturing the cells in the presence of [³⁵S]sulfate. After proteolysis, intracellular and media-elaborated mucopolysaccharides were fractionated by Dowex 1 chromatography. One fraction, identified as heparan sulfate by chromatographic, electrophoretic, and enzyme susceptibility properties, accumulated in Sanfilippo glial cells in greater amounts than in controls. Heparan sulfate was also excreted into the culture media by both Sanfilippo and normal cultures, and it constituted a major fraction of the sulfated mucopolysaccharides synthesized by glial cells. Sanfilippo and normal fibroblasts were also included in these studies for comparative purposes. Sanfilippo fibroblasts accumulated significantly increased amounts of heparan sulfate as compared to normal fibroblasts. Heparan sulfate was excreted into the culture media by Sanfilippo and normal fibroblasts in equivalent amounts, but in contrast to glial cells, it was only a minor component of the sulfated mucopolysaccharides produced. Cultured glial cells should provide a useful system for investigating the role of heparan sulfate in glial cell function.     

SULFATE METABOLISM IN PANCREATIC ACINAR CELLS

The metabolism of inorganic sulfate in pancreatic acinar cells was studied by electron microscope radioautography in mice injected with sulfate-³⁵S. Labeled sulfate was concentrated in the Golgi complex at 10 min. Within 30 min, much of the radioactive material had been transferred to condensing vacuoles. These were subsequently transformed into zymogen granules. By 4 hr after injection, some of the zymogen granules with radioactive contents were undergoing secretion, and labeled material was present in the pancreatic duct system. The Golgi complex in pancreatic acinar cells is known to be responsible for concentrating and packaging digestive enzymes delivered to it from the endoplasmic reticulum. Our work demonstrates that the Golgi complex in these cells is also engaged in the manufacture of sulfated materials, probably sulfated mucopolysaccharides, which are packaged along with the enzymes in zymogen granules and released with them into the pancreatic secretion.     

N-acetylgalactosamine 4,6-bissulfate in rat urine II. Occurrence in rat cartilage and blood

The intraperitoneal injection of inorganic [³⁵S]sulfate to rat was followed by the rapid appearance in urine of a labeled compound which behaved as N-acetylgalactosamine 4,6-bissulfate on paper chromatography and paper electrophoresis and when treated with two sulfatases with a high degree of specificity toward the sulfate bonds at positions 4 and 6, respectively.Enzymatically-prepared N-acetylgalactosamine 4,6 [6-³⁵S]bissulfate was injected intravenously into rats. Of the injected dose, 90% was excreted unchanged in the urine during the subsequent 12 h, suggesting that the urinary N-acetylgalactosamine 4,6-bissulfate may derive from blood as renal filtrate.Examination of the rats injected with inorganic [³⁵S]sulfate revealed the presence of labeled N-acetylgalactosamine 4,6-bissulfate at significant levels in the blood and cartilage, but at much lower levels in the liver. The cartilage component was highest in its rate of ³⁵S uptake, suggesting that the blood component may derive at least in some part from the cartilage.Exposure of surviving cartilage slices to inorganic [³⁵S]sulfate, followed by extraction of the slices with hot 50% ethanol yielded a number of radioactive compounds, of which three were characterized as UDP-N-acetylgalactosamine-4,6-[³⁵S]bissulfate, N-acetylgalactosamine-1-phosphate 4,6-[³⁵S]bissulfate and N-acetylgalactosamine 4,6-[³⁵S]bissulfate. By subjecting the prelabeled tissue to chase incubation, it was possible to show that the UDP-N-acetylgalactosamine-4,6-bissulfate in the tissue disappeared with an approximate half-life of 10 min with a concomitant appearance in the medium of N-acetylgalactosamine 4,6-bissulfate and its 1-phosphate ester. These results suggest the occurrence in cartilage of an enzymatic system which is responsible for rapid turnover of UDP-N-acetylgalactosamine-4,6-bissulfate and possibly required for the rapid secretion of N-acetylgalactosamine 4,6-bissulfate into extracellular field.     

Diagnosis of Hunter's syndrome carriers; Radioactive sulphate incorporation into fibroblasts in the presence of fructose 1-phosphate

Summary Mutual correction of co-cultivated fibroblasts from patients with Hunter's and Hurler's syndrome could be inhibited by either fructose 1-phosphate or mannose 6-phosphate. In the presence of fructose 1-phosphate a 50% mixture of fibroblasts from a patient with Hunter's syndrome and a normal homozygous individual showed an increased³⁵S-sulphate incorporation into acid mucopolysaccharides. When fibroblast cultures from one obligate and two possible carriers of Hunter's syndrome were tested for³⁵S-sulphate incorporation, the cultures showed either twice the normal³⁵S-sulphate incorporation into acid mucopolysaccharides in the presence of fructose 1-phosphate or an abnormally high incorporation in the presence as well as in the absence of the sugar phosphate.     

Prostaglandin A2 and S uptake in connective tissue

Rats deficient in essential fatty acids (EFA) incorporated lesser amounts of radioactive sulfate into lung, kidney, spleen, heart, costal cartlidge, long bone and skull bone than did normal control animals. Administration of prostaglandin A₂ stimulated ³⁵S uptake by lung, kidney and aorta while ³⁵S levels in costal cartilage, tibial cap and long bone were strikingly reduced. Comments are presented suggesting that this metabolic mechanism may explain, in part, cartilage and bone resorption in areas of inflammation, such as arthritis, both rheumatoid arthritis and osteoarthritis.     

Prostaglandin A2 and 35S uptake in connective tissue

Rats deficient in essential fatty acids (EFA) incorporated lesser amounts of radioactive sulfate into lung, kidney, spleen, heart, costal cartlidge, long bone and skull bone than did normal control animals. Administration of prostaglandin A₂ stimulated ³⁵S uptake by lung, kidney and aorta while ³⁵S levels in costal cartilage, tibial cap and long bone were strikingly reduced. Comments are presented suggesting that this metabolic mechanism may explain, in part, cartilage and bone resorption in areas of inflammation, such as arthritis, both rheumatoid arthritis and osteoarthritis.     

Characterization of the chondroitin sulfate produced by B16 mouse melanoma cells

The mucopolysaccharides produced by B16 mouse melanoma cells have been isolated in milligram quantities from the spent media in which the cells were grown in the presence of 2-amino-2-deoxy-d-glucose-t and ³⁵S]-sulfate. The mucopolysaccharides obtained by precipitation with cetylpyridinium chloride from the Pronase digest of the media were further purified by gel filtration, ion-exchange chromatography, and treatment with nucleases. The major components were identified as chondroitin-4-sulfates by identification of the hexosamine as 2-amino-2-deoxy-d-galactose, and by digestibility with hyaluronidases, chondroitinase AC, and chondro-4-sulfatase. The o.r.d. curve and i.r. spectra of these components also confirmed their similarity to chondroitin-4-sulfate from cartilage. The molecular weight of the polysaccharide chains was estimated to be in the range 90,000–120,000 by sedimentation equilibrium analysis.     

Histochemical and Autoradiographic Studies on the Effects of Aging on the Mucopolysaccharides of the Periosteum

An autoradiographic study was made using S³⁵-sulfate for the localization, distribution, and variation in the mucopolysaccharide content of the femoral periosteum of rats from birth to old age. The mucopolysaccharides were also studied histochemically, using toluidine blue O, Rinehart and Abu'l-Haj's colloidal iron method, and the periodic acid-Schiff reaction, before and after hyaluronidase treatment. Autoradiograms revealed the uptake of S³⁵ particularly in the vicinity of the preosseous zone and adjacent osteoblasts. This labelling was highest at the period of rapid bone growth. With increasing age, the S³⁵ uptake became progressively less. The preosseous zone showed γ-metachromatic staining at all ages after treatment with toluidine blue. Active osteoblasts were mostly orthochromatic, however, β-metachromasia was exhibited at a later age. Abundant amounts of intra- and extracellular mucopolysaccharides of both the acid and neutral type were demonstrated in the periosteum. S³⁵ uptake and γ-metachromasia show the presence of sulfated mucopolysaccharides, of which chondroitin sulfate predominates in the preosseous zone. Since S³⁵ uptake is high in active osteoblasts, the inability to demonstrate metachromasia in osteoblasts may indicate either that chondroitin sulfate is liberated as fast as it is being produced, or that it may be present within the cells in a precursor form not detectable by histochemical methods.     

The N-Terminal Cleavage of Chondromodulin-I in Growth-Plate Cartilage at the Hypertrophic and Calcified Zones during Bone Development

Chondromodulin-I (ChM-I) is a 20–25 kDa anti-angiogenic glycoprotein in cartilage matrix. In the present study, we identified a novel 14-kDa species of ChM-I by immunoblotting, and purified it by immunoprecipitation with a newly raised monoclonal antibody against ChM-I. The N-terminal amino acid sequencing indicated that it was an N-terminal truncated form of ChM-I generated by the proteolytic cleavage at Asp³⁷-Asp³⁸. This 14-kDa ChM-I was shown by the modified Boyden chamber assay to have very little inhibitory activity on the VEGF-A-induced migration of vascular endothelial cells in contrast to the intact 20–25 kDa form of ChM-I (ID₅₀ = 8 nM). Immunohistochemistry suggested that 20–25 kDa ChM-I was exclusively localized in the avascular zones, i.e. the resting, proliferating, and prehypertrophic zones, of the cartilaginous molds of developing long bone, whereas the 14-kDa form of ChM-I was found in hypertrophic and calcified zones. Immunoblotting demonstrated that mature growth-plate chondrocytes isolated from rat costal cartilage actively secrete ChM-I almost exclusively as the intact 20–25 kDa form into the medium in primary culture. Taken together, our results suggest that intact 20–25 kDa ChM-I is stored as a component of extracellular matrix in the avascular cartilage zones, but it is inactivated by a single N-terminal proteolytic cleavage in the hypertrophic zone of growth-plate cartilage.     

Immunohistochemical,autoradiographic and electron microscopic studies on the transformation of fibroblasts into chondrocytes in the mouse subfascia induced by bone morphogenetic protein

Summary Functional morphology on the transformation of fibroblasts into chondrocytes induced by bone morphogenetic protein (BMP) was studied by light and electron microscopy using ³⁵S autoradiography and immunohistochemistry for S-100 protein and type-II collagen. A pellet containing BMP obtained from a murine osteosarcoma was transplanted into the mouse subfascia. By 3 days after implantation, many typical fibroblasts, which were free of the silver grains for ³⁵S and devoid of both S-100 protein and type-II collagen, entered the pellet region. By 5 days, the fibroblasts in the pellet region became polygonal in shape, and cytoplasmic vesicles and vacuoles appeared, both containing a homogeneous substance of low electron density. At 5 days, autoradiography revealed many silver grains for ³⁵S over the Golgi apparatus and vesicles and vacuoles of the cells in the pellet region as well as over the surrounding extracellular matrix. Moreover, the cells at 5 days displayed immunoreactivity to both proteins. The extracellular matrix around the cell began to show clear metachromasia and increased in amount with time. At 9 days all the cells in the pellet region were round or oval in shape and surrounded by an abundant cartilaginous matrix. The rough endoplasmic reticulum and Golgi apparatus were extremely well developed, and a large number of vacuoles and vesicles were seen in the cytoplasm. These cells showed intense immunoreactivity to both proteins, and strong accumulation of sulfur was visualized in the extracellular matrix by autoradiography. These results suggest that the fibroblasts in the pellet region change into chondroblasts by 5 days, and become typical chondrocytes by 9 days.     

The enhancement of in vitro survival and chondrogenesis of limb bud cells by cartilage conditioned medium

Dissociated stage 21–28 chick embryo limb bud cells showed an increasing ability to produce cartilage colonies in vitro with in vivo maturation. In addition dissociated stage 21–28 chick embryo limb bud cells exposed to cartilage conditioned medium continuously or only for 48 hr prior to subculture showed an enhanced (as much as 15-fold) ability to form differentiated cartilage colonies. By this criterion, cells were more responsive to conditioned medium prior to stage 25. Conditioned medium from fibroblast cultures caused an inhibition of cartilage colony formation, suggesting that the effect is cell-type specific. Besides increasing cartilage colony formation by enhanced cell survival, the incorporation of S³⁵O₄ into isolated glycosaminoglycans is also stimulated when limb bud cells are exposed to cartilage conditioned medium. The results support a model for cell differentiation which involves the enhancement of a particular differentiated capacity by a diffusible cell-type-specific macromolecule.     

Histochemistry of the glands associated with the reproductive tract ofLymnaea stagnalis

Summary The albumen gland, the muciparous gland and the oöthecal gland of female genital tract of Lymnaea stagnalis, collected in spring, autumn and winter have been studied.The reactions for polysaccharides, proteins and RNA have been performed in order to characterise the secretion of the glands.The albumen gland secretion consists almost exclusively of slightly acid polysaccharides whose histochemical reactions, according to Lison and Grainger and Shillitoe confirm the presence of galactogen. Proteins are also present in the secretion. The muciparous gland secretion consists of strongly acid mucopolysaccharides (non sulphated) produced by large cells among which small cells containing sulphated mucopolysaccharides are present.In the oöthecal gland two zones are present, one with a single type of cells containing acid mucopolysaccharides, and the other with two different types of cells: the first with mucopolysaccharides and the second with sulphated mucopolysaccharides, proteins and glycogen at the basis of the cell. Sialic acids are not present in the secretion of the glands studied.The polysaccharidic composition of the secretion of the glands is different from gland to gland. The secretion of the glands gradually changes and gets acid according to the composition of the various membranes and envelopes wrapping up the eggs.     

A fraction from extracts of demineralized adult bone stimulates the conversion of mesenchymal cells into chondrocytes

Demineralized adult bone contains factors which stimulate nonskeletal mesenchymal cells to undergo a developmental progression resulting in de novo endochondral ossification. In this study, isolated embryonic stage 24 chick limb bud mesenchymal cells maintained in culture were utilized as an in vitro assay system for detection of specific bioactive components solubilized from adult chicken bone matrix. Guanidinium chloride extracts (4 M) of demineralized-defatted bone were fractionated and tested in limb mesenchymal cell cultures for possible effects upon growth and chondrogenesis. Two low-molecular-weight fractions were found to be active in these cultures. A cold water-insoluble, but warm Trisbuffered saline-soluble fraction provoked a dose-dependent increase in the amount of cartilage formed after 7 days of continuous exposure as evidenced by an increased number of chondrocytes observed in living cultures, elevated cell-layer-associated ³⁵S incorporation per microgram DNA, and greater numbers of toluidine blue-staining foci (i.e., cartilage nodules). Growth inhibitory substances were detected in a low-molecular-weight, water-soluble fraction; 7 days of continuous exposure to this material resulted in less cartilage formation and reduced cell numbers (accumulated DNA) on each plate. These observations demonstrate the usefulness of stage 24 chick limb bud cell cultures for identifying bioactive factors extracted from adult bone matrix. In addition, the action of these factors on mesenchymal cells may now be studied in a cell culture system.     

Sulfated mucopolysaccharide synthesis and secretion in endothelial cell cultures

The cells that line the lumen of rabbit aorta have been obtained in a quantity sufficient for mass culture. Autoradiography of the cells incubated with ³⁵S-sulfuric acid and electrophoretic analysis of ³⁵S mucopolysaccharides extracted from the cells and from the medium indicate that these cells synthesize and secrete various species of sulfated mucopolysaccharides. In the steady state, only one major and one minor component are found inside the cell. The major intracellular component is resistant to degradation by chondroitinase ABC. Two major fractions and one minor fraction are found in the culture medium at the end of a 24 h labelling period. Both of the major components extracted from the medium are not present in the cell in an appreciable amount.     

RADIOAUTOGRAPHIC COMPARISON OF THE UPTAKE OF GALACTOSE-H3 AND GLUCOSE-H3 IN THE GOLGI REGION OF VARIOUS CELLS SECRETING GLYCOPROTEINS OR MUCOPOLYSACCHARIDES

The radioautographic distribution of the label of galactose-H³ was compared with that of glucose-H³ in a series of secretory cells of the rat. Whereas the glucose label appeared in all mucous cells, the galactose label was incorporated only into certain mucous cells. Whenever either label was incorporated, however, it was located first in the Golgi region and later in the secretion product, mucus. Several lines of evidence, including extraction of glucose label with peracetic acid—beta glucuronidase, indicated that the material synthesized in the Golgi region was glycoprotein in nature. In chondrocytes, both the galactose and the glucose label appeared first in the Golgi region and later in cartilage matrix; extraction of glucose label with hyaluronidase indicated that much of it consisted of mucopolysaccharide. In all secretory cells, the extraction of glycogen by amylase had no effect on Golgi radioactivity. Such extraction did not eliminate the scattered cytoplasmic label also seen after glucose-H³ injection, but completely eliminated that seen after galactose-H³. Consequently, the galactose-H³ label in the Golgi region stood out more clearly, and was detected in many cells: pancreas, liver, epididymis, and intestinal columnar cells. In the latter, label later appeared in the surface coat. Thus, radioautography after injection of galactose-H³, as after glucose-H³, indicates that synthesis of complex carbohydrates takes place in the Golgi region of many secretory cells.     

The conversion of injected glucose into renal glycogen and mucopolysaccharides

Summary Tritiated glucose has been injected into rabbits in various states of hydration. The renal papilla of all animals showed an uptake of the label, converted into glycogen, and into mucopolysaccharides, in a manner dependent on the water balance of the animal.In papillae of control animals, the glycogen of the collecting duct epithelial cells and the mucopolysaccharides of the interstitium were labelled.In papillae of animals in an aqueous diuresis, the collecting duct glycogen was lightly labelled and there was no label over the interstitium.Antidiuretic hormone caused a diversion of label from the collecting ducts into interstitial mucopolysaccharides.The significance of these findings, with respect to renal concentrating ability, is discussed.The author wishes to thank Dr. M. K. S. Hathorn for help with the statistical analysis. Mr. K. Gamblin and Mr. P. L. Hyam gave valuable technical assistance. This research formed a part of the work approved for the degree of Ph. D. (London).     

The role of the Golgi complex in sulfate metabolism

This investigation was designed to determine if sulfate metabolism is the function of a particular cell organelle, or whether the site of sulfation varies, depending upon the type of cell and the class of sulfated compound. Rats and mice were injected intravenously with inorganic sulfate labeled with ³⁵S (H₂ ³⁵SO₄), and were then killed by vascular perfusion of fixative 5–30 min later. Several tissues were prepared for electron microscope autoradiography. 14 different types of specialized cells which incorporated the labeled sulfate were analyzed. In every case, the sulfate was initially detected in the smooth membranes and vesicles of the Golgi complex. Available evidence indicates that these cells were engaged in the synthesis of several different sulfated compounds, including mucopolysaccharides, glycoproteins, lipids, and steroids. These results lead to the generalization that the enzymes required for the transfer of inorganic sulfate to a variety of acceptor molecules are located in the Golgi complex.     

Effects of fibroblasts of different origin on long term maintenance of xenotransplanted human epidermal kerationocytes in immunodeficient mice

We examined effects of fibroblasts of different origin on long-term maintenance of xenotransplanted human epidermal keratinocytes. A suspension of cultured epidermal cells, originating from adult human trunk skin, was injected into double mutant immunodeficient (BALB/c nu/scid) mice subcutaneously, with or without cultured fibroblastic cells of different origin. At one week after transplantation, the epidermal cells generated epidermoid cysts consisting of human epidermis-like tissue. When the epidermal cells were injected alone or together with fibroblastic cells derived from human bone marrow, muscle fascia, or murine dermis, organized epidermoid cysts regressed within 6 weeks. In contrast, when the epidermal cells were injected together with human dermal fibroblasts, generated epidermoid cysts were maintained in vivo for more than 24 weeks. Histological examination showed that the reorganized epidermis, after injection of both epidermal keratinocytes and dermal fibroblasts, retained normal structures of the original epidermis during 6 to 24 weeks after transplantation. The results indicate that human dermal fibroblasts facilitate the long-term maintenance of the reorganized epidermis after xenotransplantation of cultured human epidermal keratinocytes by supporting self renewal of the human epidermal tissue in vivo.     

Autoradiographic detection of mucopolysaccharide accumulation in single fibroblasts

Synopsis A method is described for localizing acid mucopolysaccharides autoradiographically in cultured cells. Normal fibroblasts and fibroblasts, from patients suffering from Mucopolysaccharidosis II disease (MPS II), were cultured for six days in the presence of³⁵SO₄ and one day in unlabelled medium. The cultured cells were transferred to a plastic film dish and, after settling, they were rapidly quenched, freeze-dried, fixed in osmium tetroxide vapour and embedded in Epon. Grain counting after autoradiography in 2 m sections revealed a significant difference (P>0.001)iin³⁵SO₄ incorporation in the perinuclear cytoplasm of MPS II cells and control cells grown under the same conditions. Autoradiography was also performed after mixing MPS II cells and control fibroblasts in a ratio 11. 8 prior to freezing and the same ratio was found between labelled and unlabelled fibroblasts. These results demonstrate the feasibility of the present autordiographic technique for the detection of the acid mucopolysaccharide storage at the single cell level.