Collagen synthesis by regenerating rabbit ear tissue

The principal collagen types synthesized during two distinct phases of regeneration in rabbit ears have been investigated, in order to relate altered phenotypic expression in connective tissue cells to regeneration of cartilage. To do this, radioactively labeled collagens synthesized in short-term culture by selected regenerating ear tissues were analyzed by ion-exchange chromatography and SDS-gel electrophoresis of the intact collagens and of the cyanogen bromide peptides derived from them. Prior to the appearance of cartilage, rabbit ear holes are filled by an outgrowth of mesenchyme-like cells derived locally from adjacent tissues. These cells produce a mixture of collagens including type I, [α1(I)]₂α2, and the type I trimer, [α1(I)]₃, but not type II collagen. Trimer production represents about one-fourth of the collagen synthesized in either a 4-, 10-, or a 24-hr incubation. Trimer is not made by tissues from healing skin wounds nor is it present in normal, uninjured ear tissues. Type II collagen synthesis was detected in tissues taken from late regenerates containing histologically recognizable cartilage, and direct analysis of regenerated cartilage confirmed the presence of type II collagen in the matrix. Thus, regenerated cartilage in the rabbit ear system contains the normal cartilage collagen, type II, while the proliferating cell mass from which the cartilage develops synthesizes the unusual collagen, [α1(I)]₃.     

Studies on cartilage formation. XVIII. Changes of the composition of glycosaminoglycans in the regenerating articular surface.

The cartilaginous articular surface of the distal part of the femur of adult dogs was removed and the composition of GAGs was determined in the granulation tissue adhering to the bone wound and in that adhering to the articular capsule 7, 33, and 70 days after operation. The articular cartilage and the synovial layer of the articular capsule of intact adult dogs were also studies. The materials were digested with papain and the released GAGs were fractionated according to Svejcar and Robertson's method. The articular cartilage of non-operated dogs contained, on the average, 65.3% ChS, 13% KS, 5.8% HA and 15.8% GAG of lower molecular weight. The synovial layer of the capsule contained 41.1% HA, 15.3% Ch4-S and Ch6-S, 13.7% DS, 21.7% KS, 2% H and 6% GAG of lower molecular weight. The granulation tissue of the articular surface and that adhering to the capsule show a different developmental course. The former differentiates into cartilage, whereas the latter is simply added to the tissue of the capsule. The two tissues are different in GAG composition as early as on the 7th postoperative day. With time an increase of Ch4-S, Ch6-S and KS can be observed in the tissue of the articular surface. The tissue adhering to the capsule is characterized by a high HA and an increasing DS content. From the study of the composition of GAG's (proportion of GAG building stones) a deeper insight can be obtained into the details of GAG biosynthesis characteristic of cartilage than from the analysis of quantitative data of ChS. In the development of GAG composition characteristic of the tissue, the epimerase reactions participating in GAG biosynthesis, and the mechanisms regulating their activities seem to play a primary role.     

Epidermal downgrowths in regenerating rabbit ear holes.

Rabbits are unique among mammals in that their ears can regenerate tissues from the margins of full thickness holes which grow in and completely fill the opening in about two months. The circular blastema that forms around the edges of the hole differentiates a new sheet of cartilage as it regenerates in a centripetal direction. Similar holes in other mammals fail to regenerate and form scar tissue instead of a blastema. Histological studies of the healing around the edges of rabbit ear holes reveal that during the second week, when the epidermis is completing its migration across the wound from the opposite sides of the ear, conspicuous tongues of epidermal cells grow down into the underlying tissues at the edges of the wound. These epidermal downgrowths are situated between the original intact dermis of the skin and the more central tissues which give rise to the blastema. Such downgrowths are of a transient nature, and are no longer found once the blastema rounds up toward the end of the second week. Since they are not found in the healing of similar wounds in rabbit ears prevented from regenerating by prior removal of their cartilaginous sheets, nor in the naturally nonregenerating ears of sheep and dogs, it is considered that these downgrowths of healing epidermis may play a role in the unusual regenerative response of ear tissues in the rabbit.     

The metabolic heterogeneity of rabbit ear cartilage chondroitin sulphate

The only glycosaminoglycans that can be isolated from the ear cartilage of 2-month-old rabbits are chondroitin 4-sulphate and chondroitin 6-sulphate. These chondroitin sulphates exhibit molecular-weight polydispersity when isolated from tissue by papain digestion. The chondroitin sulphate is metabolically heterogeneous in that radioactive precursors [(14)C]glucose or [(35)S]sulphate are preferentially incorporated into the higher-molecular-weight polymers both in vivo and in vitro. No transfer of radioactivity from the high-molecular-weight chondroitin sulphate to the low-molecular-weight chondroitin sulphate was seen during 15 days in vivo. It is suggested that there are at least two pools of proteoglycan in the tissue. One of these pools is metabolically active whereas the other is not.     

Intracellular lipids in rabbit ear cartilage during tissue regeneration

Circular holes 10 mm in diameter were punched in the proximal region of rabbit ears, and the intracellular lipid content of the regenerated cartilage and the neighbouring old cartilage was studied histochemically up to the 32nd week after wounding. Chondroblasts appeared in the peripheral zone of the regenerated tissue towards the end of the 3rd week, but no intracellular lipids were observed until the 8th week. In the following weeks chondrocytes and intracellular lipids appeared in the intermediate and central zones of the regenerated tissue, the production of cartilage and intracellular lipid being particularly vigorous in the central zone during the last weeks of the study. In the old cartilage adjoining the wound, intracellular lipid levels declined considerably except in new cells produced by proliferation of the perichondrium after wounding. Phospholipids were only observed in the youngest cartilage cells and disappeared when deposits of neutral lipids began to be formed. The interpretation of these observations and the function of intracellular lipids in cartilage are discussed.     

Studies on cartilage formation. XXII. Investigations of certain oxidative metabolic processes in regenerating articular cartilage

The distal articular surface of the femur was surgically removed in 57 dogs. Succinate dehydrogenase and cytochrome oxidase activities were assayed on postoperative days 7, 20, 26, 33 and 70 in the regenerating, chondrifying articular surface and in the granulation tissue adhering to the capsule. In the 70-day samples, the cyanide-induced inhibition of oxygen consumption was determined and enzyme histochemical reactions (cytochrome oxidase, monoamine oxidase, xanthine oxidase, peroxidase and "catalase") were performed. The succinate dehydrogenase activity was the highest in the early postoperative stage in both tissues. This was followed by a definite decrease and a subsequent significant increase in activity when chondrification took place. Measurement of cytochrome oxidase activity could not reveal any convincing result, presumably because of the properties of the tissues studied. The oxygen consumption by the chondrifying articular surface at 70 days was inhibited to about 50% by cyanide, and about 90% inhibition was observed in the tissue adhering to the capsule. The cells of the regenerating articular surface possess cytochrome oxidase and a cyanide- (and sodium azide-) resistant oxidase activity. The enzyme activity of the cartilaginous islets exceeded that of their connective tissue environment. The cytochrome oxidase activity increased in the cells during cartilage differentiation. Presumably, some further cyanide-sensitive and cyanide-resistant oxidases are present in chondroblasts and young chondrocytes.     

The effects of unilamellar perichondrial dissection on the growth of rabbit ear cartilage

The effects of elevation of the perichondrium from a surface of growing ear cartilage were investigated in immature rabbits. Eight 21-day-old rabbits completed the study in which perichondrium was elevated from one cartilaginous surface of one ear and the nonoperated ear served as a control. By maturity, both ears had developed symmetrically and no statistically significant difference could be demonstrated in length and surface area. Although several ears demonstrated subtle shape changes, the overall growth and development of the surgically manipulated ear cartilages did not appear to be affected. These findings appear to contradict a widely held view that perichondrial dissection of developing cartilage has a high potential for subsequent growth disturbances. The corollary has been that cartilage manipulation, such as that required in the surgical repair of the cleft lip nose deformity, should be delayed until the growth of cartilage is complete. These data would support the findings of long-term clinical studies which demonstrate the efficacy of early limited perichondrial dissection in the correction of the cleft lip nose deformity.     

Sulphated glycosaminoglycans in regenerating rat liver.

The total weight percentage glycosaminoglycan content of rat liber was found to increase by 50% in the first 30 h after partial hepatectomy. The content returned to near normal by the third day, but then increased again to a second maximum at 5-6 days, only to gradually decline to normal by the ninth day, when regeneration was nearly complete. This biphasic pattern was most marked in the chondroitin sulphate A/C component, with a 6-fold increase by the sixth day. Dermatan sulphate showed the same temporal trend, whereas heparan sulphate remained relatively unaltered. No such changes were detected in the livers of rats subjected to sham operation. The possible molecular mechanisms underlying the apparent link between cellular glycosaminoglycan content and proliferative tendency are discussed.     

Studies on cartilage formation. XVI. Chemical and histochemical assay of lipids in the regenerating articular cartilage.

The articular surface of the distal part of the femur was removed operatively in dogs, and the regenerating articular surface and the GTC were investigated at different stages from the 7th to the 70th postoperative days. During this period cartilage islets arose in the GTAS, while the GTC transformed to connective tissue. At 7 days the lipid content of the tissue was markedly higher than at the other stages studied. Lipids, predominantly triglycerides, were present in extracellular form as well. From the 20th to the 70th day the PL fraction became predominant and, in addition to the pre-existing lecithin, relatively large quantities of lysolecithin, sphingomyelin, phosphatidyl-ethanolamine, phosphatidyl-serine and phosphatidyl-inositol could be gradually demonstrated. Differences were noted in the time of appearance and binding of PLs between the two types of granulation tissue. As time proceeded, the proportion of saturated fatty acids decreased in favour of unsaturated ones. At 70 days, the GTAS contained fatty acids up to C18. About 50% of the fatty acids consisted of C16:1, C18:2 and C18:1. At the same stage, in the GTC C16:1, C18:1 and C20:1 were present in larger amounts. Of the free fatty acids C16:1, C16 and C18 were in predominance in the GTAS and the proportion of fatty acids having more then one double bonds increased with time. In the GTC C16 and C18:1 were in great majority. According to histochemical evidence, the tissues did not contain extracellular lipids from the 20th postoperative day. In the cells, the presence of glycerides, PLs, lipoproteins and cholesterol was demonstrated. In addition, in cartilage precursors of more advanced maturity, a considerable fatty acid positivity was noted.     

Ultrastructural demonstration of cartilage acid glycosaminoglycans

Synopsis A method for the demonstration of cartilage acid glycosaminoglycans by light and electron microscopy is described. Rabbit ear cartilage was fixed in cacodylate buffered 2.5% methanol-free formaldehyde with 0.001 M Ruthenium Red andp-chloromercuribenzoate (PCMB). Dehydration was carried out in ethylene glycol followed by embedding in the water-soluble glycol methacrylate (GMA). In some experiments unfixed cartilage was rapidly dehydrated. Sections, 1 thick, and ultrathin sections from the same blocks were stained with 0.001 M Ruthenium Red. Semi-thin sections from cartilage fixed without heavy metal additives were, in addition, stained with the acidophilic fluorochrome Berberine sulphate. It was found that Ruthenium Red intensely stained the same pericellular zone that stained metachromatically with Toluidine Blue or fluoresced after staining with Berberine sulphate. Prior treatment with 0.05% cetylpyridinium chloride entirely blocked the three reactions. Previous digestion with 0.2 mg hyaluronidase/ml for 30 min at 37°C led to the abolition of the fluorescence reaction with Berberine sulphate. It is concluded that Ruthenium Red selectively stains cartilage acid glycosaminoglycans. With the electron microscope the pericellular zones were found to be built up of a three-dimensional branched meshwork of fibrils covered with a mantle of electron-dense material, presumably acid glycosaminoglycans bound to Ruthenium Red.     

The glycosaminoglycans of human tracheobronchial cartilage

1. The glycosaminoglycans of human tracheobronchial cartilages from subjects of various ages were liberated by proteolysis of the tissue and purified by ion-exchange chromatography. Purified glycosaminoglycans were fractionated on Dowex 1 resin and cetylpyridinium chloride was used to separate chondroitin sulphates and keratan sulphates occurring in the same fraction. 2. The total chondroitin sulphate content of the cartilages decreased linearly with increasing age. Age-dependent changes in the chemical heterogeneity of chondroitin sulphate were observed, a low-sulphated compound making up 25% of the total glycosaminoglycan at birth but rapidly diminishing in content during the first 6 months of life. Of the total chondroitin sulphate the 6-isomer became rather more prominent than the 4-isomer with increasing age. 3. The total keratan sulphate content of the cartilages increased from trace amounts only at birth to a plateau value by the beginning of the fifth decade. Of the total keratan sulphate approx. 70% was due to a high-molecular-weight compound with a sulphate/hexosamine ratio of 1.5-1.8: 1.0. The degree of sulphation varied between compounds isolated from different individuals. The remaining 30% of the keratan sulphate appeared to be intimately associated with chondroitin 6-sulphate and could only be separated from it after treatment with 0.45m-potassium hydroxide. The hybrid glycosaminoglycans were of lower molecular weight and had a lower sulphate/hexosamine ratio than the major keratan sulphate compound.     

Histochemistry of glycosaminoglycans in cartilage ground substance

Summary The critical-electrolyte-concentration staining method using Alcian blue (AB) was applied to etched semithin Epon-embedded sections. The distribution of various glycosaminoglycans (GAGs) was studied in hyaline, elastic, cellular and fibrous cartilage obtained from humans and rodents. The staining patterns in semithin sections were found to correspond to those obtained using paraffin-embedded material. Lectin histochemistry was performed on consecutive sections. The following peroxidase-labelled lectins were used: Ricinus communis A I, Arachis hypogaea, Ulex curopaeus A I, Triticum vulgaris, Helix pomatia, Limax flavus, and concanavalin A. The lectin-binding capacity of cartilaginous ground substance was found to be low, as was expected on account of the few free sugar residues of GAGs. Chondroitin sulphate, the most widely distributed GAG, did not exhibit lectin staining. The lectin-binding site (positive staining for all lectins tested except H. pomatia) observed corresponded to areas positive forkeratan sulphate, as shown by AB staining in preceding or following sections. The pronounced lectin binding seen in cellular structures and the inner territorial matrix regions is considered to be due to higher concentrations of oligosaccharides involved in the metabolism of GAGs.Supported by the Hochschuljubiläumsstiftung der Stadt Wien     

Studies on cartilage formation XIX. Oxygen and glucose supply of the regenerating articular surface.

Complete removal of the articular cartilage in dogs is followed by regeneration of the articular surface. At the site of the bone wound, granulation tissue develops, which later differentiates into cartilage. The O2 and glucose supply of the regenerating articular surface is ensured by the synovial fluid, by the large exposed surface of the medullary cavity, and by the capillary network of the granulation tissue. Oxygen and glucose supply of the articular surface in different stages of differentiation has been statistically analyzed. It is suggested that in the early stage of regeneration O2 supply comes predominantly from the capillaries of the granulation tissue. Later on, as capillarization regresses, the oxygen supply, originating from the synovia and medullary cavity, assumes a more important role. In the stage of cartilage regeneration an oxygen-deficient state can be supposed in the entire articular surface, but areas differing in oxygen supply may be formed owing to local differences (due mainly to the extent of vascularization and degree of generation of the subchondral bone layer). At the site of chondrogenesis, conditions allowing aerobic metabolism of cells with reduced O2 requirements seem to be ensured. Glucose supply deriving from the above-mentioned sources satisfies the highest glucose requirements of the cells in the regenerating articular surface.