Julio C. Pita

Partition of calcium, phosphate, and protein in the fluid phase aspirated at calcifying sites in epiphyseal cartilage

A reproducible method, adapted from renal micropuncture techniques, was developed for sampling 10-40 mmul of a clear fluid from epiphyseal cartilage of normal or rachitic rats in vivo, either from the hypertrophic cell zone (C(f1)) or surface resting cell cartilage (L(f1)). Characterization of this fluid depended upon quantitation of protein, total inorganic phosphate (P(it)), total calcium (Ca(t)), nucleotide, and hemoglobin in volumes of 20 mmul. Established methods for macroscale measurements of each of these parameters have been modified to permit direct spectrophotometric readings on samples of 10(-10)-10(-11) g. The fluid from hypertrophic and peripheral resting cell cartilage was of an extracellular nature as evidenced by a high chloride and sodium, as well as low potassium, protein, and nucleotide content. The pH of fluid isolated from endochrondral plates in vivo was measured under oil as a function of P(CO2) and the computed bicarbonate was elevated above concurrent serum levels. After ultracentrifugation of C(f1) of normal, rachitic, and healing rachitic animals, nonprotein-bound calcium (Ca(f)) and phosphate (P(if)) were determined on supernatant fluids. The hypertrophic cell cartilage fluid of rachitic rats was distinguished by a high ratio C(f1)/serum of P(if). This ratio returned to normal during treatment of rickets. The upper limit for ionic activity A(1) Ca(++) x A HPO(4) (=) was too low to initiate precipitation of brushite or dicalcium phosphate but was in a range of supersaturation in respect to crystalline apatites. Thus these data are consistent with initiation of calcification by heterogeneous nucleation of mineral in the septal matrix but can be reconciled alternately with a precipitation mechanism only if the site of initial mineral phase separation is outside the septal matrix.

Mechanical behavior and biochemical composition of canine knee cartilage following periods of joint disuse and disuse with remobilization

The mechanical behavior and biochemical composition of articular cartilage were studied in an experimental model of joint disuse, in which the canine knee was immobilized in a sling at 90 degrees of flexion. Articular cartilage from the surface zone of the femur was tested in an isometric tensile test and full-thickness cartilage on the tibial plateau was tested in a compressive indentation test. Water, proteoglycan and collagen contents were measured in site-matched samples. Site-specific increases in the tensile moduli (approximately 88% above control values in distal femoral groove) were observed in cartilage after 8 weeks of joint disuse, and after 3 weeks of remobilization following either 4 (approximately 140%, distal and proximal femoral groove) or 8 weeks (approximately 140%, distal femoral groove) of joint disuse. In contrast, the compressive properties of cartilage determined in the indentation test exhibited no change from control values with joint disuse or disuse followed by remobilization. Water contents increased at some sites on the tibia after 8 weeks of joint disuse (approximately 6% of tissue wet weight, posterior site), but not in the surface zone tissue of the femur. Proteoglycan/collagen and cartilage thickness were not found to change with disuse or disuse followed by remobilization. Reduced values for the ratio of proteoglycan:water were observed in the surface zone tissue of the femur (approximately 23%, distal femoral groove) and in the full-thickness tissue of the tibia (approximately 21%, anterior and posterior sites) after periods of joint disuse. In this study, the measured material properties suggest that the articular surface remains intact following periods of disuse or disuse with remobilization. This finding suggests one important difference between this model of joint disuse and other experimental models in which cartilage changes are both progressive and degenerative, such as surgically-induced joint instability.

Demonstration of macromolecular inhibitor(s) of calcification and nucleational factor(s) in fluid from calcifying sites in cartilage

An extracellular fluid phase (C(f1)), aspirated by micropuncture techniques from the hypertrophic cell zone of calcifying epiphyseal certilage, has been characterized in a calcifying system in vitro in respect to the behavior of sedimenting and supernatant fractions after high speed ultracentrifugation. To perform these tests on the starting samples of 20 nl of C(f1), macroscopic analytical methods were scaled down for the identification of relevant organic components, including hexuronic acid and proteinpolysaccharides (PPL). The mineral accretion system was designed to simulate physiologic conditions in the calcifying cartilage septa of normal rats, and the mineral used for seeding was an immature calcium phosphate similar to native cartilage mineral. Normal C(f1) or its dilutions in synthetic lymph up to 1:4 completely prevented mineral accretion in vitro. The inhibitory action was localized to the sedimented fractions after ultracentrifugation and could be destroyed by incubation with trypsin or hyaluronidase. The sediment of C(f1) contained 2 mg of hexuronic acid per ml of C(f1) and gave a strong reaction of identification for a light fraction of PPL by fluorescent antibodies to rat PPL. PPL fractions were tested in the same mineral accretion systems as C(f1) and exhibited responses similar to those of C(f1). Also, there was evidence of a mineral phase in C(f1) of normal rats, in C(f1) of rats with healing rickets, but not in C(f1) of untreated rachitic rats. These results are interpreted to indicate that certain PPLs function as an inhibitor of crystal growth at extracellular sites premonitory to calcification. Evidence for a low density inhibitor of mineral accretion was found in normal serum but not in C(f1).

The pathogenesis of osteoarthritis

This article reviews the etiology and pathogenesis of osteoarthritis, particularly one of several current concepts concerning the possible central mechanisms regulating degradation of cartilage. According to this theory, degradation involves diffuse or focal exposure of the extracellular matrix to active neutral metalloproteinases, which then results in injury as well as initiation of repair processes. Diffuse matrix exposure is probably not a physiologic aberrancy but rather a pathologic result of either physical injury to local chondrocytes or inflammatory mediators.

Localization of collagenase in the growth plate of rachitic rats.

In the transition from proliferation to hypertrophic cell zones in the growth plate, there is an increase in chondrocyte volume and a corresponding decrease in collagen content to accommodate the enlarging cells. It is postulated that collagenase accounts for this collagen loss. To test this hypothesis, tibial growth plates were obtained from normal rats, rachitic rats deficient in vitamin D and phosphate, and rats after 48 and 72 h of healing from rickets. Collagenase was quantitated by a pellet assay based on the release of solubilized collagen from the endogenous insoluble collagen in the tissue homogenates. A fourfold greater collagen release and a concomitant sixfold greater hypertrophic cell volume were measured in rachitic growth plates compared with normal age-matched controls. During healing of rickets, collagenase activity and hypertrophic cell volume returned almost to control levels. Rachitic growth plates were dissected into the juxtaepiphyseal 1/3 and the juxtametaphyseal 2/3. The latter portion contained greater than 95% of the hypertrophic cells and 86% of the collagenase. The collagen-degrading activity was extracted from this region and was shown to be a true collagenase by its production of typical A fragments of tropocollagen produced by collagenase action. The enzyme was activated by aminophenylmercuric acetate and trypsin and was inhibited by EDTA, 1,10-phenanthroline, and a tissue inhibitor of metalloproteinases from human articular cartilage. Inhibitors of aspartic, cysteine, and serine proteases had no effect. Micropuncture fluids aspirated from rachitic cartilage contained latent collagenase activity, indicating an extracellular localization. Negative tests for hemoglobin in the rachitic cartilage samples indicated that there was no contamination by capillaries and that this was not a source of collagenase. It is concluded that extracellular collagenase accounts for the loss of cartilage matrix in the hypertrophic zone, and that this process may be distinct from that of capillary invasion.

Evidence for a role of proteinpolysaccharides in regulation of mineral phase separation in calcifying cartilage

Our previous studies have indicated the presence of a macromolecular inhibitor of in vitro mineral growth, as well as a mineral nucleational agent in extracellular matrix fluid aspirated by micropuncture methods from epiphyseal hypertrophic cell cartilage. In this report, new miniaturized methods were used to extract proteinpolysaccharide complexes (PPC) from cartilage, to isolate a light fraction (PPL-C), and further, to separate it into R1, R2, and SR2 subfractions. These methods were applied to PPL-C complexes separated from microdissected epiphyseal cartilages and to cetylpyridinium chloride (CPC) precipitates of extracellular matrix fluid aspirated from similar cartilages. Most of all of the inhibitory action on an in vitro system of mineral growth shown by whole cartilage PPL-C and by cartilage fluid PPC obtained from noncalcifying sites was contained in the R2 fraction which represented (1/4)-[unk] of the total hexuronate. The R2 fraction was diminished or absent from calcified cartilage fluids and from whole calcified epiphyseal septa. The ratio R1 + R2: SR2 ranged from 0.37 to 0.71 in the fluids and whole tissue samples of noncalcified cartilages. The R2 fraction was distinguished from SR2 by a 2- to 3-fold higher protein: hexuronate ratio. These data are interpreted to indicate that the inhibitory R2 fraction was degraded or otherwise inactivated at the zone of provisional calcification and that this inhibitor participates in the physiological mechanism that regulates endochondral calcification.

Effects of vitamin D metabolites on healing of low phosphate, vitamin D-deficient induced rickets in rats

A model of low-phosphate, vitamin D-deficient rachitic rats was used to compare the effects of 1 alpha(OH)D3, 1,25(OH)2D3, and 24,25(OH)2D3 on cartilage and bone. The rats were maintained for 3 weeks on a high-calcium, low-phosphate, vitamin D-deficient diet, during which period they developed severe rickets. The rachitic rats were injected for 2 or 3 consecutive days with a physiologic dose of either metabolite. Other littermates were given a single dose of 50,000 IU of cholecalciferol in combination with a normal diet. Samples of cartilage fluid (Cfl) and of blood were removed prior to sacrifice for biochemical studies of some parameters of calcification. These parameters were correlated with the results of light and electron microscopic studies of the growth plate cartilage and bone. Treatment with 1 alpha (OH)D3 or with 1,25(OH)2D3, in spite of increasing Ca and P levels in the Cfl, induced only partial healing of the rickets. In contrast, 24,25(OH)2D3 or vitamin D with a normal diet resulted in complete morphologic and biochemical healing of the rickets. Transmission electron microscopic (TEM) studies have shown partial mineralization of the wide hypertrophic zone of the growth plate following treatment with 1 alpha(OH)D3 or with 1,25(OH)2D3. Mineralization was more complete with 24,25(OH)2D3 treatment. The results of this study emphasize the importance of 24,25(OH)2D3 for normal endochondral bone formation and mineralization.

Extrusion of pyrophosphate into extracellular media by osteoarthritic cartilage incubates.

The distribution of calcium pyrophosphate mineral phase, almost exclusively confined to articular cartilage in chondrocalcinosis, and the high level of pyrophosphate (PPi) ion relative to serum in synovial fluid in patients with either chondrocalcinosis or advanced osteoarthritis led to an investigation of whether cartilage cells elaborate PPi ions. Incubates of articular cartilage from young rabbits but not from mature rabbits, as well as growth plates cartilage, released PPi into incubation media during a 4h period. Control rabbit ear cartilage and synovial membrane elaborated negligible amounts of PPi. The PPi was shown to be undialyzable but could be dissociated from the alkaline phosphatase by ultracentrifugation. In 16 patients with osteoarthritis, a substantial output of PPi by samples of articular cartilage from the knee was demonstrated. It is postulated that either rapid cell division and matrix synthesis found in the base of ulcerating osteoarthritic cartilage or remodeling calcified sites are the source of the PPi in such osteoarthritic cartilage. It is further hypothesized that this PPi output accounts at least in part for the elevated PPi levels found in synovial fluid of patients with osteoarthritis.

Calcificaiton of growth plate cartilage with special reference to studies on micropuncture fluids.

No final comprehensive hypothesis of the chain of events involved in inhibition of calcification can be constructed at the present time. The flow diagram in Figure 1 is presented only as a working hypothesis currently used by the authors. Insofar as the Cfl is representative of native factors at calcifying sites, none of the major theories on the nature of mineral formation at present seem excluded. As in the fields of clotting and complement pathways, where backup systems seem to operate, one should not be surprised if more than one system operates in cartilaginous calcification.

Lysozyme in preosseous cartilage VII. Evidence for physiological role of losozyme in normal endochondral calcification

Abstract Previous work demonstrated that micropuncture aspirates from rat epiphysical plate cartilage contain a nucleating agent for Ca 3 (PO 4 ) 2 mineral growth, and that the nucleation is inhibited by proteoglycan aggregates. In this report data are described which show that mammalian lysozyme inactivates the inhibition. When micropuncture aspirates are incubated in vitro with mammalian lysozyme, a rapid, spontaneous initiation of mineral growth occurs. Incubation of proteoglycan aggregate preparations in the presence of cartilagea lysozyme, but not hen egg white lysozyme, causes a marked decrease of the sedimentation coefficients of the proteoglycans, usually to values close to those obtained with proteoglycan monomer preparations. The inhibition of this effect of mammalian lysozyme by a specific inhibitor of the enzyme tri( N -acetyl-D-glucosamine) suggests that it may be enzymatic in nature.