Osteoclastic bone degradation and the role of different cysteine proteinases and matrix metalloproteinases: differences between calvaria and long bone.

Osteoclastic bone degradation involves the activity of cathepsin K. We found that in addition to this enzyme other, yet unknown, cysteine proteinases participate in digestion. The results support the notion that osteoclasts from different bone sites use different enzymes to degrade the collagenous bone matrix. INTRODUCTION: The osteoclast resorbs bone by lowering the pH in the resorption lacuna, which is followed by secretion of proteolytic enzymes. One of the enzymes taken to be essential in resorption is the cysteine proteinase, cathepsin K. Some immunolabeling and enzyme inhibitor data, however, suggest that other cysteine proteinases and/or proteolytic enzymes belonging to the group of matrix metalloproteinases (MMPs) may participate in the degradation. In this study, we investigated whether, in addition to cathepsin K, other enzymes participate in osteoclastic bone degradation. MATERIALS AND METHODS: In bones obtained from mice deficient for cathepsin K, B, or L or a combination of K and L, the bone-resorbing activity of osteoclasts was analyzed at the electron microscopic level. In addition, bone explants were cultured in the presence of different selective cysteine proteinase inhibitors and an MMP inhibitor, and the effect on resorption was assessed. Because previous studies showed differences in resorption by calvarial osteoclasts compared with those present in long bones, in all experiments, the two types of bone were compared. Finally, bone extracts were analyzed for the level of activity of cysteine proteinases and the effect of inhibitors hereupon. RESULTS: The analyses of the cathepsin-deficient bone explants showed that, in addition to cathepsin K, calvarial osteoclasts use other cysteine proteinases to degrade bone matrix. It was also shown that, in the absence of cathepsin K, long bone osteoclasts use MMPs for resorption. Cathepsin L proved to be involved in the MMP-mediated resorption of bone by calvarial osteoclasts; in the absence of this cathepsin, calvarial osteoclasts do not use MMPs for resorption. Selective inhibitors of cathepsin K and other cysteine proteinases showed a stronger effect on calvarial resorption than on long bone resorption. CONCLUSIONS: Our findings suggest that (1) cathepsin K-deficient long bone osteoclasts compensate the lack of this enzyme by using MMPs in the resorption of bone matrix; (2) cathepsin L is involved in MMP-mediated resorption by calvarial osteoclasts; (3) in addition to cathepsin K, other, yet unknown, cysteine proteinases are likely to participate in skull bone degradation; and finally, (4) the data provide strong additional support for the existence of functionally different bone-site specific osteoclasts.     

Calvarial Osteoclasts Express a Higher Level of Tartrate-Resistant Acid Phosphatase than Long Bone Osteoclasts and Activation Does not Depend on Cathepsin K or L Activity

Bone resorption by osteoclasts depends on the activity of various proteolytic enzymes, in particular those belonging to the group of cysteine proteinases. Next to these enzymes, tartrate-resistant acid phosphatase (TRAP) is considered to participate in this process. TRAP is synthesized as an inactive proenzyme, and in vitro studies have shown its activation by cysteine proteinases. In the present study, the possible involvement of the latter enzyme class in the in vivo modulation of TRAP was investigated using mice deficient for cathepsin K and/or L and in bones that express a high (long bone) or low (calvaria) level of cysteine proteinase activity. The results demonstrated, in mice lacking cathepsin K but not in those deficient for cathepsin L, significantly higher levels of TRAP activity in long bone. This higher activity was due to a higher number of osteoclasts. Next, we found considerable differences in TRAP activity between calvarial and long bones. Calvarial bones contained a 25-fold higher level of activity than long bones. This difference was seen in all mice, irrespective of genotype. Osteoclasts isolated from the two types of bone revealed that calvarial osteoclasts expressed higher enzyme activity as well as a higher level of mRNA for the enzyme. Analysis of TRAP-deficient mice revealed higher levels of nondigested bone matrix components in and around calvarial osteoclasts than in long bone osteoclasts. Finally, inhibition of cysteine proteinase activity by specific inhibitors resulted in increased TRAP activity. Our data suggest that neither cathepsin K nor L is essential in activating TRAP. The findings also point to functional differences between osteoclasts from different bone sites in terms of participation of TRAP in degradation of bone matrix. We propose that the higher level of TRAP activity in calvarial osteoclasts compared to that in long bone cells may partially compensate for the lower cysteine proteinase activity found in calvarial osteoclasts and TRAP may contribute to the degradation of noncollagenous proteins during the digestion of this type of bone. An erratum to this article is available at .     

The bone lining cell: its role in cleaning Howship's lacunae and initiating bone formation.

In this study we investigated the role of bone lining cells in the coordination of bone resorption and formation. Ultrastructural analysis of mouse long bones and calvariae revealed that bone lining cells enwrap and subsequently digest collagen fibrils protruding from Howship's lacunae that are left by osteoclasts. By using selective proteinase inhibitors we show that this digestion depends on matrix metalloproteinases and, to some extent, on serine proteinases. Autoradiography revealed that after the bone lining cells have finished cleaning, they deposit a thin layer of a collagenous matrix along the Howship's lacuna, in close association with an osteopontin-rich cement line. Collagenous matrix deposition was detected only in completely cleaned pits. In bone from pycnodysostotic patients and cathepsin K-deficient mice, conditions in which osteoclastic bone matrix digestion is greatly inhibited, bone matrix leftovers proved to be degraded by bone lining cells, thus indicating that the bone lining cell "rescues" bone remodeling in these anomalies. We conclude that removal of bone collagen left by osteoclasts in Howship's lacunae is an obligatory step in the link between bone resorption and formation, and that bone lining cells and matrix metalloproteinases are essential in this process.     

Differences in matrix composition between calvaria and long bone in mice suggest differences in biomechanical properties and resorption: Special emphasis on collagen

The mammalian skeleton consists of bones that are formed in two different ways: long bones via endochondral ossification and flat bones via intramembranous ossification. These different formation modes may result in differences in the composition of the two bone types. Using the 2D-difference in gel electrophoresis technique and mass spectrometry, we analyzed the composition of murine mineral-associated proteins of calvaria and long bone. Considerable differences in protein composition were observed. Flat bones (calvariae) contained more soluble collagen (8x), pigment epithelium derived factor (3x) and osteoglycin (4x); whereas long bones expressed more chondrocalcin (3x), thrombospondin- 1 (4x), fetuin (4x), secreted phosphoprotein 24 (3x), and thrombin (7x). Although cystatin motifs containing proteins, such as secreted phosphoprotein 24 and fetuin are highly expressed in long bone, they did not inhibit the activity of the cysteine proteinases cathepsin B and K. The solubility of collagen differed which coincided with differences in collagen crosslinking, long bone containing 3x more (hydroxylysine)-pyridinoline. The degradation of long bone collagen by MMP2 (but not by cathepsin K) was impaired. These differences in collagen crosslinking may explain the differences in the proteolytic pathways osteoclasts use to degrade bone. Our data demonstrate considerable differences in protein composition of flat and long bones and strongly suggest functional differences in formation, resorption, and mechanical properties of these bone types.     

Family 2 cystatins inhibit osteoclast-mediated bone resorption in calvarial bone explants

Osteoclastic bone resorption depends on the activity of various proteolytic enzymes, in particular those belonging to the group of cysteine proteinases. Biochemical studies have shown that cystatins, naturally occurring inhibitors of these enzymes, inhibit bone matrix degradation. Since the mechanism by which cystatins exert this inhibitory effect is not completely resolved yet, we studied the effect of cystatins on bone resorption microscopically and by Ca-release measurements. Calvarial bone explants were cultured in the presence or absence of family 2 cystatins and processed for light and electron microscopic analysis, and the culture media were analyzed for calcium release. Both egg white cystatin and human cystatin C decreased calcium release into the medium significantly. Microscopic analyses of the bone explants demonstrated that in the presence of either inhibitor, a high percentage of osteoclasts was associated with demineralized non-degraded bone matrix. Following a 24-h incubation in the presence of cystatin C, 41% of the cells were adjacent to areas of demineralized non-degraded bone matrix, whereas in controls, this was only 6%. If bone explants were cultured with both PTH and cystatin C, 60% of the osteoclasts were associated with demineralized non-degraded bone matrix, compared to 27% for bones treated with PTH only (P < 0.01). Our study provides evidence that cystatins, the naturally occurring inhibitors of cysteine proteinases, reversibly inhibit bone matrix degradation in the resorption lacunae adjacent to osteoclasts. These findings suggest the involvement of cystatins in the modulation of osteoclastic bone degradation.     

Plasminogen activators are involved in the degradation of bone by osteoclasts

Osteoclastic bone degradation depends on the activity of several proteolytic enzymes, in particular to those belonging to the classes of cysteine proteinases and matrix metalloproteinases (MMPs). Yet, several findings suggest that the two types of plasminogen activators (PA), the tissue- and urokinase-type PA (tPA and uPA, respectively) are also involved in this process. To investigate the involvement of these enzymes in osteoclast-mediated bone matrix digestion, we analyzed bone explants of mice that were deficient for both tPA and uPA and compared them to wild type mice. The number of osteoclasts as well as their ultrastructural appearance was similar for both genotypes. Next, calvarial and metatarsal bone explants were cultured for 6 or 24 h in the presence of selective inhibitors of cysteine proteinases or MMPs and the effect on osteoclast-mediated bone matrix degradation was assessed. Inhibition of the activity of cysteine proteinases in explants of control mice resulted in massive areas of non-digested demineralized bone matrix adjacent to the ruffled border of osteoclasts, an effect already maximal after 6 h. However, at that time point these demineralized areas were not observed in bone explants from uPA/tPA deficient mice. After prolonged culturing (24 h), a comparable amount of demineralized bone matrix adjacent to actively resorbing osteoclasts was observed in the two genotypes, suggesting that degradation was delayed in uPA/tPA deficient bones. The activity of cysteine proteinases as assessed in bone extracts, proved to be higher in extracts from uPA/tPA(-/-) bones. Immunolocalization of the integrin alpha(v)beta(3) of in vitro generated osteoclasts demonstrated a more diffuse labeling of osteoclasts derived from uPA/tPA(-/-) mice. Taken together, our data indicate that the PAs play a hitherto unrecognized role in osteoclast-mediated bone digestion. The present findings suggest that the PAs are involved in the initial steps of bone degradation, probably by a proper integrin-dependent attachment to bone.     

Bone resorption by isolated osteoclasts in living versus devitalized bone: differences in mode and extent and the effects of human recombinant tissue inhibitor of metalloproteinases

The incubation of isolated osteoclasts with devitalized bone has become a widely used method for the recent study of bone resorption. Although the studies employing this method have definitively demonstrated that isolated osteoclasts have an avid capacity to resorb devitalized bone, the resorption in this model appears to be different from that of living bone as observed in vivo and in organ culture studies. To evaluate how the resorption of living bone is different from that of devitalized bone, we have extended this bone resorption model using isolated osteoclasts by including both devitalized and living bone substrates. Living bone substrates were freshly prepared from calvaria of 8- to 12-month-old mice. Periosteum, cellular components, and osteoid were completely scraped off to leave a rigid, smooth, mineral-exposed surface for the isolated osteoclasts to act upon. Some of the bone pieces were devitalized by repeated freezing and thawing. Living and devitalized bones were cultured with isolated rabbit osteoclasts for 60 h with or without recombinant human tissue inhibitor of metalloproteinases (100 micrograms/ml). The extent of bone resorption was assessed by measuring both the area and the depth of resorption pits. Comparing the areas of the resorption pits showed significantly more resorption in living bone than in devitalized bone (27% of that of living bone). Recombinant human TIMP reduced the resorption of living bone by 73% but did not, however, inhibit the resorption of devitalized bone. Similarly, resorption pits formed on the living bones were significantly deeper (on the average, 12.4 microns) than those formed on the devitalized bones (on the average, 4.3 microns). The average depth of the resorption pits on living bone was significantly reduced by the presence of the inhibitor, whereas there was no difference between the control and inhibitor-treated devitalized bones. These results suggest that the mechanisms underlying the resorption of living bone and that of devitalized bone are not the same and that the resorption of living bone is aided by osteocytes.     

Different Cysteine Proteinases Involved in Bone Resorption and Osteoclast Formation

Cysteine proteinases, especially cathepsin K, play an important role in osteoclastic degradation of bone matrix proteins and the process can, consequently, be significantly inhibited by cysteine proteinase inhibitors. We have recently reported that cystatin C and other cysteine proteinase inhibitors also reduce osteoclast formation. However, it is not known which cysteine proteinase(s) are involved in osteoclast differentiation. In the present study, we compared the relative potencies of cystatins C and D as inhibitors of bone resorption in cultured mouse calvariae, osteoclastogenesis in mouse bone marrow cultures, and cathepsin K activity. Inhibition of cathepsin K activity was assessed by determining equilibrium constants for inhibitor complexes in fluorogenic substrate assays. The data demonstrate that whereas human cystatins C and D are equipotent as inhibitors of bone resorption, cystatin D is 10-fold less potent as an inhibitor of osteoclastogenesis and 200-fold less potent as an inhibitor of cathepsin K activity. A recombinant human cystatin C variant with Gly substitutions for residues Arg⁸, Leu⁹, Val¹⁰, and Trp¹⁰⁶ did not inhibit bone resorption, had 1,000-fold decreased inhibitory effect on cathepsin K activity compared to wildtype cystatin C, but was equipotent with wildtype cystatin C as an inhibitor of osteoclastogenesis. It is concluded that (i) different cysteine proteinases are likely to be involved in bone resorption and osteoclast formation, (ii) cathepsin K may not be an exclusive target enzyme in any of the two systems, and (iii) the enzyme(s) involved in osteoclastogenesis might not be a typical papain-like cysteine proteinase.     

A peptidyl derivative structurally based on the inhibitory center of cystatin C inhibits bone resorption in vitro

Human cystatin C is a cysteine proteinase inhibitor belonging to the cystatin superfamily, which previously has been shown to inhibit bone resorption in bone organ culture. The aminoterminal segment, Arg(8)-Leu(9)-Val(10)-Gly(11) (RLVG), of the single polypeptide chain of cystatin C constitutes an essential part of its inhibitory center. In the present study, the effect of benzyloxycarbonyl-Arg(8)-Leu(9)-Val(10)-Gly(11)-diazomethane (Z-RLVG-CHN(2)) on bone resorption in vitro was compared with the effects of cystatin C and calcitonin. Bone resorption was assessed by the release of (45)Ca and (3)H from mouse calvarial bones prelabeled with [(45)Ca]CaCl(2) and [(3)H]-proline, respectively. Z-RLVG-CHN(2) concentration-dependently inhibited the release of (45)Ca and (3)H in bones stimulated by parathyroid hormone (PTH), with half-maximal inhibition obtained at 1 micromol/L. The inhibitory actions of Z-RLVG-CHN(2) and cystatin C were persistent, whereas action induced initially by calcitonin was lost with time. The inhibition caused by Z-RLVG-CHN(2) and cystatin C on PTH-stimulated (45)Ca release was observed after 6 h, whereas inhibition by calcitonin was seen already after 2 h. In contrast, the inhibitory effects of Z-RLVG-CHN(2) and cystatin C, as well as that of calcitonin, on (3)H release was seen already after 2 h. Z-RLVG-CHN(2), in which the reactive carboxyterminal diazomethane was substituted by nonreactive groups [-OH, -NH(2), or -N(CH(3))(2)], resulted in peptidyl derivatives, which, in contrast to Z-RLVG-CHN(2) and cystatin C, inhibited neither cysteine proteinases nor bone resorption. In contrast to wild-type cystatin C, recombinant human cystatin C with Gly substitutions for residues Arg(8), Leu(9), Val(10), and Trp(106), and with low or nonexistent affinity for cysteine proteinases, did not display any inhibitory effect on bone resorption. These data strongly indicate that Z-RLVG-CHN(2) inhibits bone resorption in vitro by a mechanism that seems primarily to be due to an inhibition of bone matrix degradation via cysteine proteinases. The data also corroborate the hypothesis that cystatin C inhibits bone resorption by virtue of its cysteine proteinase inhibitory capacity.     

Cathepsin K knockout mice develop osteopetrosis due to a deficit in matrix degradation but not demineralization.

Cathepsin K is a cysteine protease expressed predominantly in osteoclasts. Activated cathepsin K cleaves key bone matrix proteins and is believed to play an important role in degrading the organic phase of bone during bone resorption. Mutations in the human cathepsin K gene have been demonstrated to be associated with a rare skeletal dysplasia, pycnodysostosis. The degree of functional activity of the mutated forms of cathepsin K in these individuals has not been elucidated, but is predicted to be low or absent. To study the role of cathepsin K in bone resorption, we have generated mice deficient in the cathepsin K gene. Histologic and radiographic analysis of the mice revealed osteopetrosis of the long bones and vertebrae, and abnormal joint morphology. X-ray microcomputerized tomography images allowed quantitation of the increase in bone volume, trabecular thickness, and trabecular number in both the primary spongiosa and the metaphysis of the proximal tibiae. Not all bones were similarly affected. Chondrocyte differentiation was normal. The mice also had abnormalities in hematopoietic compartments, particularly decreased bone marrow cellularity and splenomegaly. The heterozygous animals appeared normal. Close histologic examination of bone histology revealed fully differentiated osteoclasts apposed to small regions of demineralized bone. This strongly suggests that cathepsin K-deficient osteoclasts are capable of demineralizing the extracellular matrix but are unable to adequately remove the demineralized bone. This is entirely consistent with the proposed function of cathepsin K as a matrix-degrading proteinase in bone resorption.     

Isolation of osteoclasts from fetal rat long bones

Cell isolates containing multinucleate osteoclasts were obtained from longitudinally split fetal rat long bones by treatment with testicular hyaluronidase. The total yield of osteoclasts and the osteoclast enrichment of the isolate were increased if the intact bones were first cultured for 72 h. Even greater enhancement was obtained if the bones were treated with 1,25-dihydroxycholecalciferol [1,25(OH)2D3] during the culture period. This technique resulted in a cell population containing approximately 15% osteoclasts in yields greater than 50 osteoclasts per long bone. The yield of osteoclasts and the percentage of osteoclasts correlated well with the extent of bone resorption induced by 1,25(OH)2D3. The effectiveness of several isolation procedures was compared using the 1,25(OH)2D3-treated long bones. Conventional digestion with 1 mg/ml crude collagenase gave a much poorer yield of osteoclasts than simply agitating the split long bones. Hyaluronidase plus EDTA was not significantly different from EDTA alone. Even with milder procedures, however, the isolated osteoclasts were damaged as judged by their failure to exclude trypan blue. The osteoclasts are obviously very fragile cells. The isolation technique coupled with May-Grunwald-Giemsa staining permitted reliable determination of the median number of nuclei per osteoclast. This parameter was the same in uncultured bones or in bones cultured for 72 h in control media. Treatment with 1,25(OH)2D3 increased the nuclear number. At lower levels of bone resorption, nuclear number did not increase, but it was significantly greater in more highly resorbed bones.     

An ultrastructural evaluation of the effects of cysteine-proteinase inhibitors on osteoclastic resorptive functions

This study was designed to evaluate the effects of specific and potent cathepsin inhibitors on osteoclastic resorptive functions in vitro by means of a novel ultrastructural assay system. Mouse bone marrow cell-derived osteoclasts were suspended on dentine slices and cultured for 48 hours in the presence of either E-64 (a generalized cysteine proteinase inhibitor) or Z-Phe-Phe-CHN₂ (a selective cathepsin L inhibitor). After the removal of cultured osteoclasts, co-cultured dentine slices were examined using electron microscopy: backscattered (BSEM), scanning (SEM), and atomic force (AFM). In morphometric analyses of BSEM images, there were no significant differences in the areas of demineralized dentine surfaces between control and inhibitor-treated groups, suggesting that cathepsin inhibitors had no effect on dentine demineralization by cultured osteoclasts. However, in SEM and AFM observations, both inhibitors remarkably reduced to the same extent, the formation of deep resorption lacunae on dentine slices that had resulted from degradation of matrix collagen. In addition, Z-Phe-Phe-CHN₂ treatment produced deeper, ring-like grooves with little collagen exposure in shallow resorption lacunae. These results strongly suggest that (1) cathepsins released by osteoclasts are involved in the formation of deep resorption lacunae, and (2) cathepsin L plays a key role in bone resorption.     

Comparison in localization between cystatin C and cathepsin K in osteoclasts and other cells in mouse tibia epiphysis by immunolight and immunoelectron microscopy

We compared the distribution of a cysteine proteinase inhibitor, cystatin C, with that of cathepsin K in osteoclasts of the mouse tibia by immunolight and immunoelectron microscopy. Light microscopically, strong immunoreactivity for cystatin C was found extracellularly along the resorption lacuna and intracellularly in the organelles of osteoclasts. In serial sections, various patterns of cystatin C and cathepsin K localization were seen, specifically: (1) some resorption lacuna were positive for both cystatin C and cathepsin K; (2) others were positive for either cystatin C or cathepsin K, but not both; and (3) some lacuna were negative for both. In osteoclasts, the localization of cystatin C was similar to that of cathepsin K. Furthermore, cystatin C immunoreactivity was detected in preosteoclasts and osteoblasts, whereas cathepsin K was seen only in preosteoclasts. Electron microscopically, cystatin C immunoreactive products were found in the rough endoplasmic reticulum (ER), Golgi apparatus, vesicles, granules, and vacuoles of osteoclasts. These cystatin C-positive vesicles had fused or were in the process of fusion with the ampullar vacuoles (extracellular spaces) containing cystatin C-positive, fragmented, fibril-like structures. The extracellular cystatin C was deposited on and between the cytoplasmic processes of ruffled borders, and on and between type I collagen fibrils. In the basolateral region of osteoclasts, cystatin C-positive vesicles and granules also fused with vacuoles that contained cystatin C-positive or negative fibril-like structures. These results indicate that osteoclasts not only synthesize and secrete cathepsin K from the ruffled border into the bone resorption lacunae, but also a cysteine proteinase inhibitor, cystatin C. Therefore, it is suggested that cystatin C regulates the degradation of bone matrix by cathepsin K, both extracellularly and intracellularly.     

Isolation of osteoclasts from fetal rat long bones

Summary Cell isolates containing multinucleate osteoclasts were obtained from longitudinally split fetal rat long bones by treatment with testicular hyaluronidase. The total yield of osteoclasts and the osteoclast enrichment of the isolate were increased if the intact bones were first cultured for 72 h. Even greater enhancement was obtained if the bones were treated with 1,25-dihydroxycholecalciferol [1,25(OH)₂D₃] during the culture period. This technique resulted in a cell population containing approximately 15% osteoclasts in yields greater than 50 osteoclasts per long bone. The yield of osteoclasts and the percentage of osteoclasts correlated well with the extent of bone resorption induced by 1,25(OH)₂D₃. The effectiveness of several isolation procedures was compared using the 1,25(OH)₂D₃-treated long bones. Conventional digestion with 1 mg/ml crude collagenase gave a much poorer yield of osteoclasts than simply agitating the split long bones. Hyaluronidase plus EDTA was not significantly different from EDTA alone. Even with milder procedures, however, the isolated osteoclasts were damaged as judged by their failure to exclude trypan blue. The osteoclasts are obviously very fragile cells. The isolation technique coupled with May-Grunwald-Giemsa staining permitted reliable determination of the median number of nuclei per osteoclast. This parameter was the same in uncultured bones or in bones cultured for 72 h in control media. Treatment with 1,25(OH)₂D₃ increased the nuclear number. At lower levels of bone resorption, nuclear number did not increase, but it was significantly greater in more highly resorbed bones.     

The type I collagen fragments ICTP and CTX reveal distinct enzymatic pathways of bone collagen degradation.

Bone resorption may generate collagen fragments such as ICTP and CTX, which can be quantified in serum and/or urine by using specific immunoassays, and which are used as clinical markers. However, the relative abundance of ICTP and CTX varies according to the type of bone pathology, suggesting that these two fragments are generated through distinct collagenolytic pathways. In this study, we analyzed the release of ICTP and CTX from bone collagen by the proteinases reported to play a role in the solubilization of bone matrix. Cathepsin K released large amounts of CTX, but did not allow a detectable release of ICTP. Conversely, the matrix metalloproteinases (MMPs) MMP-2, -9, -13, or -14 released ICTP, but did not allow a detectable release of CTX. Next we analyzed the release of ICTP and CTX from bone explants cultured in the presence of well-established inhibitors of these proteinases and of matrix solubilization. An inhibitor of cysteine proteinases including cathepsin K, inhibited the release of CTX, but not the release of ICTP. MMP inhibitors inhibited the release of ICTP, but also that of CTX, in agreement with the putative role of MMPs in the initiation of bone resorption in addition to matrix solubilization. Similarly the treatment of mice bearing bone metastasis with an MMP inhibitor led to a significant reduction of serum ICTP and CTX, and osteolytic lesions. We conclude that the generation of ICTP and CTX depends on different collagenolytic pathways. This finding may explain why these two markers may discriminate between different bone pathologies.     

A specific subtype of osteoclasts secretes factors inducing nodule formation by osteoblasts

Osteoclasts are known to be important for the coupling process between bone resorption and formation. The aim of this study was to address when osteoclasts are anabolically active. Human monocytes were differentiated into mature osteoclasts by treatment with M-CSF and RANKL. Conditioned medium was collected from macrophages, pre-osteoclasts, and mature functional or non-resorbing osteopetrotic osteoclasts on either bone, plastic, decalcified bone or dentine with or without diphyllin, E64 or GM6001. Osteoclasts numbers were measured by TRACP activity. Bone resorption was evaluated by CTX-I and calcium release. The osteoblastic cell line 2T3 was treated with 50% of CM or non-CM for 12days. Bone formation was assessed by Alizarin Red extraction. CM from mature osteoclasts induced bone formation, while CM from macrophages did not. Non-resorbing osteoclasts generated from osteopetrosis patients showed little resorption, but still an induction of bone formation by osteoblasts. Mimicking the reduction in bone resorption using the V-ATPase inhibitor Diphyllin, the cysteine proteinase inhibitor E64 and the MMP-inhibitor GM6001 showed that CM from diphyllin and E64 treated osteoclasts showed reduced ability to induce bone formation compared to CM from vehicle treated osteoclasts, while CM from GM6001 treated osteoclasts equaled vehicle CM. Osteoclasts on either dentine or decalcified bone showed strongly attenuated anabolic capacities. In conclusion, we present evidence that osteoclasts, both dependent and independent of their resorptive activity, secrete factors stimulating osteoblastic bone formation.     

Responsiveness of parathyroid hormone to bone resorption in 13-day-old embryonic chick calvaria cultures

To clarify what kind of process participates in bone resorption, time course of indices of bone resorption was investigated using 13-day-old embryonic chick calvaria. When calvariae were cultured with parathyroid hormone (PTH) at 0.01 U/ml for 8 days, hydroxyproline (Hyp) release was already stimulated by PTH in cultures by 1 to 2 days but stimulation of⁴⁵Ca release was not observed even in cultures by 6 to 8 days. Furthermore, stimulation of collagenase release by PTH was observed prior to that of Hyp release. These results indicate that collagenase release precedes Hyp release, which is followed by⁴⁵Ca release. The release of tartrate-resistant acid phosphatase (TrACP), a marker enzyme of osteoclast, was stimulated by PTH at 0.1 U/ml and above to a greater extent in cultures by 5 to 8 days (phase 11) than in cultures by 0 to 4 days (phase 1). E-64, an inhibitor of cysteine proteinase, inhibited PTH-stimulated⁴⁵Ca release strongly in phase 11 but showed a slight decrease in Hyp release in the same phase. These results suggest that first PTH stimulates collagenase production from osteoblasts, secondly collagenase degrades uncalcified collagen and lastly osteoclasts resorb mineralized bones.     

A scrutiny of matrix metalloproteinases in osteoclasts: evidence for heterogeneity and for the presence of MMPs synthesized by other cells

Genetic diseases and knockout mice stress the importance of matrix metalloproteinases (MMPs) in skeletal turnover. Our study aims at clarifying which MMPs are expressed by osteoclasts. Previous analyses of this basic question led to conflicting reports in the literature. In the present study, we used a variety of approaches: PCR, Northern blots, Slot blots, in situ hybridization, and immunohistochemistry. We analyzed osteoclasts in culture as well as osteoclasts in native bone at different locations and compared mouse and rabbit osteoclasts. Osteoclasts express MMP-9 and -14 in all conditions, although to a variable extent, and they are able to synthesize MMP-3, -10, and -12, at least under some circumstances. The induction of a given MMP in osteoclasts is influenced by its environment (e.g., osteoclast culture vs. native bone, and various sites within the same bone) and depends on the species (e.g., mouse vs. rabbit). Osteoclasts show high amounts of MMP-2 and -13 protein presumably made to a large extent by other cells, thereby documenting how proteinases of nonosteoclastic origin may contribute to osteoclast activities and giving insight in why the resorptive activity of purified osteoclasts appears insensitive to MMP inhibitors. Our study shows that the confusion about osteoclastic MMPs in the literature reflects the remarkable ability of osteoclasts to adapt to their environment, as required by the structural or functional diversity of bone tissue. Our observations provide basic information needed for understanding the emerging role of MMPs in controlling cell signaling and bone resorption.     

Role of mineralizing cartilage in osteoclast and osteoblast recruitment

Periost-free, live and/or devitalized cartilaginous long bone rudiments of fetal mice were transplanted under the renal capsule of adult syngeneic mice to study the role of cells and intercellular matrix in the recruitment and formation of osteoclasts and osteoblasts, both identified by means of enzyme- and immunohistochemical methods. Live bone rudiments recruited host-derived osteoclasts within 5 days after transplantation. Osteoblasts developed as rapidly as osteoclasts and participated in the modeling of the rudiments into hemopoietic bone marrow containing ossicles. Devitalized bone rudiments, killed before osteoclastic invasion had occurred, did not recruit osteoclasts or osteoblasts, and were not resorbed up till 35 days after transplantation. Co-transplantation of live and devitalized bone rudiments however resulted in osteoclastic resorption of the killed rudiments, starting 9 days after transplantation. Again the live rudiments were modeled into ossicles. Devitalized bone rudiments which had been invaded by osteoclasts before killing and transplantation, did recruit host osteoclasts, but at a slower rate than live rudiments, and depending on the number of resorption sites at the time of transplantation. Osteoblasts were not formed. These data suggest that in developing long bones chondrocyte activity is involved in the recruitment of osteoclasts as well as osteoblasts. Matrix components diffusing from resorbing surfaces seem to be involved in osteoclast recruitment.