Collagenase cleavage of type I collagen is essential for both basal and parathyroid hormone (PTH)/PTH-related peptide receptor-induced osteoclast activation and has differential effects on discrete bone compartments.

Expression of a constitutively active PTH/PTHrP receptor in cells of osteoblast lineage in vivo (CL2+) causes increases in trabecular bone volume and trabecular bone formation and, conversely, a decrease in the periosteal mineral apposition rate. Collagenase-3 (matrix metalloprotease-13) is a downstream target of PTH action. To investigate the relevance of collagenase cleavage of type I collagen for the CL2+ bone phenotype, we bred CL2+ animals with mice carrying a mutated col1 alpha 1 gene that encodes a protein resistant to digestion by collagenase-3 and other collagenases (rr). Adult tibias and parietal bones from 4-wk-old double-mutant animals (CL2+/rr) and from control littermates were analyzed. Trabecular bone volume was higher in CL2+/rr than in CL2+ mice. This increase occurred despite a modest reduction in bone formation rate, which was, however, still significantly higher that in wild-type littermates, and therefore must reflect decreased bone resorption in rr mice. Osteoclast number was increased in CL2+/rr animals compared with either wild-type or CL2+ mice, suggesting that collagenase-dependent collagen cleavage affected osteoclast function rather than osteoclast number and/or differentiation. Interestingly, the periosteal mineral apposition rate was similar in CL2+/rr and CL2+ animals and was significantly lower than that in wild-type animals. Our study provides evidence that collagenase activity is important for both basal and PTH/PTHrP receptor-dependent osteoclast activation. Furthermore, it indicates that a mild impairment of osteoclast activity is still compatible with increased osteoblast function. Lastly, it supports the hypothesis that collagenases can be a downstream effector of PTH/PTHrP receptor action in trabecular bone, but not in periosteum.

[Secondary osteoporosis and glucocorticoid-induced osteoporosis]. / Ostéoporoses secondaires et ostéoporose cortisonique.

In order to assess properly the diagnosis of osteoporosis, a short clinical investigation is required to address potential causes for bone loss. Osteoporosis used to be suspected in a patient with vertebral demineralization, but nowadays it is often diagnosed in a patient with a low bone mass on a screening dual-energy X-ray absorptiometry (DEXA). In this setting, it is important for the clinician to look for secondary osteoporosis, especially in men in whom secondary osteoporosis is more frequent than in women, before discussing any specific therapy. The major causes are longterm glucocorticoid therapy, endocrine (hypogonadism, primary hyperparathyroidism, hyperthyroidism), or digestive diseases.

Osteocyte and osteoblast apoptosis and excessive bone deposition accompany failure of collagenase cleavage of collagen.

Mice carrying a targeted mutation (r) in Col1a1, encoding a collagenase-resistant form of type I collagen, have altered skeletal remodeling. In hematoxylin and eosin-stained paraffin sections, we detect empty lacunae in osteocytes in calvariae from Col1a1(r/r) mice at age 2 weeks, increasing through age 10-12 months. Empty lacunae appear to result from osteocyte apoptosis, since staining of osteocytes/periosteal osteoblasts with terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling is increased in Col1a1(r/r) relative to wild-type bones. Osteocyte perilacunar matrices stained with Ab that recognizes collagenase collagen alpha1(I) chain cleavage ends in wild-type but not Col1a1(r/r) calvariae. Increased calvarial periosteal and tibial/femoral endosteal bone deposition was found in Col1a1(r/r) mice from ages 3-12 months. Calcein labeling of calvarial surfaces was increased in Col1a1(r/r) relative to wild-type mice. Daily injections of synthetic parathyroid hormone for 30 days increased calcein-surface labeling in wild-type but caused no further increase in the already high calcein staining of Col1a1(r/r) bones. Thus, failure of collagenase cleavage of type I collagen in Col1a1(r/r) mice is associated with osteocyte/osteoblast death but increases bone deposition in a manner that mimics the parathyroid hormone-induced bone surface activation seen in wild-type mice.

Multiple domains interacting with Gs in the porcine calcitonin receptor.

The molecular basis for Gs activation by the calcitonin (CT) receptor was investigated. Based upon the analysis of conserved regions in G protein-coupled receptors, two nonoverlapping regions in the heptahelical porcine CT receptor (CTR) were selected as candidate Gs-interacting domains: the third intracellular loop residues 327-344 (KLKESQEAESHMYLKAVR, P3 region) and the C-tail residues 404-418 (KRQWNQYQAQRWAGR, P4 region). To assess their Gs-interacting function, we expressed these sequences in hybrid insulin-like growth factor II receptors in which the receptor native Gi-interacting domain was converted to CTR sequences. In COS cells transfected with either P3- or P4-substituted hybrid receptor, membrane adenylyl cyclase activity significantly increased. The up-regulated activity of cAMP was confirmed by measuring the transcriptional activity of the cAMP response element in cells expressing either hybrid receptor. A mutant CTR lacking the P4 region maintained positive cAMP response but with an attenuated maximal capacity to produce cAMP. In contrast, we could not assess the function of the P3 region using a conventional deletion method, as CT bound poorly to cells transfected with either of the two P3-deficient CTRs (one lacking the P3 region and the other lacking P3 but having the P3 sequence in reverse orientation). These data suggest that the third intracellular loop and the C-tail in CTR have domain-specific roles in Gs activation and that the hybrid receptor approach used here, combined with a conventional mutagenesis approach, is useful for intact cell analysis and functional dissection of G protein-coupled receptors.

Bone resorption induced by parathyroid hormone is strikingly diminished in collagenase-resistant mutant mice.

Parathyroid hormone (PTH) stimulates bone resorption by acting directly on osteoblasts/stromal cells and then indirectly to increase differentiation and function of osteoclasts. PTH acting on osteoblasts/stromal cells increases collagenase gene transcription and synthesis. To assess the role of collagenase in the bone resorptive actions of PTH, we used mice homozygous (r/r) for a targeted mutation (r) in Col1a1 that are resistant to collagenase cleavage of type I collagen. Human PTH(1-34) was injected subcutaneously over the hemicalvariae in wild-type (+/+) or r/r mice four times daily for three days. Osteoclast numbers, the size of the bone marrow spaces and periosteal proliferation were increased in calvariae from PTH-treated +/+ mice, whereas in r/r mice, PTH-induced bone resorption responses were minimal. The r/r mice were not resistant to other skeletal effects of PTH because abundant interstitial collagenase mRNA was detected in the calvarial periosteum of PTH-treated, but not vehicle-treated, r/r and +/+ mice. Calcemic responses, 0.5-10 hours after intraperitoneal injection of PTH, were blunted in r/r mice versus +/+ mice. Thus, collagenase cleavage of type I collagen is necessary for PTH induction of osteoclastic bone resorption.

The parathyroid hormone (PTH)/PTH-related peptide receptor mediates actions of both ligands in murine bone.

PTH and PTH-related peptide (PTHrP) have been shown to bind to and activate the same PTH/PTHrP receptor. Recent studies have demonstrated, however, the presence of additional receptors specific for each ligand. We used the PTHrP and PTH/PTHrP receptor gene knock-out models to investigate whether this receptor mediates the actions of both ligands in bone. The similar phenotype of the PTHrP (-/-) and PTH/PTHrP receptor (-/-) animals in the growth plate of the tibia suggests that this receptor mediates the actions of PTHrP. Electron microscopic studies have confirmed the accelerated differentiation and disordered organization of chondrocytes, with the accumulation of large amounts of dispersed glycogen granules in the cytoplasm of proliferative and maturing cells of both genotypes. The contrasting growth plate mineralization patterns of the PTHrP (-/-) and PTH/PTHrP receptor (-/-) mice, however, suggest that the actions of PTHrP and the PTH/PTHrP receptor are not identical. Studies using calvariae from PTH/PTHrP receptor (-/-) embryos demonstrate that this receptor solely mediates the ability of PTH and PTHrP to stimulate adenylate cyclase in bone and to stimulate bone resorption. Furthermore, we show that osteoblasts of PTH/PTHrP receptor (-/-) animals, but not PTHrP (-/-) animals, have decreased levels of collagenase 3, osteopontin, and osteocalcin messenger RNAs. The PTH/PTHrP receptor, therefore, mediates distinct physiologic actions of both PTH and PTHrP.

Heterotopic ossification in the setting of neuromuscular blockade.

OBJECTIVE: Heterotopic ossification (HO) is a disorder characterized by the formation of new bone in tissue that does not ossify under normal conditions. We report a series of 6 cases in which HO occurred in the setting of adult respiratory distress syndrome (ARDS). We wished to show that HO can occur after neuromuscular blockade and that these cases might provide additional evidence that HO is influenced by neural mechanisms. METHODS: Cases of HO were selected from the consultation services at the Massachusetts General Hospital and the Brigham and Women's Hospital. Affected patients all had ARDS and had been treated with a neuromuscular blocking agent. Patients with a history of stroke, burn, head trauma, spinal cord injury, or joint replacement were excluded from this study. RESULTS: Heterotopic bone appeared around large joints in a pattern identical to that seen in patients with paralysis, traumatic brain injury, severe burns, or trauma. New bone formation was self-limited over a period of 1-2 years. Alkaline phosphatase and technetium bone scan were sensitive ways of detecting early disease and monitoring disease activity. Medical therapies had limited benefit. Surgical excision of mature new bone appeared to be the only definitive therapy. CONCLUSION: Neuromuscular blockade in the setting of ARDS appears to be an important risk factor for the development of HO. The similarity of these cases of HO occurring in patients with brain or spinal cord injury raises the possibility that neural mechanisms may be important in the pathogenesis of this disease. Whether the type of neuromuscular blocking agent and the duration of use are important determinants of disease severity remains to be determined.

Ehlers-Danlos syndrome type VIIA and VIIB result from splice-junction mutations or genomic deletions that involve exon 6 in the COL1A1 and COL1A2 genes of type I collagen.

Ehlers-Danlos syndrome (EDS) type VII results from defects in the conversion of type I procollagen to collagen as a consequence of mutations in the substrate that alter the protease cleavage site (EDS type VIIA and VIIB) or in the protease itself (EDS type VIIC). We identified seven additional families in which EDS type VII is either dominantly inherited (one family with EDS type VIIB) or due to new dominant mutations (one family with EDS type VIIA and five families with EDS type VIIB). In six families, the mutations alter the consensus splice junctions, and, in the seventh family, the exon is deleted entirely. The COL1A1 mutation produced the most severe phenotypic effects, whereas those in the COL1A2 gene, regardless of the location or effect, produced congenital hip dislocation and other joint instability that was sometimes very marked. Fractures are seen in some people with EDS type VII, consistent with alterations in mineral deposition on collagen fibrils in bony tissues. These new findings expand the array of mutations known to cause EDS type VII and provide insight into genotype/phenotype relationships in these genes.

The activity of collagenase-1 is required for keratinocyte migration on a type I collagen matrix.

We have shown in a variety of human wounds that collagenase-1 (MMP-1), a matrix metalloproteinase that cleaves fibrillar type I collagen, is invariably expressed by basal keratinocytes migrating across the dermal matrix. Furthermore, we have demonstrated that MMP-1 expression is induced in primary keratinocytes by contact with native type I collagen and not by basement membrane proteins or by other components of the dermal or provisional (wound) matrix. Based on these observations, we hypothesized that the catalytic activity of MMP-1 is necessary for keratinocyte migration on type I collagen. To test this idea, we assessed keratinocyte motility on type I collagen using colony dispersion and colloidal gold migration assays. In both assays, primary human keratinocytes migrated efficiently on collagen. The specificity of MMP-1 in promoting cell movement was demonstrated in four distinct experiments. One, keratinocyte migration was completely blocked by peptide hydroxymates, which are potent inhibitors of the catalytic activity of MMPs. Two, HaCaTs, a line of human keratinocytes that do not express MMP-1 in response to collagen, did not migrate on a type I collagen matrix but moved efficiently on denatured type I collagen (gelatin). EGF, which induces MMP-I production by HaCaT cells, resulted in the ability of these cells to migrate across a type I collagen matrix. Three, keratinocytes did not migrate on mutant type I collagen lacking the collagenase cleavage site, even though this substrate induced MMP-1 expression. Four, cell migration on collagen was completely blocked by recombinant tissue inhibitor of metalloproteinase-1 (TIMP-1) and by affinity-purified anti-MMP-1 antiserum. In addition, the collagen-mediated induction of collagenase-1 and migration of primary keratinocytes on collagen was blocked by antibodies against the alpha2 integrin subunit but not by antibodies against the alpha1 or alpha3 subunits. We propose that interaction of the alpha2beta1 integrin with dermal collagen mediates induction of collagenase-1 in keratinocytes at the onset of healing and that the activity of collagenase-1 is needed to initiate cell movement. Furthermore, we propose that cleavage of dermal collagen provides keratinocytes with a mechanism to maintain their directionality during reepithelialization.

Different collagenase gene products have different roles in degradation of type I collagen.

Vertebrate collagenases, matrix metalloproteinases (MMPs), cleave type I collagen at a single helical locus. We show here that rodent interstitial collagenases (MMP-13), but not human fibroblast collagenase (MMP-1), cleave type I collagen at an additional aminotelopeptide locus. Collagenase cDNAs and chimeric constructs in pET-3d, juxtaposing MMP-13 sequences amino-terminal to the active site in the catalytic domain and MMP-1 sequences carboxyl-terminal and vice versa, were expressed in Escherichia coli. Assays utilized collagen from wild type (+/+) mice or mice that carry a targeted mutation (r/r) that encodes substitutions in alpha1(I) chains that prevent collagenase cleavage at the helical locus. MMP-13 and chimeric molecules that contained the MMP-13 sequences amino-terminal to the active site cleaved (+/+) collagen at the helical locus and cleaved cross-linked (r/r) collagen in the aminotelopeptide (beta components converted to alpha chains). Human MMP-1 and chimeric MMP-1/MMP-13 with MMP-1 sequences amino-terminal to the active site cleaved collagen at the helical locus but not in the aminotelopeptide. All activities were inhibited by TIMP-1, 1,10-phenanthroline, and EDTA. Sequences in the distal two-thirds of the catalytic domain determine the aminotelopeptide-degrading capacity of MMP-13.

Expression of two human skeletal calcitonin receptor isoforms cloned from a giant cell tumor of bone. The first intracellular domain modulates ligand binding and signal transduction.

Two distinct calcitonin (CT) receptor (CTR)-encoding cDNAs (designated GC-2 and GC-10) were cloned and characterized from giant cell tumor of bone (GCT). Both GC-2 and GC-10 differ structurally from the human ovarian cell CTR (o-hCTR) that we cloned previously, but differ from each other only by the presence (GC-10) or absence (GC-2) of a predicted 16-amino acid insert in the putative first intracellular domain. Expression of all three CTR isoforms in COS cells demonstrated that GC-2 has a lower binding affinity for salmon (s) CT (Kd approximately 15 nM) than GC-10 or o-hCTR (Kd approximately 1.5 nM). Maximal stimulatory concentrations of CT resulted in a mean accumulation of cAMP in GC-2 transfected cells that was greater than eight times higher than in cells transfected with GC-10 after normalizing for the number of receptor-expressing cells. The marked difference in maximal cAMP response was also apparent after normalizing for receptor number. GC-2 also demonstrated a more potent ligand-mediated cAMP response compared with GC-10 for both human (h) and sCT (the EC50 values for GC-2 were approximately 0.2 nM for sCT and approximately 2 nM for hCT; EC50 values for GC-10 were approximately 6 nM for sCT and approximately 25 nM for hCT). Reverse transcriptase PCR of GCT RNA indicated that GC-2 transcripts are more abundant than those encoding for GC-10. In situ hybridization on GCT tissue sections demonstrated CTR mRNA expression in osteoclast-like cells. We localized the human CTR gene to chromosome 7 in band q22. The distinct functional characteristics of GC-2 and GC-10, which differ in structure only in the first intracellular domain, indicate that the first intracellular domain of the CTR plays a previously unidentified role in modulating ligand binding and signal transduction via the G protein/adenylate cyclase system.

Is collagenase (matrix metalloproteinase-1) necessary for bone and other connective tissue remodeling?

In physiologic remodeling of bone and other connective tissues, proteinases such as the matrix metalloproteinases (MMPs) which can cleave Type I collagen play a critical role. In bone, MMP-1 is secreted by stromal fibroblasts, osteoblasts, and osteoclasts. Only the collagenases (MMP-1 and MMP-8) cleave native undenatured collagen at neutral pH. The cleavage is site specific at a single locus in the alpha 1(I) chain between Gly775/Ile776. The authors have altered the amino acid sequences around the collagenase cleavage site by site-directed mutagenesis of the murine Col1a-I gene, introducing Pro for Gln774, Pro for Ala777, and Met for Ile776. The mutant Col1a-I gene has been expressed in Mov13 fibroblasts, and secreted Type I collagen molecules have been found to be resistant to cleavage at Gly775/Ile776 by MMP-1 or MMP-8. This subtle mutation was introduced recently into the endogenous Col1a-I gene by homologous recombination in embryonic stem cells to determine the role of collagenase in vivo. Chimaeric mice derived from blastocysts injected with these embryonic stem cells transmitted the mutant Col1a-I gene to their offspring. Surprisingly, homozygous mutant mice reproduce and appear to develop normally. The mechanisms of collagen resorption in remodeling of bone and soft tissues in these mice are being examined currently. Information should be derived that will be useful in interpreting human disorders characterized by increased collagen deposition, such as osteopetrosis and dermal fibrosis.

Cloning and characterization of a mouse brain calcitonin receptor complementary deoxyribonucleic acid and mapping of the calcitonin receptor gene.

We have identified and characterized a mouse brain calcitonin receptor (CTR) complementary DNA (cDNA). This cDNA encodes a receptor protein that, after expression, has high affinity binding for salmon calcitonin (Kd approximately, 12.5 nM) and is coupled to adenylate cyclase. The binding affinity of this expressed receptor for salmon calcitonin is lower than that described for the previously cloned porcine renal and human ovarian CTRs, but is similar to that of the recently described rat brain CTR, designated the C1b form of the receptor. Analysis of the deduced structure of the mouse brain CTR reveals that it is highly related to the other CTR cDNAs that belong to a distinct family of G-protein-coupled receptors with seven transmembrane-spanning domains. The major structural feature that distinguishes the mouse cDNA clone from the other CTRs is the presence of a consecutive 111-basepair nucleotide sequence that encodes a 37-amino acid sequence which is predicted to localize to the first extracellular loop between the second and third transmembrane-spanning domains. We have mapped the CTR gene in the mouse to the proximal region of chromosome 6, which is homologous to the 7q region of human chromosome 7; only a single CTR gene was identified. Preliminary analysis of the mouse CTR gene reveals that it is complex, consisting of multiple exons separated by lengthy introns that would allow for splice variants consistent with the existence of multiple CTR isoforms predicted from the CTR cDNA clones. The differential cellular and tissue distribution of these functionally distinct CTR isoforms provides the molecular basis for the previously reported widespread distribution and functional heterogeneity of the CTR.

Characterization of the structural and functional properties of cloned calcitonin receptor cDNAs.

We have recently cloned CTRs from cDNA libraries prepared from porcine renal and human ovarian cell lines. In situ hybridization and Northern analysis confirm the widespread distribution of CTR mRNA in numerous tissues. Hydropathy plots of the predicted amino acid sequence of the receptors demonstrate multiple hydrophobic regions that could generate 7 transmembrane spanning domains, similar to other G protein-coupled receptors. Searches of databanks for proteins with related amino acid sequences reveals that the CTRs are closely related to the receptors for parathyroid hormone/parathyroid hormone related peptide, secretin, vasoactive intestinal peptide, growth hormone releasing hormone, glucagon-like peptide-1 and glucagon. These receptors have no significant sequence homology to other G protein-coupled receptors, and therefore, appear to comprise a distinct receptor family. Expression of the hCTR or pCTR in COS cells results in expression of high affinity CTRs which are coupled to adenylate cyclase (AC). The hCTR, however, demonstrates higher affinity for human and salmon CT compared to the pCTR. Both CTRs demonstrate low affinity binding and AC activation in response to calcitonin gene related peptide, amylin or secretin, providing a possible explanation for the cross-reactivity among these peptides in vivo. Stable transfectants expressing the pCTR increase cAMP levels and increases in cytosolic free Ca2+ concentration consistent with dual coupling to AC and phospholipase C. Additional studies will help to establish the structural basis for this functional property as well as the evolutionary relationship of the members of this newly identified family of receptors.

Some molecular mechanisms of glucocorticoid action.

Glucocorticoids, in excess, profoundly affect the skeleton by increasing bone resorption, decreasing bone formation and altering intestinal absorption and renal excretion of mineral ions. The mechanisms underlying these actions are complex but many involve changes in expression of genes encoding critical proteins. Interaction of the glucocorticoid with its nuclear receptor results in the induction of either positive events (transactivation) by direct interaction with cis-acting sequences, or negative (transrepression) events by repression of gene transcription and/or alteration of mRNA half-lives. An example is the inhibition by glucocorticoids of collagenase synthesis. Induction of the collagenase (procollagenase) gene by inflammatory mediators, such as interleukin-1, can be inhibited by glucocorticoid transrepression. The glucocorticoid-receptor complex binds to a protein complex AP-1; consisting of the proteins c-JUN and c-FOS) and prevents this complex from inducing activation of the procollagenase gene. These observations may be applicable to the interpretation of other glucocorticoid actions and explain some of their adverse effects on the skeleton.

Susceptibility of type I collagen containing mutated alpha 1(1) chains to cleavage by human neutrophil collagenase.

Two members of the matrix metalloproteinase family which can cleave native types I, II and III triple helical collagens are collagenases from fibroblasts and neutrophils. These enzymes are the products of different genes which share structural motifs but are only 57% identical. In this study, we determined the site of cleavage in the alpha 1(I) chains and showed that the neutrophil collagenase acted at the same site as the fibroblast collagenase. We also used collagens as substrates which were generated by site-directed mutagenesis of the murine Col1a1 gene and found that the pattern of susceptibility to cleavage by purified neutrophil collagenase was indistinguishable from that previously described for the fibroblast collagenase. Collagens containing substitutions of Pro for Ile-776 (P1) were not cleaved; whereas those containing substitutions of Met for Ile-776 were cleaved. Type I collagen which contained alpha 1(I) chains in which there were double substitutions of Pro for Gln-774 (P2) and Ala-777 (P2') were also not cleaved. These type I collagens contained wild type alpha 2(I) chains as well as mutant alpha 1(I) chains in the mixed helical trimers; the alpha 2(I) chain in the trimers containing the resistant alpha 1(I) chains were also not cleaved by the neutrophil collagenase.