Mammalian expression of full-length bovine aggrecan and link protein: formation of recombinant proteoglycan aggregates and analysis of proteolytic cleavage by ADAMTS-4 and MMP-13

Aggrecan, a large chondroitin sulfate (CS) and keratan sulfate (KS) proteoglycan, has not previously been expressed as a full-length recombinant molecule. To facilitate structure/function analysis, we have characterized recombinant bovine aggrecan (rbAgg) and link protein expressed in COS-7 cells. We demonstrate that C-terminally truncated rbAgg was not secreted. Gel filtration chromatography of rbAgg and isolated glycosaminoglycan (GAG) chains, and their susceptibility to chondroitinase ABC digestion indicate that the GAG chains are predominantly CS, which likely occupy fewer serine residues than native aggrecan. To confirm functionality, we determined that rbAgg bound hyaluronan and recombinant link protein to form proteoglycan aggregates. In addition, cleavage of rbAgg by ADAMTS-4 revealed that the p68 form of ADAMTS-4 preferentially cleaves within the CS-2 domain, whereas the p40 form only effectively cleaves within the interglobular domain (IGD). MMP-13 cleaved rbAgg within the IGD, but cleaved more rapidly at a site within the CS domains, suggesting a role in C-terminal processing of aggrecan. Our results demonstrate that recombinant aggrecan can be used for in vitro analyses of matrix protease-dependent degradation of aggrecan in the IGD and CS domains, and both recombinant aggrecan and link protein can be used to study the assembly of proteoglycan aggregates with hyaluronan.

Decreased Production of Collagen Type III in Cultured Smooth Muscle Cells from Varicose Vein Patients Is due to a Degradation by MMPs: Possible Implication of MMP-3

An alteration of extracellular matrix is involved in varicose veins. We have previously shown that collagen III production, but not its mRNA expression, is decreased in cultured smooth muscle cells (SMC) from varicose veins, involving an over-production of collagen I. In this study, the mechanisms involved in this collagen III reduction are explored. Steady state levels of collagen III mRNA and its ability to translate a protein were evaluated. Neither stability nor functionality of the alpha1(III) coding mRNA were affected in cells from varicose veins. Potential intracellular degradations of collagen III were investigated with inhibitors of intracellular proteases but the production was unaffected. The level of N-terminal propeptides of collagen III in the extracellular medium was determined and was similar in SMC from control and varicose veins. The stability of collagen III was determined by time-course experiments and a degradation of the protein was observed in cells from varicose veins. The production of collagen III was partially restored in cells from varicose veins in the presence of Marimastat, a matrix metalloproteinase (MMP) inhibitor. The mRNA expression and protein production of MMP3 were increased in cells from varicose veins. Fibronectin, a potential substrate of MMP3, was decreased in SMC from varicose veins. In conclusion, collagen III, and probably fibronectin, are degraded extracellularly in SMC from varicose veins by a mechanism involving MMPs, and maybe MMP3 by a direct or an indirect pathway. The degradation of collagen III and fibronectin may have repercussions for the mechanical properties of the venous wall.

Human glioblastomas overexpress ADAMTS-5 that degrades brevican

Selective cleavage of the Glu395-Ser396 bond of brevican, one of the major proteoglycans in adult brain tissues, is thought to be important for glioma cell invasion. Our previous biochemical study demonstrated that ADAMTS-4, a member of the ADAMTS (a disintegrin and metalloproteinase with thrombospondin motifs) family, has such an activity. In the present study, we examined brevican-degrading activities of ADAMTS-1, -4 and -5 at the cellular level, and their expression and localization in human glioma tissues. In 293T transfectants expressing ADAMTS-4 or ADAMTS-5, brevican was cleaved into two major fragments in an identical pattern, but no such degradation was observed with ADAMTS-1 transfectants. When the expression levels of these ADAMTS species were examined by real-time quantitative PCR, only ADAMTS-5 was found to be overexpressed in glioblastoma tissues compared to control normal brain tissues (P <0.05). In situ hybridization and immunohistochemistry demonstrated that ADAMTS-5 is expressed predominantly in glioblastoma cells. Forced expression of ADAMTS-5 in glioma cell lines stimulated cell invasion. These results demonstrate for the first time that ADAMTS-5 is capable of degrading brevican and is overexpressed in glioblastoma cells, and suggest that ADAMTS-5 may play a role in glioma cell invasion through the cleavage of brevican.

Altered production and proteolytic processing of brevican by transforming growth factor beta in cultured astrocytes

Brevican, a proteoglycan of the lectican family, inhibits neurite outgrowth and may also stabilize synapses. Little is known about its expression or function in vitro. This study seeks to determine whether a brevican-containing matrix is present in neural cultures, and if so, how the production of brevican may be modulated. To accomplish this, the content of brevican and its proteolytic fragments were measured in primary cultures of neurons, astrocytes and microglia after treatment with cytokines. These experiments revealed that astrocytes and neurons express several isoforms of brevican, whereas microglia do not produce this proteoglycan. Cleavage fragments of brevican were found primarily in neuronal and astrocyte culture medium. ADAMTS4 (a disintegrin and metalloproteinase with thrombospondin motifs), a protease that selectively cleaves lecticans, was detected in cultures of neurons, astrocytes and microglia. When astrocytes were challenged with various cytokines, it was found that treatment with transforming growth factor beta (TGFbeta) resulted in a marked increase in intact brevican in the culture medium that was accompanied by a trend for a decrease in ADAMTS-generated fragments of brevican and apparent ADAMTS activity. Thus, TGFbeta may play a role in neuronal plasticity through its regulation of brevican and the activity of the ADAMTSs.

Mutations Near Amino End of α1(I) Collagen Cause Combined Osteogenesis Imperfecta/Ehlers-Danlos Syndrome by Interference with N-propeptide Processing

Patients with OI/EDS form a distinct subset of osteogenesis imperfecta (OI) patients. In addition to skeletal fragility, they have characteristics of Ehlers-Danlos syndrome (EDS). We identified 7 children with types III or IV OI, plus severe large and small joint laxity and early progressive scoliosis. In each child with OI/EDS, we identified a mutation in the first 90 residues of the helical region of alpha1(I) collagen. These mutations prevent or delay removal of the procollagen N-propeptide by purified N-proteinase (ADAMTS-2) in vitro and in pericellular assays. The mutant pN-collagen which results is efficiently incorporated into matrix by cultured fibroblasts and osteoblasts and is prominently present in newly incorporated and immaturely cross-linked collagen. Dermal collagen fibrils have significantly reduced cross-sectional diameters, corroborating incorporation of pN-collagen into fibrils in vivo. Differential scanning calorimetry revealed that these mutant collagens are less stable than the corresponding procollagens, which is not seen with other type I collagen helical mutations. These mutations disrupt a distinct folding region of high thermal stability in the first 90 residues at the amino end of type I collagen and alter the secondary structure of the adjacent N-proteinase cleavage site. Thus, these OI/EDS collagen mutations are directly responsible for the bone fragility of OI and indirectly responsible for EDS symptoms, by interference with N-propeptide removal.

Regulated Expression of ADAMTS Family Members in Follicles and Cumulus Oocyte Complexes: Evidence for Specific and Redundant Patterns During Ovulation1

Protease cascades are essential for many biological events, including the LH-induced process of ovulation. ADAMTS1 (a disintegrin and metalloproteinase with thrombospondin-like repeats-1) is expressed and hormonally regulated in the ovary by LH and the progesterone receptor. To determine whether other family members might be expressed and regulated in the rodent ovary, those closely related to ADAMTS1 (ADAMTS4 and ADAMTS5) were analyzed in the mouse ovary by reverse transcription-polymerase chain reaction as well as by Western blot, immunohistochemical, and immunocytochemical analyses using highly specific antibodies. Prior to ovulation, ADAMTS4 and ADAMTS5 were coexpressed in granulosa cells of most follicles, whereas ADAMTS5 was also present in granulosa cells of atretic follicles. Following ovulation, ADAMTS1 and ADAMTS4 (but not ADAMTS5) were expressed in multiple cell types, including those within the highly vascular ovulation cone that marks the site of follicle rupture, endothelial cells of newly forming corpora lutea, and cumulus cells within the ovulated cumulus cell-oocyte complex (COC). Versican, a substrate for ADAMTS1 and ADAMTS4, colocalized with these proteases and hylauronan on the cumulus cell surface. To further characterize induction of these proteases and associated molecules, COCs and granulosa cells were isolated from preovulatory follicles and treated with FSH. In expanded COCs and differentiated granulosa cells, FSH induced expression of ADAMTS4 and versican message and protein, whereas increased levels of ADAMTS1 protein was observed in the media of granulosa cells where it was stabilized by heparin in this in vitro system. These studies provide the first evidence that ADAMTS1, ADAMTS4, and ADAMTS5 are expressed in spatiotemporal patterns that suggest distinct as well as some overlapping functions that relate to the broad expression pattern of versican in granulosa cells of small follicles, expanded COCs, and endothelial cells of the mouse ovary.

ADAMTS5 is the major aggrecanase in mouse cartilage in vivo and in vitro

Aggrecan is the major proteoglycan in cartilage, endowing this tissue with the unique capacity to bear load and resist compression. In arthritic cartilage, aggrecan is degraded by one or more 'aggrecanases' from the ADAMTS (a disintegrin and metalloproteinase with thrombospondin motifs) family of proteinases. ADAMTS1, 8 and 9 have weak aggrecan-degrading activity. However, they are not thought to be the primary aggrecanases because ADAMTS1 null mice are not protected from experimental arthritis, and cleavage by ADAMTS8 and 9 is highly inefficient. Although ADAMTS4 and 5 are expressed in joint tissues, and are known to be efficient aggrecanases in vitro, the exact contribution of these two enzymes to cartilage pathology is unknown. Here we show that ADAMTS5 is the major aggrecanase in mouse cartilage, both in vitro and in a mouse model of inflammatory arthritis. Our data suggest that ADAMTS5 may be a suitable target for the development of new drugs designed to inhibit cartilage destruction in arthritis, although further work will be required to determine whether ADAMTS5 is also the major aggrecanase in human arthritis.

Les collagènes du derme : au-delà de leurs propriétés structurales

The extracellular matrix is a complex network composed of macromolecules such as collagens, proteoglycans and elastin that strongly interact with each other and with cells to maintain the structural integrity of many tissues. These interactions also sustain important cell programs such as migration, proliferation, differentiation and apoptosis. The skin, and more specifically the dermis, contains an extreme diversity of macromolecules that reflects the importance of the composition and organization of the matrix components in providing physical properties and function of the tissues. The most abundant matrix components are the collagens that form a super-family of 27 different members which are divided into different subgroups. The fibrillar collagens, types I, III and V, the FACIT collagens, types XII, XIV and XVI, and collagen VI are all expressed in the collagen-rich dermis. Although the structural features of these collagens are now well characterized, their functions remain elusive. Mutations in human collagen genes give rise to numerous connective tissue diseases including dermis disorders. For example, clinical manifestations in the classical Elhers-Danlos syndrome caused by collagen V gene mutations occur predominantly in the dermis. However, the genotype-phenotype relationship is not clearly established as well as the relation between the distribution and the function of the collagens in dermis. There is no doubt that the ongoing and future work using in vivo approaches will provide new cues regarding the function of collagens in dermis.

α2-Macroglobulin Is a Novel Substrate for ADAMTS-4 and ADAMTS-5 and Represents an Endogenous Inhibitor of These Enzymes

Osteoarthritis is characterized by the loss of aggrecan and collagen from the cartilage extracellular matrix. The proteinases responsible for the breakdown of cartilage aggrecan include ADAMTS-4 (aggrecanase 1) and ADAMTS-5 (aggrecanase 2). Post-translational inhibition of ADAMTS-4/-5 activity may be important for maintaining normal homeostasis of aggrecan metabolism, and thus, any disruption to this inhibition could lead to accelerated aggrecan breakdown. To date TIMP-3 (tissue inhibitor of matrix metalloproteinases-3) is the only endogenous inhibitor of ADAMTS-4/-5 that has been identified. In the present studies we identify alpha(2)-macroglobulin (alpha(2)M) as an additional endogenous inhibitor of ADAMTS-4 and ADAMTS-5. alpha(2)M inhibited the activity of both ADAMTS-4 and ADAMTS-5 in a concentration-dependent manner, demonstrating 1:1 stoichiometry with second-order rate constants on the order of 10(6) and 10(5) m(-1) s(-1), respectively. Inhibition of the aggrecanases was mediated by proteolysis of the bait region within alpha(2)M, resulting in physical entrapment of these proteinases. Both ADAMTS-4 and ADAMTS-5 cleaved alpha(2)M at Met(690)/Gly(691), representing a novel proteinase cleavage site within alpha(2)M and a novel site of cleavage for ADAMTS-4 and ADAMTS-5. Finally, the use of the anti-neoepitope antibodies to detect aggrecanase-generated alpha(2)M-fragments in synovial fluid was investigated and found to be uninformative.

Proprotein convertase furin interacts with and cleaves pro-ADAMTS4 (Aggrecanase-1) in the trans-Golgi network

A member of the A disintegrin and metalloproteinase domain with thrombospondin type-1 motifs (ADAMTS-4) protease family can efficiently cleave aggrecan at several sites detected in joints of osteoarthritic patients. Although recent studies have shown that removal of the prodomain of ADAMTS4 is critical for its ability to degrade aggrecan, the cellular mechanisms for its processing and trafficking remain unclear. In this study, by using both furin-specific inhibitor and RNA interference technique, we demonstrate that furin plays an important role in the intracellular removal of ADAMTS4 prodomain. Further, we demonstrate that proADAMTS4 can be processed by means of multiple furin recognition sites: (206)RPRR(209), (209)RAKR(212), or (211)KR(212). The processing of proADAMTS4 was completely blocked by brefeldin A treatment, suggesting that processing occurs in the trans-Golgi network. Indeed, ADAMTS4 is co-localized with furin in trans-Golgi network. Interestingly, the pro form of ADAMTS4, not its mature one, co-precipitates with furin, suggesting that furin physically interacts with the prodomain of ADAMTS-4. In addition, our evidence suggests that a furin-independent pathway may also contribute to the activation of ADAMTS4. These results indicate that the activation mechanism for ADAMTS4 can be targeted for therapeutical intervention against this enzyme.

Transforming growth factor-beta induces secretion of activated ADAMTS-2. A procollagen III N-proteinase

The metalloproteinase ADAMTS-2 has procollagen I N-proteinase activity capable of cleaving procollagens I and II N-propeptides in vitro, whereas mutations in the ADAMTS-2 gene in dermatosparaxis and Ehlers-Danlos syndrome VIIC show this enzyme to be responsible in vivo for most biosynthetic processing of procollagen I N-propeptides in skin. Yet despite its important role in the regulation of collagen deposition, information regarding regulation and substrate specificity of ADAMTS-2 has remained sparse. Here we demonstrate that ADAMTS-2 can, like the procollagen C-proteinases, be regulated by transforming growth factor-beta 1 (TGF-beta 1), with implications for mechanisms whereby this growth factor effects net increases in formation of extracellular matrix. TGF-beta 1 induced ADAMTS-2 mRNA approximately 8-fold in MG-63 osteosarcoma cells in a dose- and time-dependent, cycloheximide-inhibitable manner, which appeared to operate at the transcriptional level. Secreted ADAMTS-2 protein induced by TGF-beta 1 was 132 kDa and was identical in size to the fully processed, active form of the protease. Biosynthetic processing of ADAMTS-2 to yield the 132-kDa form is shown to be a two-step process involving sequential cleavage by furin-like convertases at two sites. Surprisingly, purified recombinant ADAMTS-2 is shown to cleave procollagen III N-propeptides as effectively as those of procollagens I and II, whereas processing of procollagen III is shown to be decreased in Ehlers-Danlos VIIC. Thus, the dogma that procollagen I and procollagen III N-proteinase activities are provided by separate enzymes appears to be false, whereas the phenotypes of dermatosparaxis and Ehlers-Danlos VIIC may arise from defects in both type I and type III collagen biosynthesis.

Collagen II containing a Cys substitution for Arg-alpha1-519: abnormal interactions of the mutated molecules with collagen IX

Single amino acid substitutions in collagen II cause heterogeneous cartilage disorders including some chondrodysplasias and certain forms of heritable osteoarthritis. In this study, we examined molecular interactions between normal collagen II and collagen IX, and the effect of a Cys substitution for Arg-alpha1-519 in collagen II on these interactions. Binding assays showed that the association equilibrium constant of collagen IX-collagen II interaction is 15 x 10(6) M(-1). Specificity of the interaction was analyzed by the binding of collagen IX to recombinant collagen II variants lacking fragments of 234 amino acids corresponding to particular D-periods. The results indicated that the C-terminal half of collagen II, which includes the D3 and D4 periods, has a high affinity for collagen IX, and that the nontriple helical telopeptides of collagen II are not essential for the specific binding of collagen IX. Computer analysis of the surface of the mutated collagen II and binding assays showed that a Cys substitution for Arg-alpha1-519 changes electrostatic properties around the mutation site, increases the affinity of mutant collagen II for collagen IX, and possibly alters the specificity of the interaction. Thus, the results indicate that interactions between collagen II and collagen IX are site specific and that single amino acid substitutions in collagen II may change the molecular interactions with collagen IX that could destabilize the cartilaginous matrix.

Role of iron load on fibrogenesis in chronic hepatitis C

BACKGROUND/AIMS

In chronic viral hepatitis, an enhanced iron load is related to lower response to interferon. Furthermore, iron, through the production of oxygen radicals, may stimulate hepatocyte necrosis and the activation of cells responsible for synthesis and deposition of extracellular matrix. We investigated the relationship between iron load, evaluated by serum assays, and liver fibrogenesis in chronic active viral hepatitis.

METHODOLOGY

Serum iron, ferritin, transferrin saturation and serum markers of hepatic fibrogenesis (Laminin and the amino-terminal peptide of procollagen III-NPIIIP-) were assayed in 102 patients (47 females, 55 males, mean age 42.48 years) affected by chronic hepatitis C virus and in 81 healthy controls (47 males, 34 females). In hepatitis C virus patients (studied before alpha-interferon treatment) a semiquantitative score for portal inflammation, necrosis and fibrosis was applied to liver biopsy.

RESULTS

Serum indices of iron load were higher in hepatitis C virus patients than in controls, and were higher in cirrhotic than in chronic hepatitis cases. Ferritin and serum iron were positively correlated with NPIIIP and laminin; moreover cases with ferritin levels over the normal limit for sex and age had higher levels of NPIIIP and laminin than cases with normal or poor iron status.

CONCLUSIONS

Our data suggest that even a mild increase of iron load stimulates hepatic fibrogenesis, probably adding oxygen free radical injury to the damage of viral infection.

Human Ehlers-Danlos syndrome type VII C and bovine dermatosparaxis are caused by mutations in the procollagen I N-proteinase gene

Ehlers-Danlos syndrome (EDS) type VIIC is a recessively inherited connective-tissue disorder, characterized by extreme skin fragility, characteristic facies, joint laxity, droopy skin, umbilical hernia, and blue sclera. Like the animal model dermatosparaxis, EDS type VIIC results from the absence of activity of procollagen I N-proteinase (pNPI), the enzyme that excises the N-propeptide of type I and type II procollagens. The pNPI enzyme is a metalloproteinase containing properdin repeats and a cysteine-rich domain with similarities to the disintegrin domain of reprolysins. We used bovine cDNA to isolate human pNPI. The human enzyme exists in two forms: a long version similar to the bovine enzyme and a short version that contains the Zn++-binding catalytic site but lacks the entire C-terminal domain in which the properdin repeats are located. We have identified the mutations that cause EDS type VIIC in the six known affected human individuals and also in one strain of dermatosparactic calf. Five of the individuals with EDS type VIIC were homozygous for a C-->T transition that results in a premature termination codon, Q225X. Four of these five patients were homozygous at three downstream polymorphic sites. The sixth patient was homozygous for a different transition that results in a premature termination codon, W795X. In the dermatosparactic calf, the mutation is a 17-bp deletion that changes the reading frame of the message. These data provide direct evidence that EDS type VIIC and dermatosparaxis result from mutations in the pNPI gene.

Recombinant procollagen II: Deletion of D period segments identifies sequences that are required for helix stabilization and generates a temperature-sensitive N-proteinase cleavage site

A cDNA cassette system was used to synthesize recombinant versions of procollagen II in which one of the four blocks of 234 amino acids that define a repeating D periods of the collagen triple helix were deleted. All the proteins were triple helical and all underwent a helix-to-coil transition between 25 and 42 degreesC as assayed by circular dichroism. However, the details of the melting curves varied. The procollagen lacking the D1 period unfolded 3 degreesC lower than a full-length molecule. With the procollagen lacking the D4 period, the first 25% of unfolding occurred at a lower temperature than the full-length molecule, but the rest of the structure unfolded at the same temperature. With the procollagen lacking the terminal D0.4 period, the protein unfolded 3 degreesC lower than the full-length molecule and a smaller fraction of the protein was secreted by stably transfected clones than with the other recombinant procollagens. The results confirmed previous suggestions that the collagen triple helix contains regions of varying stability and they demonstrated that the two D periods at the end of the molecule contain sequences that serve as clamps for folding and for stabilizing the triple helix. Reaction of the recombinant procollagens with procollagen N-proteinase indicated that in the procollagen lacking the sequences, the D1 period assumed an unusual temperature-sensitive conformation at 35 degreesC that allowed cleavage at an otherwise resistant Gly-Ala bond between residues 394 and 395 of the alpha1(II) chain.

Surface located procollagen N-propeptides on dermatosparactic collagen fibrils are not cleaved by procollagen N-proteinase and do not inhibit binding of decorin to the fibril surface

Dermatosparaxis is a recessive disorder of animals (including man) which is caused by mutations in the gene for the enzyme procollagen N-proteinase and is characterised by extreme skin fragility. Partial loss of enzyme activity results in accumulation of pNcollagen (collagen with N-propeptides) and abnormal collagen fibrils in the fragile skin. How the N-propeptides persist in the tissue and how abnormal fibril morphology results in fragile skin is poorly understood. Using biochemical and quantitative mass mapping electron microscopy we showed that the collagen fibrils in the skin of a dermatosparactic calf contained 57% type I pNcollagen and 43% type I collagen and the fibrils were irregularly arranged in bundles and hieroglyphic in cross-section. Image analysis of the fibril cross-sections suggested that the deviation from circularity of dermatosparactic fibrils was caused by N-propeptides of pNcollagen being located at the fibril surface. Comparison of experimental and theoretical axial mass distributions of the fibrils showed that the N-propeptides were located to the overlap zone of the fibril D-period (where D=67 nm, the characteristic axial periodicity of collagen fibrils). Treatment of the dermatosparactic fibrils with N-proteinase did not remove the N-propeptides from the fibrils, although the N-propeptides were efficiently removed by trypsin and chymotrypsin. However, the N-propeptides were efficiently cleaved by the N-proteinase when the pNcollagen molecules were extracted from the fibrils. These results are consistent with close packing of N-propeptides at the fibril surface which prevented cleavage by the N-proteinase. Long-range axial mass determination along the fibril length showed gross non-uniformity with multiple mass bulges. Of note is the skin fragility in dermatosparaxis, and also the appearance of mass bulges along the fibril long axis symptomatic of the fragile skin of mice which lack decorin. Western blot analysis showed that the dermatosparactic fibrils bound elevated levels of the proteoglycan, compared with normal skin fibrils. The results showed that N-propeptides can distort the morphology of fibrils, that they do not inhibit binding of gap-associated macromolecules (such as decorin) and that the normal mechanical properties of skin are strongly dependent on the close association of near-cylindrical fibrils, thereby enabling maximal fibril-fibril interactions.

Procollagen N-proteinase and procollagen C-proteinase. Two unusual metalloproteinases that are essential for procollagen processing probably have important roles in development and cell signaling

As soon as procollagen precursors of fibrillar collagens were discovered in the early 1970s, it became apparent that connective tissues must contain proteolytic activities that cleave the N-propeptides and the C-propeptides from procollagens. Isolation and characterization of the enzymic activities, however, proved to be unexpectedly difficult. Both proteinases are large and are synthesized in several different forms with polypeptide chains ranging in size from 70 kDa to about 130 kDa. The N-proteinase has the unusual property of cleaving the N-propeptides from type I and type II procollagens if the proteins are in a native conformation, but not if the proteins are partially unfolded so that the N-telopeptides are no longer in a hair-pin configuration. The C-proteinase specifically cleaves native and denatured types I, II and III procollagens. It also specifically cleaves a precursor of lysyl oxidase and laminin 5. Both enzymes and their variants have structures that place them in a large and expanding super-family of over 200 zinc-binding metalloproteinases. The larger of two forms of the N-proteinase contains an RGD sequence for binding through integrins and properdin repeats similar to those found in thrombospondin. The shorter 70 kDa form of the C-proteinase is identical to the protein that was previously identified as bone morphogenic protein-1. Both the 70 kDa C-proteinase and two larger forms are homologous to proteins that are expressed early in development in a variety of organisms, including Drosophila, sea urchin, and fish. Therefore, the data suggest that both the N- and C-proteinases have important biological functions in addition to the roles in the processing of procollagens.

A recombinant homotrimer of type I procollagen that lacks the central two D-periods. The thermal stability of the triple helix is decreased by 2 to 4 degrees C

A D-period cassette system was developed that can be used to synthesize a variety of recombinant homotrimers of type I procollagen. A construct lacking the central two D-periods of pro alpha 1(I) chains was assembled and expressed as a recombinant protein in the mammalian cell line. The recombinant protein was purified to homogeneity and the thermal stability of the triple helix assayed by rapid protease digestion. The results indicated that deletion of the central 468 amino acids from the major triple helix lowered the thermal stability of the protein by 2 to 4 degrees C. The results therefore begin to define regions of the molecule that vary in their contributions to helical stability.

Elevated collagen turnover in Nigerian children with calcium-deficiency rickets

Calcium deficiency is a major etiological determinant of rickets in Nigerian children and is accompanied by undermineralization of the developing bone matrix which is composed largely of type I collagen. We have assessed types I and III collagen metabolism by measuring the circulating concentrations of teh N- and C-terminal pro-peptides (intact PINP and PICP) and the C-terminal telopeptide (ICTP) of type I collagen, and the N-terminal pro-peptide (PIIINP) of type III collagen in 94 healthy Nigerian children and in 44 children aged 1-5 years with active calcium-deficiency rickets. In active rickets the mean levels of the four collagen metabolites were approximately twofold higher than in the healthy children, despite a wide variation of individual values. Mean intact PINP was 812 +/- 279 versus 403 +/- 189 microg/liter; PICP was 573 +/- 265 versus 348 +/- 299 microg/liter; PIIINP was 16.8 +/- 8.6 versus 10.8 +/- 3.6 microg/liter, and ICTP was 28.4 +/- 17.2 versus 11.9 +/- 4.1 microg/liter (all P < 0.001), in rachitic and healthy children, respectively. Healthy children younger than 3 years had higher levels of all the collagen metabolites than those between 3 and 5 years (all P < 0.05). Alkaline phosphatase was greater in rickets than in the healthy group (P < 0.001) whereas mean osteocalcin levels were slightly lower (P = 0.009). 1,25(OH)2D correlated with all the collagen propeptides, but not with ICTP in the healthy children. No such correlations were found in rickets, where there was a poor inverse correlation between 1,25(OH)2D and ICTP. These data suggest that collagen turnover is elevated in cases of calcium-deficiency rickets, where vitamin D status is adequate, possibly indicating increased turnover of undermineralized osteoid.

Transforming growth factor-beta regulation of bone morphogenetic protein-1/procollagen C-proteinase and related proteins in fibrogenic cells and keratinocytes

Transforming growth factor-beta1 (TGF-beta1) induces increased extracellular matrix deposition. Bone morphogenetic protein-1 (BMP-1) also plays key roles in regulating vertebrate matrix deposition; it is the procollagen C-proteinase (PCP) that processes procollagen types I-III, and it may also mediate biosynthetic processing of lysyl oxidase and laminin 5. Here we show that BMP-1 is itself up-regulated by TGF-beta1 and that secreted BMP-1, induced by TGF-beta1, is either processed to an active form or remains as unprocessed proenzyme, in a cell type-dependent manner. In MG-63 osteosacrcoma cells, TGF-beta1 elevated levels of BMP-1 mRNA approximately 7-fold and elevated levels of mRNA for mammalian tolloid (mTld), an alternatively spliced product of the BMP1 gene, to a lesser extent. Induction of RNA was dose- and time-dependent and cycloheximide-inhibitable. Secreted BMP-1 and mTld, induced by TGF-beta1 in MG-63 and other fibrogenic cell cultures, were predominantly in forms in which proregions had been removed to yield activated enzyme. TGF-beta1 treatment also induced procollagen N-proteinase activity in fibrogenic cultures, while expression of the procollagen C-proteinase enhancer (PCPE), a glycoprotein that stimulates PCP activity, was unaffected. In contrast to fibrogenic cells, keratinocytes lacked detectable PCPE under any culture conditions and were induced by TGF-beta1 to secrete BMP-1 and mTld predominantly as unprocessed proenzymes.

Incomplete processing of type II procollagen by a rat chondrosarcoma cell line

The Swarm rat chondrosarcoma cell line, RCS-LTC, deposits an extracellular matrix that contains the typical type II, IX, and XI collagen phenotype of hyaline cartilage, but the fibrils appear abnormally thin. By N-terminal sequence analysis, the type II collagen from the matrix was shown to have retained its N-propeptides with no evidence of normal processing to type II collagen. Amplification and sequencing of cDNA prepared from the pro alpha1(II) mRNA of these cells showed a normal N-propeptide cleavage site. Furthermore, the type II N-procollagen could be processed to type II collagen by incubation with culture medium from normal chondrocytes. The findings indicate that the RCS-LTC cell line fails to express an active type II procollagen N-proteinase and, therefore, offers a useful culture system in which to study the role of N-propeptide removal in fibrillogenesis.

Collagen fibrillogenesis during sea urchin development--retention of SURF motifs from the N-propeptide of the 2alpha chain in mature fibrils

The sea urchin 2alpha fibrillar collagen chain has a unique amino-propeptide structure with several repetitions of a still unknown 140-145-amino-acid, four-Cys module called SURF (for sea urchin fibrillar module). To follow the expression of the amino-propeptide of the 2alpha chain and assign a function to this domain, we have overproduced in Escherichia coli several recombinant proteins corresponding either to the amino-propeptide or to the amino-telopeptide. Monoclonal and/or polyclonal antibodies against these recombinant proteins allowed us to observe a similar tissue distribution during the first stages of development. A signal is first observed at the prism stage as intracellular spots in mesenchymal cells. In plutei, immunofluorescence staining is observed around the skeleton spicules and as a thin meshwork surrounding the mesenchymal cells. At the ultrastructural level, and using antibodies against the amino-propeptide, gold particles are observed at the surface of 25 nm thin periodic fibrils. By rotary shadowing, these fibrils show a brush-bottle aspect, exhibiting at their surface numerous periodically distributed thin rods ended by a small globule. These data indicate that the amino-propeptide is maintained during fibrillogenesis. As previously suggested, the retention of the amino-propeptide could play an important role in regulation of the fibril growth. We propose that the important region of this amino-propeptide in the widely encountered 25-nm-diameter fibrils is the short triple-helical segment. The globular part of the amino-propeptide will not only restrict the fibril growth but also interact with other neighbouring components and playing, as suspected from our immunofluorescence studies, a function during the spiculogenesis of the sea urchin embryo.

Flavonoids alter bone-remodelling in auditory ossicle organ cultures

The beneficial role of bioflavonoids in an otosclerosis-like bone-remodelling process can be implicated from its interference with bone resorption induced by prostaglandin E2 (PGE2) in cultured guinea pig ossicles. Ipriflavone (7-isopropoxy-isoflavon) and quercetin reduced PGE2-elevated collagenase-like peptidase (Cl-peptidase) activity and potentiated a PGE2-induced decrease in collagen synthesis. The fact that PGE2 effects are mediated through cyclic AMP in bone turnover and flavonoids act synergistically with PGE2 in collagen synthesis confirm a cyclic AMP phosphodiesterase inhibitory role of flavonoids. It has already been attempted to use Ipriflavone medical treatment of otosclerosis. Quercetin, which has a better than Ipriflavone water-solubility seems as promising as Ipriflavone in the control of the otosclerotic bone-remodelling disturbance.

Significance of the levels of carboxy terminal type II procollagen peptide, chondroitin sulfate isomers, tissue inhibitor of metalloproteinases, and metalloproteinases in osteoarthritis joint fluid

The joint fluid levels of several molecules that reflect the anabolism and catabolism of cartilage matrix and its inflammation were quantitated in patients with primary osteoarthritis (OA) and traumatic arthritis. The carboxy terminal type II procollagen increased in primary OA and traumatic arthritis joint fluid and was thought to be a good marker of the repair response of chondrocytes. We found that the increase of this molecule in the joint correlated well with body mass index in primary OA and the degree of cartilage erosion caused by joint instability in traumatic arthritis. Chondroitin 6-sulfate, an integral part of human aggrecan, was also high in OA and traumatic arthritis joint fluids, and showed a similar distribution with keratan sulfate in each disease group. Stromelysin-1 and tissue inhibitor of metalloproteinases-1 levels in joint fluid were very high in RA, but levels in patients with OA were low. Carboxy terminal type II procollagen appeared most sensitive in the evaluation of risk factors of OA such as obesity and joint instability, compared to other markers tested.

Substitution of serine for glycine 883 in the triple helix of the pro alpha 1 (I) chain of type I procollagen produces osteogenesis imperfecta type IV and introduces a structural change in the triple helix that does not alter cleavage of the molecule by procollagen N-proteinase

Type I procollagen secreted by dermal fibroblasts from an individual with osteogenesis imperfecta type IV was a mixture of normal molecules and molecules that were post-translationally overmodified. The individual was heterozygous for a G to A transition in the COL1A1 gene that resulted in the substitution of serine for glycine 883 in one or both of the pro alpha 1 (I) chains. The thermal stability of molecules containing overmodified chains was lower by 2 degrees C than that of normal molecules. However, following cleavage of the molecules with vertebrate collagenase, the temperature of denaturation of the overmodified A fragments (residues 1-775 of the helix did not contain the substitution) was 2 degrees C greater than that of A fragments from normal molecules. The rates of cleavage by procollogen N-proteinase (EC 3.4.214.14) (N-proteinase) of procollagen molecules in normal and osteogenesis imperfecta samples were not significantly different. The procollagen molecules in the osteogenesis imperfecta sample were also indistinguishable from those in control samples by rotary shadowing electron microscopy. The results suggest that this substitution of serine for glycine in the alpha 1 (I) chain of procollagen, like the substitution of aspartate for the same glycine previously described (Lightfoot, S. J., Holmes, D. F., Brass, A., Grant, M. E., Byers, P. H., and Kadler, K. E. (1992) J. Biol. Chem. 267, 25521-25528), can alter the structure of the triple helix N-terminal to the site of the substitution. However, in contrast to the aspartate for glycine substitution, the structural change is insufficient to delay the cleavage of the procollagen by N-proteinase and results in a mild rather than lethal phenotype.

Cleavage of type I procollagen by C- and N-proteinases is more rapid if the substrate is aggregated with dextran sulfate or polyethylene glycol

The enzymes procollagen C- and N-proteinases specifically cleave carboxyl- and amino-terminal propeptides of procollagens. After cleavage of the propeptides, the resulting collagens self-assemble into fibrils. In most previous experiments with the enzymes, the substrate was monomeric type I procollagen. Here we have prepared aggregates of type I procollagen from chick embryo tendons by using 1 to 100 micrograms/ml of 500-kDa dextran sulfate or 3 to 5% (w/v) polyethylene glycol (M(r) 3350). Aggregation of the substrate with dextran sulfate increased its rate of cleavage by purified or crude C-proteinase from chick embryo tendons 10- to 15-fold. Aggregation of the substrate with 25 to 100 microgram/ml of dextran sulfate increased the rate of cleavage by purified N-proteinase about 4-fold. The rate of cleavage by crude N-proteinase was enhanced only about 2-fold, apparently because of partial precipitation of the enzyme by dextran sulfate. Using polyethylene glycol to aggregate the substrate increased the rate of cleavage by procollagen C-proteinases 5- to 20-fold. Aggregation with polyethylene glycol also increased the rate of cleavage by purified procollagen N-proteinases 2- to 5-fold. With crude N-proteinase, the rate of cleavage was increased only 1.5-fold. The results suggest that the rate of cleavage of the substrate by both enzymes is increased by the aggregation of the substrate itself by dextran sulfate or polyethylene glycol. The increased rates of cleavage seen after aggregation of substrate can be used to develop more sensitive assays for the enzymic activities.

Self-assembly into fibrils of collagen II by enzymic cleavage of recombinant procollagen II. Lag period, critical concentration, and morphology of fibrils differ from collagen I

A recently developed recombinant system for synthesis of human procollagen II by stably transfected host cells was used to prepare adequate amounts of protein to study the self-assembly of collagen II into fibrils. The procollagen II was cleaved to pCcollagen II by procollagen N-proteinase (EC 3.4.24.14), the pCcollagen II was chromatographically purified, and the pCcollagen II was then used as a substrate to generate collagen II fibrils by cleavage with procollagen C-proteinase. The kinetics for assembly of collagen II fibrils were similar to those observed previously for the self-assembly of collagen I in that a distinct lag phase was observed followed by a sigmoidal propagation phase. However, under the same experimental conditions, the lag time for assembly of collagen II fibrils was 5-6-fold longer, and the propagation rate for collagen II fibrils was about 30-fold lower than for collagen I fibrils. The relatively long lag time for the assembly of collagen II into fibrils made it possible to demonstrate that most of the conversion of pCcollagen II to collagen II occurred in the solution phase. The critical concentration at 37 degrees C for collagen II was about 50-fold greater than the critical concentration for collagen I. The Gibbs free energy change for the assembly of collagen II into fibrils was -40 kJ/mol, a value that was about 14 kJ/mol less than the free energy change for collagen I and about the same as the free energy change for the homotrimer of collagen I. Dark-field light microscopy and negative-staining electron microscopy demonstrated that the collagen II fibrils were thin and formed network-like structures. The results demonstrated, therefore, that the structural information of the monomer is sufficient to explain the characteristically small diameters and arcade-like geometry of collagen II fibrils found in cartilage and other tissues.

Self-assembly of collagen I from a proband homozygous for a mutation that substituted serine for glycine at position 661 in the alpha 2(I) chain. Possible relationship between the effects of mutations on critical concentration and the severity of the phenotype

Procollagen I was isolated from cultured skin fibroblasts from a proband who was homozygous for a mutation in the COL1A2 gene that substituted a serine codon for a glycine codon at position 661 of the alpha 2(I) chain. The procollagen I was cleaved to pCcollagen I by procollagen N-proteinase and the pCcollagen I was used as a substrate for assay of self-assembly of collagen I into fibrils. The mutated pCcollagen I was cleaved to collagen I by procollagen C-proteinase at the same rate as control pCcollagen I. However, self-assembly of the mutated collagen I had a lag period that was 15-fold greater than the lag period observed with normal collagen I under the same conditions. Also, self-assembly of the mutated collagen I had a propagation rate of about one-fourth of the propagation rate of normal collagen I. In addition, the critical concentration for fibril assembly was slightly increased. Rotary shadowing electron microscopy of the mutated procollagen I did not reveal any increased flexibility of the triple helix as was seen previously with two mutated procollagens I in which there were substitutions of cysteine for glycine residues in the alpha 1(I) chain (Vogel, B. E., Doelz, R., Kadler, K. E., Hojima, Y., Engel, J., and Prockop, D. J. (1988) J. Biol. Chem. 263, 19249-19255; Lightfoot, S. J., Holmes, D. F., Brass, A., Grant, M. E., Byers, P. H., and Kadler, K. E. (1992) J. Biol. Chem. 267, 25521-25528). However, morphometric analysis by dark-field light microscopy and electron microscopy showed that the fibrils formed from the mutated collagen I appeared thicker in diameter than the fibrils formed from the normal collagen I. Comparison of the results with similar data on four mutated procollagens previously studied raised the possibility that mutations which markedly increase the critical concentration of fibril assembly produce more severe phenotypes than mutations which change other parameters of fibril assembly.

Characterization of type I procollagen N-proteinase from fetal bovine tendon and skin. Purification of the 500-kilodalton form of the enzyme from bovine tendon

Procollagen N-proteinase (EC 3.4.24.14) is the enzyme that specifically cleaves the NH2-terminal propeptides from type I procollagen. Two forms of N-proteinase with apparent molecular sizes of 300 and 500 kDa were found in partially purified preparations from fetal bovine tendon extracts. The 500-kDa form of enzyme was purified 16,000-fold with a recovery of 8% from the extracts of the tendons by six purification steps. The purified enzyme was a neutral, Ca(2+)-dependent proteinase (5-10 mM) that was inhibited by metal chelators. The 500-kDa enzyme contained unreduced polypeptides of 58, 125, 170, and 190 kDa which were separated by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. Electron microscopic study indicated that the enzyme molecules were generally globular and had diameters of 33 +/- 4 nm. Other properties of the 500-kDa enzyme were: 1) the Km for type I procollagen is 35 nM at pH 7.5 and 35 degrees C, and the kcat is 290 h-1; 2) the activation energy for reaction with type I procollagen is 10,050 cal mol-1; 3) the isoelectric point is 3.8; 4) the enzyme cleaves the NH2-terminal propeptides of type II procollagen as well as type I procollagen but not of type III procollagen; and 5) the enzyme specifically cleaves a -Pro-Gln- bond in the pro-alpha 1(I) chain and an -Ala-Gln- bond in the pro-alpha 2(I) chain. The bovine N-proteinase with a mass of 300 kDa was found to be similar to the 500-kDa enzyme and appeared to be a degraded form of the 500-kDa enzyme generated during purification. The N-proteinase from fetal bovine skin extracts also contained 300-kDa and 500-kDa enzyme forms.

Further evidence that the failure to cleave the aminopropeptide of type I procollagen is the cause of Ehlers-Danlos syndrome type VII

Dermal fibroblasts from a Chinese Ehlers-Danlos syndrome type VII patient synthesized approximately equal amounts of normal pro-alpha 2(I) chains of type I procollagen and abnormal ones with electrophoretic mobility of pN alpha 2(I) chains, in which the amino-propeptide (N-propeptide) was retained. Reverse-transcriptase PCR analysis of the proband's RNA showed outsplicing of the 54 base exon 6 in half of the pro-alpha 2(I) mRNAs. Exon 6 encodes 18 amino acids of the N-telopeptide which contains the procollagen N-proteinase cleavage site and a cross-link precursor lysine. Loss of these sequences would result in failure to cleave the amino-propeptide of pro-alpha 2(I) and the accumulation of pN-alpha 2(I) chains. Nucleotide sequencing analyses of the proband's COL1A2 gene showed the presence of a T to C transition at position +2 of intron 6 in one allele and the proband is heterozygous for the defect. This mutation which destroyed the consensus GT dinucleotide at the 5' splice donor site of the intron is responsible for the loss of exon 6 by exon skipping. Electron microscopic analysis of the patient's dermis showed the presence of abnormal collagen I fibrils of irregular diameter and circularity. This mutation in COL1A2 in an EDS VII patient is the first reported case in the Chinese population and is identical to one reported for another EDS-VII (Libyan) patient. The occurrence of an identical mutation in two probands of different ethnic origin is direct evidence that the mutant genotype is the cause of the EDS VII phenotype.(ABSTRACT TRUNCATED AT 250 WORDS)

A tripeptide deletion in the triple-helical domain of the pro alpha 1(I) chain of type I procollagen in a patient with lethal osteogenesis imperfecta does not alter cleavage of the molecule by N-proteinase

Dermal fibroblasts from a fetus with perinatal lethal osteogenesis imperfecta synthesized normal and abnormal type I procollagen molecules. The abnormal molecules contained one or two pro alpha 1(I) chains in which glycine, alanine, and hydroxyproline at positions 874, 875, and 876 in the triple-helical region were deleted as the result of a 9-base pair genomic deletion. Molecules that contained abnormal chains were overmodified from the site of the deletion toward the amino-terminal region of the molecule. Secretion of the overmodified molecules was impaired. The thermal stability of molecules containing abnormal chains was lower than that of normally modified molecules. After cleavage of molecules with vertebrate collagenase, the temperature of thermal denaturation of the overmodified A fragments was greater than that of the fragments from the normal molecules. The rates of cleavage of the normal and the abnormal molecules by N-proteinase were indistinguishable. Our findings suggest that the tripeptide deletion introduces a shift in the phase of the chains in the triple helix. This structural change is propagated from the site of the deletion toward the amino terminus of the molecule, but the subsequent alteration in the structure of the N-proteinase cleavage site is not sufficient to cause a decrease in the rate of cleavage by the enzyme.

Type I procollagens containing substitutions of aspartate, arginine, and cysteine for glycine in the pro alpha 1 (I) chain are cleaved slowly by N-proteinase, but only the cysteine substitution introduces a kink in the molecule

Type I procollagen was purified from the medium of dermal fibroblasts cultured from four individuals with osteogenesis imperfecta (OI) type II who had mutations in the COL1A1 gene of type I procollagen. The procollagens were mixtures of normal molecules and molecules that contained substitutions of aspartate for glycine 97, arginine for glycine 550, cysteine for glycine 718, and aspartate for glycine 883 in one or both of the alpha 1 (I) chains of the molecule. The procollagens were cleaved more slowly than control type I procollagen by procollagen N-proteinase. Double-reciprocal plots of initial relative velocities and initial substrate concentrations indicated that the OI procollagens were all cleaved slowly by N-proteinase because of decreased Vmax, rather than increased Km. This suggested that slow cleavage of the OI procollagens by N-proteinase was the result of slow conversion of the N-proteinase-procollagen complex. Further experiments showed that the vertebrate collagenase A fragment of the aspartate for glycine alpha 1(I) 883 OI procollagen that contained the N-proteinase cleavage site but not the site of the substitution was also cleaved more slowly by N-proteinase than the normal vertebrate collagenase A fragments in the samples. These data show, for the first time, that an altered triple-helical structure is propagated from the site of a substitution of a bulky residue for glycine to the amino-terminal end of the procollagen molecule and disrupts the conformation of the N-proteinase cleavage site. Rotary shadowing electron microscopy of molecules in the preparation of cysteine for glycine alpha 1(I)-718 showed the presence of a kink in approximately 5% of a population of molecules in which 60% were abnormal and 20% contained a disulfide bond. In contrast, procollagens containing aspartate and arginine for glycine were indistinguishable by rotary shadowing electron microscopy from those in control samples. The results here confirm previous suggestions that substitution of cysteine for glycine in the alpha 1(I) chain of type I collagen can introduce a kink near the site of the substitution. However, the presence of a kink is not a prerequisite for delayed cleavage of abnormal procollagens by N-proteinase.

Temperature-induced post-translational over-modification of type I procollagen. Effects of over-modification of the protein on the rate of cleavage by procollagen N-proteinase and on self-assembly of collagen into fibrils

Previous observations suggested that incubating fibroblasts at elevated temperature caused over-modification of type I procollagen by post-translational enzymes because of a delay in folding of the collagen triple helix. Here, human skin fibroblasts were incubated at 40.5 instead of 37 degrees C, and the type I procollagen secreted into the medium was isolated. Analysis of the protein indicated that there was an increase of about 5 residues of hydroxylysine/alpha chain and about 1 residue of glycosylated hydroxylysine/alpha chain. Assays with procollagen N-proteinase indicated that the N-propeptide of the over-modified collagen was cleaved at a decreased rate, apparently because the over-modification altered the conformation-dependent cleavage site for the enzyme. Assays in a system for assembly of collagen into fibrils demonstrated that the over-modified protein had a higher critical concentration for self-assembly. Also, the fibrils formed from the over-modified collagen at 31 and 29 degrees C had smaller diameters than fibrils formed from normal type I collagen. The results provide direct evidence for earlier suggestions that post-translational over-modification of a fibrillar collagen can alter the morphology of the fibrils formed. The results also indicate that some of the biological consequences of the mutations in type I procollagen causing heritable disorders must be ascribed to the effects of post-translational over-modifications that frequently occur as secondary consequences of changes in the primary structure of the protein.

Heterogeneity in dermatosparaxis is shown by contraction of collagen gels

Dermal fibroblasts from sheep exhibiting a mild form of dermatosparaxis were able to contract reconstituted, fibrillar collagen gels at the same rate as control dermal fibroblasts, indicating a normal interaction between the cells and a collagenous matrix. An extract from dermatosparactic skin was shown, after partial purification, to have N-proteinase activity, although the level of activity was much lower than found in normal skin. These data show that dermatosparaxis is a heterogeneous disease, since in the severe forms of the disease the defect has been characterized as an absence of N-proteinase and an inability of the cells to interact with and contract collagen gels.

C1q, a collagen-like complement subcomponent, in dermatosparactic cattle: its extracellular modification is not affected by lack of procollagen N-terminal proteinase (pN-proteinase)

C1q, a collagen-like complement protein, was purified from the serum of a dermatosparactic calf which lacks procollagen N-terminal proteinase (pN-proteinase). The specific hemolytic activity of the serum C1q from the dermatosparactic animal was identical to that of C1q from a normal calf. Gel-filtration of serum from the dermatosparactic calf, on Sepharose 6B, showed the presence of C1q-antigenic material at only one position which was identical to the elution position of normal bovine C1q. No difference, under dissociating conditions, could be seen in the size of the chains of C1q in specific immunoprecipitates isolated from the sera of dermatosparactic and normal animals, as judged by polyacrylamidegel electrophoresis (PAGE) in the presence of sodium dodecyl sulfate (SDS). The C1q from the dermatosparactic animal showed the same N-terminal amino acid and tryptic-digest peptide pattern on HPLC as C1q from the normal calf. These results strongly suggest that pN-proteinase is not involved in the extracellular processing of C1q.

Mutations that alter the primary structure of type I procollagen have long-range effects on its cleavage by procollagen N-proteinase

Type I/II procollagen N-proteinase was partially purified from chick embryos and used to examine the rate of cleavage of a series of purified type I procollagens synthesized by fibroblasts from probands with heritable disorders of connective tissue. The rate of cleavage was normal with procollagen from a proband with osteogenesis imperfecta that was overmodified by posttranslational enzymes. Therefore, posttranslational overmodification of the protein does not in itself alter the rate of cleavage under the conditions of the assay employed. Cleavage of the procollagen, however, was altered in several procollagens with known mutations in primary structure. Two of the procollagens had in-frame deletions of 18 amino acids encoded by exons 11 and 33 of the pro alpha 2(I) gene. In both procollagens, both the pro alpha 1(I) and the pro alpha 2(I) chains were totally resistant to cleavage. With a procollagen in which glycine-907 of the alpha 2(I) chain domain was substituted with aspartate, both pro alpha chains were cleaved but at a markedly decreased rate. The results, therefore, establish that mutations that alter the primary structure of the pro alpha chains of procollagen at sites far removed from the N-proteinase cleavage site can make the protein resistant to cleavage by the enzyme. The long-range effects of in-frame deletions or other changes in amino acid sequence are probably explained by their disruption of the hairpin structure that is formed by each of the three pro alpha chains in the region containing the cleavage site and that is essential for cleavage of the procollagen molecule by N-proteinase.

Type I procollagen N-proteinase from chick embryo tendons. Purification of a new 500-kDa form of the enzyme and identification of the catalytically active polypeptides

Procollagen N-proteinase (EC 3.4.24.14), the enzyme that cleaves the NH2-terminal propeptides from type I procollagen, was purified over 20,000-fold with a yield of 12% from extracts of 17-day-old chick embryo tendons. The procedure involved precipitation with ammonium sulfate, adsorption on concanavalin A-Sepharose, and five additional column chromatographic steps. The purified enzyme was a neutral, Ca2+-dependent proteinase (5-10 mM) that was inhibited by metal chelators. It had a molecular mass of 500 kDa as determined by gel filtration. The enzyme contained unreduced polypeptides of 61, 120, 135, and 161 kDa that were separated by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. The 135- and 161-kDa polypeptides were catalytically active after elution from the polyacrylamide gel. Other properties of 500-kDa enzyme are: 1) the Km for type I procollagen is 54 nM at pH 7.5 and 35 degrees C, and the kappa cat is 350 h-1; 2) the activation energy for reaction with type I procollagen is 7,100 cal mol-1; 3) the isoelectric point is 3.6; and 4) the enzyme specifically cleaves the NH2-terminal propeptides of type I and II procollagen, but not of type III procollagen. A minor form of N-proteinase with a 300-kDa mass was also purified and was found to contain a 90-kDa polypeptide as the major active polypeptide. The enzyme appeared to be a degraded form of the 500-kDa N-proteinase. The properties of the 300-kDa enzyme were similar to those observed for the 500-kDa enzyme.

A substitution of cysteine for glycine 748 of the alpha 1 chain produces a kink at this site in the procollagen I molecule and an altered N-proteinase cleavage site over 225 nm away

In previous work (Vogel, B. E., Minor, R. R., Freund, M., and Prockop, D. J. (1987) J. Biol. Chem. 262, 14737-14744), we identified a single-base mutation that converted the glycine at position 748 of the alpha 1 chain of type I procollagen to a cysteine in a proband with a lethal variant of osteogenesis imperfecta. In addition to posttranslational overmodification, the abnormal molecules displayed decreased thermal stability and a decreased rate of secretion. An unexplained finding was that procollagen was poorly processed to pCcollagen in postconfluent cultures of skin fibroblasts. Here, we show that the procollagen synthesized by the proband's cells is resistant to cleavage by procollagen N-proteinase, a conformation-sensitive enzyme. Since the only detectable defect in the molecule was the cysteine for glycine substitution, we assembled several space-filling models to try to explain how the structure of the N-proteinase cleavage site can be affected by an amino acid substitution over 700 amino acid residues or 225 nm away. The models incorporated a phase shift of a tripeptide unit in one or both of the alpha 1 chains. The most satisfactory models produced a flexible kink of 30 degrees or 60 degrees at the site of the cysteine substitution. Therefore, we examined the procollagen by electron microscopy. About 25% of the molecules had a kink not seen in control samples, and the kink was at the site of the cysteine substitution.

Cleavage of type I and type II procollagens by type I/II procollagen N-proteinase. Correlation of kinetic constants with the predicted conformations of procollagen substrates

The kinetic constants were examined for the cleavage of several types of procollagen by type I/II procollagen N-proteinase. The Km values were essentially the same (0.2 microM) for chick type I procollagen, human type I procollagen, and chick type II procollagen. However, the Vmax values differed over a 14-fold range. As reported previously, the enzyme did not cleave denatured type I or II procollagen. Also, it did not cleave human type III procollagen which contains the same scissle -Pro-Gln- bond as the pro-alpha 1(I) chain of type I procollagen. To explain the observations, Chou-Fasman rules were used to compare the secondary structures of the cleavage sites in the procollagens. The results supported a previous suggestion (Helseth, D. L., Jr., Lechner, J. L., and Veis, A. (1979) Biopolymers 18, 3005-3014) that the region carboxyl-terminal to cleavage site in the pro-alpha 1(I) chain of type I procollagen was in a hairpin conformation consisting of a beta-sheet, beta-turn, and beta-sheet. In both chick and human type I procollagen, the hairpin loop in the pro-alpha 1(I) chain consisted of about 18 amino acids. The cleavage site itself was in a short alpha-helical structure of four or five amino acids. The pro-alpha 2(I) chains had a similar hairpin loop of about 14 amino acids and alpha-helix of four or five amino acids containing the cleavage site. Chick type II procollagen, which had the highest Vmax value, had a longer hairpin structure of 22 amino acids, and the cleavage site was in a longer alpha-helical domain of 10 amino acids. In contrast, type III procollagen had a random-coil conformation in the same region. The results help to explain the unusual substrate requirements of type I/II N-proteinase. They also help explain why mutations that produce in-frame deletions of amino acids 84 or more residues carboxyl-terminal to the cleavage site make the protein resistant to the enzyme.

Cloning of a complementary DNA for rabbit proactivator. A metalloproteinase that activates synovial cell collagenase, shares homology with stromelysin and transin, and is coordinately regulated with collagenase

Rabbit proactivator is a neutral metalloproteinase that activates another metalloproteinase, procollagenase, and degrades noncollagenous matrix. We describe the construction of an activator complementary DNA (cDNA) clone, which is 1.9 kb, that selects a 2.1-kb messenger RNA (mRNA) in Northern blot hybridizations. Nucleic acid sequence studies of the activator cDNA indicate 1) that it encodes protein Mr 53,881, 2) that this protein exhibits approximately 80% homology with rat transin, an oncogene-induced protein with a previously unknown function, and 3) that, in the first 172 residues, it is virtually identical to the rabbit metalloproteinase, stromelysin. Homology between rabbit activator and human skin collagenase is approximately 50%. Activator and collagenase mRNA are coordinately regulated; untreated cultures of rabbit synovial fibroblasts produce low levels of each protein, but addition of phorbol myristate acetate (10(-8)M) results in an increase in mRNA for both proteins by 2.5-5 hours. Adding all-trans-retinoic acid (10(-6)M) or dexamethasone (10(-7)M) to phorbol-stimulated cells coordinately suppresses both activator and collagenase mRNA. Our data suggest the existence of coordinately regulated metalloproteinases that are important in the modulation of connective tissue metabolism.

Effect of oxygen tension on the quantities of procollagenase-activating angiogenic factor present in the developing kitten retina

Maintenance of newborn kittens in an oxygen rich atmosphere followed by a recovery period in a normal atmosphere mimicked the effects of the human disease retrolental fibroplasia. The retinas of such kittens contained significantly raised levels of low molecular weight angiogenic material (as measured by procollagenase activation) when compared with those of a control group of kittens.

Assembly and processing of procollagen type III in chick embryo blood vessels

The processing of [3H]proline-labeled procollagen III in excised chick embryo blood vessels was found to differ significantly from that of procollagen I in the same tissue. While first the amino propeptides and then the carboxyl propeptides were fairly rapidly cleaved from procollagen I, only the carboxyl propeptides were split off procollagen III, leaving pN-collagen III. This intermediate, which is only slowly converted to collagen III by loss of amino propeptides, was characterized by its sedimentation properties, isolation of the amino propeptide, and reaction with purified antibodies that are specific against bovine amino propeptide III. It is interchain disulfide-linked, both through the amino propeptide and the carboxyl ends of the collagen chains. The conversion of procollagen III to pN-collagen III either in blood vessels, or after isolation by a carboxyl procollagen peptidase obtained from chick tendon fibroblast cultures, is inhibited by 50 mM arginine. Underhydroxylated procollagen III was isolated from blood vessels treated with alpha, alpha'-dipyridyl. Its amino propeptides reacted with the above antibodies but were not linked to each other. In contrast, its carboxyl propeptides were interchain disulfide-bridged, supporting previous suggestions that the carboxyl propeptides play a role in the assembly of procollagen trimer.

Activity of procollagen-prolyl-hydroxylase and N-acetyl-beta-glucosaminidase in liver biopsies from patients with chronic liver diseases

In 5 mg of liver tissue obtained by needle biopsy from patients with chronic liver diseases, activity of both Procollagen-prolyl-hydroxylase and N-Acetyl-beta-glucosaminidase was measured. The activity of both enzymes increased due to the activity of fibrosis, but prolylhydroxylase increased more. The relation of these two enzyme activities in the development of liver fibrosis is discussed.