Separate and overlapping specificities in rheumatoid arthritis antibodies binding to citrulline- and homocitrulline-containing peptides related to type I and II collagen telopeptides

IntroductionOur objective was to find out if there are antibodies binding to homocitrulline-containing type I and II collagen carboxyterminal telopeptides in sera of patients with rheumatoid arthritis (RA), and if these antibodies cross-react with citrulline and homocitrulline in the same peptide sequence.MethodsA total of 72 RA and 72 control sera were analyzed for binding using enzyme-linked immunosorbent assay to citrulline- or homocitrulline-containing type I and II collagen carboxyterminal telopeptides, as well as to cyclic citrullinated peptide (CCP) and to mutated citrullinated vimentin (MCV). Specificities of the antibodies were tested using inhibition-ELISA.ResultsOf the RA sera, 39 (54%) and 41 (57%) were positive for binding to CCP and MCV, respectively. Further, 34 (47%) and 30 (42%) of the patients had specific antibodies binding to and being inhibited by citrulline-containing type I collagen telopeptides and by citrulline-containing type II collagen carboxyterminal telopeptides, respectively. The corresponding figures regarding homocitrulline-containing type I and homocitrulline-containing type II collagen telopeptides were 16 (22%) and 14 (19%). Most of the patients, who were seropositive for citrullinated peptides, showed binding in multiple assays. A total of 10 (14%) RA patients were positive for all the tested peptide pairs, while 28 (39%) of them had antibodies that contained overlapping specifities between citrulline and homocitrulline in the same peptide sequence.ConclusionsAntibodies to both citrulline and homocitrulline containing type I and II collagen telopeptides can be found in sera of RA patients. These antibodies are not constant from one RA patient to another, but contain separate or overlapping specificities within the same peptide sequence varying between individuals. Our results suggest some relationship between citrulline and homocitrulline-recognizing antibodies, since homocitrulline antibodies exist mainly in individuals seropositive to anti-CCP and anti-MCV.

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Osteogenesis imperfecta type IV: evidence of abnormal triple helical structure of type I collagen

Summary Skin fibroblasts from a patient with mild osteogenesis imperfecta (OI) type IV synthesize two populations of type I procollagen molecules. One population contains pro1(I) and pro2(I) chains that migrate normally in sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and a second population contains only slower migrating pro1(I) and pro2(I) chains. The total amount of type I procollagen made by OI cells and the ratio of pro1(I): pro2(I) is normal. When labeled under conditions that inhibit post-translational modification of pro chains, the OI cells produce only single populations of pro1(I) and pro2(I) chains indicating that the apparent increased molecular weight of some OI pro chains is due to excessive post-translational modification rather than peptidyl insertions. Peptide maps indicate that excessive post-translational modification occurs along the entire triple helical segment of some 1(I) and 2(I) chains produced by OI cells. The effect of the mutation is to lower the melting temperature of the molecules containing slow migrating 1(I) and 2(I) chains to 39.5°C (compared to 41.5°C for control), and to delay secretion of the overmodified type I procollagen from OI cells. These data are consistent with a mutation near the carboxyl-terminal end of the triple helical domain which delays triple helical formation and renders all chains available for further post-translational modification amino-terminal to the mutation. Such alterations in triple helical structure, thermal stability, and secretion previously associated only with the lethal OI type II phenotype are thus also seen in the mild OI type IV phenotype.     

Isolation and purification of cyanogen bromide-derived peptides of type II collagen directly from tissue (Swarm chondrosarcoma)

A preparative procedure is described for isolating type II collagen-fragments directly from tissue. Swarm chondrosarcoma from rat, a cartilagenous tissue rich in type II collagen, was digested by cyanogen bromide in 70% formic acid. The resulting crude extract was desalted (G 25 column chromatography) and lyophylized. The yield of peptide mixture was about 1 250 mg obtained from 100 g tissue. The method of purification commonly used for type II collagen prior to cyanogen bromide-cleavage yielded 20 mg peptides from 100 g tissue. Separation of the cyanogen bromide-derived fragments was performed by gel filtration. The column was run at 43 degrees C (denaturing-temperature of collagens) to avoid fibril formation, and a volatile buffer was used (ammonium formate buffer, pH 7.5) so that the effluent fractions could be easily lyophylized. Two-dimensional gel electrophoresis of the main peaks of the column profile demonstrated that this purification step resulted in a good separation of the fragment mixture, although additional steps may be necessary for complete separation of the peptides. The most striking advantages of the method for direct digestion of tissue outlined here are the increase in yield (about 60-fold) and the reduction of purification steps (avoiding type II collagen purification).     

Covalent structure of collagen: amino acid sequence of three cyanogen bromide-derived peptides from human alpha 1(V) collagen chain

Type V collagen was prepared from human amnionic/chorionic membranes and separated into alpha 1(V) and alpha 2(V) polypeptide chains. The alpha 1(V) chain was digested with cyanogen bromide and nine peptides were obtained and purified. Three of the peptides, alpha 1(V)CB1, CB4, and CB7 having molecular weights of 5000, 8000, and 6000, respectively, were further analyzed by amino acid sequence analysis and thermolytic or tryptic digestions. CB1 contained 54 amino acids and identification of its complete sequence was aided by thermolysin digestion and isolation of two peptides, Th1 and Th2. CB4 contained 81 amino acids and sequence analysis of intact CB4 and five tryptic peptides provided us with its complete amino acid sequence. The peptide CB7 contained 67 amino acids and was cleaved into four tryptic peptides that were used for complete sequence analysis. The above results represent the first available covalent structure information on the alpha 1(V) collagen chain. These data enabled us to establish the location of these peptides within the helical structure of other collagen chains. CB4 was homologous to residues 66-145 in the collagen chain while CB1 represented residues 146-200 and CB7 was homologous with residues 201-269. This alignment was facilitated by identification of a helical collagen crossing site consisting of Hyl-Gly-His-Arg located at positions 87-90 in all collagen chains of this size thus far identified. Seventy-one percent homology (excluding Gly residues) was found between amino acids in this region of the alpha 1(XI) and of alpha 1(V) collagen chains while only 21 and 19% identity was calculated for the same region of alpha 2(V) and alpha 1(I) collagen chains, respectively.     

Binding of soluble type I collagen to fibroblasts: effects of thermal activation of ligand, ligand concentration, pinocytosis, and cytoskeletal modifiers

Efficient binding of native, soluble 125I-labeled type I rat collagen to mouse 3T3 fibroblast monolayers requires prior warming of the ligand to 35-37 degrees C for 10-30 min. Decreased binding at high ligand concentrations is ascribed to ligand-ligand interactions rather than to negative cooperativity. Addition of bacterial collagenase to monolayers labeled with the 125I-ligand releases a constant fraction (80%) of the bound ligand over a 2-h interval at 37 degrees C, indicating that little of the ligand becomes inaccessible by pinocytosis. Colchicine (10(-7) M) and vinblastine (5 X 10(-8) M) do not inhibit binding by morphologically intact monolayers. Cytochalasins and concanavalin A show dose-related inhibition of binding by intact monolayers that is due to a reduction in the number of available binding sites rather than to a change in binding site affinity. The collagen binding site on the fibroblast surface is proposed as an organizing center for the assembly of periodic type I collagen fibrils.     

Binding of soluble type I collagen molecules to the fibroblast plasma membrane.

Soluble 125I-labeled type I collagen binds to cultured fibroblasts but not to cultured epithelia. The binding of the ligand to fibroblasts is reversible, saturable and highly specific for sequences contained within the helical portions of the alpha1 and alpha2 chains. The amount of ligand bound is dependent upon cell number and ligand concentration. Binding is decreased but measurable at 4 degrees C. The steady state binding is greater at 26 degrees than at 37 degrees C due to a more rapid dissociation of the ligand-acceptor complex at 37 degrees C. The half-life of the complex is 46 min at 37 degrees C and approximately 2.5 hr at 26 degrees C. Scatchard plots of binding data indicate a single class of high affinity binding sites (KD = 1.2 X 10(-11) M) with each fibroblast binding approximately 500,000 molecules at saturation. Pretreatment of fibroblasts with bacterial collagenase, chondroitinase ABC or testicular hyaluronidase does not affect the binding reaction, whereas pretreatment of the cells with phospholipase C increases the amount of ligand bound. Ligand binding is decreased but not abolished after fibroblasts are treated with trypsin concentrations which remove surface fibronectin. Fibroblast monolayers treated with antiserum against fibronectin bind the radiolabeled ligand normally. In contrast to collagen, addition of excess fibronectin does not accelerate the dissociation of bound ligand from fibroblasts. Possible functions for surface-bound collagen are discussed.     

Altered triple helical structure of type I procollagen in lethal perinatal osteogenesis imperfecta

Cultured dermal fibroblasts from an infant with the lethal perinatal form of osteogenesis imperfecta (type II) synthesize normal and abnormal forms of type I procollagen. The abnormal type I procollagen molecules are excessively modified during their intracellular stay, have a lower than normal melting transition temperature, are secreted at a reduced rate, and form abnormally thin collagen fibrils in the extracellular matrix in vitro. Overmodification of the abnormal type I procollagen molecules was limited to the NH2-terminal three-fourths of the triple helical domain. Two-dimensional mapping of modified and unmodified alpha chains of type I collagen demonstrated neither charge alterations nor large insertions or deletions in the region of alpha 1(I) and alpha 2(I) in which overmodification begins. Both the structure and function of type I procollagen synthesized by cells from the parents of this infant were normal. The simplest interpretation of the results of this study is that the osteogenesis imperfecta phenotype arose from a new dominant mutation in one of the genes encoding the chains of type I procollagen. Given the requirement for glycine in every third position of the triple helical domain, the mutation may represent a single amino acid substitution for a glycine residue. These findings demonstrate further heterogeneity in the biochemical basis of osteogenesis imperfecta type II and suggest that the nature and location of mutations in type I procollagen may determine phenotypic variation.     

Analysis of cyanogen bromide peptides of type I collagen from a patient with lethal osteogenesis imperfecta.

The CNBr peptides of type I collagen from bone of a patient with lethal osteogenesis imperfecta and age-matched controls were isolated by molecular-sieve chromatography and their amino acid compositions were determined. No differences were found between the compositions of the peptides from the patient and those from the controls, except for an increase in the degree of hydroxylation of lysine in all peptides from the patient. Type I collagen CNBr peptides from chick-embryo skin [Barnes, Constable Morton & Kodicek (1971) Biochem. J. 125, 925--928] and guinea-pig scar tissue [Shuttleworth, Forrest & Jackson (1975) Biochim. Biophys. Acta 379, 207--216] also have an increased degree of hydroxylation of lysine with an otherwise normal amino acid composition, and it was believed that this could be an embryonic form of collagen. As a similar collagen was present in the bones of the patient studied, it seems possible that the same 'embryonic' collagen is synthesized during development, in repair process and also in genetic disorders of collagen metabolism.     

Binding of human monomeric type I collagen to platelets

Interaction of platelets with subendothelial collagen is important in primary hemostasis and thrombosis. Although activation of platelets by collagen polymers has been widely investigated, only insufficient data are available concerning the binding of genetically distinct collagen types in their triple helical (monomeric) form to platelets. We report on the binding of 125I-labeled human type I collagen to platelets. The binding assay was performed at 20 degrees C in the presence of arginine in order to prevent polymerization of the collagen monomers. The binding of monomeric 125I-labeled human type I collagen is dose- and time-dependent, saturable and specific, since it is competitively inhibited by unlabeled type I collagen, but not by unlabeled human type V collagen. Scatchard analysis reveals a class of specific high affinity binding sites with a Kd of 2.5 X 10(-8) M. These results suggest that platelets interact with type I collagen through specific binding sites, and that there are various different binding sites on the platelet membrane for the genetically distinct collagen types.     

Covalent structure of collagen: amino acid sequence of cyanogen bromide peptides from the amino-terminal segment of type III collagen of human liver

Human liver type III collagen was prepared by limited pepsin digestion, differential salt precipitation, and carboxymethylcellulose chromatography. Cyanogen bromide digestion of purified type III collagen chains yielded nine distinct peptides. Three peptides, alpha1(III)-CB3, alpha1(III)-CB7, and alpha1(III)-CB6, were isolated by carboxymethylcellulose chromatography and Sephadex G-50 SF gel filtration. Automated Edman degradation together with selective hydroxylamine cleavage and chymotrypsin and trypsin digestion enabled determination of their complete amino acid sequence. Compared with type I collagen, the data show tentative homology of alpha1(III)-CB3 with alpha1(I)-CB1, alpha1(I)-CB2, and alpha1(I)-CB4; alpha1(III)-CB7 with alpha1(I)-CB5; and alpha1(III)-CB6 with the amino-terminal portion of alpha1(I)-CB8. Close interspecies homology was found between the sequences presented here with 90 residues of alpha1(III)-CB3 and 26 of alpha1(III)-CB8 of calf aorta. The present study establishes the amino acid sequence of 229 residues near the amino terminus or nearly one-quarter of the type III collagen chains. The disaccharide, Glc-Gal, was convalently bound to hydroxylysine at a position corresponding to the same location in the alpha1(I) chain.     

Binding of 1-anilinonaphthalene-8-sulfonic acid to type I collagen

The existence of a hydrophobic cluster on the COOH-telopeptides of type I collagen has been observed by studies on the binding of 1-anilinonaphthalene-8-sulfonic acid (ANS) to this protein. Collagen contains one binding site for the fluorescent probe. This hydrophobic cluster remains after pepsin digestion thus indicating that it is formed by the undegraded portions of the COOH-extrahelical ends of the protein. Energy transfer from tyrosine to ANS has been observed. The triple helix of collagen does not bind ANS.     

Collagen-induced arthritis in rats. Examination of the epitope specificities of circulating and cartilage-bound antibodies produced by outbred and inbred rats using cyanogen bromide-derived peptides purified from heterologous and homologous type II collagens.

To determine the number and location of antibody binding epitopes on type II collagen, outbred and inbred rats were immunized with chick, bovine, human, and rat type II collagen (CII, BII, HII, and RII); all sera were assayed for reaction with a panel of CB peptides purified and renatured from the immunizing collagen and from RII. Antibody reaction patterns (profiles) varied among individual outbred rats but were essentially constant over time and changed little after boosting. The strongest antibody reactions were to CB11, CB9-7, and CB12 followed by CB8, CB10, and CB6. Antibody profiles varied depending on the species of collagen used for immunization and the strain of rat immunized. Except for CB10, where antibodies were largely specific for heterologous collagens, antibodies reactive with all other CB peptides cross-reacted strongly with renatured rat CB peptides. Sera from inbred BB rats immunized with BII, CII, or HII reacted best with CB11, unlike antisera to RII that reacted strongly with CB9-7. Inbred LEW, COP, WKY, F344, and BUF rats immunized with BII reacted strongest with CB9-7 and variably with CB11 and CB12. BBxLEW F1 hybrid rats reacted almost equally with CB11 and CB9-7 producing an antibody profile intermediate to those elicited in the parent strains. Finally, antibodies reactive with rat CB11, CB9-7, and CB12 could be eluted from normal rat cartilage incubated in anti-BII serum; antibody eluate profiles generally paralleled the profile produced by the sera applied to cartilage. Taken together, these findings indicate that multiple antibody-reactive epitopes on type II collagen may be instrumental in the initiation of collagen-induced arthritis in rats, particularly shared or cross-reactive epitopes located within CB11, CB9-7, CB12, and CB8.     

Mechanical properties of native and cross-linked type I collagen fibrils

Micromechanical bending experiments using atomic force microscopy were performed to study the mechanical properties of native and carbodiimide-cross-linked single collagen fibrils. Fibrils obtained from a suspension of insoluble collagen type I isolated from bovine Achilles tendon were deposited on a glass substrate containing microchannels. Force-displacement curves recorded at multiple positions along the collagen fibril were used to assess the bending modulus. By fitting the slope of the force-displacement curves recorded at ambient conditions to a model describing the bending of a rod, bending moduli ranging from 1.0 GPa to 3.9 GPa were determined. From a model for anisotropic materials, the shear modulus of the fibril is calculated to be 33 ± 2 MPa at ambient conditions. When fibrils are immersed in phosphate-buffered saline, their bending and shear modulus decrease to 0.07-0.17 GPa and 2.9 ± 0.3 MPa, respectively. The two orders of magnitude lower shear modulus compared with the Young's modulus confirms the mechanical anisotropy of the collagen single fibrils. Cross-linking the collagen fibrils with a water-soluble carbodiimide did not significantly affect the bending modulus. The shear modulus of these fibrils, however, changed to 74 ± 7 MPa at ambient conditions and to 3.4 ± 0.2 MPa in phosphate-buffered saline.     

The in situ conformation and axial location of the intermolecular cross-linked non-helical telopeptides of type I collagen

Background: Type I collagen contains specific lysine and hydroxylysine residues that are critical in the formation of intermolecular cross-links crucial for the normal configuration and stability of the 67 nm axial repeat of collagen fibrils in the extracellular matrix. The major cross-linkage sites are believed to occur between the non-helical terminal regions (telopeptides) and helical segments of adjacent collagen molecules. In this X-ray fibre diffraction study the tissue has been maintained in the hydrated fibrillar state, whilst detailed structural information was obtained using highly collimated synchrotron radiation. Results: The axial component of the X-ray diffraction patterns extends more than twice as far in reciprocal space than that of any already published. The structure-factor phases were calculated using the multiple isomorphous addition method, avoiding model-based approaches, and produced an electron-density profile of the molecular arrangement projected on to the fibre axis to 0.54 nm resolution. This corresponds to the phasing of 124 orders of the meridional diffraction pattern. Conclusions: The axially projected electron-density profile and the electron-density difference maps showed that both the N- and C-terminal telopeptides are contracted structures. This profile puts narrow constraints on the possible conformations of the C-terminal telopeptide; the best fit to the electron-density profile is when the alpha1 chains adopt a folded conformation with a sharp hairpin turn around residues 13 and 14 of the 25-residue telopeptide. Our results reveal for the first time the location, parallel to the fibril axis, of the intermolecular cross-links in normal hydrated tissue. These cross-links are essential for the biological function of the tissue.     

Activity of matrix metalloproteinase-9 against native collagen types I and III

Interstitial collagen types I, II and III are highly resistant to proteolytic attack, due to their triple helical structure, but can be cleaved by matrix metalloproteinase (MMP) collagenases at a specific site, approximately three-quarters of the length from the N-terminus of each chain. MMP-2 and -9 are closely related at the structural level, but MMP-2, and not MMP-9, has been previously described as a collagenase. This report investigates the ability of purified recombinant human MMP-9 produced in insect cells to degrade native collagen types I and III. Purified MMP-9 was able to cleave the soluble, monomeric forms of native collagen types I and III at 37 degrees C and 25 degrees C, respectively. Activity against collagens I and III was abolished by metalloproteinase inhibitors and was not present in the concentrated crude medium of mock-transfected cells, demonstrating that it was MMP-9-derived. Mutated, collagenase-resistant type I collagen was not digested by MMP-9, indicating that the three-quarters/one-quarter locus was the site of initial attack. Digestion of type III collagen generated a three-quarter fragment, as shown by comparison with MMP-1-mediated cleavage. These data demonstrate that MMP-9, like MMP-2, is able to cleave collagens I and III in their native form and in a manner that is characteristic of the unique collagenolytic activity of MMP collagenases.     

HSP47 binds cooperatively to triple helical type I collagen but has little effect on the thermal stability or rate of refolding

HSP47, a collagen-specific molecular chaperone, interacts with unfolded and folded procollagens. Binding of chicken HSP47 to native bovine type I collagen was studied by fluorescence quenching and cooperative binding with a collagen concentration at half saturation (K(half)) of 1.4 x 10(-7) m, and a Hill coefficient of 4.3 was observed. Similar results are observed for the binding of mouse HSP47 recombinantly expressed in Escherichia coli. Chicken HSP47 binds equally well to native type II and type III procollagen without the carboxyl-terminal propeptide (pN type III collagen), but binding to triple helical collagen-like peptides is much weaker. Weak binding occurred to both hydroxylated and nonhydroxylated collagen-like peptides, and a significant chain length dependence was observed. Binding of HSP47 to native type I collagen had no effect on the thermal stability of the triple helix. Refolding of type I collagen in the presence of HSP47 showed minor changes, but these are probably not biologically significant. Binding of HSP47 to bovine pN type III collagen has only minor effects on the thermal stability of the triple helix and does not influence the refolding kinetics of the triple helix.     

Active negative control of collagen fibrillogenesis in vivo. Intracellular cleavage of the type I procollagen propeptides in tendon fibroblasts without intracellular fibrils

It is established fact that type I collagen spontaneously self-assembles in vitro in the absence of cells or other macromolecules. Whether or not this is the situation in vivo was unknown. Recent evidence shows that intracellular cleavage of procollagen (the soluble precursor of collagen) to collagen can occur in embryonic tendon cells in vivo, and when this occurs, intracellular collagen fibrils are observed. A cause-and-effect relationship between intracellular collagen and intracellular fibrils was not established. Here we show that intracellular cleavage of procollagen to collagen occurs in postnatal murine tendon cells in situ. Pulse-chase analyses showed cleavage of procollagen to collagen via its two propeptide-retained intermediates. Furthermore, immunoelectron microscopy, using an antibody that recognizes the triple helical domain of collagen, shows collagen molecules in large-diameter transport compartments close to the plasma membrane. However, neither intracellular fibrils nor fibripositors (collagen fibril-containing plasma membrane protrusions) were observed. The results show that intracellular collagen occurs in murine tendon in the absence of intracellular fibrillogenesis and fibripositor formation. Furthermore, the results show that murine postnatal tendon cells have a high capacity to prevent intracellular collagen fibrillogenesis.