Localization of precursor proteins and mRNA of type I and III collagens in usual interstitial pneumonia and sarcoidosis

Summary The aim of this study was to assess and compare the accumulation and distribution of newly synthesized type I and III collagens in usual interstitial pneumonia (UIP) and pulmonary sarcoidosis. Lung biopsies from 10 patients with UIP and 13 patients with sarcoidosis were investigated by immunohistochemical technique and mRNA in situ hybridization. The antibodies for the aminoterminal propeptide of type I procollagen and the aminoterminal propeptide of type III procollagen (PINP and PIIINP, respectively) were used. When compared to healthy lung, levels of type I pN- and type III pN-collagens were increased in both of these disorders. Type I procollagen was mostly present as intracellular spots in newly formed fibrosis in UIP while type III pN-collagen was expressed extracellularly underneath metaplastic alveolar epithelium. Type I procollagen was present intracellularly within and around the granulomas of sarcoidosis, whereas type III pN-collagen was expressed extracellularly, mainly around the granulomas. mRNAs of both collagens colocalized with the precursor proteins. We conclude that the expression of precursor proteins and mRNA of type I and type III collagens is increased in UIP and sarcoidosis, reflecting mainly active synthesis of these collagens in different areas of the lung.     

Immuno-electron-microscopic localization of types III pN-collagen and IV collagen,laminin and tenascin in developing and adult human spleen

The distribution of the extracellular matrix proteins types III pN-collagen and IV collagen, laminin and tenascin was investigated in fetal, infant, and adult human spleens by using immuno-electron microscopy. The presence of type III pN-collagen was assessed by using an antibody against the aminoterminal propeptide of type III procollagen. All the proteins other than type III pN-collagen were found in reticular fibers throughout development. In the white pulp of the fetus aged 16 gestational weeks, only an occasional type III pN-collagen-containing fibril was present, although type III pN-collagen was abundant in the reticular fibers of the red pulp. Conversely, in adults, most of the reticular fibers of the white pulp, but not of the red pulp, were immunoreactive for type III pN-collagen. Ring fibers, the basement membranes of venous sinuses, were well developed in both infant and adult spleens. The first signs of their formation could be seen as a discontinuous basement membrane, which was immunoreactive for type IV collagen, laminin, and tenascin in the fetus aged 20 gestational weeks. Intracytoplasmic immunoreactivity for all the proteins studied was visible in the mesenchymal cells of the fetus aged 16 gestational weeks and in the reticular cells of the older fetuses, which also showed labeling for type IV collagen and laminin in the endothelial cells. The results suggest that proteins of the extracellular matrix are produced by these stationary cells.     

Pleomorphism in type I collagen fibrils produced by persistence of the procollagen N-propeptide

The assembly of type I collagen and type I pN-collagen was studied in vitro using a system for generating these molecules enzymatically from their immediate biosynthetic precursors. Collagen generated by C-proteinase digestion of pC-collagen formed D-periodically banded fibrils that were essentially cylindrical (i.e. circular in cross-section). In contrast, pN-collagen generated by C-proteinase digestion of procollagen formed thin, sheet-like structures that were axially D-periodic in longitudinal section, of varying lateral widths (up to several microns) and uniform in thickness (approximately 8 nm). Mixtures of collagen and pN-collagen assembled to form a variety of pleomorphic fibrils. With increasing pN-collagen content, fibril cross-sections were progressively distorted from circular to lobulated to thin and branched structures. Some of these structures were similar to fibrils observed in certain heritable disorders of connective tissue where N-terminal procollagen processing is defective. The observations are considered in terms of the hypothesis that the N-propeptides are preferentially located on the surface of a growing assembly. The implications for normal diameter control of collagen fibrils in vivo are discussed.     

Purification of human procollagen type III N-proteinase from placenta and preparation of antiserum.

Procollagen type III N-proteinase, of Mr about 70,000, was detected in human placental tissue and purified from this source more than 5800-fold. It was found to be a glycoprotein, which was bound to both concanavalin A-Ultrogel and heparin-Sepharose affinity columns. Binding to a type III pN-collagen-Sepharose affinity column was used as the final step in purification. The purified enzyme accepted only native type III procollagen or [14C]carboxymethylated type III pN-collagen as its substrate; type I, type II and type IV procollagen and heat-denatured type III pN-collagen were not cleaved by the enzyme. Antibodies against this purified enzyme protein raised in rabbits demonstrated a high inhibitory effect on the enzyme activity. Immunoblotting of the denatured protein and immunoelectrophoresis of the native enzyme showed only one major antigenic component, again with an Mr of about 70,000. The antibodies cross-reacted with the enzyme preparation from foetal-calf aorta smooth-muscle cells.     

Interaction between proteoglycan subunit and type II collagen from bovine nasal cartilage, and the preferential binding of proteoglycan subunit to type I collagen.

We studied the interaction of proteoglycan subunit with both types I and II collagen. All three molecular species were isolated from the ox. Type II collagen, prepared from papain-digested bovine nasal cartilage, was characterized by gel electrophoresis, amino acid analysis and CM-cellulose chromatography. By comparison of type I collagen, prepared from papain-digested calf skin, with native calf skin acid-soluble tropocollagen, we concluded that the papain treatment left the collagen molecules intact. Interactions were carried out at 4 degrees C in 0.06 M-sodium acetate, pH 4.8, and the results were studied by two slightly different methods involving CM-cellulose chromatography and polyacrylamide-gel electrophoresis. It was demonstrated that proteoglycan subunit, from bovine nasal cartilage, bound to cartilage collagen. Competitive-interaction experiments showed that, in the presence of equal amounts of calf skin acid-soluble tropocollagen (type I) and bovine nasal cartilage collagen (type II), proteoglycan subunit bound preferentially to the type I collagen. We suggest from these results that, although not measured under physiological conditions, it is unlikely that the binding in vivo between type II collagen and proteoglycan is appreciably stronger than that between type I collagen and proteoglycan.     

Assessment of procollagen processing defects by fibroblasts cultured in the presence of dextran sulphate.

The culture of skin fibroblasts in the presence of 0.01% (w/v) dextran sulphate results in complete proteolytic processing of procollagen to collagen. Processing occurs predominantly via a pN-collagen intermediate, suggesting that C-propeptide cleavage occurs early during the processing pathway. The processed collagen is associated with the cell-layer fraction. This method of inducing procollagen processing was evaluated for use in detecting procollagen processing abnormalities in heritable connective-tissue diseases. Abnormal type I procollagen processing was clearly demonstrated in two cases with known defects of pN-propeptide cleavage. In one, the cleavage deficiency was due to diminished N-proteinase activity (dermatosparaxis) and in the other case (Ehler's-Danlos syndrome type VIIA) the cleavage site was deleted. In a case of osteogenesis imperfecta (type II) the slow electrophoretic migration of type I collagen alpha-chains due to over-modification of lysine was readily demonstrated. Inefficient procollagen processing was also evident in this patient, as had been previously reported [de Wet, Pihlanjaniemi, Myers, Kelly & Prockop (1983) J. Biol. Chem. 258, 7721-7728]. Thus this method of culture in the presence of dextran sulphate provides a simple and rapid procedure for the detection of procollagen processing defects and electrophoretic abnormalities.     

Procollagen intermediates during tendon fibrillogenesis

The purpose of this study was to correlate ultrastructural features of tendon collagen fibrils at various stages of development with the presence of procollagen, pN-collagen, pC-collagen, and the free amino propeptides and carboxyl propeptide of type I procollagen. Tendons from 10-, 14-, and 18-day chicken embryos reveal small, well-defined intercellular compartments containing collagen fibrils with diameters showing a unimodal distribution. At 21 days (hatching) and 9 days (post hatching) and at 5 weeks (post hatching), the compartments are larger, less well-defined, and there is multimodal distribution of tendon fibril diameters. Procollagen and the intermediates pN-collagen and pC-collagen are present in tendons up to 18 days. Thereafter there is a marked reduction in procollagen, whereas the intermediates persist throughout all stages of development. Similarly, free amino propeptides and carboxyl propeptides of type I procollagen were found at all stages. The amino propeptide of type III procollagen was restricted to the peritendineum until 7 weeks post hatching. At that time, a network of fibrils containing the amino propeptide of type III procollagen was seen delineating well-circumscribed compartments of collagen fibrils throughout the entire tendon. This study supports the notion that pN- and pC-collagen have an extracellular role and participate in collagen fibrillogenesis.     

Completion of the amino acid sequence of the alpha 1 chain from type I calf skin collagen. Amino acid sequence of alpha 1(I)B8.

The complete amino acid sequence of the 279-residue CNBr peptide CB8 from the alpha 1 chain of type I calf skin collagen is presented. It was determined by sequencing overlapping fragments of CB8 produced by Staphylococcus aureus V8 proteinase, trypsin, Endoproteinase Arg-C and hydroxylamine. Tryptic cleavages were also made specific for lysine by blocking arginine residues with cyclohexane-1,2-dione. This completes the amino acid sequence analysis of the 1054-residues-long alpha (I) chain of calf skin collagen.     

Selective decrease of type I collagen synthesis in Fraser mice skin

Quantification and biosynthesis of type I and type III collagens were determined in skin of control and Fraser mice (Cat^Fraser mutation), which exhibit a genetically determined cataract. Skin organ cultures were labelled with [³H]proline. Pepsin-solubilized collagens were studied using three different approaches: (a) differential salt precipitation at neutral pH, followed by SDS-polyacrylamide gel electrophoresis; (b) differential salt precipitation at acid pH followed by SDS-polyacrylamide gel electrophoresis. (c) CNBr peptide analysis. These methods gave consistent and reproducible results, indicating a selective decrease of type I collagen in Fraser mouse skin as compared to control mouse skin. Metabolic labelling of skin organ cultures showed a decreased specific radioactivity of hydroxy[³H]proline in type I collagen of Fraser mouse skin. The concordant results of these experiments suggest a genetically determined alteration of interstitial collagen metabolism in the Fraser mutation apparently specifically concerning the expression of type I collagen gene(s).     

Morphology of sheet-like assemblies of pN-collagen, pC-collagen and procollagen studied by scanning transmission electron microscopy mass measurements

At high concentrations, type I pN-collagen, pC-collagen and procollagen (the first 2 generated from procollagen by enzymic cleavage of C-propeptides and N-propeptides, respectively) can all be made to assemble in vitro into thin D-periodic sheets or tapes. Scanning transmission electron microscopy mass measurements show that the pN-collagen sheets and procollagen tapes have a mass per unit area corresponding to that of approximately 6.8 monolayers of close-packed molecules. pN-collagen sheets are extensive and remarkably uniform in mass thickness (fractional S.D. 0.035); procollagen tapes are neither as extensive nor as uniform in thickness. The mean thickness of pC-collagen tapes is less and the variability is greater. In pN-collagen sheets, the overlap: gap mass contrast in a D-period is increased from 5:4 (the ratio in a native collagen fibril) to 6:4, showing that the N-propeptides do not project into the gap but are folded back over the overlap zone. Assuming all N-propeptides to be constrained to the two surfaces of a sheet, their surface density can be found from the mass thickness of the sheet. In a lateral direction (i.e. normal to the axial direction where the spacing is D-periodic), the N-propeptide domains are calculated to be spaced, centre to centre, by 2.23 (+/- 0.1) nm on both surfaces. This value (approx. 1.5 x the triple-helix diameter) implies close-packing laterally with adjacent domains in contact. Sheet formation and the "surface-seeking" behaviour of propeptides can be understood in terms of the dual character of the molecules, evident from solubility data, with propeptides possessing interaction properties very different from those displayed by the rest of the molecule. The form and stability of sheets (and of first-formed fibrils assembling in vivo) could, it is suggested, depend on the partially fluid-like nature of lateral contacts between collagen molecules.     

Interpretation of the electron microscopical appearance of collagen fibrils from corneal stroma

The appearance in the electron microscope of mechanically-dispersed corneal collagen has been observed after positive staining with phosphotungstic acid and/or uranyl acetate and after negative staining with phosphotungstate ions. The distributions of positive stains (both cationic and anionic) were similar to those observed in other type I collagens (e.g. skin, tendon). A high correlation was found between charge density in the fibril and the distribution of charged amino acids predicted from the sequence of calf skin collagen. This correlation could be improved by including type III sequence data, suggesting the presence of 20% type III collagen within each fibril. Negative staining showed the usual collagen D-periodicity but without a clear gap/overlap structure. Detailed analysis revealed at least six sites where stain penetration was inhibited. Specific staining of glycosides using N,N,N′,N′-tetramethylethylenediamine(TEMED)-osmate suggested that these sites identify the covalent attachment of disaccharides to the collagen. Using synchroton X-ray diffraction from TEMED-osmate stained corneas we have determined the locations of the stain ions (and hence the glycosides) in the moist tissue. The results demonstrate that even though the detailed charge distribution and axial molecular packing in corneal collagen are similar to other type I collalgens, carbohydrate material, probably disaccharide, is attached at fairly regular intervals. This does not occur in other type I collagens. In particular, the presence of glycoside in the overlap region may play a role in producing the narrow uniform fibrils which are essential for the transparency of the cornea.     

Fourier transform IR spectroscopy of collagen and gelatin solutions: deconvolution of the amide I band for conformational studies

The ir spectra of lathyritic rat skin collagen and calf skin gelatin solutions at a variety of temperatures were obtained using Fourier transform ir spectroscopy and a 9-reflection, 2-pass ZnSe prism sample cell. The spectra were then deconvolved (based on Kauppinnen's method) and the behavior of the amide I band at ～ 1650 cm^?1 observed in detail. Throughout the temperature range studied (4–50°C), three component absorption peaks within the amide I band (at 1633, 1643, and 1660 cm^?1) are common to the spectra irrespective of the degree of triple helix content of the sample. Changes in the relative intensities of these component peaks are, however, conformationally dependent. During denaturation of the triple helix, the dominant 1660-cm^?1 component in the native collagen spectrum diminishes and the 1633-cm^?1 peak becomes relatively intensified. The inherently strong basicity of the carbonyl group of the proline residues together with the frequent occurrence of this imino acid in the X position of the Gly-X-Y triplet of collagen largely accounts for the ?30-cm^?1 shift of the amide I band during denaturation. Temperature and conformationally dependent changes in the fine structure of the amide I band from dilute solutions of collagen can be monitored in a reproducible and quantitative fashion.     

Immune response to calf collagen type I in mice: A combined control ofIr-1A and nonH-2 linked genes

The genetically controlled immune response to calf skin collagen type I in mice could be demonstrated to be governed by at least two genes. One is linked to theH-2 complex and located within theIA subregion. High-responder alleles areH-2 ^b ,H-2 ^f , andH-2 ^s . The other gene(s) is not linked to theH-2 complex and high-responder allele(s) are found in the genome of B10 mice but not in the genome of DBA mice. There are strong indications that theIr-1A gene controls the response at the T-cell level, whereas it is assumed that the background gene(s) control the immune response at a different level.     

Mutations near amino end of alpha1(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.     

A fine structure map of spontaneous and induced mutations in the lambda repressor gene, including insertions of IS elements

Summary Mutations at over 70 sites in the cI gene have been mapped by 4-factor crosses and assigned precise or approximate positions in the DNA sequence. 16 of 25 spontaneous mutations were insertions of IS1, IS3 or IS5 into AT-rich regions of cI. The 5-methylcytosine in the sequence Cm⁵CAGG is a hot spot for spontaneous cI amber mutations. Recombination frequencies between mutations were proportional to distance with the exception of amber mutations at 4 sites, including the host spot for spontaneous mutations. Mutations with a given phenotype are clustered on the genetic map. No missense mutations affecting repressor activity were found in the central one-third of cI, but 5 of 6 ind ^- mutations were located in this region. The aminoterminal third of the gene contains the sites of most trans-dominant cI^- mutations, and of all ts mutations that result in repressors that are reversibly inactivated at high temperatures.     

Negative staining studied by TEM and STEM mass measurements: Preliminary observations on collagen sheets negatively stained with uranyl acetate

Quantitative mass measurements by dark-field scanning transmission EM and conventional bright-field transmission EM have been used to determine the increase in mass brought about by negative staining. pN-collagen (which forms sheets of uniform thickness and known mass per unit area) was used as a test specimen; the negative stain was uranyl acetate (1%, pH 4.4). The mass increase corresponded to the addition of roughly 8 uranyl acetate molecules per nm² for lightly negatively stained specimens; for heavily stained specimens, it was 30 molecules or more. The appearance of the image was related to the mass increase. This preliminary study shows that mass measurements can provide a basis for the quantitative interpretation of images from negatively stained specimens.     

cAMP-dependent protein kinases, their subunits, and cAMP-binding protein from four sources: a comparison of physical characteristics determined by polyacrylamide gel electrophoresis

The physical characteristics of cAMP-dependent protein kinases and their, regulatory subunits from calf uterus, human uterus, human mammary tumor, and rat pituitary and of cAMP-binding protein from calf uterus were determined by quantitative polyacrylamide gel electrophoresis in buffers containing the detergent, Triton X-100. In the four tissues, protein kinases of either type A¹, with molecular weight (M_r) = 200,000, or type B, of M_r = 80,000, or both, previously described were found. Trivial charge isomerism, or size isomerism, exists within each of the two classes, Protein Kinase A and B. The protein kinase recombined from the regulatory and catalytic subunits is not significantly different from the crude or isolated protein kinase. Protein Kinases A and B exist each in either one of the isozyme forms I and II but these are not reflected in polyacrylamide gel electrophoresis at pH 10.2. Protein Kinase B appears to be a product of the partial proteolysis of Protein Kinase A. The regulatory subunits of Protein Kinases A from the four tissues are distinct from those of Protein Kinases B. No physical distinction exists between regulatory subunits derived from isozyme forms I and II. cAMP-Binding Proteins A and B are physically indistinguishable, by polyacrylamide gel electrophoresis at pH 10.2, from the regulatory subunits of Protein Kinases A and B, respectively.     

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.     

Molecular mechanism of alpha 1(I)-osteogenesis imperfecta/Ehlers-Danlos syndrome: unfolding of an N-anchor domain at the N-terminal end of the type I collagen triple helix

We demonstrate that 85 N-terminal amino acids of the alpha1(I) chain participate in a highly stable folding domain, acting as the stabilizing anchor for the amino end of the type I collagen triple helix. This anchor region is bordered by a microunfolding region, 15 amino acids in each chain, which include no proline or hydroxyproline residues and contain a chymotrypsin cleavage site. Glycine substitutions and amino acid deletions within the N-anchor domain induce its reversible unfolding above 34 degrees C. The overall triple helix denaturation temperature is reduced by 5-6 degrees C, similar to complete N-anchor removal. N-propeptide partially restores the stability of mutant procollagen but not sufficiently to prevent N-anchor unfolding and a conformational change at the N-propeptide cleavage site. The ensuing failure of N-proteinase to cleave at the misfolded site leads to incorporation of pN-collagen into fibrils. Similar, but weaker, effects are caused by G88E substitution in the adjacent triplet, which appears to alter N-anchor structure as well. As in Ehlers-Danlos syndrome (EDS) VIIA/B, fibrils containing pN-collagen are thinner and weaker causing EDS-like laxity of large and small joints and paraspinal ligaments. However, distinct structural consequences of N-anchor destabilization result in a distinct alpha1(I)-osteogenesis imperfecta (OI)/EDS phenotype.     

Raman scattering of collagen, gelatin, and elastin.

The Raman spectra of collagen, gelatin, and elastin are presented. The Raman lines in the latter two spectra are assigned by deuterating the amide N-H groups in gelatin and by studying the superposition spectra of the constituent amino acids. Two lines appear at 1271 and 1248 cm^?1 in the spectra of collagen and gelatin that can be assigned to the amide III mode. Possibly, the appearance of two amide III lines is related to the biphasic nature of the tropocollagen molecule, i.e., proline-rich (nonpolar) and proline-poor (polar) regions distributed along the chain. The melting, or collagen-to-gelatin transition, in water-soluble calf skin collagen is studied and the 1248-cm^?1 amide III line is assigned to the 3₁ helical regions of the tropocollagen molecule. Elastin is thought to be mostly random and the Raman spectrum confirms this assertion. Strong amide I and III lines appear at 1668 and 1254 cm^?1, respectively, and only weak scattering is observed at 938 cm^?1. These features have been shown to be characteristic of the disordered conformation in proteins.