The roles of types XII and XIV collagen in fibrillogenesis and matrix assembly in the developing cornea

Corneal transparency depends on the architecture of the stromal extracellular matrix, including fibril diameter, packing, and lamellar organization. The roles of collagen types XII and XIV in regulation of corneal fibrillogenesis and development were examined. The temporal and spatial expression patterns were analyzed using semi-quantitative RT-PCR, in situ hybridization, Western analysis, and immunohistochemistry. Expression of types XII and XIV collagens in cornea development demonstrated that type XII collagen mRNA levels are constant throughout development (10D-adult) while type XIV mRNA is highest in early embryonic stages (10D-14D), decreasing significantly by hatching. The spatial expression patterns of types XII and XIV collagens demonstrated a homogeneous signal in the stroma for type XIV collagen, while type XII collagen shows segregation to the sub-epithelial and sub-endothelial stroma during embryonic stages. The type XII collagen in the anterior stroma was an epithelial product during development while fibroblasts contributed in the adult. Type XIV collagen expression was highest early in development and was absent by hatching. Both types XII and type XIV collagen have different isoforms generated by alternative splicing that may alter specific interactions important in fibrillogenesis, fibril-fibril interactions, and higher order matrix assembly. Analysis of these splice variants demonstrated that the long XII mRNA levels were constant throughout development, while the short XII NC3 mRNA levels peaked early (12D) followed by a decrease. Both type XIV collagen NC1 splice variants are highest during early stages (12D-14D) decreasing by 17D of development. These data suggest type XII collagen may have a role in development of stromal architecture and maintenance of fibril organization, while type XIV collagen may have a role in regulation of fibrillogenesis.     

Type XIV collagen, a new homotrimeric molecule extracted from fetal bovine skin and tendon, with a triple helical disulfide-bonded domain homologous to type IX and type XII collagens

Previously undescribed disulfide-bonded collagenous pepsin-derived fragments have been isolated from fetal calf tendon and skin. One fragment, 10.5 kDa after reduction, was shown to be similar but distinct to the COL1 domain of the recently characterized type XII collagen (64% primary structure identity). The similarity includes important features such as size, location of the cysteine residues, and nature and position of an imperfection of the triple helix. From fetal calf skin, two approximately 34-kDa disulfide-bonded trimeric fragments were isolated in the unreduced form. Amino acid sequencing showed that one fragment contained solely the COL1 domain of type XII collagen while the other one only contained the COL1 domain of the new chain. Like type XII collagen, the new chain is therefore part of a homotrimeric molecule and should thus be considered as a distinct collagen type. We propose to call the molecule from which this fragment is derived, type XIV collagen, with a chain composition (alpha 1 (XIV]3. The presence of a domain similar to the COL1 domain of collagens types IX and XII suggests that type XIV collagen belongs to the group of fibril-associated collagens with interrupted triple helices (FACIT). Two other fragments, 13.5 and 17 kDa after reduction, were also purified. They were shown to contain the same triple helical domain with different pepsin cleavage sites at the amino terminus. Several tryptic peptides were sequenced, and the derived sequences could be aligned with the COL2 domain of type XII collagen or with flanking sequences in the NC2 and NC3 domains (61% sequence identity). These fragments are very likely to be also derived from type XIV collagen.     

Characterization of collagen types XII and XIV from fetal bovine cartilage.

The structurally related type XII-like collagen molecules TL-A and TL-B were recently identified in fetal bovine epiphyseal cartilage and subsequently shown to be collagen types XII and XIV, respectively. By indirect immunofluorescent staining of cartilage using monoclonal antibodies to the NC3 domains of each molecule, it was shown that type XII collagen was present predominantly around cartilage canals, the articular surface, subperichondrial margins, and the perichondrium, was less so in the remaining cartilage matrix, and was absent from the growth plate region. In the permanent cartilage of trachea, type XII stained somewhat more intensely in the margins beneath the loose connective tissue. Type XIV collagen localized more uniformly throughout the articular cartilage and was also absent from the growth plate region, whereas in tracheal cartilage, its distribution was similar to type XII. We have characterized the structure of these cartilage molecules and compared them with those from fetal bovine skin. Extraction of cartilage with 1 M NaCl and differential NaCl precipitation yields a fraction enriched for these two collagens. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting with monoclonal antibodies to the large amino-terminal non-triple-helical domain, NC3, revealed the presence in cartilage of two forms of type XII collagen: type XIIB, the molecule previously identified in chick and bovine tissues, and type XIIA, a much larger form equivalent to the molecule recently identified in WISH-transformed epithelial cell culture medium (Lunstrum, G. P., McDonough, A. M., Marinkovich, M. P., Keene, D. R., Morris, N. P., and Burgeson, R. E. (1992) J. Biol. Chem. 267, 20087-20092). Digestion with bacterial collagenase shows that the increased mass is present in the NC3A domain. Additional purification by velocity sedimentation and observation of rotary-shadowed images demonstrates molecules with extended non-triple-helical arms approximately 80 nm in length analogous to the WISH cell molecules. Electrophoretic mobilities of bands corresponding to type XIIA, but not type XIIB, are sensitive to chondroitinase ABC, indicating that type XIIA is a chondroitin sulfate proteoglycan and that modification occurs predominantly within the NC3A domain distal to NC3B. Neither type XIIB from skin nor type XIIA from WISH cells are chondroitinase-sensitive. By similar analysis, a portion of the type XIV collagen chains in cartilage was also sensitive to chondroitinase digestion. Chondroitin sulfate is apparently not located on its NC3 domain. As in skin, collagen types XII and XIV have subtly different distributions within cartilage and type XII may have a tissue-specific structure.     

Age-related changes and location of type I, III, IV, V and VI collagens during development of four foetal skeletal muscles of double-muscled and normal bovine animals.

The aim of this work was to study the variability in the quantities of hydroxyproline, of type I and III collagens and in the location of types, I, III, IV, V, VI in four muscles of normal and double-muscled (DM) cattle. Samples were collected from foetuses at different ages post-conception. Both in the two genetic types and in muscles, from 110 days, types I, III, V, VI were located in perymisium and types I, IV, V, VI in endomysium. The amounts of hydroxyproline and of type I collagen increased from 150 to 180 or 230 days then decreased up to 260 days, with a trend to lower quantities in muscles of DM animals. Depending on the muscle and of the genetic type, amounts of type III, or changed as those of type I, or remained stable. Whatever the genetic type, at the end of gestation, proportions of type I and III in the total collagen are not identical in the four muscles, differences between muscles being particularly marked for type III, CT and MA muscles being the richer in this type. In addition, these two muscles contained less type III in DM animals than in normal ones.     

Active remodeling in idiopathic interstitial pneumonias: evaluation of collagen types XII and XIV.

Fibril-associated collagens with interrupted triple helices (FACITs) XII and XIV act as fibril organizers and assist in the maintenance of uniform fibril size. We investigated the spatial expression patterns of collagens XII and XIV in cryptogenic organizing pneumonia (COP)/organizing pneumonia (OP) and in idiopathic pulmonary fibrosis (IPF)/usual interstitial pneumonia (UIP) and compared them to normal human lung. Study subjects included 10 patients with COP/OP, 10 patients with IPF/UIP, and 8 control subjects. Immunostaining for collagens XII and XIV was carried out in paraffin-embedded human lung tissue sections. Picrosirius red histochemical staining for collagen I expression and electron microcopy to evaluate fibril diameter were also performed. In normal lung, collagens XII and XIV were expressed in perivascular and subpleural connective tissue. In COP/OP, both collagens showed intense staining in perivascular connective tissue, thickened alveolar septae, and subpleural areas. In IPF/UIP, XII and XIV were expressed in perivascular connective tissue, in areas of established fibrosis, and in areas of subpleural thickening. Only collagen XII was expressed in granulation tissue plugs in COP/OP and in fibroblastic foci in IPF/UIP. Collagen type I was overexpressed in fibrotic areas. Electron micrographs revealed obvious fibril diameter alteration and fusion in the same areas. FACITs XII and XIV are expressed in normal and fibrotic lung. Unlike collagen XIV, collagen XII was expressed in granulation tissue plugs in COP/OP and in fibroblast foci in IPF/UIP. This may suggest a possible distinct role for both collagens in the modulation of the extracellular matrix during the onset of fibrotic process.     

Purification and characterization of native type XIV collagen.

A new molecule, type XIV collagen, with domains homologous to type IX and XII collagens has been recently discovered in pepsin extracts of fetal bovine tissues (Dublet, B., and van der Rest, M. (1991) J. Biol. Chem. 266, 6853-6858). In the present study, we describe the purification and the characterization of the intact native form of this newly discovered collagen. By using only two chromatographic steps we were able to obtain pure type XIV collagen. Furthermore, minor modifications of the protocol allowed us to perform the simultaneous large scale purification of type XII and type XIV collagens from the same tissue. Intact type XIV collagen migrates on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) as two bands of 220 and 290 kDa (reducing conditions). After collagenase treatment, a single band of 190 kDa is observed, which represents the large non-collagenous domain of the molecule (NC3). Rotary shadowing electron micrographs of intact type XIV collagen show a cross-shaped structure formed by a thin tail attached through a central globule to three identical "fingers." These properties are similar to those previously described for intact chicken type XII collagen (Dublet, B., Oh, S., Sugrue, S. P., Gordon, M. K., Gerecke, D. R., Olsen, B. R., and van der Rest, M. (1989) J. Biol. Chem. 264, 13150-13156), but the two molecules are different gene products and have charge and glycosylation differences. Finally, we show that the three chains of purified type XIV collagen have an apparent molecular mass of approximately 220 kDa and are not cross-linked to each other by bonds other than disulfide bridges. The same observation was made for type XII collagen. In both cases, the 290-kDa migrating band in SDS-PAGE is due to incomplete denaturation in electrophoresis sample buffer in the absence of urea.     

Collagen heterogeneity and quantification in developing bovine nuchal ligament.

The collagenous components were investigated in peptic digests of developing bovine nuchal ligament. Types I and III collagen were the major species isolated, but the presence of types IV, V and VI was also shown. Changes in the pepsin-susceptibility of nuchal ligament during foetal development were observed. CNBr-cleavage peptide analysis indicated that type I collagen became cross-linked rapidly, as evidenced by the lack of alpha 1(I)CB6. At present it is not clear if this decrease in pepsin-susceptibility is due to cross-linking of collagen, to increased deposition of elastin, or to both. Quantification of collagen types I and III was shown to depend on the method used. When pepsin-solubilized material was examined an apparent increase in type III collagen with respect to foetal age was observed, whereas when CNBr digests of intact ligament were examined a relatively constant amount of type III collagen (approx. 24%) was found. The constant amount of type III collagen observed during foetal development changed at birth and increased in mature nuchal ligament to represent approx. 45% of the total collagen.     

Relationship between extracellular matrix, contractile apparatus, muscle mass and strength in case of glucocorticoid myopathy

The purpose of this study was to evaluate the effect of dexamethasone on the contractile apparatus and extracellular matrix (ECM) components of slow-twitch (ST) soleus (Sol) and fast-twitch (FT) extensor digitorum longus (EDL) muscle. The specific aim was to assess the development of glucocorticoid-induced myopathy on the level of contractile apparatus and ECM, paying attention to the expression of fibrillar forming collagen types I and III and nonfibrillar type IV collagen expression in extracellular compartment of muscle. Degradation of myofibrillar proteins increased from 2.62+/-0.28 to 5.58+/-0.49% per day during glucocorticoids excess. Both fibril- and network-forming collagen-specific mRNA levels decreased at the same time in both types of skeletal muscle. Specific mRNA level for MMP-2 did not change significantly during dexamethasone administration. Hindlimb grip strength simultaneously decreased. The effect of excessive glucocorticoids on the extracellular compartment did not differ significantly in skeletal muscles with different twitch characteristics.     

Comparison of foetal metabolic differentiation in three cattle muscles

Metabolic differentiation of Semitendinosus (ST), Cutaneus trunci (CT) and Masseter (MA) in cattle foetuses aged from 110 to 260 days was studied by measuring isocitrate dehydrogenase (ICDH, oxidative) and lactate dehydrogenase (LDH, glycolytic) activities. The five LDH isoenzymes were separated by electrophoresis and assayed by densitometry. ICDH activity increased from 210 days onwards in the three muscles but more intensively in MA (oxidative). LDH activity increased from 170 days onwards in ST, 180 days onwards in CT and only from 210 days onwards in MA and was higher in the glycolytic muscles (ST and CT). The proportion of the LDH-M subunit increased during foetal life in glycolytic muscles. At 110 days, it was higher in CT, intermediate in ST and lower in MA. These results show that 1) metabolic differentiation of bovine muscle begins during the last third of foetal life and 2) the proportion of the LDH-M subunit seems to be related to the contractile type of adult muscle from the first stages of foetal life.     

The mouse alpha 1(XII) and human alpha 1(XII)-like collagen genes are localized on mouse chromosome 9 and human chromosome 6.

Type XII collagen is a member of the FACIT (fibril-associated collagens with interrupted triple helices) group of extracellular matrix proteins. Like the other members of this group, collagen types IX and XIV, type XII has alternating triple-helical and non-triple-helical domains. Because of its structure, its association with collagen fibrils, and its distribution in dense connective tissues, type XII is thought possibly to act as a cross-bridge between fibrils and resist shear forces caused by tension. A portion of the ffuse gene was isolated by screening a genomic library with a chicken alpha 1 (XII) cDNA probe, followed by subcloning and sequence analysis. Comparison of exon sequences with the sequence of a mouse cDNA clone allowed the mouse gene to be identified as the alpha 1 (XII) collagen gene. In the mouse, Col12a1 is located on chromosome 9, as determined by linkage analysis using DNA from interspecific backcrosses with Mus spretus. Screening of a human genomic library also allowed the isolation of a human alpha 1(XII)-like gene (CoL12A1). This gene was mapped to chromosome 6 by blot hybridization to DNA from human/hamster hybrid cell lines. This information should prove useful in determining the role of type XII collagen genes as candidate genes in inheritable connective tissue diseases.     

TGF-beta alters collagen XII and XIV mRNA levels in cultured equine tenocytes.

The effects of TGF-beta 1, beta 2 and beta 3 (TGF-beta) on levels of mRNA corresponding to the alpha chains of type XII and type XIV collagens in equine tenocyte cultures were assessed using the ribonuclease protection assay (RPA). The level of alpha1(XII) mRNA in untreated monolayer cultures was approximately 50- to 100-fold greater than alpha1(XIV) mRNA level. Addition of TGF-beta resulted in an increase in the amount of alpha1(XII) present and a decrease of alpha1(XIV) mRNA in a dose-dependent manner. Specifically, the level of alpha1(XII) mRNA was doubled, but alpha1(XIV) was decreased to 30% of control by the addition of 2 ng/ml of TGF-beta 1 to the cultures. These effects were completely abrogated by neutralizing antibody specific for TGF-beta. In addition, electron microscopy demonstrated that bundled collagen fibers were formed in the intercellular spaces of multilayered tenocytes which had been cultured for 2 weeks in the presence of exogenous TGF-beta 1 together with ascorbic acid phosphate. These results suggest that type XII and/or type XIV collagens modulate the structure of ECM formed by tenocytes in culture.     

Pre- and post-natal growth and protein turnover in smooth muscle, heart and slow- and fast-twitch skeletal muscles of the rat.

The growth of one smooth and three individual striated muscles was studied from birth to old age (105 weeks), and where possible during the later stages of foetal life also. Developmental changes in protein turnover (measured in vivo) were related to the changing patterns of growth within each muscle, and the body as a whole. Developmental growth (i.e. protein accumulation) in all muscles involved an increasing proportion of protein per unit wet weight, as well as cellular hypertrophy. The contribution of the heart towards whole-body protein and nucleic acid contents progressively decreased from 18 days of gestation to senility. In contrast, post-natal changes in both slow-twitch (soleus) and fast-twitch (tibialis anterior) skeletal muscles remained reasonably constant with respect to whole-body values. Such age-related growth in all four muscle types was accompanied by a progressive decline in both the fractional rates of protein synthesis and breakdown, the changes in synthesis being more pronounced. Age for age, the fractional rates of synthesis were highest in the oesophageal smooth muscle, similar in both cardiac and the slow-twitch muscles, and lowest in the fast-twitch tibialis muscle. Despite these differences, the developmental fall in synthetic rates was remarkably similar in all four muscles, e.g. the rates at 105 weeks were 30-35% of their values at weaning. Such developmental changes in synthesis were largely related to diminishing ribosomal capacities within each muscle. When measured under near-steady-state conditions (i.e. 105 weeks of age), the half-lives of mixed muscle proteins were 5.1, 10.4, 12.1 and 18.3 days for the smooth, cardiac, soleus and tibialis muscles respectively. Old-age atrophy was evident in the senile animals, this being more marked in each of the four muscle types than in the animal as a whole. In each muscle of the senile rats the protein content and composition per unit wet weight, and both the fractional and total rates of synthesis, were significantly lower than in the muscles of younger, mature, animals (i.e. 44 weeks). In the soleus the decreased synthesis rate appeared to be related to a further fall in the ribosomal capacity. In contrast, the changes in synthesis in the three remaining muscles correlated with significant decreases in the synthetic rate per ribosome.(ABSTRACT TRUNCATED AT 400 WORDS)     

Genetic variability of foetal bovine myoblasts in primary culture

Selected strains of adult bovines and those which either have high muscle growth capacity or are double-muscled present particular characteristics of muscle fibres and collagen at slaughter that favour meat tenderness. For double-muscled bovines, it has been shown that these characteristics originated during foetal life. However, no studies have been done to determine the origin of muscle growth superiority in bovine with high muscle growth capacity compared to those with a low muscle growth capacity. Therefore, the objective of this study was to examine the proliferation and differentiation phases of myoblasts in primary culture taken from high and low muscle growth capacity foetuses at 110 days post-conception. These cultures were analysed on 1, 2, 3, 4, 6, 8, 10 days of culture. The proliferation phase was monitored by appropriate marker antibodies. The differentiation was studied by immunocytochemistry with specific antibodies for foetal, I, II (IIa and IIb), I and IIb, I and IIa myosin heavy chains (MHCs) and connectin respectively, and by immunoblotting with desmin antibody. A higher proliferation, a lower fusion and a delayed differentiation of the late markers namely MHCs fast (IIa and IIb) and connectin were shown in high muscle growth capacity foetuses compared to low capacity ones. The results indicate that the muscle growth superiority of high muscle growth capacity bovines seems, therefore, to have a similar foetal origin to that of double-muscled ones.     

Contractile differentiation of foetal cattle muscles: intermuscular variability

off actile differentiation was studied in six foetal muscles exhibiting different contractile characteristics in adult cattle: the Masseter, Diaphragma, Biceps femoris, Longissimus thoracis, Semitendinosus and Cutaneus trunci. These muscles were excised from foetuses aged 60-260 days. Fibre types were identified by immunohistochemistry using three monoclonal antibodies raised against types 1, 2a, 2b (or 2x) and foetal myosin heavy chains. The different myosin isoforms were also separated by electrophoresis, identified by immunoblotting and quantified by ELISA. At least two generations of cells were observed in all the muscles studied. The primary, early differentiated one, gave rise to type II fibres in Cutaneus trunci and type I fibres in all remaining muscles. The secondary generation of cells differentiated later than the first generation of cells. Its pattern of differentiation was more complex in particular from 150 to 210 days. It formed slow fibres in slow adult muscles, fast fibres in fast adult muscles and both types in mixed muscles. Precocity of differentiation was muscle-type dependent and related to muscle function at birth.     

Articular cartilage and changes in Arthritis: Collagen of articular cartilage

The extracellular framework and two-thirds of the dry mass of adult articular cartilage are polymeric collagen. Type II collagen is the principal molecular component in mammals, but collagens III, VI, IX, X, XI, XII and XIV all contribute to the mature matrix. In developing cartilage, the core fibrillar network is a cross-linked copolymer of collagens II, IX and XI. The functions of collagens IX and XI in this heteropolymer are not yet fully defined but, evidently, they are critically important since mutations in COLIX and COLXI genes result in chondrodysplasia phenotypes that feature precocious osteoarthritis. Collagens XII and XIV are thought also to be bound to fibril surfaces but not covalently attached. Collagen VI polymerizes into its own type of filamentous network that has multiple adhesion domains for cells and other matrix components. Collagen X is normally restricted to the thin layer of calcified cartilage that interfaces articular cartilage with bone.     

Articular cartilage and changes in Arthritis: Collagen of articular cartilage

The extracellular framework and two-thirds of the dry mass of adult articular cartilage are polymeric collagen. Type II collagen is the principal molecular component in mammals, but collagens III, VI, IX, X, XI, XII and XIV all contribute to the mature matrix. In developing cartilage, the core fibrillar network is a cross-linked copolymer of collagens II, IX and XI. The functions of collagens IX and XI in this heteropolymer are not yet fully defined but, evidently, they are critically important since mutations in COLIX and COLXI genes result in chondrodysplasia phenotypes that feature precocious osteoarthritis. Collagens XII and XIV are thought also to be bound to fibril surfaces but not covalently attached. Collagen VI polymerizes into its own type of filamentous network that has multiple adhesion domains for cells and other matrix components. Collagen X is normally restricted to the thin layer of calcified cartilage that interfaces articular cartilage with bone.     

Procoagulant activity of collagen. Effect of difference in type and structure of collagen

Procoagulant activities of different types and structures of collagen were examined. Collagens used were types I (including its methylated and succinylated forms), II, III, IV and V. Each collagen was coated on an inner surface of a glass tube. The change of fluidity during coagulation of blood in the tube was measured by means of a new rheological technique. For monomeric collagen, the procoagulant activity of the succinylated form (negatively charged) was higher than that of the methylated form (positively charged). The procoagulant activity of type IV (dry) was lower than that of other types of collagen. For fibrillar collagens, the initiation of coagulation for type V (non-banded) was fairly delayed compared to those for types I, II and III (banded). An increase in water content in both monomeric and fibrillar forms promoted procoagulant activity. For most of the collagen forms, the addition of factor XII inhibitor (Polybrene) to blood brought about a remarkable delay of the initiation of coagulation, suggesting that the activation of factor XII on the collagen surface is one of main factors governing procoagulant activity. In addition, our data suggest that large numbers of adherent platelets to the collagen surface promote activation of the intrinsic coagulation system.     

Immunohistochemical analysis of bFGF,TGF-beta1 and catalase in rectus abdominis muscle from cattle foetuses at 180 and 260 days post-conception

The potential for muscle growth depends on myoblast proliferation, which occurs essentially during the first two thirds of the foetal period in cattle. Thereafter, myofibres acquire their contractile and metabolic properties. Proliferation is regulated by molecular growth factors and by the tissue oxidative activity. The aim of this study was the quantification by immunochemistry of basic fibroblast growth factor (bFGF) and transforming growth factor beta 1 (TGF-beta1) and also of enzyme catalase (CAT) activity in rectus abdominis muscle. Samples were collected from cattle foetuses of different growth potential at 180 and 260 days post-conception (dpc). One major conclusion from this work is that protein contents of the muscle tissue bFGF and, to a lower extent, CAT activity decreased with increasing age during the foetal life. No differences were found between the different genotypes of cattle. However, the CAT to bFGF ratio tended to be lower in fast-growing cattle and increased with foetal age. TGF-beta1 did not change with age and was localised mostly at the vascular bed. CAT was detected in smooth and rough reticulum in striated muscles at 180dpc, and additionally in mitochondria at 260dpc. In conclusion, the balance between intracellular growth factors (bFGF and TGF-beta1) and the activity of antioxidant enzyme CAT may participate in the regulation of the transition from myoblast proliferation to differentiation. Thus, increased ratio of CAT to bFGF might be a good index indicating initiation of muscle maturation in cattle foetus prior to birth.