Involvement of HMGB1 and HMGB2 proteins in exogenous DNA integration reaction into the genome of HeLa S3 cells

Electrophoretic and Western blot studies were conducted on collagen fractions extracted from Sepia officinalis (cuttlefish) cartilage using a modified salt precipitation method developed for the isolation of vertebrate collagens. The antibodies used had been raised in rabbit against the following types of collagen: Sepia I-like; fish I; human I; chicken I, II, and IX; rat V; and calf IX and XI. The main finding was that various types of collagen are present in Sepia cartilage, as they are in vertebrate hyaline cartilage. However, the main component of Sepia cartilage is a heterochain collagen similar to vertebrate type I, and this is associated with minor forms similar to type V/XI and type IX. The cephalopod type I-like heterochain collagen can be considered a first step toward the evolutionary development of a collagen analogous to the typical collagen of vertebrate cartilage (type II homochain). The type V/XI collagen present in molluscs, and indeed all phyla from the Porifera upwards, may represent an ancestral collagen molecule conserved relatively unchanged throughout evolution. Type IX-like collagen seems to be essential for the formation of cartilaginous tissue.     

Immunohistochemical study of collagens of the extracellular matrix in cartilage of Sepia officinalis

We used various anti-collagen antibodies to perform indirect immunofluorescent staining of cartilage sections from cuttlefish (S. officinalis). On ultrathin sections and collagen fibril preparations from the same tissue, we performed immunostaining with colloidal gold. The extracellular matrix (ECM) of S. officinalis cartilage reacted intensely and homogeneously with an antibody directed against type I-like collagen isolated from the cartilage of cuttlefish and with anti-rat type V collagen antibody. A weak reaction was observed with anti-fish and anti-chicken type I collagen antibodies, while no reaction was observed with anti-rat type I and anti calf type II collagen antibodies. Anti-chicken type II, anti calf type IX and type XI collagen antibodies reacted weakly with ECM, while stained cell bodies and cell processes reacted more intensely. A similar pattern of reaction was observed on cartilage section and isolated collagen fibrils prepared for electron microscopy. These findings suggest that ECM of cuttlefish cartilage may be composed of molecules similar to the type I, type V, type IX and type XI collagen molecules of vertebrates. Cephalopods have evolved a cartilage of structure and macromolecular organisation similar to that of vertebrate cartilage. However, the main molecular components of S. officinalis cartilage--type I-like and type V collagens--differ from those of vertebrate cartilage. We suggest that this type I-like collagen can be considered an initial step toward the evolution of type II collagen typical of vertebrates.     

Fibril-forming collagens in lamprey

Five types of collagen with triple-helical regions approximately 300 nm in length were found in lamprey tissues which show characteristic D-periodic collagen fibrils. These collagens are members of the fibril forming family of this primitive vertebrate. Lamprey collagens were characterized with respect to solubility, mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, carboxylmethyl-cellulose chromatography, peptide digestion patterns, composition, susceptibility to vertebrate collagenase, thermal stability, and segment long spacing-banding pattern. Comparison with fibril-forming collagens in higher vertebrates (types I, II, III, V, and XI) identified three lamprey collagens as types II, V, and XI. Both lamprey dermis and major body wall collagens had properties similar to type I but not the typical heterotrimer composition. Dermis molecules had only alpha 1(I)-like chains, while body wall molecules had alpha 2(I)-like chains combined with chains resembling lamprey type II. Neither collagen exhibited the interchain disulfide linkages or solubility properties of type III. The conservation of fibril organization in type II/type XI tissues in contrast to the major developments in type I and type III tissues after the divergence of lamprey and higher vertebrates is consistent with these results. The presence of type II and type I-like molecules as major collagens and types V and XI as minor collagens in the lamprey, and the differential susceptibility of these molecules to vertebrate collagenase is analogous to the findings in higher vertebrates.     

Differences in Chain Usage and Cross-linking Specificities of Cartilage Type V/XI Collagen Isoforms with Age and Tissue

Collagen type V/XI is a minor but essential component of collagen fibrils in vertebrates. We here report on age- and tissue-related variations in isoform usage in cartilages. With maturation of articular cartilage, the α1(V) chain progressively replaced the α2(XI) chain. A mix of the molecular isoforms, α1(XI)α1(V)α3(XI) and α1(XI)α2(XI)α3(XI), best explained this finding. A prominence of α1(V) chains is therefore characteristic and a potential biomarker of mature mammalian articular cartilage. Analysis of cross-linked peptides showed that the α1(V) chains were primarily cross-linked to α1(XI) chains in the tissue and hence an integral component of the V/XI polymer. From nucleus pulposus of the intervertebral disc (in which the bulk collagen monomer is type II as in articular cartilage), type V/XI collagen consisted of a mix of five genetically distinct chains, α1(XI), α2(XI), α3(XI), α1(V), and α2(V). These presumably were derived from several different molecular isoforms, including α1(XI)α2(XI)α3(XI), (α1(XI))₂α2(V), and others. Meniscal fibrocartilage shows yet another V/XI phenotype. The findings support and extend the concept that the clade B subfamily of COL5 and COL11 gene products should be considered members of the same collagen subfamily, from which, in combination with clade A gene products (COL2A1 or COL5A2), a range of molecular isoforms has evolved into tissue-dependent usage. We propose an evolving role for collagen V/XI isoforms as an adaptable polymeric template of fibril macro-architecture.The collagen framework of hyaline cartilages is based on a covalently cross-linked heteropolymeric network of types II, IX, and XI collagens. During development, collagen type IX molecules are covalently linked to the surface of thin, new fibrils of type II collagen polymerized on a template of type XI collagen (1–5). In fetal cartilage, type XI collagen is a heterotrimer of three genetically distinct chains, α1(XI), α2(XI), and α3(XI) in a 1:1:1 ratio (6–9). The α3(XI) chain has the same primary sequence as α1(II), but the chains differ in their post-translational processing and cross-linking properties (7–9). All three collagen subunits, II, IX, and XI, are heavily cross-linked in the same fibril through a lysyl oxidase-mediated mechanism (2, 5, 9). The location of the cross-links determined by sequence analysis of peptides prepared from proteolytically degraded fibrils reveals a high degree of chain specificity (9). Collagen XI molecules are linked to each other in a head-to-tail fashion by N-telopeptide² to helix cross-links and laterally to type II collagen molecules through α1(II) C-telopeptides (9). Isolated from mature articular cartilage, type XI collagen includes a significant pool of α1(V) chains (6), implying the presence of V/XI hybrid molecules. The ratio of type XI collagen to type II collagen is about 1 to 10 in fetal bovine and human epiphyseal cartilage when compared with 1 to 30 in adult articular cartilage. Similarly, the ratio of collagen IX to collagen II falls from about 1 to 10 to 1 to 100 between fetal and adult. In adult articular cartilage, most of the collagen IX is located in the immediate pericellular matrix (10–12).The intervertebral disc has a unique collagen architecture that combines features of ligament and cartilage in its morphology, function, and matrix biochemistry. The lamellar fabric of the outer annulus fibrosus combines collagens I and II fibrils in a complex weave with a radial gradient from mostly type I in the outermost layers and mostly type II in the interior. Nucleus pulposus, the gel-like center of the young intervertebral disc, has a similar collagen molecular phenotype to hyaline cartilage in which types II, IX, and XI collagens are the principal cross-linked fibrillar components (13–16). Collagen IX in the disc has a different protein isoform to that of hyaline cartilages. The α1(IX) chain is expressed as a short form that lacks the amino-terminal NC4 domain (16). One of the aims of the present study was to determine whether a unique pattern of type V/XI hybrid molecules is present in disc tissue when compared with articular cartilage and a more typical fibrocartilage, the knee meniscus.The results show an accumulation of collagen α1(V) chains as articular cartilage matures. A related but distinct complexity in chain usage in the type V/XI collagen of nucleus pulposus is also revealed. Such tissue diversity suggests that the different molecular isoforms produce functional differences in the type V/XI polymeric template on which the bulk fibril architecture of a tissue is built.     

Areas of asbestoid (amianthoid) fibers in human thyroid cartilage characterized by immunolocalization of collagen types I,II, IX,XI and X

The distribution of type I, II, IX, XI and X collagens in and close to areas of asbestoid (amianthoid) fibers in thyroid cartilages of various ages was investigated in this study. Asbestoid fibers were first detected in thyroid cartilage from a 3-year-old male child. Areas of asbestoid fibers functionally appear to serve as guide rails for vascularization of thyroid cartilage. Alcian blue staining in the presence of 0.3 M MgCl₂ revealed a loss of glycosaminoglycans in areas of asbestoid fibers. In addition, the fibers reacted positively with antibodies against collagen types II, IX and XI, but showed no staining with antibodies to collagen types I and X. Territorial matrix of adjacent chondrocytes showed the same staining pattern. In addition to staining for type II, IX and XI collagens, asbestoid fibers showed strong immunostaining for type I collagen after puberty but not for type X collagen. However, groups of chondrocytes within areas of asbestoid fibers reacted strongly with antibodies to type X collagen, suggesting that this collagen plays an important role in matrix of highly differentiated chondrocytes. The finding that these type X collagen-positive chondrocytes also revealed immunostaining for type I collagen confirms previous studies showing that hypertrophic chondrocytes can further differentiate into cells that are characterized by the synthesis of type X and I collagens.     

Susceptibility of cartilage collagens type II, IX, X, and XI to human synovial collagenase and neutrophil elastase

The action of purified rheumatoid synovial collagenase and human neutrophil elastase on the cartilage collagen types II, IX, X and XI was examined. At 25 degrees C, collagenase attacked type II and type X (45-kDa pepsin-solubilized) collagens to produce specific products reflecting one and at least two cleavages respectively. At 35 degrees C, collagenase completely degraded the type II collagen molecule to small peptides whereas a large fragment of the type X molecule was resistant to further degradation. In contrast, collagen type IX (native, intact and pepsin-solubilized type M) and collagen type XI were resistant to collagenase attack at both 25 degrees C and 35 degrees C even in the presence of excess enzyme. Mixtures of type II collagen with equimolar amounts of either type IX or XI did not affect the rate at which the former was degraded by collagenase at 25 degrees C. Purified neutrophil elastase, shown to be functionally active against soluble type III collagen, had no effect on collagen type II at 25 degrees C or 35 degrees C. At 25 degrees C collagen types IX (pepsin-solubilized type M) and XI were also resistant to elastase, but at 35 degrees C both were susceptible to degradation with type IX being reduced to very small peptides. Collagen type X (45-kDa pepsin-solubilized) was susceptible to elastase attack at 25 degrees C and 35 degrees C as judged by the production of specific products that corresponded closely with those produced by collagenase. Although synovial collagenase failed to degrade collagen types IX and XI, all the cartilage collagen species examined were degraded at 35 degrees C by conditioned culture medium from IL1-activated human articular chondrocytes. Thus chondrocytes have the potential to catabolise each cartilage collagen species, but the specificity and number of the chondrocyte-derived collagenase(s) has yet to be resolved.     

Axial structure of the heterotypic collagen fibrils of vitreous humour and cartilage

We have compared the axial structures of negatively stained heterotypic, type II collagen-containing fibrils with computer-generated staining patterns. Theoretical negative-staining patterns were created based upon the "bulkiness" of the individual amino acid side-chains in the primary sequence and the D-staggered arrangement of the triple-helices. The theoretical staining pattern of type II collagen was compared and cross-correlated with the experimental staining pattern of both reconstituted type II collagen fibrils, and fibrils isolated from adult and foetal cartilage and vitreous humour. The isolated fibrils differ markedly in both diameter and composition. Correlations were significantly improved when a degree of theoretical hydroxylysine glycosylation was applied, showing for the first time that this type of glycosylation influences the negative-staining pattern of collagen fibrils. Increased correlations were obtained when contributions from types V/XI and IX collagen were included in the simulation model. The N-propeptide of collagen type V/XI and the NC2 domain of type IX collagen both contribute to prominent stain-excluding peaks in the gap region. With decreasing fibril diameter, an increase of these two peaks was observed. Simulations of the fibril-derived staining patterns with theoretical patterns composed of proportions of types II, V/XI and IX collagen confirmed that the thinnest fibrils (i.e. vitreous humour collagen fibrils) have the highest minor collagen content. Comparison of the staining patterns showed that the organisation of collagen molecules within vitreous humour and cartilage fibrils is identical. The simulation model for vitreous humour, however, did not account for all stain-excluding mass observed in the staining pattern; this additional mass may be accounted for by collagen-associated macromolecules.     

Collagen XI chain misassembly in cartilage of the chondrodysplasia (cho) mouse

Molecular mechanisms controlling the assembly of cartilage-specific types II, IX and XI collagens into a heteropolymeric network of uniformly thin, unbanded fibrils are not well understood, but collagen XI has been implicated. The present study on cartilage from the homozygous chondrodysplasia (cho/cho) mouse adds support to this concept. In the absence of alpha1(XI) collagen chains, thick, banded collagen fibrils are formed in the extracellular matrix of cho/cho cartilage. A functional knock-out of the type XI collagen molecule has been assumed. We have re-examined this at the protein level to see if, rather than a complete knock-out, alternative type XI chain assemblies were formed. Mass spectrometry of purified triple-helical collagen from the rib cartilage of cho/cho mice identified alpha1(V) and alpha2(XI) chains. These chains were recovered in roughly equal amounts based on Coomassie Blue staining of SDS-PAGE gels, in addition to alpha1(II)/alpha3(XI) collagen chains. Using telopeptide-specific antibodies and Western blot analysis, it was further shown that type V/XI trimers were present in the matrix cross-linked to each other and to type II collagen molecules to form heteropolymers. Cartilage from heterozygous (cho/+) mice contained a mix of alpha1(V) and alpha1(XI) chains and a mix of thin and thick fibrils on transmission electron microscopy. In summary, the results imply that native type XI collagen molecules containing an alpha1(XI) chain are required to form uniformly thin fibrils and support a role for type XI collagen as the template for the characteristic type II collagen fibril network of developing cartilage.     

The effects of mechanical stability on the macromolecules of the connective tissue matrices produced during fracture healing. I. The collagens

Summary The distribution of types I, II, III, V and IX collagens in healing fractures of the rabbit tibia has been demonstrated by immunofluorescent techniques. It has also been shown that the mechanical stability of the healing fracture affects both the distribution and types of the collagens present.The initial fibrous matrix contains types III and V collagens; type I collagen was only located in this matrix if unfixed tissue was used. In mechanically stable fractures, cancellous bone forms over the entire periosteal surface by 5–7 days; type I collagen is laid down within the previous fibrous matrix. The trabeculae are heterogeneous in their collagen content. The cavities contain a matrix of types III and V collagens. Small nodules of cartilage may be present between 7 and 14 days; these contain types II and IX collagens.In mechanically unstable fractures, cancellous bone is initially formed away from the fracture gap. The fibrous tissue over the gap is replaced by cartilage; types II and IX collagens are laid down on the pre-existing fibrous matrix. The cartilage is replaced by endochondral ossification. At the ossification front, type I collagen is found around the chondrocyte lacunae of the spicules of cartilage. The new trabeculae contain a core of cartilage which is surrounded by a bone matrix of types I and V collagens.The fracture gaps are invaded by fibrous tissue, which contain types III and V collagens. This is later replaced by cancellous bone.     

Cellular heterogeneity in cultured human chondrocytes identified by antibodies specific for alpha 2(XI) collagen chains

Collagen type XI is a component of hyaline cartilage consisting of alpha 1(XI), alpha 2(XI), and alpha 3(XI) chains; with 5-10% of the total collagen content, it is a minor but significant component next to type II collagen, but its function and precise localization in cartilaginous tissues is still unclear. Owing to the homology of the alpha 3(XI) and alpha 1(II) collagen chains, attempts to prepare specific antibodies to native type XI collagen have been unsuccessful in the past. In this study, we report on the preparation and use for immunohistochemistry of a polyclonal antibody specific for alpha 2(XI) denatured collagen chains. The antibody was prepared by immunization with the isolated alpha 2(XI) chain and reacts neither with native type XI collagen nor type I, II, V, or IX by ELISA or immunoblotting, nor with alpha 1(XI) or alpha 3(XI), but with alpha 2(XI) chains. Using this antibody, it was possible to specifically localize alpha 2(XI) in cartilage by pretreating tissue sections with 6 M urea. In double immunofluorescence staining experiments, the distribution of alpha 2(XI) as indicative for type XI collagen in fetal bovine and human cartilage was compared with that of type II collagen, using a monoclonal antibody to alpha 1(II). Type XI collagen was found throughout the matrix of hyaline cartilage. However, owing to cross-reactivity of the monoclonal anti-alpha 1(II) with alpha 3(XI), both antibodies produced the same staining pattern. Cellular heterogeneity was, however, detected in monolayer cultures of human chondrocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sites of stromelysin cleavage in collagen types II, IX, X, and XI of cartilage

Human recombinant stromelysin-1 was shown to cleave four types of collagen (types II, IX, X, and XI) prepared from bovine and rat cartilages at specific sites. Stromelysin-1 cleaved salt-soluble native molecules of type IX collagen into two main triple-helical fragments, COL1 and COL2,3. Protein microsequencing identified the exact cleavage sites in the NC2 domain of all three chains, alpha 1(IX), alpha 2(IX), and alpha 3(IX). Stromelysin-1 also acted as a "telopeptidase," in that it efficiently clipped intact molecules of types II and XI collagens at sites just inside their terminal cross-linking hydroxylysine residues. Native molecules of type X collagen were cleaved by stromelysin-1 within their triple helical domains at a COOH-terminal site that reduced the alpha 1(X) chain size by 10 kDa. These findings suggest an important role for stromelysin in the turnover and remodeling of the collagenous matrix of cartilage both normally and in degenerative joint disease.     

Expression of collagen type I and type II in consecutive stages of human osteoarthritis

In normal hyaline cartilage the predominant collagen type is collagen type II along with its associated collagens, for example, types IX and XI, produced by normal chondrocytes. In contrast, investigations have demonstrated that in vitro a switch from collagen type II to collagen type I occurs. Some authors have detected collagen type I in osteoarthritic cartilage also in vivo, especially in late stages of osteoarthritis, while others have not. In the light of these diverging results, we have attempted to elucidate which type of collagen, type I and/or type II, is synthesized in the consecutive stages of human osteoarthritis. We performed in situ hybridization and immunohistochemistry with cartilage tissue samples from patients suffering from various stages of osteoarthritis. Furthermore, we quantitated our results on the gene expression of collagen type I and type II with the help of real-time PCR. We found that with the progression of the disease not only collagen type II, but also increasing amounts of collagen type I mRNA were produced. This supports the conclusion that collagen type I gradually becomes one of the factors involved in the pathogenesis of osteoarthritis.     

Immunohistochemical study of subepidermal connective of molluscan integument

Sections of integument from gastropod, bivalve and cephalopod species were studied immunohistochemically to determine reactivity to antibody against the type I-like collagen from Sepia cartilage and antibodies against components of the extracellular matrix (ECM) of vertebrate connective tissue: type I, III, IV, V, and VI collagens, laminin, nidogen and heparan sulphate. All samples exhibited similar reactivities to the antibodies, although differences in the intensity and localization of the immunostaining were found that were clearly correlated with between-species differences in integumental ultrastructure. These findings indicate that the composition of the integumental ECM is similar in the three classes of molluscs examined and that several types of collagen are present. However molluscan subepidermal connective tissue differs from the ECM of vertebrate dermis: molluscan integumental ECM contains collagens similar to type I, V and VI collagens but has no type III-similar collagen. Furthermore molecules similar to the type IV collagen, laminin, nidogen and heparan sulphate of vertebrates were present ubiquitously in molluscan basement membrane, confirming the statement that the structure and composition of basement membrane have remained constant throughout the evolution of all animal phyla.     

Endocrine cells in the gastric mucosa of elasmobranch fishes. An ultrastructural study

The endocrine cells of gastric mucosa of two elasmobranch species were studied by light and electron microscopy. Five cell types were identified in the fundic mucosa, four of which are of "open type". All of them show pleomorphic granules of variable size, except those of the type V cell which are round in shape and of comparatively small diameter. Six different cell types are found in the pyloric mucosa, all of "open type" except for type XI cells which appear to be "closed". Pyloric types VIII, IX, X and XI cells show similar structural characteristics as fundus types I, V, II and IV respectively. Silver impregnation was also used at both light and electron microscopical levels. No functional classification or analogies with other vertebrate gastric endocrine cells were attempted as these would be too speculative on the basis of ultrastructural characteristics only.     

Isolation of human type X collagen and immunolocalization in fetal human cartilage

Type X collagen was extracted with 1 M NaCl and 10 mM dithiothreitol at neutral pH from fetal human growth plate cartilage and purified to homogeneity by gel filtration and anion-exchange chromatography. The purified protein migrates in SDS/polyacrylamide gels with an apparent Mr of 66,000 under reducing conditions, and as a high-Mr oligomer under non-reducing conditions. Purified collagenase digests most of the molecule; pepsin digestion at 4 degrees C decreases the Mr of the monomer to 53,000. A rabbit antiserum was raised against purified human type X collagen; the IgG fraction was specific for this collagen by criteria of ELISA and immunoblotting after absorption with collagen types I, II, VI, IX and XI. Immunohistological studies localized type X collagen exclusively in the zone of hypertrophic and calcifying cartilage.     

A novel and highly conserved collagen (pro(alpha)1(XXVII)) with a unique expression pattern and unusual molecular characteristics establishes a new clade within the vertebrate fibrillar collagen family

The type XXVII collagen gene codes for a novel vertebrate fibrillar collagen that is highly conserved in man, mouse, and fish (Fugu rubripes). The pro(alpha)1(XXVII) chain has a domain structure similar to that of the type B clade chains (alpha1(V), alpha3(V), alpha1(XI), and alpha2(XI)). However, compared with other vertebrate fibrillar collagens (types I, II, III, V, and XI), type XXVII collagen has unusual molecular features such as no minor helical domain, a major helical domain that is short and interrupted, and a short chain selection sequence within the NC1 domain. Pro(alpha)1(XXVII) mRNA is 9 kb and expressed by chondrocytes but also by a variety of epithelial cell layers in developing tissues including stomach, lung, gonad, skin, cochlear, and tooth. By Western blotting, type XXVII antisera recognized multiple bands of 240-110 kDa in tissue extracts and collagenous bands of 150-140 kDa in the conditioned medium of the differentiating chondrogenic ATDC5 cell line. Phylogenetic analyses revealed that type XXVII, together with the closely related type XXIV collagen gene, form a new, third clade (type C) within the vertebrate fibrillar collagen family. Furthermore, the exon structure of the type XXVII collagen gene is similar to, but distinct from, those of the genes coding for the type A or B clade pro(alpha) chains.     

The head cartilage of cephalopods II. Ultrastructure of isolated native collagen fibrils and of polymeric aggregates obtained in Vitro: Comparison with the cartilage of mammals

Native collagen fibrils were isolated from cephalopod head cartilage and mammal hyaline cartilage. The analysis with TEM after positive and negative staining demonstrated that the fibrils have a periodic structure similar to that of fibrillar type I collagen of mammals. The banding pattern of polymeric forms (SLS, FLS) obtained in vitro from squid cartilage collagen was remarkably different from the analogous forms of mammal collagen types I and II.     

D-periodic distribution of collagen type IX along cartilage fibrils

It has recently become apparent that collagen fibrils may be composed of more than one kind of macromolecule. To explore this possibility, we developed a procedure to purify fibril fragments from 17-d embryonic chicken sternal cartilage. The fibril population obtained shows, after negative staining, a uniformity in the banding pattern and diameter similar to the fibrils in situ. Pepsin digestion of this fibril preparation releases collagen types II, IX, and XI in the proportion of 8:1:1. Rotary shadowing of the fibrils reveals a d-periodic distribution of 35-40-nm long projections, each capped with a globular domain, which resemble in form and dimensions the aminoterminal globular and collagenous domains, NC4 and COL3, of type IX collagen. The monoclonal antibody (4D6) specific for an epitope close to the amino terminal of the COL3 domain of type IX collagen bound to these projections, thus confirming their identity. Type IX collagen is therefore distributed in a regular d-periodic arrangement along cartilage fibrils, with the chondroitin sulfate chain of type IX collagen in intimate contact with the fibril.     

Concerted modulation of alpha 1(XI) and alpha 2(V) collagen mRNAs in bovine vascular smooth muscle cells.

We have isolated a partial cDNA for alpha 1(XI) collagen from a bovine smooth muscle cell (SMC) library. Previously, this collagen was not known to be expressed in SMCs. Comparison of the nucleotide and deduced amino acid sequence of the 2.7-kilobase bovine clone and the human alpha 1(XI) sequence indicates 92 and 98% homology, respectively. Bovine SMCs in culture were found to produce alpha 1(XI) mRNA. However, alpha 2(XI) and alpha 1(II) collagen RNA were not detectable; therefore, SMCs cannot synthesize the same type XI collagen as found in cartilage. Since type XI collagen is structurally related to type V collagen, the expression of alpha 1(XI) and alpha 2(V) collagen mRNA in SMCs was characterized. Levels of alpha 1(XI) and alpha 2(V) collagen mRNAs were low in exponentially growing SMCs and increased 3-4-fold as cells became confluent. Increased mRNA levels were also observed when exponentially growing subconfluent SMCs were incubated in medium containing 0.5% fetal bovine serum for 24 h, similar to the effects of serum deprivation on the expression of types I and III collagen genes (Kindy, M. S., Chang, C.-J., and Sonenshein, G. E. (1988) J. Biol. Chem. 263, 11426-11430). However, as cell density increased, serum deprivation resulted in very different responses for these collagen genes. Serum deprivation caused a decrease in expression of alpha 1(XI) and alpha 2(V) collagen mRNAs in cultures as they approached confluence. In contrast, at confluence alpha 1(I) and alpha 2(I) mRNA levels no longer responded to serum concentration whereas expression of alpha 1(III) mRNA remained inducible by serum deprivation. These results suggest concerted regulation of alpha 1(XI) and alpha 2(V) collagen gene expression, which is distinct from that for the chains of type I and type III collagen with respect to cell density and serum.