Differentiated activities of decorin and biglycan in the progression of post-traumatic osteoarthritis.

OBJECTIVE: To delineate the activities of decorin and biglycan in the progression of post-traumatic osteoarthritis (PTOA). DESIGN: Three-month-old inducible biglycan (BgniKO) and decorin/biglycan compound (Dcn/BgniKO) knockout mice were subjected to the destabilization of the medial meniscus (DMM) surgery to induce PTOA. The OA phenotype was evaluated by assessing joint structure and sulfated glycosaminoglycan (sGAG) staining via histology, surface collagen fibril nanostructure and calcium content via scanning electron microscopy, tissue modulus via atomic force microscopy-nanoindentation, as well as subchondral bone structure and meniscus ossification via micro-computed tomography. Outcomes were compared with previous findings in the inducible decorin (DcniKO) knockout mice. RESULTS: In the DMM model, BgniKO mice developed similar degree of OA as the control (0.44 [-0.18 1.05] difference in modified Mankin score), different from the more severe OA phenotype observed in DcniKO mice (1.38 [0.91 1.85] difference). Dcn/BgniKO mice exhibited similar histological OA phenotype as DcniKO mice (1.51 [0.97 2.04] difference vs control), including aggravated loss of sGAGs, salient surface fibrillation and formation of osteophyte. Meanwhile, Dcn/BgniKO mice showed further cartilage thinning than DcniKO mice, resulting in the exposure of underlying calcified tissues and aberrantly high surface modulus. BgniKO and Dcn/BgniKO mice developed altered subchondral trabecular bone structure in both Sham and DMM groups, while DcniKO and control mice did not. CONCLUSION: In PTOA, decorin plays a more crucial role than biglycan in regulating cartilage degeneration, while biglycan is more important in regulating subchondral bone structure. The two have distinct activities and modest synergy in the pathogenesis of PTOA.

Achilles tendons from decorin- and biglycan-null mouse models have inferior mechanical and structural properties predicted by an image-based empirical damage model.

Achilles tendons are a common source of pain and injury, and their pathology may originate from aberrant structure function relationships. Small leucine rich proteoglycans (SLRPs) influence mechanical and structural properties in a tendon-specific manner. However, their roles in the Achilles tendon have not been defined. The objective of this study was to evaluate the mechanical and structural differences observed in mouse Achilles tendons lacking class I SLRPs; either decorin or biglycan. In addition, empirical modeling techniques based on mechanical and image-based measures were employed. Achilles tendons from decorin-null (Dcn(-/-)) and biglycan-null (Bgn(-/-)) C57BL/6 female mice (N=102) were used. Each tendon underwent a dynamic mechanical testing protocol including simultaneous polarized light image capture to evaluate both structural and mechanical properties of each Achilles tendon. An empirical damage model was adapted for application to genetic variation and for use with image based structural properties to predict tendon dynamic mechanical properties. We found that Achilles tendons lacking decorin and biglycan had inferior mechanical and structural properties that were age dependent; and that simple empirical models, based on previously described damage models, were predictive of Achilles tendon dynamic modulus in both decorin- and biglycan-null mice.

Development of tendon structure and function: regulation of collagen fibrillogenesis.

In the tendon, the development of mature mechanical properties is dependent on the assembly of a tendon-specific extracellular matrix. This matrix is synthesized by the tendon fibroblasts and composed of collagen fibrils organized as fibers, as well as fibril-associated collagenous and non-collagenous proteins. All of these components are integrated, during development and growth, to form a functional tissue. During tendon development, collagen fibrillogenesis and matrix assembly progress through multiple steps where each step is regulated independently, culminating in a structurally and functionally mature tissue. Collagen fibrillogenesis occurs in a series of extracellular compartments where fibril intermediates are assembled and mature fibrils grow through a process of post-depositional fusion of the intermediates. Linear and lateral fibril growth occurs after the immature fibril intermediates are incorporated into fibers. The processes are regulated by interactions of extracellular macromolecules with the fibrils. Interactions with quantitatively minor fibrillar collagens, fibril-associated collagens and proteoglycans influence different steps in fibrillogenesis and the extracellular microdomains provide a mechanism for the tendon fibroblasts to regulate these extracellular interactions.

Intrinsic aging vs. photoaging: a comparative histopathological, immunohistochemical, and ultrastructural study of skin.

Cutaneous aging is a complex biological phenomenon affecting the different constituents of the skin. To compare the effects of intrinsic and extrinsic aging processes, a total of 83 biopsies were collected from sun-exposed and protected skin of healthy volunteers representing decades from the 1st to the 9th (6-84 years of age). Routine histopathology coupled with computer-assisted image analysis was used to assess epidermal changes. Immunoperoxidase techniques with antibodies against type I and type III collagens and elastin were used to quantitatively evaluate changes in collagen and elastic fibers and their ultrastructure was examined by transmission electron microscopy. Epidermal thickness was found to be constant in different decades in both sun-exposed and protected skin; however, it was significantly greater in sun-exposed skin (P = 0.0001). In protected skin, type I and III collagen staining was altered only after the 8th decade, while in sun-exposed skin the relative staining intensity significantly decreased from 82.5% and 80.4% in the 1st decade to 53.2% and 44.1% in the 9th decade, respectively (P = 0.0004 and 0.0008). In facial skin the collagen fiber architecture appeared disorganized after the 4th decade. The staining intensity of elastin in protected skin significantly decreased from 49.2% in the 1st decade to 30.4% in the 9th decade (P = 0.05), whereas in sun-exposed skin the intensity gradually increased from 56.5% in the 1st decade to 75.2% in the 9th decade (P = 0.001). The accumulated elastin in facial skin was morphologically abnormal and appeared to occupy the areas of lost collagen. Collectively, the aging processes, whether intrinsic or extrinsic, have both quantitative and qualitative effects on collagen and elastic fibers in the skin.

Type IIA procollagen: expression in developing chicken limb cartilage and human osteoarthritic articular cartilage.

Type IIA procollagen is an alternatively spliced product of the type II collagen gene and uniquely contains the cysteine (cys)-rich globular domain in its amino (N)-propeptide. To understand the function of type IIA procollagen in cartilage development under normal and pathologic conditions, the detailed expression pattern of type IIA procollagen was determined in progressive stages of development in embryonic chicken limb cartilages (days 5-19) and in human adult articular cartilage. Utilizing the antibodies specific for the cys-rich domain of the type IIA procollagen N-propeptide, we localized type IIA procollagen in the pericellular and interterritorial matrix of condensing pre-chondrogenic mesenchyme (day 5) and early cartilage (days 7-9). The intensity of immunostaining was gradually lost with cartilage development, and staining became restricted to the inner layer of perichondrium and the articular cap (day 12). Later in development, type IIA procollagen was re-expressed at the onset of cartilage hypertrophy (day 19). Different from type X collagen, which is expressed throughout hypertrophic cartilage, type IIA procollagen expression was transient and restricted to the zone of early hypertrophy. Immunoelectron microscopic and immunoblot analyses showed that a significant amount of the type IIA procollagen N-propeptide, but not the carboxyl (C)-propeptide, was retained in matrix collagen fibrils of embryonic limb cartilage. This suggests that the type IIA procollagen N-propeptide plays previously unrecognized roles in fibrillogenesis and chondrogenesis. We did not detect type IIA procollagen in healthy human adult articular cartilage. Expression of type IIA procollagen, together with that of type X collagen, was activated by articular chondrocytes in the upper zone of moderately and severely affected human osteoarthritic cartilage, suggesting that articular chondrocytes, which normally maintain a stable phenotype, undergo hypertrophic changes in osteoarthritic cartilage. Based on our data, we propose that type IIA procollagen plays a significant role in chondrocyte differentiation and hypertrophy during normal cartilage development as well as in the pathogenesis of osteoarthritis.

Production of human type I collagen in yeast reveals unexpected new insights into the molecular assembly of collagen trimers.

Substantial evidence supports the role of the procollagen C-propeptide in the initial association of procollagen polypeptides and for triple helix formation. To evaluate the role of the propeptide domains on triple helix formation, human recombinant type I procollagen, pN-collagen (procollagen without the C-propeptides), pC-collagen (procollagen without the N-propeptides), and collagen (minus both propeptide domains) heterotrimers were expressed in Saccharomyces cerevisiae. Deletion of the N- or C-propeptide, or both propeptide domains, from both proalpha-chains resulted in correctly aligned triple helical type I collagen. Protease digestion assays demonstrated folding of the triple helix in the absence of the N- and C-propeptides from both proalpha-chains. This result suggests that sequences required for folding of the triple helix are located in the helical/telopeptide domains of the collagen molecule. Using a strain that does not contain prolyl hydroxylase, the same folding mechanism was shown to be operative in the absence of prolyl hydroxylase. Normal collagen fibrils were generated showing the characteristic banding pattern using this recombinant collagen. This system offers new opportunities for the study of collagen expression and maturation.

Type V collagen: heterotypic type I/V collagen interactions in the regulation of fibril assembly.

Type V collagen is a quantitatively minor fibrillar collagen with a broad tissue distribution. The most common type V collagen isoform is alpha1(V)(2) alpha2(V) found in cornea. However, other isoforms exist, including an [alpha1(V)alpha2(V)alpha3(V)] form, an alpha1(V)(3) homotrimer and hybrid type V/XI forms. The functional role and fibrillar organization of these isoforms is not understood. In the cornea, type V collagen has a key role in the regulation of initial fibril assembly. Type I and type V collagen co-assemble into heterotypic fibrils. The entire triple-helical domain of the type V collagen molecules is buried within the fibril and type I collagen molecules are present along the fibril surface. The retained NH(2)-terminal domains of the type V collagen are exposed at the surface, extending outward through the gap zones. The molecular model of the NH(2)-terminal domain indicates that the short alpha helical region is a flexible hinge-like region allowing the peptide to project away from the major axis of the molecule; the short triple-helical regions serve as an extension through the hole zone, placing the tyrosine-rich domain at the surface. The assembly of early, immature fibril intermediates (segments) is regulated by the NH(2)-terminal domain of type V collagen. These NH(2)-terminal domains alter accretion of collagen molecules onto fibrils and therefore lateral growth. A critical density would favor the initiation of new fibrils rather than the continued growth of existing fibrils. Other type V collagen isoforms are likely to have an important role in non-cornea tissues. This role may be mediated by supramolecular aggregates different from those in the corneal stroma or by an alteration of the interactions mediated by tissue-specific type V collagen domains generated by different isoforms or aggregate structures. Presumably, the aggregate structure or specific domains are involved in the regionalization of fibril-associated macromolecules necessary for the tissue-specific regulation of later fibril growth and matrix assembly stages.

Differential expression of lumican and fibromodulin regulate collagen fibrillogenesis in developing mouse tendons.

Collagen fibrillogenesis is finely regulated during development of tissue-specific extracellular matrices. The role(s) of a leucine-rich repeat protein subfamily in the regulation of fibrillogenesis during tendon development were defined. Lumican-, fibromodulin-, and double-deficient mice demonstrated disruptions in fibrillogenesis. With development, the amount of lumican decreases to barely detectable levels while fibromodulin increases significantly, and these changing patterns may regulate this process. Electron microscopic analysis demonstrated structural abnormalities in the fibrils and alterations in the progression through different assembly steps. In lumican-deficient tendons, alterations were observed early and the mature tendon was nearly normal. Fibromodulin-deficient tendons were comparable with the lumican-null in early developmental periods and acquired a severe phenotype by maturation. The double-deficient mice had a phenotype that was additive early and comparable with the fibromodulin-deficient mice at maturation. Therefore, lumican and fibromodulin both influence initial assembly of intermediates and the entry into fibril growth, while fibromodulin facilitates the progression through growth steps leading to mature fibrils. The observed increased ratio of fibromodulin to lumican and a competition for the same binding site could mediate these transitions. These studies indicate that lumican and fibromodulin have different developmental stage and leucine-rich repeat protein specific functions in the regulation of fibrillogenesis.

Corneal opacity in lumican-null mice: defects in collagen fibril structure and packing in the posterior stroma.

PURPOSE: Gene targeted lumican-null mutants (lum(tm1sc)/lum(tm1sc)) have cloudy corneas with abnormally thick collagen fibrils. The purpose of the present study was to analyze the loss of transparency quantitatively and to define the associated corneal collagen fibril and stromal defects. METHODS: Backscattering of light, a function of corneal haze and opacification, was determined regionally using in vivo confocal microscopy in lumican-deficient and wild-type control mice. Fibril organization and structure were analyzed using transmission electron microscopy. Biochemical approaches were used to quantify glycosaminoglycan contents. Lumican distribution in the cornea was elucidated immunohistochemically. RESULTS; Compared with control stromas, lumican-deficient stromas displayed a threefold increase in backscattered light with maximal increase confined to the posterior stroma. Confocal microscopy through-focusing (CMTF) measurement profiles also indicated a 40% reduction in stromal thickness in the lumican-null mice. Transmission electron microscopy indicated significant collagen fibril abnormalities in the posterior stroma, with the anterior stroma remaining relatively unremarkable. The lumican-deficient posterior stroma displayed a pronounced increase in fibril diameter, large fibril aggregates, altered fibril packing, and poor lamellar organization. Immunostaining of wild-type corneas demonstrated high concentrations of lumican in the posterior stroma. Biochemical assessment of keratan sulfate (KS) content of whole eyes revealed a 25% reduction in KS content in the lumican-deficient mice. CONCLUSIONS: The structural defects and maximum backscattering of light clearly localized to the posterior stroma of lumican-deficient mice. In normal mice, an enrichment of lumican was observed in the posterior stroma compared with that in the anterior stroma. Taken together, these observations indicate a key role for lumican in the posterior stroma in maintaining normal fibril architecture, most likely by regulating fibril assembly and maintaining optimal KS content required for transparency.

Expression of type XIV collagen in developing chicken tendons: association with assembly and growth of collagen fibrils.

Collagen fibril assembly is a multistep process involving multiple macromolecular interactions. Type XIV collagen contains multiple domains and is capable of interacting with collagen fibrils and other extracellular matrix components. During tendon development, naturally changing expression of type XIV collagen and its variants may modulate such interactions. Type XIV collagen was studied using immunochemical and molecular approaches. Western analysis demonstrated that type XIV collagen content was high between days 14 and 19, decreasing sharply at hatching. Immunoelectron microscopy demonstrated that type XIV collagen was fibril-associated, with a periodicity of 67 nm, indicating specific interactions. Decreased fibril-associated reactivity for type XIV collagen was seen at hatching, indicating a removal of collagen XIV from the fibril surface. The expression of two NC1 splice variants was analyzed. Overall, type XIV collagen mRNA decreased significantly from day 14 to hatching. The long NC1 splice variant was the predominant species at 14 days; at 19 days the two variants were expressed in lower amounts at nearly a 1:1 ratio; at hatching, both variants were expressed minimally. Changes in splice variant expression, suggest that different functional forms of type XIV collagen are present, allowing modified interactions with fibrils during development. In conclusion, type XIV collagen is fibril-associated and developmentally regulated. Modulation of expression of the NC1 splice variants may mediate the fibril interactions that allow the transition from growing fibril intermediates to mature fibrils.

Thrombospondin 2 modulates collagen fibrillogenesis and angiogenesis.

Thrombospondin 2 (TSP2)-null mice, generated by targeted disruption of the Thbs2 gene, display a complex phenotype that is characterized, in part, by a variety of connective tissue abnormalities and increased vascular density in skin and subcutaneous tissues. In this paper we summarize the evidence that TSP2 functions as a matricellular protein to influence cell function by modulating cell-matrix interactions, rather than acting as an integral component of the matrix. Thus, the structurally abnormal collagen fibrils detected in skin appear to be the consequence of the defective adhesion demonstrated by dermal fibroblasts in culture that, in turn, result from increased matrix metalloproteinase 2 (MMP2, gelatinase A) production by these cells. Corroborating evidence for such a mode of action comes from transmission electron microscopic images of developing flexor muscle tendons that show distinct abnormalities in fibroblast-collagen fibril interactions in TSP2-null tissue. The increased vascular density seen in skin of TSP2-null mice can be reproduced in a number of models of injury, including subcutaneous implantation of polyvinyl alcohol sponges and silicone rubber discs, and excisional skin wounds. Experiments are proposed to distinguish between a primarily endothelial cell versus an extracellular matrix origin for the increased angiogenesis in TSP2-null mice.

Complete primary structure of the chicken alpha1(V) collagen chain.

Chicken alpha1(V) collagen cDNAs have been cloned by a variety of methods and positively identified. We present here the entire translated sequence of the chick polypeptide and compare selected regions to other collagen chains in the type V/XI family.

Altered corneal stromal matrix organization is associated with mucopolysaccharidosis I, III and VI.

The presence of cloudy corneas is a prominent feature of mucopolysaccharidosis (MPS) types I and VI, but not MPS IIIA or IIIB. The cause of corneal cloudiness in MPS I and VI is speculative. Transparency of the cornea is dependent on the uniform diameter and the regular spacing and arrangement of the collagen fibrils within the stroma. Alterations in the spacing of collagen fibrils in a variety of conditions including corneal edema, scars, and macular corneal dystrophy is clinically manifested as corneal opacity. The purpose of this study was to compare the structural organization of the stromal extracellular matrix of normal corneas with that of MPS corneas. The size and arrangement of collagen fibrils in cloudy corneas from patients with MPS I were examined. The alterations observed were an increased mean fibril diameter with a broader distribution in the MPS corneas. The MPS I corneas also had altered fibril spacing and more irregular packing compared with normal control corneas. The clear corneas of patients with MPS IIIA and IIIB also showed increases in mean fibril diameter and fibril spacing. However, there was less variation indicating more regularity than seen in MPS I. In addition, corneas from cat models of certain MPS were compared to the human corneas. Cats with MPS I and VI, as well as normal control cats, were examined. Structural alterations comparable to those seen in human MPS corneas were seen in MPS I and VI cats relative to normal clear corneas. The findings suggest that cloudy corneas in MPS I and VI are in part a consequence of structural alterations in the corneal stroma, including abnormal spacing, size, and arrangement of collagen fibrils.

Mice lacking matrilin-1 (cartilage matrix protein) have alterations in type II collagen fibrillogenesis and fibril organization.

Matrilin-1 (cartilage matrix protein) is a homotrimeric protein that forms collagen-dependent and collagen-independent fibrils in the extracellular matrix of cartilage. In the growth plate of developing long bones, the gene for matrilin-1 is transcribed exclusively by the chondrocytes of the zone of maturation which is situated between the zones of proliferation and hypertrophy. When associated with the cartilage collagen fibril, which consists of collagens type II, IX, and XI, matrilin-1 displays a periodicity of 59.3 nm. Matrilin-1 also interacts with the proteoglycan, aggrecan. Because of its association with the collagen fibril, we tested the hypothesis that matrilin-1 may play a role in collagen fibril formation and cartilage matrix assembly by generating mice with targeted mutations in the matrilin-1 gene. Ultrastructural studies of the cartilage of growth plates of matrilin-1 null mice reveal an abnormal type II collagen fibrillogenesis and fibril organization in the matrix of the zone of maturation. These results represent the first report on the regulation of the heterotypic type II collagen fibril by a non-collagenous protein. The abnormal fibrillogenesis had no obvious effects on skeletal development, on the organization of chondrocytes in the growth plate and on the deposition of aggrecan and the hypertrophic-specific type X collagen in the cartilaginous matrix.

Development and roles of collagenous matrices in the embryonic avian cornea.

Corneal development requires the production, assembly and sometimes replacement of a number of collagenous matrices. The embryonic chick cornea is well-characterized and offers certain advantages for studying the assembly and roles of these matrices. We will first describe the matrices to be examined. These include the corneal stroma proper, first formed as the primary stroma and subsequently as the secondary (mature) stroma; Bowman's Membrane; Descemet's Membrane; and the hemidesmosome of the epithelial cell attachment complex. We will then describe the characteristics of the collagen types involved, including: the fibrillar collagens (types I, II and V), the fibril-associated collagens (types IX, XII and XIV), and the transmembrane collagen of the hemidesmosome (type XVII). Then, in each subsequent section we will examine in detail the structure, assembly and development of each collagenous matrix, and how each specific collagen and/or combination of collagens are thought to provide the matrices with their unique properties. The work and views presented here are largely from our own laboratories. Thus, this article is not meant to be a comprehensive review of the literature. For pertinent references by others, when possible, we will cite recent reviews.

Nuclear ferritin protects DNA from UV damage in corneal epithelial cells.

Previously, we identified the heavy chain of ferritin as a developmentally regulated nuclear protein of embryonic chicken corneal epithelial cells. The nuclear ferritin is assembled into a supramolecular form indistinguishable from the cytoplasmic form of ferritin found in other cell types and thus most likely has iron-sequestering capabilities. Free iron, via the Fenton reaction, is known to exacerbate UV-induced and other oxidative damage to cellular components, including DNA. Since corneal epithelial cells are constantly exposed to UV light, we hypothesized that the nuclear ferritin might protect the DNA of these cells from free radical damage. To test this possibility, primary cultures of cells from corneal epithelium and stroma, and from skin epithelium and stroma, were UV irradiated, and DNA strand breaks were detected by an in situ 3'-end labeling method. Corneal epithelial cells without nuclear ferritin were also examined. We observed that the corneal epithelial cells with nuclear ferritin had significantly less DNA breakage than other cell types examined. Furthermore, increasing the iron concentration of the culture medium exacerbated the generation of UV-induced DNA strand breaks in corneal and skin fibroblasts, but not in the corneal epithelial cells. Most convincingly, corneal epithelial cells in which the expression of nuclear ferritin was inhibited became much more susceptible to UV-induced DNA damage. Therefore, it seems that corneal epithelial cells have evolved a novel, nuclear ferritin-based mechanism for protecting their DNA against UV damage.

Altered wound healing in mice lacking a functional osteopontin gene (spp1).

Osteopontin (OPN) is an arginine-glycine-aspartate (RGD)- containing glycoprotein encoded by the gene secreted phosphoprotein 1 (spp1). spp1 is expressed during embryogenesis, wound healing, and tumorigenesis; however, its in vivo functions are not well understood. Therefore, OPN null mutant mice were generated by targeted mutagenesis in embryonic stem cells. In OPN mutant mice, embryogenesis occurred normally, and mice were fertile. Since OPN shares receptors with vitronectin (VN), we tested for compensation by creating mice lacking both OPN and VN. The double mutants were also viable, suggesting that other RGD-containing ligands replace the embryonic loss of both proteins. We tested the healing of OPN mutants after skin incisions, where spp1 was upregulated as early as 6 h after wounding. Although the tensile properties of the wounds were unchanged, ultrastructural analysis showed a significantly decreased level of debridement, greater disorganization of matrix, and an alteration of collagen fibrillogenesis leading to small diameter collagen fibrils in the OPN mutant mice. These data indicate a role for OPN in tissue remodeling in vivo, and suggest physiological functions during matrix reorganization after injury.

Identification and functional characterization of two type VI collagen receptors, alpha 3 beta 1 integrin and NG2, during avian corneal stromal development.

PURPOSE: The development and maintenance of extracellular matrix architecture in the corneal stroma is associated with abundant type VI collagen deposition. This collagen has been implicated in mediating both cell-matrix and matrix-matrix interactions. Although corneal fibroblasts spread extensively on this collagen, its role in corneal development has not been elucidated. METHODS: To clarify the role of this collagen, two type VI collagen receptors were studied during corneal development using immunochemical techniques: alpha 3 beta 1 integrin and an integral membrane proteoglycan, NG2. RESULTS: At embryonic day 6, these receptors were present in a diffuse pattern on cells within the cornea and juxtacorneal regions, indicating a migratory phenotype. At embryonic day 14, when the stroma is fully differentiated, alpha 3 and NG2 were localized in a punctate pattern on a subset of corneal fibroblasts, whereas beta 1 was more ubiquitously expressed. Colocalization of NG2 and type VI collagen indicated that this collagen was present and punctate in its organization was associated with NG2-positive cells. Immunochemical analyses at embryonic days 5 and 14 revealed alpha 3 and beta 1 at 155 kDa and 120 kDa, respectively, and demonstrated that these subunits were interacting to form a heterodimer. NG2 was present with a core protein of 330 kDa and an intact proteoglycan of approximately 600 kDa, and analysis of stromal lysates indicated a chondroitin sulfate-containing proteoglycan. Matrix-receptor cross-linking demonstrated the interaction of beta 1 and NG2 in periocular mesenchyme cells and corneal fibroblasts with type VI collagen, whereas only a subset of cells expressed alpha 3, indicating the presence of another beta 1 integrin. No variations between in vivo and in vitro expression of either alpha 3 beta 1 or NG2 were observed. CONCLUSIONS: These data indicate that two receptors for type VI collagen, alpha 3 beta 1 and NG2, are present during corneal stromal development, with a functional interaction of these receptors with type VI collagen. These interactions may play a role in corneal cell migration, development, and maintenance of corneal architecture.

Differential expression of genes associated with collagen fibril growth in the chicken tendon: identification of structural and regulatory genes by subtractive hybridization.

Collagen fibril growth is a very rapid and abrupt process, resulting in a 4- to 5-fold increase in fibril length between 16 and 18 days of chicken metatarsal tendon development. This fibril growth is due to a postdepositional fusion/association of preformed intermediates, termed fibril segments. We propose that the regulated assembly of collagen fibrils from the segment intermediates is mediated by interactions of structural macromolecules. The cells could modulate this process by responding to cytokines and altering cell-matrix signaling, transcription, and translation. To identify the genes involved in this process a subtractive hybridization procedure was utilized. Genes of cell proliferation were excluded as major contributors to differential gene expression in avian tendon on days 14 and 19 of development after analysis of BrdUr incorporation. The BrdUr incorporation studies revealed little, if any, tendon fibroblast proliferation at both stages. This suggested that observed alterations in gene expression would be related to the pre- and postfibril growth phases in developing tendons. A total of 80 unique up- and down-regulated cDNA fragments were isolated and 26 of these were identified. There was an up-regulation of structural proteins (for example, collagen types I, VI, and XI and fibromodulin), a number of regulatory proteins (including TGF-beta 2 and IGF-1), as well as other enzymes/proteins. Northern analysis confirmed the up-regulation of mRNAs for all the structural proteins. The observed 20-fold increase of mRNA for the isolated clone corresponding to the 3' UTR of alpha 1(VI) collagen makes it a possible marker for the postfibril growth stage of collagen fibrillogenesis. The large number of isolated genes differentially expressed during the rapid phase of fibril growth reveals a fine and possibly tissue-specific control of fibrillogenesis.

Ferritin is a developmentally regulated nuclear protein of avian corneal epithelial cells.

Previously, we generated monoclonal antibodies against chicken corneal cells (Zak, N. B., and Linsenmayer, T. F. (1983) Dev. Biol. 99, 373). We have now observed that one group of these antibodies reacts with a developmentally regulated component of corneal epithelial cell nuclei. This component is the heavy chain of ferritin, as determined by analyses of immunoisolated cDNA clones and immunoblotting of the protein. Immunoblotting also suggests that the nuclear ferritin may be in a supramolecular form that is similar to the iron-binding ferritin complex found in the cytoplasm of many cells. In vitro cultures and transfection studies show that the nuclear localization depends predominantly on cell type but can be altered by the in vitro environment. The appearance of nuclear ferritin is at least partially under translational regulation, as is known to be true for the cytoplasmic form of the molecule. The tissue and developmental distributions of the mRNA for the molecule are much more extensive than the protein itself, and the removal of iron from cultures of corneal epithelial cells with the iron chelator deferoxamine prevents the appearance of nuclear ferritin. At present the functional role(s) of nuclear ferritin remain unknown, but previous studies on cytoplasmic ferritin raise the possibility that it prevents damage due to free radical generation ("oxidative stress") by sequestering iron. Although it remains to be tested whether nuclear ferritin prevents oxidative damage, we find this an attractive possibility. Since the corneal epithelium is transparent and is constantly exposed to free radical-generating UV light, it is possible that the cells of this tissue have evolved a specialized mechanism to prevent oxidative damage to their nuclear components.