The type X collagen gene. Intron sequences split the 5'-untranslated region and separate the coding regions for the non-collagenous amino-terminal and triple-helical domains

Type X collagen, expressed by hypertrophic chondrocytes, consists of homotrimeric molecules with subunits that are only about one-half the size of the polypeptides of fibrillar collagens. In this report we describe for the first time the complete primary structure of type X collagen, based on cloning and sequencing of cDNA and genomic DNA. A comparison between the nucleotide sequences of the cDNA and genomic DNA clones has also allowed determination of the complete exon structure of the type X collagen gene. Our results demonstrate that the primary translation product of the chicken type X collagen mRNA is 682 amino acid residues long with a calculated molecular mass of 67,317 Da for the nonhydroxylated form. This calculated molecular mass is in excellent agreement with the observed electrophoretic mobility of cell-free translation products with both poly(A)+ RNA isolated from chondrocytes as well as RNA transcribed in vitro from a full length cDNA construct. It is also in agreement with the observed size of type X collagen polypeptides isolated from the media of cultured hypertrophic chondrocytes. Thus, our data exclude the possibility of a high molecular weight precursor form of type X collagen. Our results also confirm that the chicken type X gene has a most unusual exon structure when compared to other vertebrate collagen genes. The gene has only three exons. One exon (97 base pairs (bp)), codes for most of the 5'-untranslated region of the mRNA, a second exon (159 bp) codes for the signal peptide and a short non-triple-helical domain, while the third exon (2136 bp) contains the coding region for the entire triple-helix and a large non-triple-helical carboxyl domain.     

The crystal at 5.5A resolution of an acid-protease from Rhizopus chinensis.

An electron density map for the pepsin-like enzyme from Rhizopus chinensis has been calculated at 5.5Å resolution. The molecular boundary has been defined and certain secondary structural details have been inferred. The molecule is bilobal and has a large cleft in which several inhibitors have been observed to bind.     

Structural organization of collagen in Metridium senile

The structure and distribution of collagen fibres in Metridium senile mesoglea has been investigated using high and small angle X-ray diffraction techniques on conventional and synchrotron sources. The mesoglea collagen axial spacing appears very close to that of rat tail tendon, which is at variance with the values previously obtained from electron microscopic observations. The different intensity distribution of the small angle X-ray diffraction maxima recorded for mesoglea and rat tail tendon indicates a different distribution of electron density inside the repeating period. Furthermore the absence of the first order, the weak second order and the strong third and sixth orders in the patterns of wet and dry mesogleal collagen could explain that only a periodicity of 20–22 nm corresponding to one-third of the true axial period observed in the electron micrographs. The analysis of the reflections at 0.29 and 1.1–1.4 nm characteristics of the collagen molecular structure have been used to determine the distribution and orientation of the collagen fibres in unstretched and stretched samples     

Complete primary structure and genomic organization of the mouse Col14a1 gene.

The entire mouse cDNA sequence for type XIV collagen was determined using overlapping PCR products. The 6456 nucleotide (nt) cDNA sequence contains a 5391-nt open reading frame encoding 1797 amino acid residues. The amino terminus has a 28-residue signal peptide that is followed by the mature polypeptide of 1769 amino acid residues with a calculated molecular mass of 193.2 kDa. The mouse alpha1(XIV) collagen chain is predicted to contain all the structural domains described for the polypeptide in chicken and human. These include fibronectin type III repeats, von Willebrand factor A domains, thrombospondin-N-terminal-like domains and two triple-helical domains similar to those of other collagen family members. The amino acid residue sequence of human alpha1(XIV) collagen showed an overall identity of 74% to the chicken sequence and 88% to the human sequence. The entire mouse genomic structure has been determined and is made up of 48 exons. Alternatively spliced forms of mouse type XIV, collagen were not identified corresponding to the findings for the human form.     

Complete primary structure and genomic organization of the mouse Col14a1 gene.

The entire mouse cDNA sequence for type XIV collagen was determined using overlapping PCR products. The 6456 nucleotide (nt) cDNA sequence contains a 5391-nt open reading frame encoding 1797 amino acid residues. The amino terminus has a 28-residue signal peptide that is followed by the mature polypeptide of 1769 amino acid residues with a calculated molecular mass of 193.2 kDa. The mouse alpha1(XIV) collagen chain is predicted to contain all the structural domains described for the polypeptide in chicken and human. These include fibronectin type III repeats, von Willebrand factor A domains, thrombospondin-N-terminal-like domains and two triple-helical domains similar to those of other collagen family members. The amino acid residue sequence of human alpha1(XIV) collagen showed an overall identity of 74% to the chicken sequence and 88% to the human sequence. The entire mouse genomic structure has been determined and is made up of 48 exons. Alternatively spliced forms of mouse type XIV, collagen were not identified corresponding to the findings for the human form.     

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

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

X-ray diffraction analysis of collagen fibers processed with glutaraldehyde and glycerol

Rat tail tendon collagen fixed with glutaraldehyde and treated with glycerol has been studied by X-ray diffraction technique. The evaluation of the distribution of the areas at higher and less density of molecular packing in the collagen fibrils has been carried out through the analysis of the intensity distribution of the low angle X-ray diffraction maxima. The results show that this treatment usually employed in the freeze-etching technique induces a modification of the degree of order in specific regions inside the axial period D.     

Structural modifications of air-dried tendon collagen on heating

The modification of collagen molecular packing as a function of the removal of bound and structural water have been investigated on air-dried rat tail tendon. Isothermal curves, dilatometric measurement, high and small angle X-ray diffraction patterns—recorded using conventional and synchrotron radiaiton sources respectively—have been obtained on samples heated in air at different temperatures up to 200°C. A shortening of collagen intermolecular distances and slight modifications of quaternary structure and fibre dimensions can be observed during the release of bound water. The removal of structural water is accompanied by disordering of the three polypeptide chains, a strong reduction of fibre length and d-axial spacing, and modifications of the electron density distribution inside the repeating period. The structural modifications observed during the removal of bound water and of most of the structural water, obtained on heating, are reversible. Release of the most lightly bound water, probably associated with the beginning of the depolymerization process, induces irreversible modification of the molecular packing.     

Factors controlling the rhythmic contraction of collagen gels by neonatal heart cells

Summary A floating collagen matrix culture of neonatal rat heart myocardial cells shows rhythmic contractions which are dependent on localization of cells, cell density, and collagen concentration. The rhythmic contractions of the collagen matrix can be registered by a device scanning the optical density at the edge of the gel and have been observed over a temperature range from 9° to 40° C. The results of the present study underline the usefulness of myocardial cell populated collagen matrixes for studies on coherent contractions of heart cell cultures.     

Interpretation of the meridional X-ray diffraction pattern from collagen fibrils in corneal stroma

The low angle X-ray diffraction pattern from corneal stroma can be interpreted as arising from the equivalent of sharp meridional reflections due to the packing of molecules along the collagen fibrils and an equatorial pattern due to the packing of these fibrils within lamellae.Axial electron density profiles for corneal collagen fibrils have been produced by combining intensity data from the meridional pattern with two independent sets of phases. The first set was obtained using an electron microscopical technique, whereas the second set consisted of calculated tendon collagen phases given in the literature. Substantial agreement between the two electron density profiles was found.A quantitative analysis of the difference between the electron density profiles of rat tail tendon and corneal collagen showed that the step between the gap and overlap regions is smaller in cornea than in tendon. This is probably due to the binding of non-collagenous material in the gap region as occurs in bone and other tissue. Two peaks corresponding to regions where electron density is greater in the cornea are situated at the gap/overlap junctions. A third region where the corneal collagen is more electron dense is located near the centre of the gap region. The proximity of these peaks to the positions of hydroxylysine residues along the fibril axis suggests that they may be the major sites at which sugars are bound to corneal collagen.     

Solid state 13C NMR study of collagen molecular dynamics in hard and soft tissues

The molecular dynamics of the collagen backbone in intact connective tissues has been elucidated using 13C line shape analysis. Since one-third of the amino acid residues in collagen are glycines, we have labeled: (a) reconstituted lathrytic (uncross-linked) chick calvaria collagen fibrils; (b) rat tail tendon (cross-linked); and (c) rat calvaria (cross-linked and mineralized) collagen with [1-13C]glycine. The proton-enhanced and normal 90 degrees - t proton-decoupled spectrum of each collagen sample shows an asymmetric chemical shift powder pattern for the glycine carbonyl carbon. The powder line width, delta, (delta = sigma zz - sigma xx) at 22 degrees C for the uncross-linked reconstituted collagen fibril is 108 ppm, whereas the maximum value of delta (140 ppm) is observed for the cross-linked and mineralized collagen fibrils in rat calvaria. The powder line widths for the cross-linked fibrils in tail tendons and demineralized calvaria are 124 and 120 ppm, respectively. However, since the same line shape and line width (145 ppm) are observed for all samples at -35 degrees C, the difference in delta values observed at room temperature is attributed to differences in molecular mobility of collagen in various samples. The line shapes are analyzed using a dynamic model in which azimuthal orientation of the collagen backbone is assumed to fluctuate as a consequence of reorientation about the helix axis. The observed line shapes are sensitive to motions having correlation times less than approximately 10(-4) s and the analysis provides the values of the root mean square fluctuation in azimuthal angle, gamma rms, due to such motions. It is found that gamma rms equals 41 degrees, 33 degrees, and 14 degrees for the uncross-linked, cross-linked, and mineralized collagens, respectively. These results provide the first information about the extent that cross-linking and mineralization restrict molecular motion in collagen.     

The molecular and fibrillar structure of collagen and its relationship to the mechanical properties of connective tissue

The conformation of type I collagen molecules has been refined using a linked-atom least-squares procedure in conjunction with high-quality X-ray diffraction data. In many tendons these molecules pack in crystalline arrays and a careful measurement of the positions of the Bragg reflections allows the unit cell to be determined with high precision. From a further analysis of the X-ray data it can be shown that the highly ordered overlap region of the collagen fibrils consists of a crystalline array of molecular segments inclined by a small angle with respect to the fibril axis. In contrast, the gap region is less well ordered and contains molecular segments that are likely to be inclined by a similar angle but in a different vertical plane to that found in the overlap region. The collagen molecule thus has a D-periodic crimp in addition to the macroscopic crimp observed visually in the collagen fibres of many connective tissues. The growth and development of collagen fibrils have been studied by electron microscopy for a diverse range of connective tissues and the general pattern of fibril growth has been established as a function of age. In particular, relationships between fibril size distribution, the content and composition of the glycosaminoglycans in the matrix and the mechanical role played by the fibrils in the tissue have been formulated and these now seem capable of explaining many new facets of connective tissue structure and function.     

Partially systematic molecular packing in the hexagonal columnar phase of dogfish egg case collagen.

The collagen that forms the egg case of the dogfish Scyliorhinus canicula is stored in bulk in the female nidamental glands. Here the collagen molecules are thought to undergo a series of distinct pH-dependent liquid crystalline aggregation phase changes before assembling into the final arrangement encountered in the mature egg case. One liquid crystalline phase is hexagonal with the centres of two adjacent hexagons about 36 nm apart. We have collected tilt series of the hexagonal phase from plastic sections of the nidamental gland and have produced a three-dimensional reconstruction of the collagen arrangement of this phase. The reconstruction features axial columns of protein density lying regularly on the vertices of hexagonal cells of edge length 21 nm. Each column is connected to three nearest neighbours by irregular sheets of protein, but there appear to be preferred molecular directions at about 40 degrees to 50 degrees to the columns. The reconstruction has been interpreted in terms of known interactions of this collagen in other assemblies.     

Are the changes in collagen caused by chronical X-irradiation similar to aging?

It has been shown that in the skin of chronically irradiated rats the proportion of collagen type III as compared to collagen type I is increased; on the other hand, no changes in the overall proportion to collagen were observed in the skin. It appears that the increased proportion of collagen type III in chronically irradiated rats is responsible for the decreased solubility of cutaneous collagen in these animals. Concomitantly, indirect evidence was accumulated for the presence of an additional cross-link in type III collagen, present only when irradiated animals served as the collagen source. This cross-link is located subterminally as long as it is not removed by limited pepsin digestion. It was concluded that the physiological decrease in solubility and the decrease in solubility observed in chronically irradiated animals have a different molecular background.     

Dermal and epidermal response to soft-tissue expansion in the pig

To evaluate the dermal and epidermal response to soft-tissue expansion in the pig, round tissue expanders were placed dorsally under tattooed patterns and inflated over 6 weeks. Surface area, skin thickness, histologic changes, and collagen content were evaluated at 6-week intervals. Epidermal thickening and dermal thinning were observed. Dermal thinning persisted 36 weeks after expansion. Dermal collagen content was decreased, although collagen density remained unchanged. Total collagen content calculated within an expanded square grid increased. These data support a theoretical gain in the dermal layer as well as epidermal layer in response to tissue expansion.     

Dependence of thermal stability on the number of hydrogen bonds in water-bridged collagen structure

The probable number of hydrogen bonds has been calculated as a function of the imino acid content for water-bridged collagen structures. With increasing imino acid content in collagen, the number of hydrogen bonds stabilizing triple-helical structures become saturation. This might explain the asymptotic character of the empirical relation between thermostability and hydroxyproline content for collagen.     

Changes in monoclonal antibody productivity of recombinant BHK cells immobilized in collagen gel particles

Animal cell perfusion high density culture is often adopted for the production of biologicals in industry. In high density culture sometimes the productivity of biologicals has been found to be enhanced. Especially in immobilized animal cell culture, significant increase in the productivity has been reported. We have found that the specific monoclonal antibody (MAb) productivity of an immobilized hybridoma cell is enhanced more than double. Several examples of enhancing productivities have been also shown by collagen immobilized cells. Immobilized cells involve some different points from non-immobilized cells in high density culture: In immobilized culture, some cells are contacted together, resulting in locally much higher cell concentration more than 10⁸ cells/ml. Information originating from a cell can be easily transduced to the others in immobilized culture because the distance between cells is much nearer. Here we have performed collagen gel immobilized culture of recombinant BHK cells which produce a human IgG monoclonal antibody in a protein-free medium for more than three months. In this high density culture a stabilized monoclonal antibody production was found with around 8 times higher specific monoclonal antibody productivity compared with that in a batch serum containing culture. No higher MAb productivity was observed using a conditioned medium which was obtained from the high density culture, indicating that no components secreted from the immobilized cells work for enhancing monoclonal antibody production. The MAb productivity by the non-immobilized cells obtained by dissolving collagen using a collagenase gradually decreased and returned to the original level in the batch culture using a fresh medium. This suggests that the direct contact of the cells or a very close distance between the cells has something to do with the enhancement of the MAb productivity, and the higher productivity is kept for a while in each cell after they are drawn apart.     

Microstructural Modeling of Collagen Network Mechanics and Interactions with the Proteoglycan Gel in Articular Cartilage

Cartilage matrix mechanical function is largely determined by interactions between the collagen fibrillar network and the proteoglycan gel. Although the molecular physics of these matrix constituents have been characterized and modern imaging methods are capable of localized measurement of molecular densities and orientation distributions, theoretical tools for using this information for prediction of cartilage mechanical behavior are lacking. We introduce a means to model collagen network contributions to cartilage mechanics based upon accessible microstructural information (fibril density and orientation distributions) and which self-consistently follows changes in microstructural geometry with matrix deformations. The interplay between the molecular physics of the collagen network and the proteoglycan gel is scaled up to determine matrix material properties, with features such as collagen fibril pre-stress in free-swelling cartilage emerging naturally and without introduction of ad hoc parameters. Methods are developed for theoretical treatment of the collagen network as a continuum-like distribution of fibrils, such that mechanical analysis of the network may be simplified by consideration of the spherical harmonic components of functions of the fibril orientation, strain, and stress distributions. Expressions for the collagen network contributions to matrix stress and stiffness tensors are derived, illustrating that only spherical harmonic components of orders 0 and 2 contribute to the stress, while orders 0, 2, and 4 contribute to the stiffness. Depth- and compression-dependent equilibrium mechanical properties of cartilage matrix are modeled, and advantages of the approach are illustrated by exploration of orientation and strain distributions of collagen fibrils in compressed cartilage. Results highlight collagen-proteoglycan interactions, especially for very small physiological strains where experimental data are relatively sparse. These methods for determining matrix mechanical properties from measurable quantities at the microscale (composition, structure, and molecular physics) may be useful for investigating cartilage structure-function relationships relevant to load-bearing, injury, and repair.