Type III collagen can be present on banded collagen fibrils regardless of fibril diameter

Monoclonal antibodies that recognize an epitope within the triple helix of type III collagen have been used to examine the distribution of that collagen type in human skin, cornea, amnion, aorta, and tendon. Ultrastructural examination of those tissues indicates antibody binding to collagen fibrils in skin, amnion, aorta, and tendon regardless of the diameter of the fibril. The antibody distribution is unchanged with donor age, site of biopsy, or region of tissue examined. In contrast, antibody applied to adult human cornea localizes to isolated fibrils, which appear randomly throughout the matrix. These studies indicate that type III collagen remains associated with collagen fibrils after removal of the amino and carboxyl propeptides, and suggests that fibrils of skin, tendon, and amnion (and presumably many other tissues that contain both types I and III collagens) are copolymers of at least types I and III collagens.     

Collagen type I and type V are present in the same fibril in the avian corneal stroma

The distribution, supramolecular form, and arrangement of collagen types I and V in the chicken embryo corneal stroma were studied using electron microscopy, collagen type-specific monoclonal antibodies, and a preembedding immunogold method. Double-label immunoelectron microscopy with colloidal gold-tagged monoclonal antibodies was used to simultaneously localize collagen type I and type V within the chick corneal stroma. The results definitively demonstrate, for the first time, that both collagens are codistributed within the same fibril. Type I collagen was localized to striated fibrils throughout the corneal stroma homogeneously. Type V collagen could be localized only after pretreatment of the tissue to partially disrupt collagen fibril structure. After such pretreatments the type V collagen was found in regions where fibrils were partially dissociated and not in regions where fibril structure was intact. When pretreated tissues were double labeled with antibodies against types I and V collagen coupled to different size gold particles, the two collagens colocalized in areas where fibril structure was partially disrupted. Antibodies against type IV collagen were used as a control and were nonreactive with fibrils. These results indicate that collagen types I and V are assembled together within single fibrils in the corneal stroma such that the interaction of these collagen types within heterotypic fibrils masks the epitopes on the type V collagen molecule. One consequence of the formation of such heterotypic fibrils may be the regulation of corneal fibril diameter, a condition essential for corneal transparency.     

In Vitro Fabrication and Physicochemical Properties of a Hybrid Fibril from Xenogeneic Collagens

A Hybrid collagen fibril (HCF) assembled from xenogeneic collagens is a special kind of collagen fibrils in vivo and plays an important role in living systems. Inspired by nature, can a HCF form in vitro? Herein, we fabricated a new HCF by neutralizing a mixture of type I bullfrog (Rana catesbeiana Shaw) skin collagen and porcine (Sus scrofa domesticus) skin collagen with a phosphate buffer, and investigated its physicochemical properties. Self-assembly kinetics and fluorescence-quenching experiments showed that a significant intermolecular interaction and co-assembly behavior occurred between bullfrog skin collagen and porcine skin collagen, thus confirming that xenogeneic collagens can self-assemble to form HCF. Differential scanning calorimetry revealed that the thermal stability of HCF was completely different from that of the syngeneic bullfrog skin and porcine skin collagen fibrils. This finding indicated that a new kind of collagen fibril was fabricated successfully. Scanning electron microscopy and transmission electron microscopy tests showed that the diameters and D-periodicity lengths of HCF were smaller than those of the syngeneic collagen fibrils, suggesting that the morphological features of HCF were distinguished from those of the syngeneic fibril samples. Moreover, viscoelasticity of a collagen gel also changed after the self-assembly of xenogeneic collagens. Meanwhile, the obtained hybrid gel still exhibited good biocompatibility and cell proliferation properties. Finding from this work provides a new idea for the improvement or regulation of collagen-based products performance.     

Role of decorin on in vitro fibrillogenesis of type I collagen

Tendon and corneal decorins are differently iduronated dermatan sulphate/proteoglycan (DS/PG) and the biochemical parameter that differentiates type I collagens is the hydroxylysine glycoside content. We have examined the effect of tendon and corneal decorins on the individual phases (tlag, dA/dt) of differently glycosylated type I collagens fibril formation, at molar ratios PG:collagen monomer ranging from 0.15 : 1 to 0.45 : 1. The results obtained indicate that decorins exert a different effect on the individual phases of fibril formation, correlated to the degree of glycosylation of collagen: at the same PG:collagen ratio the fibril formation of highly glycosylated corneal collagen is more efficiently inhibited than that of the poorly glycosylated one (tendon). Moreover tendon and corneal decorins exert a higher control on the fibrillogenesis of homologous collagen with respect to the heterologous one. These data suggest a possible tissue-specificity of the interaction decorin/type I collagen correlated to the structure of the PG and collagen present in extracellular matrices. This revised version was published online in November 2006 with corrections to the Cover Date.     

Are the polarization colors of Picrosirius red-stained collagen determined only by the diameter of the fibers?

Summary Polarization colors of various purified collagens were studied in fibers of similar thickness. Three different soluble collagens of type I, insoluble collagen type I, lathyritic collagen type I, two p-N-collagens type I, pepsin extract collagen type II, two soluble collagens type III, p-N-collagen type III, and soluble collagen type V were submitted to a routine histopathologic procedure of fixation, preparation of 5-m-thick sections, staining with Picrosirius red and examination under crossed polars. Polarization colors were determined for thin fibers (0.8 m or less) and thick fibers, (1.6–2.4 m). Most thin fibers of collagens and p-N-collagens showed green to yellowish-green polarization collors with no marked differences between the various samples. Thick fibers of all p-N-collagens, lathyritic and normal 0.15 M NaCl-soluble collagens showed green to greenish-yellow polarization colors, while in all other collagens, polarization colors of longer wavelengths (from yellowish-orange to red) were observed. These data suggested that fiber thickness was not the only factor involved in determining the polarization colors of Picrosirius red-stained collagens. Tightly packed and presumably, better aligned collagen molecules showed polarization colors of longer wavelengths. Thus, packing of collagen molecules and not only fiber thickness plays a role in the pattern of polarization colors of Picrosirius red-stained collagens.     

Immunofluorescent localization of collagen types I, II, and III in the embryonic chick eye.

The appearance and distribution of type I, II, and III collagens in the developing chick eye were studied by specific antibodies and indirect immunofluorescence. At stage 19, only type I collagen was detected in the primary corneal stroma, in the vitreous body, and along the lens surface. At later stages, type I collagen was located in the primary and secondary corneal stroma and in the fibrous sclera, but not around the lens. Type II collagen was first observed at stage 20 in the primary corneal stroma, neural retina, and vitreous body. It was particularly prominent at the interface of the neural retina and vitreous body and, from stage 30 on, in the cartilaginous sclera. The primary corneal stroma consisted of a mixture of type I and II collagens between stages 20 and 27. Invasion of the primary corneal stroma by mesenchyme and subsequent deposition of fibroblast-derived collagen corresponded with a pronounced increase of type I collagen, throughout the entire stroma, and of type II collagen, in the subepithelial region. Type II collagen was also found in Bowman's and Descemet's membranes. A transient appearance of type III collagen was observed in the corneal epithelial cells, but not in the stroma (stages 20–30). The fully developed cornea contained both type I and II collagens, but no type III collagen. Type III collagen was prominent in the fibrous sclera, iris, nictitating membrane, and eyelids.     

Corneal and scleral type I collagens: analyses of physical properties and molecular flexibility

The physical properties of type I collagen were studied by electron microscopy of rotary shadowed collagen molecules and laser light scattering techniques. The physical properties, molecular structure and flexibility of type I collagen molecules from two structurally and functionally different connective tissues, cornea and sclera, were similar when measured in HCl, pH 2.0. The molecular weights were 328 and 298 × 10² for corneal and scleral type I collagen, respectively, while the values of T_M were 33.7°C for both preparations. These values were in agreement with those obtained for other type I collagens. The higher level of glycosylation in corneal versus scleral type I collagen did not significantly modify the physical properties of type I collagen in acid solution or the charge distribution along the molecule as determined from the positively stained SLS banding patterns. Our morphological studies indicated that the collagen molecule, although relatively flexible based on electron microscopy, behaved as a long thin rod in solution. The mean end-to-end distances measured from electron micrographs were 253 and 256 nm for corneal and cler type I collagen, respectively, while the molecular contour lengths were 298 and 305 nm. The translational diffusion coefficients (0.849 and 0.857 × 10^?7cm²s^?1) were consistent with the contour lengths while the reported values in the literature for the rotational diffusion coefficient of type I collagen were consistent with the end-to-end distances. The intermediate value for molecular length obtained from the particle scattering factor (277 nm) reflects contributions from all possible molecular configurations.     

Separation of type III collagen from type I collagen and pepsin by differential denaturation and renaturation.

Types I and III collagens were solubilized from fetal human skin by limited digestion with pepsin and precipitated by dialysis against 0.02 M Na₂HPO₄. Heat denaturation of the collagens in 2 M guanidine-HCl, pH 7.5, resulted in the precipitation of the contaminant pepsin which could be removed by centrifugation. Renaturation of the denatured collagens by dialysis against deionized water at 22° for 2 hours selectively precipitated the type III collagen fibrils. Type I collagen remained in solution. The simplicity and high recovery (77%) make this a suitable approach for the rapid estimation of type III collagen in small tissue samples.     

液相色谱/质谱联用法分析不同年龄鼠皮肤中I型、III型胶原蛋白相对含量

哺乳动物皮肤真皮中胶原蛋白含量约为70%,主要为是I型、III型胶原蛋白,本实验利用稀酸溶解和酶法提取了大鼠皮肤中的总胶原蛋白,将胶原蛋白粗提品在60℃变性后用胰蛋白酶进行降解,液相色谱/质谱联用法分析了两种胶原蛋白的特征多肽,利用特征多肽比较了不同生长期大鼠皮肤中I型和III型胶原蛋白相对含量。结果表明,大鼠皮肤中的III型胶原蛋白的相对含量随生长期延长逐渐降低,而I型胶原蛋白的相对含量逐渐升高,8周后两种胶原蛋白的比例趋于稳定。本实验结果表明使用高效液相色谱/质谱联用法分析组织中的胶原蛋白类型及其动态变化具有可行性,为更好的临床应用提供了实验基础。     

Selective decrease of type I collagen synthesis in Fraser mice skin

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

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.     

Copolymerization of normal type I collagen with three mutated type I collagens containing substitutions of cysteine at different glycine positions in the alpha 1 (I) chain.

Previous observations with type I collagen from a proband with lethal osteogenesis imperfecta demonstrated that type I collagen containing a substitution of cysteine for glycine alpha 1-748 copolymerized with normal type I collagen (Kadler, K. E., Torre-Blanco, A., Adachi, E., Vogel, B. E., Hojima, Y., and Prockop, D. J. (1991) Biochemistry 30, 5081-5088). Here, three preparations containing normal type I procollagen and type I procollagen with a substitution of cysteine for glycine alpha 1-175, glycine alpha 1-691, or glycine alpha 1-988 were purified from cultured skin fibroblasts from probands with osteogenesis imperfecta. The procollagens were then used as substrates in a system for assaying the self-assembly of type I collagen into fibrils. The cysteine-substituted collagens in all three preparations were incorporated into fibrils. The cysteine alpha 1-175 and cysteine alpha 1-691 collagens were shown to increase the lag time and decrease the propagation rate constant for fibril assembly. All three preparations containing cysteine-substituted collagens formed fibrils with diameters that were two to four times the diameter of fibrils formed under the same conditions by normal type I collagen. Also, the three preparations containing cysteine substituted collagens had higher solubilities than normal type I collagen. The results, therefore, demonstrated that the three cysteine-substituted collagens copolymerized with normal type I collagen. The effects of the mutated collagens on fibril assembly can be understood in terms of a recently proposed model of fibril growth from symmetrical tips by assuming that the mutated monomers partially inhibit tip growth but not lateral growth of the fibrils. Of special interest was the observation that the Cys alpha 1-175 collagen from a proband with a non-lethal variant of osteogenesis imperfecta had quantitatively less effect on several parameters of fibril assembly at 37 degrees C than cysteine-substituted collagens from three probands with lethal variants of the disease.     

A study of staining for electron microscopy using collagen as a model system—VII. The effect of formaldehyde fixation

Exposure to formaldehyde brings about small but readily detectable changes in the staining behaviour of collagen fibrils. These changes can be interpreted in chemical terms by comparing fibril staining patterns with artificial patterns computer-generated from sequence data. Positive staining with phosphotung-state (where heavy metal is confined to anions), shows that most of the lysyl and hydroxylysyl side-chains lose their charge character as a result of formaldehyde treatment and cease to take up staining ions. The charge character of arginyl (and probably histidyl) residues is unaltered and these residues continue to react with stain. Acidic residues are also unaffected. These results accord with biochemical evidence that the initial reaction between proteins and formaldehyde leading to subsequent cross-linking involves modification of ε-amino (and α-amino) groups. They show too that the secondary condensation producing the actual cross-link does not alter the charge character of the second group, at least when it is on an arginyl (or histidyl) side-chain.Formaldehyde-induced changes in stain deposition can also be detected after negative staining, although they are slight compared with those brought about by glutaraldehyde. Unlike glutaraldehyde, formaldehyde introduces no bulky polymeric adducts into the fibril structure, and the conspicuous stain-excluding bands seen in negative staining patterns following glutaraldehyde fixation are absent after exposure to formaldehyde. For this reason, where chemical fixation is used to stabilize macromolecules and supramolecular aggregates prior to negative staining and high resolution electron optical imaging, formaldehyde would seem to be preferable to glutaraldehyde. Data from fibril staining patterns and from thermal stability measurements (made on collagen gels) show that formaldehyde fixation does not preclude a subsequent reaction with glutaraldehyde.As with other fixatives, there is reduced accessibility to stain after formaldehyde treatment. Accessibility is least in the overlap zone where the denser packing of collagen molecules provides greater opportunities for intermolecular cross-linking. Gel electrophoresis confirms that formaldehyde-induced cross-links in fibrils are predominantly intermolecular.     

MMP-12 catalytic domain recognizes and cleaves at multiple sites in human skin collagen type I and type III

Collagens of either soft connective or mineralized tissues are subject to continuous remodeling and turnover. Undesired cleavage can be the result of an imbalance between proteases and their inhibitors. Owing to their superhelical structure, collagens are resistant to many proteases and matrix metalloproteinases (MMPs) are required to initiate further degradation by other enzymes. Several MMPs are known to degrade collagens, but the action of MMP-12 has not yet been studied in detail. In this work, the potential of MMP-12 in recognizing sites in human skin collagen types I and III has been investigated. The catalytic domain of MMP-12 binds to the triple helix and cleaves the typical sites -Gly₇₇₅-Leu₇₇₆- in α-2 type I collagen and -Gly₇₇₅-Ile₇₇₆- in α-1 type I and type III collagens and at multiple other sites in both collagen types. Moreover, it was observed that the region around these typical sites contains comparatively less prolines, of which some have been proven to be only partially hydroxylated. This is of relevance since partial hydroxylation in the vicinity of a potential scissile bond may have a local effect on the conformational thermodynamics with probable consequences on the collagenolysis process. Taken together, the results of the present work confirm that the catalytic domain of MMP-12 alone binds and degrades collagens I and III.     

Collagen types I, III, and V in human embryonic and fetal skin

The dermis of human skin develops embryonically from lateral plate mesoderm and is established in an adult-like pattern by the end of the first trimester of gestation. In this study the structure, biochemistry, and immunocytochemistry of collagenous matrix in embryonic and fetal dermis during the period of 5 to 26 weeks of gestation was investigated. The dermis at five weeks contains fine, individual collagen fibrils draped over the surfaces of mesenchymal cells. With increasing age, collagen matrix increases in abundance in the extracellular space. The size of fibril diameters increases, and greater numbers of fibrils associate into fiber bundles. By 15 weeks, papillary and reticular regions are recognized. Larger-diameter fibrils, larger fibers, denser accumulations of collagen, and fewer cells distinguish the deeper reticular region from the finer, more cellular papillary region located beneath the epidermis. The distribution of collagen types I, III, and V were studied at the light microscope level by immunoperoxidase staining and at the ultrastructural level by transmission (TEM) and scanning electron microscopy (SEM) with immunogold labeling. By immunoperoxidase, types I and III were found to be evenly distributed, regardless of fetal age, throughout the dermal and subdermal connective tissue with an intensification of staining at the dermal-epidermal junction (DEJ). Staining for types III and V collagen was concentrated around blood vessels. Type V collagen was also localized in basal and periderm cells of the epidermis. By immuno-SEM, types I and III were found associated with collagen fibrils, and type V was localized to dermal cell surfaces and to a more limited extent with fibrils. The results of biochemical analyses for relative amounts of types I, III, and V collagen in fetal skin extracts were consistent with immunoperoxidase data. Type I collagen was 70-75%, type III collagen was 18-21%, and type V was 6-8% of the total of these collagens at all gestational ages tested, compared to 85-90% type I, 8-11% type III, and 2-4% type V in adult skin. The enrichment of both types III and V collagen in fetal skin may reflect in part the proportion of vessel- and nerve-associated collagen versus dermal fibrillar collagen. The accumulation of dermal fibrillar collagen with increasing age would enhance the estimated proportion of type I collagen, even though the ratios of type III to I in dermal collagen fibrils may be similar at all ages.     

Biosynthesis of skin collagens in normal and diabetic mice.

Synthesis of collagens in vitro was studied on minced mouse skins incubated with [3H]-proline in organ-culture conditions. A comparative study was carried out on genetically diabetic mice (KK strain) and control mice (Swiss strain). After incubation, neutral-salt-soluble and acid-soluble collagens were extracted. The insoluble dermis was digested by pepsin and type I and type III collagens separated by differential precipitation in neutral salt solutions. Type I and Type III collagens were characterized by ion-exchange and molecular-sieve chromatography, amino acid analysis and by the characterization of CNBr peptides. In diabetic-mouse skin, the relative proportion of type III collagen was significantly higher than in control-mouse skin. The incorporation of radioactively labelled proline into hydroxyproline of type III collagen was significantly faster in diabetic-mouse skin than in control-mouse skin.No significant modifications in the total collagen content of the skin or of their rates of synthesis were observed between the two strains. Alteration in the ratio of type III to type I collagen in the diabetic-mouse skin can be interpreted as a sign of alteration of the regulation of collagen biosynthesis and may be related to the structural alterations observed in the diabetic intercellular matrix.     

Kinetics of hydrolysis of type I,II, and III collagens by the class I and IIClostridium histolyticum collagenases

The kinetics of hydrolysis of rat tendon type I, bovine nasal septum type II, and human placental type III collagens by class I and class IIClostridium histolyticum collagenases (CHC) have been investigated. To facilitate this study, radioassays developed previously for the hydrolysis of these [³H]acetylated collagens by tissue collagenases have been adapted for use with the CHC. While the CHC are known to make multiple scissions in these collagens, the assays are shown to monitor the initial proteolytic events. The individual kinetic parametersk _cat andK _M have been determined for the hydrolysis of all three collagens by both class I and class II CHC. The specific activities of these CHC toward fibrillar type I and III collagens have also been measured. In contrast to human tissue collagenases, neither class of CHC exhibits a marked specificity toward any collagen type either in solution or in fibrillar form. The values of the kinetic parametersk _cat andK _M for the CHC are similar in magnitude to those of the human enzymes acting on their preferred substrates. Thus, the widely held view that the CHC are more potent collagenases is not strictly correct. As with the tissue collagenases, the local collagen structure at the cleavage sites is believed to play an important role in determining the rates of the reactions studied.     

Candidate cell and matrix interaction domains on the collagen fibril, the predominant protein of vertebrates

Type I collagen, the predominant protein of vertebrates, polymerizes with type III and V collagens and non-collagenous molecules into large cable-like fibrils, yet how the fibril interacts with cells and other binding partners remains poorly understood. To help reveal insights into the collagen structure-function relationship, a data base was assembled including hundreds of type I collagen ligand binding sites and mutations on a two-dimensional model of the fibril. Visual examination of the distribution of functional sites, and statistical analysis of mutation distributions on the fibril suggest it is organized into two domains. The "cell interaction domain" is proposed to regulate dynamic aspects of collagen biology, including integrin-mediated cell interactions and fibril remodeling. The "matrix interaction domain" may assume a structural role, mediating collagen cross-linking, proteoglycan interactions, and tissue mineralization. Molecular modeling was used to superimpose the positions of functional sites and mutations from the two-dimensional fibril map onto a three-dimensional x-ray diffraction structure of the collagen microfibril in situ, indicating the existence of domains in the native fibril. Sequence searches revealed that major fibril domain elements are conserved in type I collagens through evolution and in the type II/XI collagen fibril predominant in cartilage. Moreover, the fibril domain model provides potential insights into the genotype-phenotype relationship for several classes of human connective tissue diseases, mechanisms of integrin clustering by fibrils, the polarity of fibril assembly, heterotypic fibril function, and connective tissue pathology in diabetes and aging.     

A study of staining for electron microscopy using collagen as a model system—VI. Uranyl nitrate negative staining patterns and their correlation with sequence data

Collagen is used as a model system to study the mechanism of negative staining. Negative staining patterns from reconstituted fibrils of type I calf skin collagen (of known amino acid sequence) were compared with chemical data by a computer-aided correlation procedure. The stain used was uranyl nitrate, pH 3.2 and 4.9. The results show that the ‘bulkiness’ (average cross-sectional area or ‘plumpness’) of amino acid side chains is the dominant stain-excluding factor determining the small-scale distribution of stain along the collagen fibril. Some contribution of positive staining can also be demonstrated by the analysis described here.     

Collagen fibrillogenesis in vitro: comparison of types I, II, and III

The self-assembly of pepsin-extracted types I, II, and III collagen was studied to determine how differences in the triple-helical structure between collagen types influence in vitro collagen fibrillogenesis. Collagen types I, II, and III were extracted and purified from bovine sources, and were studied in solution by laser light scattering, pH titration, and determination of turbidity-time curves. The molecular weights were between 280,000 and 289,000, while the translational diffusion coefficients and particle scattering factors at 175.5 degrees were consistent with those expected for single collagen molecules. Titration of collagen types I, II, and III between pH 7.0 and 2.0 using HCl indicated that type I collagen had the most titratable carboxylic groups with type II and III having significantly fewer titratable groups. The self-assembly of these collagens was studied in vitro in phosphate-buffered saline. The time course and extent of fibril formation were studied turbidimetrically, and were found to be dependent on collagen type. Apparent rate constants were determined for both the lag and growth phases of fibril formation. The rates of both phases were greater for type III than for type I collagen, with the rates for type II collagen being intermediate. The extent of fibril formation was based on the turbidity per unit concentration (specific turbidity) extrapolated to zero concentration (intrinsic turbidity), which was found to be greater for type I than for type III collagen. Type II collagen had the smallest intrinsic turbidity. The specific and intrinsic turbidity values were consistent with the relative fibril diameters seen in dermis and cartilage by transmission electron microscopy. These observations indicate that helix-helix interactions are important in the regulation of the rate and extent of collagen fibrillogenesis and may be involved in the determination of fibril structure.