Partial biochemical and immunologic characterization of fibrillin microfibrils from sea cucumber dermis.

The dermis of the sea cucumber Cucumaria frondosa is a mutable collagenous tissue composed of collagen fibrils, microfibrils, proteoglycans, and other soluble and insoluble components. A major constituent of the dermis is a network of 10-14 nm microfibrils which surrounds and penetrates bundles of collagen fibrils. These microfibrils, which are morphologically very similar to the fibrillin microfibrils of vertebrates, were found to be insoluble in protein denaturants, including chaotropic agents and ionic and nonionic detergents, regardless of the reduction of disulfide bonds. The microfibrils are covalently crosslinked by epsilon-(gamma-glutamyl)lysine at a concentration of 3.725 nmol/mg dry weight of purified insoluble material. The network is susceptible to proteolysis by trypsin, chymotrypsin, and pancreatic elastase, but not by bacterial collagenase. Amino acid compositional analysis of the network shows it to be composed of 25% ASX and GLX residues. Comparison with the proteins in the SwissProt database gives the network protein a high probability of being related to the mammalian protein fibrillin. The network is glycosylated: approximately 7% of the mass is constituted by neutral and amino sugars. The intact microfibrillar network cross-reacted with a well-characterized antiserum to mammalian fibrillin.

Molecular structure and functional morphology of echinoderm collagen fibrils.

The collagenous tissues of echinoderms, which have the unique capacity to rapidly and reversibly alter their mechanical properties, resemble the collagenous tissues of other phyla in consisting of collagen fibrils in a nonfibrillar matrix. Knowledge of the composition and structure of their collagen fibrils and interfibrillar matrix is thus important for an understanding of the physiology of these tissues. In this report it is shown that the collagen molecules from the fibrils of the spine ligament of a sea-urchin and the deep dermis of a sea-cucumber are the same length as those from vertebrate fibrils and that they assemble into fibrils with the same repeat period and gap/overlap ratio as do those of vertebrate fibrils. The distributions of charged residues in echinoderm and vertebrate molecules are somewhat different, giving rise to segment-long-spacing crystallites and fibrils with different banding patterns. Compared to the vertebrate pattern, the banding pattern of echinoderm fibrils is characterized by greatly increased stain intensity in the c3 band and greatly reduced stain intensity in the a3 and b2 bands. The fibrils are spindle-shaped, possessing no constant-diameter region throughout their length. The shape of the fibrils is mechanically advantageous for their reinforcing role in a discontinuous fiber-composite material.

Native collagen fibrils from echinoderms are molecularly bipolar.

Collagen fibrils are generally assumed to be cylinders with uniform diameters (except possibly at their ends) and to be composed of molecules all of which have the same polarity. These assumptions have been largely untested because of the extreme difficulty associated with isolating entire native fibrils. Intact collagen fibrils are readily extracted from certain echinoderms, however, and we have therefore analyzed the molecular structure of these fibrils. Our electron microscopic analyses show the above assumptions to be false: echinoderm fibrils, which previously have been shown to be symmetrically spindle shaped, are also molecularly bipolar. Their constituent molecules have their N-termini oriented toward the nearest fibril end, and they are antiparallel in the fibril center. The shape and molecular arrangement of these fibrils have implications for fibrillogenesis.

Compression loading in vitro regulates proteoglycan synthesis by tendon fibrocartilage.

The regulation of proteoglycan synthesis in a fibrocartilaginous tissue by mechanical loading was assessed in vitro. Discs of bovine tendon fibrocartilage were loaded daily with unconfined, cyclic, uniaxial compression (5 s/min, 20 min/day) and the synthesis of large and small proteoglycans was measured by incorporation of [35S]sulfate. All discs synthesized predominantly large proteoglycan when first placed in culture. After 2 weeks in culture nonloaded discs synthesized predominantly small proteoglycans whereas loaded discs continued to produce predominantly large proteoglycan. The turnover of 35S-labeled proteoglycan was not significantly altered by the compression regime. Increased synthesis of large proteoglycans was induced by a 4-day compression regime following 21 days of culture without compression. Inclusion of cytochalasin B during compression mimicked this induction. Autoradiography demonstrated that cell proliferation was minimal and confined to the disc edges whereas 35S-labeled proteoglycan synthesis occurred throughout the discs. These experiments demonstrate that mechanical compression can regulate synthesis of distinct proteoglycan types in fibrocartilage.