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The fibrous components are of three kinds: collagenous, elastic, and reticular. Most abundant are the fibres composed of the protein collagen. The fibrous components of loose areolar connective tissue, when viewed with the light microscope, appear as colourless strands of varying diameter running in all directions, and, if not under tension, these have a slightly undulant course. At high magnification, the larger strands are seen to be made up of bundles of smaller fibres. The smallest fibres visible with the light microscope can be shown with the electron microscope to be composed of multiple fibrils up to 1000 angstroms (one Å = 1 × 10−7 mm) in diameter. These unit fibrils are cross-striated with transverse bands repeating every 640 Å along their length.

Collagen is of commercial as well as medical interest, because leather is the dense collagen of the dermis of animal skins preserved and toughened by the process called tanning. Fresh collagen dissolves in hot water, and the product is gelatin. Under appropriate conditions, collagen can be brought into solution without chemical change. The fundamental units in such solutions are slender tropocollagen molecules about 14 Å wide and 2800 Å long. Collagen appears to be secreted in this form by the connective-tissue cells called fibroblasts, and the tropocollagen molecules assemble extracellularly to form striated collagen fibrils. By an alteration of the physicochemical conditions, tropocollagen in solution can be induced to polymerize with the formation of cross-striated fibrils identical to native collagen, thus simulating in the test tube the process of assembly that is believed to take place during fibrogenesis in the living organism. Analysis of the structure of collagen by X-ray diffraction has shown that the tropocollagen molecule consists of three side-by-side polypeptide chains—linear combinations of a number of amino acids, which are subunits of proteins—each in the form of a left-handed helix. These three left-handed helices are further twisted around one another to form a major right-handed helix. Upon chemical analysis, the amino acid composition of collagen is found to be unique in its high proline content and in the fact that one-third of the amino acid residues are glycine. Proline is one of several so-called nonessential amino acids (i.e., animals can synthesize it from glutamic acid and do not require dietary sources) and accounts for about 15 percent of collagen content.

Collagen is the only naturally occurring protein known to contain significant amounts of both hydroxyproline and hydroxylysine. Hydroxyproline constitutes about 14 percent of collagen. It was first isolated in 1902 from gelatin, a breakdown product of collagen. The hydroxylysine component of collagen is believed to play an important role in stabilizing intramolecular and intermolecular cross-links in collagen. This cross-linking capacity appears to be a function of the hydroxyl groups (―OH) present on hydroxylysine. These groups also serve as attachment sites for carbohydrates, particularly certain forms of galactose and glucosylgalactose. The attachment of these carbohydrates occurs via a process known as glycosylation.

Two of the three polypeptide chains constituting the tropocollagen molecule are similar to collagen in amino acid composition, while the third is distinctly different. In the tissues, the collagen fibrils are believed to be held together by a polysaccharide component.

Elastic fibres are composed of the protein elastin and differ from collagenous fibres in dimensions, pattern, and chemical composition. They do not have uniform subunits comparable to the unit fibrils of collagen. They present a variable appearance in electron micrographs; sometimes they appear to have an amorphous core surrounded by minute fibrils, while in other sites they appear to consist exclusively of dense amorphous material. Whether there are in fact two components or whether these are differing forms of the same substance is not yet clear. At the light-microscope level, the fibres vary in diameter and often branch and reunite to form extensive networks in loose connective tissue. When present in high concentration, they impart a yellow colour to the tissue. In elastic ligaments, the fibres are very coarse and are arranged in parallel bundles. In the walls of arteries, elastin is present in the form of sheets or membranes perforated by openings of varying size. Elastic fibres are extremely resistant to hot water, to strong alkali, and even to digestion with the proteolytic enzyme trypsin. They can be digested, however, by a specific enzyme, elastase, present in the pancreas. Upon chemical analysis, elastin, like collagen, is found to be rich in glycine and proline, but it differs in its high content of valine and in the presence of an unusual amino acid, desmosine. As their name implies, elastic fibres are highly distensible and, when broken, recoil like rubber bands. Changes in this property and diminution in their numbers are thought to be, in part, responsible for the loss of elasticity of the skin and of the blood-vessel walls in old age.

Reticular fibres are distinguished by their tendency to form fine-meshed networks around cells and cell groups and by virtue of their property of staining black, because of adsorption of metallic silver, when they are treated with alkaline solutions of reducible silver salts. They were formerly believed to be composed of a distinct protein, reticulin, but electron microscopy has revealed that reticular fibres are small fascicles of typical collagen fibrils interwoven to form a network. It is now apparent that reticular fibres are simply a form of collagen, and their distinctive staining depends upon the mode of association of the fibrils and possibly upon subtle differences in their relation to the polysaccharide material that binds them together.