Collagen fibrillogenesis in tendon development: current models and regulation of fibril assembly.

Tendons are collagen-based fibrous tissues that connect and transmit forces from muscle to bone. These tissues, which are high in collagen type I content, have been studied extensively to understand collagen fibrillogenesis. Although the mechanisms have not been fully elucidated, our understanding has continued to progress. Here, we review two prevailing models of collagen fibrillogenesis and discuss the regulation of the process by candidate cellular and extracellular matrix molecules. Although numerous molecules have been implicated in the regulation of collagen fibrillogenesis, we focus on those that have been suggested to be particularly relevant to collagen type I fibril formation during tendon development, including members of the collagen and small leucine-rich proteoglycan families, as well as other molecules, including scleraxis, cartilage oligomeric matrix protein, and cytoskeletal proteins.

Collagen fragments modulate innate immunity.

Activation of the innate immune response in diseases such as rheumatoid arthritis and atherosclerosis leads to the production of proinflammatory cytokines that can promote collagenolysis. While a number of studies suggest that inflammation plays a major role in initiating collagen degradation, the effect of collagen and collagen-degradation fragments on the inflammatory response is not well understood. We now demonstrate that different collagen fragments can either augment or suppress IL-1beta production from human peripheral-blood monocytes. These data have wide-ranging implications for how amino acid variation in collagen affects disease and suggest that collagen degradation leads to the production of peptides that can modulate inflammation.