Endothelial cell CD36 regulates membrane ceramide formation, exosome fatty acid transfer and circulating fatty acid levels.

Endothelial cell (EC) CD36 controls tissue fatty acid (FA) uptake. Here we examine how ECs transfer FAs. FA interaction with apical membrane CD36 induces Src phosphorylation of caveolin-1 tyrosine-14 (Cav-1Y14) and ceramide generation in caveolae. Ensuing fission of caveolae yields vesicles containing FAs, CD36 and ceramide that are secreted basolaterally as small (80-100 nm) exosome-like extracellular vesicles (sEVs). We visualize in transwells EC transfer of FAs in sEVs to underlying myotubes. In mice with EC-expression of the exosome marker emeraldGFP-CD63, muscle fibers accumulate circulating FAs in emGFP-labeled puncta. The FA-sEV pathway is mapped through its suppression by CD36 depletion, blocking actin-remodeling, Src inhibition, Cav-1Y14 mutation, and neutral sphingomyelinase 2 inhibition. Suppression of sEV formation in mice reduces muscle FA uptake, raises circulating FAs, which remain in blood vessels, and lowers glucose, mimicking prominent Cd36-/- mice phenotypes. The findings show that FA uptake influences membrane ceramide, endocytosis, and EC communication with parenchymal cells.

Recent developments in cartilage research: matrix biology of the collagen II/IX/XI heterofibril network.

Research on cartilage is intensifying as efforts expand to discover disease-modifying drugs to treat or prevent osteoarthritis. Proteolytic damage to the collagen fabric of cartilage is a critical, and probably early, component of the pathogenesis of degenerative joint disease. Here we summarize recent findings on the unique heteromeric structure of cartilage collagen fibrils, including the key role of collagen IX, a covalently bonded fibril-adapter molecule. A highly specific pattern of cross-linking sites that involves all three component gene products strongly suggests that collagen IX has evolved to function as an interfibrillar network-bonding agent. This is supported from the genetic evidence that mutations in all three collagen IX genes can produce a phenotype in which cartilage matrix integrity and early-onset osteoarthritis are a feature. From the structure of the cartilage collagen heteropolymer we also predict a pivotal role for telopeptide (non-triple-helical) proteolytic cleavages in the remodelling and degradation of collagen fibrils.