Collagenase from human polymorphonuclear leukocytes (neutrophil collagenase) attacks collagen type II in solution at a rate intermediate to those of type I and III collagens. This enzyme alone is not able to initiate degradation of native human articular cartilage. If the cartilage is first treated with leukocyte elastase, collagenase slowly degrades collagen. Confirming earlier findings by other investigators, elastase has a dual action on cartilage: The enzyme removes proteoglycans, thus demasking collagen fibers and giving collagenase access to them, and solubilizes collagen at a sizable rate. Although neutrophil collagenase cleaves collagen type II in solution at a high rate, the native, cross-linked status of collagen in cartilage makes it a relatively poor substrate for this enzyme. On a weight by weight scale, elastase and collagenase display about the same collagenolytic potential on human articular cartilage. The elastase/collagenase system from human polymorphonuclear leukocytes could represent a cooperative proteolytic complex in the destruction of cartilage in rheumatoid arthritis.
Winter wheat (Triticum aestivum) was grown in very close proximity to a nuclear‐fuel chemical separations facility to determine the environmental behavior and potential health hazard of chronic low‐level releases of plutonium (Pu) to the atmosphere from that facility. The majority (>95%) of the contamination of wheat plants was surfical contamination resulting from direct deposition of recently released Pu‐bearing particles onto plant surfaces and resuspension of Pu from soil. Internal contamination resulting from root uptake of Pu was negligible compared to surface contamination. The major pathway (>70%) of Pu to wheat grain was via harvesting activities when Pu was transferred from the surface of vegetative portions of plants to the surface of the grain. Radiation dose resulting from consumption of grain grown in the vicinity of a nuclear‐fuel separations facility is negligible compared to that currently received from natural and fallout sources of radiation.
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