Neutrophil response following intratracheal instillation of collagen peptides into rat lungs.

Inflammatory lung diseases are associated with destruction of interstitial collagen and release of degraded collagen fragments into the lower respiratory tract. To determine whether degraded collagen might be one factor mediating the cellular influx, we measured polymorphonuclear leukocytes (PMN) in bronchoalveolar lavage fluid following intratracheal instillation of collagen peptides. The responses to collagenous peptides derived from collagen digested with bacterial collagenase and to the collagenous-like polytripeptide (proline-proline-glycine) were examined. Both types of collagen peptides were chemotactic for human PMN in vitro. Two days following instillation of 5 mg collagenous peptides, we observed a threefold increase in the percentage of PMN in lavage fluid with a maximum (fivefold) response on day 6. Since other chemoattractants produce a response within hours when instilled intratracheally, we postulated that the late neutrophil influx produced with collagen may be the result of production of a neutrophil chemoattractant by alveolar macrophages. Alveolar macrophages treated with collagenous or collagenous-like peptides released PMN chemotactic factors, and the time course of release of chemotactic activity by alveolar macrophages in vitro correlated with the in vivo finding of a 2-6-day delay in PMN accumulation in the lungs. These observations are consistent with the idea that collagen peptides may stimulate alveolar macrophages to produce chemotactic factors for neutrophils. This mechanism may play a role in the accumulation of phagocytic cells in the lung following injury.

Kinetics of intracellular degradation of newly synthesized collagen.

The objective of this work was to determine the time dependence of the basal component of intracellular degradation of newly synthesized collagen. Chick embryo tendon fibroblasts were incubated with [14C]proline, and degradation was quantified by measuring hydroxy[14C]proline in a low molecular weight fraction. When cultures were pulse labeled for 15 min and then incubated under chase conditions for 105 min, the amount of degraded collagen attained a value equal to approximately 20% of the amount synthesized during the labeling period; the data were fit with a simple exponential function that had a 40-min rise time and a 12-min lag time. In continuously labeled cultures, the rates of collagen synthesis and secretion reached constant values within 15 and 45 min, respectively. Degradation products were first detected 6-9 min after collagen synthesis began and were transported out of the cells more rapidly than intact collagenous molecules; however, percent degradation increased slowly and did not reach a constant value even after 240 min of incubation. Since collagen degradation lags collagen synthesis, it follows that degradation is a posttranslational, rather than a cotranslational, process, and since degradation and secretion are kinetically distinguishable, it follows that they occur in parallel pathways. A simple nonlinear model for posttranslational processing of collagen is proposed.

Degradation of soluble collagen by ozone or hydroxyl radicals.

Collagen exposed to ozone or hydroxyl radicals was degraded in a time- and dose-dependent manner. This degradation was inhibited by free radical scavengers. Furthermore, lower levels of these oxidants did not degrade the molecule, but caused it to become susceptible to proteolytic degradation. We suggest an alternative mechanism by which oxygen-derived free radicals participate in the destruction of extracellular matrix observed during acute lung injury by oxidant gas, in addition to the commonly accepted proteinase-antiproteinase theory of lung injury.