Lung-derived mediators induce cytokine production in downstream organs via an NF-κB-dependent mechanism.

In the setting of acute lung injury, levels of circulating inflammatory mediators have been correlated with adverse outcomes. Previous studies have demonstrated that injured, mechanically ventilated lungs represent the origin of the host inflammatory response; however, mechanisms which perpetuate systemic inflammation remain uncharacterized. We hypothesized that lung-derived mediators generated by mechanical ventilation (MV) are amplified by peripheral organs in a "feed forward" mechanism of systemic inflammation. Herein, lung-derived mediators were collected from 129X1/SVJ mice after 2 hours of MV while connected to the isolated perfused mouse lung model setup. Exposure of liver endothelial cells to lung-derived mediators resulted in a significant increase in G-CSF, IL-6, CXCL-1, CXCL-2, and MCP-1 production compared to noncirculated control perfusate media (P < 0.05). Furthermore, inhibition of the NF-κB pathway significantly mitigated this response. Changes in gene transcription were confirmed using qPCR for IL-6, CXCL-1, and CXCL-2. Additionally, liver tissue obtained from mice subjected to 2 hours of in vivo MV demonstrated significant increases in hepatic gene transcription of IL-6, CXCL-1, and CXCL-2 compared to nonventilated controls. Collectively, this data demonstrates that lung-derived mediators, generated in the setting of MV, are amplified by downstream organs in a feed forward mechanism of systemic inflammation.

Inhibition by bestatin of a mouse ascites tumor dipeptidase. Reversal by certain substrates.

Bestatin, [(2S,3R)-3-amino-2-hydroxy-4-phenyl-butanoyl]-L-leucine, a known inhibitor of aminopeptidases, is shown to be a potent linear competitive inhibitor (KI,2.7 nM) of a dipeptidase purified from Ehrlich-Lettré hyperdiploid mouse ascites tumor cells. This inhibition can be classified as "slow binding" but not as "tight binding." Substrate protects the enzyme from bestatin inhibition when enzyme and inhibitor are in approximately equimolar concentrations. Addition of substrate (6 mM) partially (by about 20%) reverses dipeptidase inhibition by bestatin, but the time required for maximum recovery depends on the nature of the substrate. Substrates with lower Km (0.28-1.4 mM) values that exhibit substantial substrate inhibition require longer times (23-65 min) than those with higher Km values that show little substrate inhibition. Substrates with Km values higher than 1.5 mM do not reverse inhibition. The inhibition of the tumor dipeptidase by bestatin has been compared with inhibition by a variety of inhibitors of other Zn-metallo-proteolytic enzymes. These inhibitors were far less potent (KI, 0.063-10 mM), indicating a difference between the tumor dipeptidase and other enzymes of that class. Our results are discussed in terms of a postulated model of the bestatin molecule in the active site of the tumor dipeptidase, an enzyme which has not been studied by x-ray crystallographic means. The phenyl group of bestatin is placed in a hydrophobic pocket that is external but adjacent to the active site of the tumor dipeptidase. The shape of this pocket, as it appears from our results plus modeling, is such that only certain R groups of substrate can fit. The existence of such a pocket might explain the differential effect of substrates in the reversal of bestatin inhibition of the dipeptidase and also might explain substrate inhibition by misalignment of R groups into this pocket.

The effect of Mn2+ and Co2+ on the activities of a zinc metallodipeptidase from a mouse ascites tumor.

Kinetic studies of the effect of addition of Co2+ or Mn2+ to a highly purified dipeptidase from Ehrlich-Lettré mouse ascites tumor cells show that these metals specifically activate the hydrolyses of certain classes of dipeptides. This enzyme was previously (S. Hayman and E. K. Patterson, 1971, J. Biol. Chem. 246, 660) reported to be a Zn-metalloenzyme. It is now shown that Zn is the only metal that can partially restore the activity of the EDTA-inhibited dipeptidase in cleaving Ala-Gly. Addition of Co2+ increases the Vmax of N-terminal Gly-dipeptides with increase in Km while addition of Mn2+ primarily activates the hydrolysis of Pro-Gly, again with increases in both Vmax and Km. Prior incubation (5 min, 30 degrees) of the dipeptidase with the appropriate metal ions causes decrease in initial lag time in the Co2+-activated hydrolysis of Gly-Gly and the Mn2+-activated hydrolysis of Pro-Gly. Long-term (6-19 hr, 0 degrees) incubation of the enzyme with Co2+ results in loss of activity toward Ala-Gly with a concomitant 13-fold increase in the rate of Gly-Gly hydrolysis and loss of 70% of the Zn2+ from the dipeptidase; these effects can be partially reversed by addition of Zn2+. In contrast, long-term incubation of the enzyme with Mn2+ results in no loss of Zn2+ and a twofold increase in activity toward Pro-Gly. One affinity constant of 1.4 muM for Co2+ and two constants of 0.23 and 27 muM for Mn2+ were determined by kinetic experiments. Comparison of the properties of this tumor enzyme with a dipeptidase purified in our laboratory from Escherichia coli B, and with mammalian dipeptidases highly purified by others, shows remarkable similarities in molecular weights and molecular activities toward the preferred substrates but in the case of bacterial dipeptidase, differences in substrate specificities and in the effect of metal ions.