Inhibition of Dimethylarginine Dimethylaminohydrolase 1 Improves the Outcome of Sepsis in Pregnant Mice.

Sepsis is one of the most important causes of maternal mortality. In our previous work, we established a polymicrobial sepsis (cecal ligation and puncture [CLP]) model in murine pregnancy and found that pregnant mice had a greater susceptibility to septic shock. In this model, mortality seemed to be associated with the development of early hemodynamic dysfunction and although circulating cytokine levels were similar, "off target" lung inflammatory cell numbers were greater in pregnant mice.Here, we have used the same CLP model to test the hypothesis that inhibiting the metabolism of the endogenous inhibitor of nitric oxide synthase, asymmetric dimethylarginine would improve the outcome of sepsis in pregnancy. We used a dimethylarginine dimethylaminohydrolase 1-selective inhibitor (L-257), which reduces vascular nitric oxide synthesis without impairing immune cell function, in combination with a broad-spectrum antibiotic (Imipenem) and studied the outcome of septic shock in pregnant mice. Treatments were administered 3 h after CLP and samples were taken 3 h later. Both Imipenem and L-257 treatment alone slightly improved mortality rates from 13% (NaCl) to 20% (Imipenem) and 33% (L-257), whereas the combination of Imipenem and L-257 significantly improved survival to 50%. Imipenem and L-257 together prevented cardiovascular collapse and improved both organ function and bacterial killing, but did not reduce lung inflammatory cell numbers and actually increased lung cytokine levels.These data suggest that conventional management in combination with selective inhibition of DDAH1 may have therapeutic potential in the management of sepsis in pregnancy.

Rapid onset of severe septic shock in the pregnant mouse†.

AIMS: Globally, sepsis is a major cause of mortality through the combination of cardiovascular collapse and multiorgan dysfunction. Pregnancy appears to increase the risk of death in sepsis, but the exact reason for the greater severity is unclear. In this study, we used polymicrobial sepsis induced by cecal ligation and puncture (CLP) and high-dose intraperitoneal lipopolysaccharide (LPS; 10 or 40 mg, serotype 0111: B4) to test the hypotheses that pregnant mice are more susceptible to sepsis and that this susceptibility was mediated through an excessive innate response causing a more severe cardiovascular collapse rather than a reduction in microbe killing. METHODS AND RESULTS: Initial studies found that mortality rates were greater, and that death occurred sooner in pregnant mice exposed to CLP and LPS. In pregnant and nonpregnant CD1 mice monitored with radiotelemetry probes, cardiovascular collapse occurred sooner in pregnant mice, but once initiated, occurred over a similar timescale. In a separate study, tissue, serum, and peritoneal fluid (for protein, flow cytometry, nitric oxide, and bacterial load studies) were collected. At baseline, there was no apparent Th1/Th2 bias in pregnant mice. Post CLP, the circulating cytokine response was the same, but leukocyte infiltration in the lung was greater in pregnant mice, but only TNFα levels were greater in lung tissue. The bacterial load in blood and peritoneal fluid was similar in both groups. CONCLUSION: Sepsis-related mortality was markedly greater in pregnant mice. Cardiovascular collapse and organ dysfunction occurred sooner in pregnancy, but bacterial killing was similar. Circulating and tissue cytokine levels were similar, but immune cell extravasation into other organs was greater in pregnant mice. These data suggest that an excessive innate immune system response as shown by the exaggerated lung infiltration of leukocytes may be responsible for the greater mortality. Approaches that reduce off-site trafficking may improve the prognosis of sepsis in pregnancy.