Role of SLc11a1 Gen in Warm Ischemia-Reperfusion Injury
Wyllie, Samuel   
Baylor College of Medicine, Houston, TX, United States

While improvements in surgical techniques and pharmacological interventions have improved the outcome of liver resections, hemorrhagic shock, and organ transplantation, injury, rejection and eventual organ failure due to Ischemia-reperfusion (I/R) injury continue to be common place in the clinical setting. Accordingly, the development of novel treatment modalities to prevent or minimize I/R injury would be of tremendous benefit. Substantial evidence exist to support the notion that Kupffer cells (KC) are responsible for the early-phase of I/R injury, and sets the stage for the more severe polymorphonuclear leukocyte (PMN)-mediated late-phase injury. However, mechanisms by which KC and PMNs mediate their respective phases of I/R injury are not fully understood. This is reflected in the lack of success with conventional modes of therapeutic intervention both at the experimental and clinical levels. We have identified a gene, Slc11a1, which is induced during I/R injury, and mediates the production of pro-and anti-inflammatory cytokines. Consistent with this is the reduced levels of plasma TNF-alpha observed in Slc11a1-/- mice during the early phase of liver I/R injury. Slc11a1 proposed function of the regulating iron homeostasis in KC and PMNs, and its level of expression may ultimately determine if the liver is protected from I/R injury by modulating the degree of injury during both the early- and late-phases of I/R injury. To test this hypothesis we propose three aims: (1) We will determine if disruption of the Slc11a1 gene protects the mouse liver from I/R injury. To investigate this, we will look at both the early- and late-phases of I/R injury in the mouse liver model, in vivo. Standard biochemical and histological techniques will be employed to evaluate blood transaminases and H&E liver sections, in conjunction with molecular techniques to monitor the protein and mRNA levels of Slc11a1 and pro-and anti-inflammatory cytokines. (2) We will determine if disruption of the Slc11a1 gene blunts the activation/priming of KC and infiltrating PMNs during I/R injury. Slc11a1 mediates the activation of KC and PMNs. Therefore, we will isolate these cells from livers subjected to I/R, and use standard biochemical and molecular techniques to evaluate their degree of activation/priming by looking at spontaneous superoxide anion and NO production, and NF-kappaB activation. (3) We will determine the mechanism(s) by which the Slc11a1 gene elicits activation of KC and PMNs. If disruption Slc11a1 protects the liver from I/R injury by modulating mediation of iron homeostasis, then deferoxamine pretreatment of Slc11a1+/+ mice before I/R injury should protect the liver from I/R mediated injury, as observed for Slc11a1-/- mice. Furthermore, pretreatment with Fe2SO4 should reverse the protection observed in Slc11a11-/- mice. As in Aim #1, we will assess liver injury with use of standard biochemical and histological techniques. These studies will identify molecular mechanisms by which Slc11a1 modulates liver I/R injury, and will provide a novel target for therapeutic intervention in I/R-mediated organ injury.