Shiguang Liu

Lipotoxicity Causes Multisystem Organ Failure and Exacerbates Acute Pancreatitis in Obesity

Unsaturated fatty acids cause lipotoxicity and mediate acute adverse outcomes in obese individuals with pancreatitis. The Burden of Adiposity As if diabetes and heart disease were not burden enough, obese people who suffer trauma, burns, or other critical conditions have an increased likelihood of death. During these exacerbated illnesses, multiple organs can fail, a situation that is particularly hard to reverse. How the presence of excess adipose tissue contributes to the severity of these diseases is not clear, but understanding the mechanisms could provide clues for possible treatments. Pancreatitis is a relatively well-defined disease that tends to be worse in the obese and, in its most severe form, is accompanied by multi-organ failure. By using a combination of patient investigation, in vitro cell studies, and an animal model, Navina et al. have assembled evidence that pinpoints the culprits in the obesity-related complications of this disease: unsaturated fatty acids liberated by lipolysis from adipose tissue. The authors carefully examine the pancreases of 24 patients who had died of pancreatitis. The staining patterns indicated that nonesterified fatty acids, derived by lipolysis of excess intrapancreatic fat, contributed to the pancreatic necrosis in these patients. To test this idea, the authors used a cell culture system and showed that it is unsaturated fatty acids that do the damage, impairing acinar cell activities, inhibiting mitochondrial function, releasing calcium, and causing cell death. But what about the failure of other organs? To answer this question, the authors used obese mice with pancreatitis and, by inhibiting lipolysis with the drug orlistat, were able to prevent the pancreatic-associated rise in serum unsaturated fatty acids and, of most importance, to reduce damage to the lung and kidney, as well as mortality. It is not yet clear which lipase is the critical one for multiorgan failure or where it is located. But once revealed, this potential therapeutic target may specify a treatment that enhances the survival of critically ill obese patients. Obesity increases the risk of adverse outcomes during acute critical illnesses such as burns, severe trauma, and acute pancreatitis. Although individuals with more body fat and higher serum cytokines and lipase are more likely to experience problems, the roles that these characteristics play are not clear. We used severe acute pancreatitis as a representative disease to investigate the effects of obesity on local organ function and systemic processes. In obese humans, we found that an increase in the volume of intrapancreatic adipocytes was associated with more extensive pancreatic necrosis during acute pancreatitis and that acute pancreatitis was associated with multisystem organ failure in obese individuals. In vitro studies of pancreatic acinar cells showed that unsaturated fatty acids were proinflammatory, releasing intracellular calcium, inhibiting mitochondrial complexes I and V, and causing necrosis. Saturated fatty acids had no such effects. Inhibition of lipolysis in obese (ob/ob) mice with induced pancreatitis prevented a rise in serum unsaturated fatty acids and prevented renal injury, lung injury, systemic inflammation, hypocalcemia, reduced pancreatic necrosis, and mortality. Thus, therapeutic approaches that target unsaturated fatty acid–mediated lipotoxicity may reduce adverse outcomes in obese patients with critical illnesses such as severe acute pancreatitis.

Transcriptional regulation of CXC-ELR chemokines KC and MIP-2 in mouse pancreatic acini

Neutrophils and their chemoattractants, the CXC-ELR chemokines keratinocyte cytokine (KC) and macrophage inflammatory protein-2 (MIP-2), play a critical role in pancreatitis. While acute pancreatitis is initiated in acinar cells, it is unclear if these are a source of CXC-ELR chemokines. KC and MIP-2 have NF-κB, activator protein-1 (AP-1) sites in their promoter regions. However, previous studies have shown increased basal and reduced caerulein-induced AP-1 activation in harvested pancreatic tissue in vitro, which limits interpreting the caerulein-induced response. Moreover, recent studies suggest that NF-κB silencing in acinar cells alone may not be sufficient to reduce inflammation in acute pancreatitis. Thus the aim of this study was to determine whether acinar cells are a source of KC and MIP-2 and to understand their transcriptional regulation. Primary overnight-cultured murine pancreatic acini were used after confirming their ability to replicate physiological and pathological acinar cell responses. Upstream signaling resulting in KC, MIP-2 upregulation was studied along with activation of the transcription factors NF-κB and AP-1. Cultured acini replicated critical responses to physiological and pathological caerulein concentrations. KC and MIP-2 mRNA levels increased in response to supramaximal but not to physiological caerulein doses. This upregulation was calcium and protein kinase C (PKC), but not cAMP, dependent. NF-κB inhibition completely prevented upregulation of KC but not MIP-2. Complete suppression of MIP-2 upregulation required dual inhibition of NF-κB and AP-1. Acinar cells are a likely source of KC and MIP-2 upregulation during pancreatitis. This upregulation is dependent on calcium and PKC. MIP-2 upregulation requires both NF-κB and AP-1 in these cells. Thus dual inhibition of NF-κB and AP-1 may be a more successful strategy to reduce inflammation in pancreatitis than targeting NF-κB alone.

β-Catenin is Essential for Ethanol Metabolism and Protection Against Alcohol-mediated Liver Steatosis in Mice

The liver plays a central role in ethanol metabolism, and oxidative stress is implicated in alcohol‐mediated liver injury. β‐Catenin regulates hepatic metabolic zonation and adaptive response to oxidative stress. We hypothesized that β‐catenin regulates the hepatic response to ethanol ingestion. Female liver‐specific β‐catenin knockout (KO) mice and wild‐type (WT) littermates were fed the Lieber‐Decarli liquid diet (5% ethanol) in a pairwise fashion. Liver histology, biochemistry, and gene‐expression studies were performed. Plasma alcohol and ammonia levels were measured using standard assays. Ethanol‐fed (EtOH) KO mice exhibited systemic toxicity and early mortality. KO mice exhibited severe macrovesicular steatosis and 5 to 6‐fold higher serum alanine aminotransferase and aspartate aminotransferase levels. KO mice had a modest increase in hepatic oxidative stress, lower expression of mitochondrial superoxide dismutase (SOD2), and lower citrate synthase activity, the first step in the tricarboxylic acid cycle. N‐Acetylcysteine did not prevent ethanol‐induced mortality in KO mice. In WT livers, β‐catenin was found to coprecipitate with forkhead box O3, the upstream regulator of SOD2. Hepatic alcohol dehydrogenase and aldehyde dehydrogenase activities and expression were lower in KO mice. Hepatic cytochrome P450 2E1 protein levels were up‐regulated in EtOH WT mice, but were nearly undetectable in KO mice. These changes in ethanol‐metabolizing enzymes were associated with 30‐fold higher blood alcohol levels in KO mice. Conclusion: β‐Catenin is essential for hepatic ethanol metabolism and plays a protective role in alcohol‐mediated liver steatosis. Our results strongly suggest that integration of these functions by β‐catenin is critical for adaptation to ethanol ingestion in vivo. (HEPATOLOGY 2012;)

ADP-ribosylation Factor 1 Protein Regulates Trypsinogen Activation via Organellar Trafficking of Procathepsin B Protein and Autophagic Maturation in Acute Pancreatitis

Background: Autophagy and cathepsin B-mediated trypsin generation may be deleterious in acute pancreatitis. The role of ARF1 in the process is unknown. Results: BFA-mediated ARF1 inhibition prevents caerulein-induced processing of procathepsin B and perturbs autophagic maturation. Conclusion: ARF1-dependent trafficking of procathepsin B and autophagic maturation result in trypsinogen activation. Significance: ARF1 plays a significant role in acute pancreatitis. Several studies have suggested that autophagy might play a deleterious role in acute pancreatitis via intra-acinar activation of digestive enzymes. The prototype for this phenomenon is cathepsin B-mediated trypsin generation. To determine the organellar basis of this process, we investigated the subcellular distribution of the cathepsin B precursor, procathepsin B. We found that procathepsin B is enriched in Golgi-containing microsomes, suggesting a role for the ADP-ribosylation (ARF)-dependent trafficking of cathepsin B. Indeed, caerulein treatment increased processing of procathepsin B, whereas a known ARF inhibitor brefeldin A (BFA) prevented this. Similar treatment did not affect processing of procathepsin L. BFA-mediated ARF1 inhibition resulted in reduced cathepsin B activity and consequently reduced trypsinogen activation. However, formation of light chain 3 (LC3-II) was not affected, suggesting that BFA did not prevent autophagy induction. Instead, sucrose density gradient centrifugation and electron microscopy showed that BFA arrested caerulein-induced autophagosomal maturation. Therefore, ARF1-dependent trafficking of procathepsin B and the maturation of autophagosomes results in cathepsin B-mediated trypsinogen activation induced by caerulein.