Under conditions of starvation and disease, the gut barrier becomes impaired, and trophic feeding to prevent gut mucosal atrophy has become a standard treatment of critically ill patients. However, the mechanisms responsible for the beneficial effects of enteral nutrition have remained a mystery. Using in vitro and in vivo models, we demonstrate that the brush-border enzyme, intestinal alkaline phosphatase (IAP), has the ability to detoxify lipopolysaccharide and prevent bacterial invasion across the gut mucosal barrier. IAP expression and function are lost with starvation and maintained by enteral feeding. It is likely that the IAP silencing that occurs during starvation is a key component of the gut mucosal barrier dysfunction seen in critically ill patients.A mong the most critical functions of the mammalian gut mucosa is to provide a barrier to luminal microbes and toxins while simultaneously allowing for the necessary digestion and absorption of dietary nutrients. The molecular mechanisms that govern barrier function are incompletely understood, but it is clear that under conditions of starvation and disease, the gut barrier becomes impaired, leading to significant morbidity and mortality (1-8). Trophic enteral feeding to prevent gut mucosal atrophy and resultant barrier dysfunction has become part of the standard treatment of intensive care unit patients (9-14). The mechanism(s) responsible for the beneficial effects of trophic feeding are not understood.Intestinal alkaline phosphatase (IAP), a brush-border protein that hydrolyzes monophosphate esters, is expressed exclusively in villus-associated enterocytes and is considered an excellent marker for crypt-villus differentiation (15-18). Narisawa et al. (19) reported that compared with their wild-type (WT) littermates, mice lacking IAP gained more weight under conditions of a high-fat diet. In addition, several studies have shown that the IAP enzyme is capable of detoxifying LPS, likely through dephosphorylation of the lipid A moiety, the primary source of its endotoxic effects (20). Despite these few reports, the physiological role of IAP within the gut has not been elucidated. Results and DiscussionTo examine the functional role of IAP, we developed in vitro model systems using intestinal cell lines (T84, HT-29, and IEC-6) that express little or no IAP under basal conditions. Stable cell lines were created that overexpress IAP (Fig. 1A), and enzyme assays were used to determine the cellular localization of the ectopically expressed IAP protein. The results in Fig. 1B show that parent cells make little, if any, endogenous IAP. In contrast, large amounts of IAP enzyme are seen in the stably transfected cells. Importantly, the vast majority of the IAP activity is in the membrane fraction as opposed to the cytosol. Fig. 1C shows the results of the control experiment used to validate our separation of membranous and cytosolic fractions, confirming that the majority of the MAPK enzyme activity exists within the cytosol rather than the membrane. This membrane ...
High levels of the pro-inflammatory cytokines, interleukin-1beta (IL-1beta) and tumor necrosis factor-alpha (TNF-alpha), are present in the gut mucosa of patients suffering form various diseases, most notably inflammatory bowel diseases (IBD). Since the inflammatory milieu can cause important alterations in epithelial cell function, we examined the cytokine effects on the expression of the enterocyte differentiation marker, intestinal alkaline phosphatase (IAP), a protein that detoxifies bacterial lipopolysaccharides (LPS) and limits fat absorption. Sodium butyrate (NaBu), a short-chain fatty acid and histone deacetylase (HDAC) inhibitor, was used to induce IAP expression in HT-29 cells and the cells were also treated +/- the cytokines. Northern blots confirmed IAP induction by NaBu, however, pretreatment (6 h) with either cytokine showed a dose-dependent inhibition of IAP expression. IAP Western analyses and alkaline phosphatase enzyme assays corroborated the Northern data and confirmed that the cytokines inhibit IAP induction. Transient transfections with a reporter plasmid carrying the human IAP promoter showed significant inhibition of NaBu-induced IAP gene activation by the cytokines (100 and 60% inhibition with IL-1beta and TNF-alpha, respectively). Western analyses showed that NaBu induced H4 and H3 histone acetylation, and pretreatment with IL-1beta or TNF-alpha did not change this global acetylation pattern. In contrast, chromatin immunoprecipitation showed that local histone acetylation of the IAP promoter region was specifically inhibited by either cytokine. We conclude that IL-1beta and TNF-alpha inhibit NaBu-induced IAP gene expression, likely by blocking the histone acetylation within its promoter. Cytokine-mediated IAP gene silencing may have important implications for gut epithelial function in the setting of intestinal inflammatory conditions.
BackgroundTransfusion-associated hyperkalemic cardiac arrest is a serious complication in patients receiving packed red blood cell (PRBC) transfusions. Mortality from hyperkalemia increases with large volumes of PRBC transfusion, increased rate of transfusion, and the use of stored PRBCs. Theoretically, hyperkalemia may be complicated by low cardiac output, acidosis, hyperglycemia, hypocalcemia, and hypothermia. In this study, we focus on transfusion-related hyperkalemia involving only medical intensive care unit (MICU) patients.MethodThis prospective observational study focuses on PRBC transfusions among MICU patients greater than 18 years of age. Factors considered during each transfusion included patient’s diagnosis, indication for transfusion, medical co-morbidities, acid-base disorders, K+ levels before and after each PRBC transfusion, age of stored blood, volume and rate of transfusion, and other adverse events. We used Pearson correlation and multivariate analysis for each factor listed above and performed a logistic regression analysis.ResultsBetween June 2011 and December 2011, 125 patients received a total of 160 units of PRBCs. Median age was 63 years (22 - 92 years). Seventy-one (57%) were females. Sixty-three patients (50%) had metabolic acidosis, 75 (60%) had acute renal failure (ARF), and 12 (10%) had end-stage renal disease (ESRD). Indications for transfusion included septic shock (n = 65, 52%), acute blood loss (n = 25, 20%), non-ST elevation myocardial infarction (NSTEMI) (n = 25, 20%) and preparation for procedures (n = 14, 11%). Baseline K+ value was 3.9 ± 1.1 mEq/L compared to 4.3 ± 1.2 mEq/L post-transfusion respectively (P = 0.9). During this study period, 4% of patients developed hyperkalemia (K+ 5.5 mEq/L or above). The mean change of serum potassium in patients receiving transfusion ≥ 12 days old blood was 4.1 ± 0.4 mEq/L compared to 4.8 ± 0.3 mEq/L (mean ± SD) in patients receiving blood 12 days or less old. Sixty-two patients (77.5%) that were transfused stored blood (for more than 12 days) had increased serum K+; eight (17.7%) patients received blood that was stored for less than 12 days. In both univariate (P = 0.02) and multivariate (P = 0.04) analysis, findings showed that among all factors, transfusion of stored blood was the only factor that affected serum potassium levels (95% CI: 0.32 - 0.91). No difference was found between central and peripheral intravenous access (P = 0.12), acidosis (P = 0.12), ARF (P = 0.6), ESRD (P = 0.5), and multiple transfusions (P = 0.09). One subject developed a sustained cardiac arrest after developing severe hyperkalemia (K+ = 9.0) following transfusion of seven units of PRBCs. Multivariate logistic regression showed linear correlation between duration of stored blood and serum K+ (R2 = 0.889).ConclusionThis study assesses factors that affect K+ in patients admitted to MICU. Results from the study show that rise in serum K+ level is more pronounced in patients who receive stored blood (> 12 days). Future studies should focus on the use of altered s...
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