Somatostatin as Inflow Modulator in Liver-transplant Recipients With Severe Portal Hypertension: A Randomized Trial.

OBJECTIVE: To investigate the safety and efficacy of somatostatin as liver inflow modulator in patients with end-stage liver disease (ESLD) and clinically significant portal hypertension (CSPH) undergoing liver transplantation (LT) (ClinicalTrials.gov number,01290172). BACKGROUND: In LT, portal hyperperfusion can severely impair graft function and survival, mainly in cases of partial LT. METHODS: Thirty-three patients undergoing LT for ESLD and CSPH were randomized double-blindly to receive somatostatin or placebo (2:1). The study drug was administered intraoperatively as 5-mL bolus (somatostatin: 500 µg), followed by a 2.5 mL/h infusion (somatostatin: 250 µg/h) for 5 days. Hepatic and systemic hemodynamics were measured, along with liver function tests and clinical outcomes. The ischemia-reperfusion injury (IRI) was analyzed through histological and protein expression analysis. RESULTS: Twenty-nine patients (18 receiving somatostatin, 11 placebo) were included in the final analysis. Ten patients responded to somatostatin bolus, with a significant decrease in hepatic venous portal gradient (HVPG) and portal flow of -28.3% and -29.1%, respectively. At graft reperfusion, HVPG was lower in patients receiving somatostatin (-81.7% vs -58.8%; P = 0.0084), whereas no difference was observed in the portal flow (P = 0.4185). Somatostatin infusion counteracted the decrease in arterial flow (-10% vs -45%; P = 0.0431). There was no difference between the groups in the severity of IRI, incidence of adverse events, long-term complications, graft, and patient survival. CONCLUSIONS: Somatostatin infusion during LT in patients with CSPH is safe, reduces the HVPG, and preserves the arterial inflow to the graft. This study establishes the efficacy of somatostatin as a liver inflow modulator.

Specific inhibition of the redox activity of ape1/ref-1 by e3330 blocks tnf-α-induced activation of IL-8 production in liver cancer cell lines.

APE1/Ref-1 is a main regulator of cellular response to oxidative stress via DNA-repair function and co-activating activity on the NF-κB transcription factor. APE1 is central in controlling the oxidative stress-based inflammatory processes through modulation of cytokines expression and its overexpression is responsible for the onset of chemoresistance in different tumors including hepatic cancer. We examined the functional role of APE1 overexpression during hepatic cell damage related to fatty acid accumulation and the role of the redox function of APE1 in the inflammatory process. HepG2 cells were stably transfected with functional and non-functional APE1 encoding plasmids and the protective effect of APE1 overexpression toward genotoxic compounds or FAs accumulation, was tested. JHH6 cells were stimulated with TNF-α in the presence or absence of E3330, an APE1 redox inhibitor. IL-8 promoter activity was assessed by a luciferase reporter assay, gene expression by Real-Time PCR and cytokines (IL-6, IL-8, IL-12) levels measured by ELISA. APE1 over-expression did not prevent cytotoxicity induced by lipid accumulation. E3330 treatment prevented the functional activation of NF-κB via the alteration of APE1 subcellular trafficking and reduced IL-6 and IL-8 expression induced by TNF-α and FAs accumulation through blockage of the redox-mediated activation of NF-κB. APE1 overexpression observed in hepatic cancer cells may reflect an adaptive response to cell damage and may be responsible for further cell resistance to chemotherapy and for the onset of inflammatory response. The efficacy of the inhibition of APE1 redox activity in blocking TNF-α and FAs induced inflammatory response opens new perspectives for treatment of inflammatory-based liver diseases.

Differential proteomic analysis of subfractioned human hepatocellular carcinoma tissues.

To discover new potential biomarkers of HCC, we used 2-DE gel separation and MALDI-TOF-MS analysis of partially enriched nuclear fractions from liver biopsies of 20 different patients. We obtained a proteomic map of subfractioned liver samples including about 200 common protein spots, among which identified components corresponded to expression products of 52 different genes. A differential analysis of proteins from tumoral and control tissues revealed a significant change in the expression level of 16 proteins associated to cytoskeletal, stress response and metabolic functions. These data may provide novel candidate biomarkers for HCC and useful insights for understanding the mechanisms of HCC pathogenesis and progression.

Modern strategies to identify new molecular targets for the treatment of liver diseases: The promising role of Proteomics and Redox Proteomics investigations.

Oxidative stress, due to an imbalance between the generation of ROS and the antioxidant defense capacity of the cell, is a major pathogenetic event occurring in several liver diseases, ranging from metabolic to proliferative. Main sources of ROS are represented by mitochondria and cytochrome P450 enzymes in the hepatocytes, Küppfer cells, and neutrophils. Oxidative stress affects major cellular components including lipids, DNA, and proteins. Through modulation of protein structure/function, ROS can influence gene expression profile by affecting intracellular signal transduction pathways. While several enzymatic and nonenzymatic markers of chronic oxidative stress are well known in liver, early protein targets of oxidative injury are yet poorly defined. Identification of these biomarkers will enable early detection of liver diseases and will allow monitoring the degree of liver damage, the response to pharmacological therapies, and the development of new therapeutic approaches. In the era of molecular medicine, new proteomic methodologies promise to establish a relationship between pathological hallmarks of the disease and protein structural/functional modifications, thus allowing a better understanding and a more rational therapy on liver disorders. Purpose of this review is to critically analyze the application of proteomic and redox proteomic approaches to the study of oxidative stress-linked liver diseases.

Subcellular localization of APE1/Ref-1 in human hepatocellular carcinoma: possible prognostic significance.

APE1/Ref-1, normally localized in the nucleus, is a regulator of the cellular response to oxidative stress. Cytoplasmic localization has been observed in several tumors and correlates with a poor prognosis. Because no data are available on liver tumors, we investigated APE1/Ref-1 subcellular localization and its correlation with survival in 47 consecutive patients undergoing hepatocellular carcinoma (HCC) resection. APE1/Ref-1 expression was determined by immunohistochemistry in HCC and surrounding liver cirrhosis (SLC) and compared with normal liver tissue. Survival probability was evaluated using Kaplan-Meier curves (log-rank test) and Cox regression. Cytoplasmic expression of APE1/Ref-1 was significantly higher in HCC than in SLC (P = 0.00001); normal liver showed only nuclear reactivity. Patients with poorly differentiated HCC showed a cytoplasmic expression three times higher than those with well-differentiated HCC (P = 0.03). Cytoplasmic localization was associated with a median survival time shorter than those with negative cytoplasmic reactivity (0.44 compared with 1.64 years, P = 0.003), and multivariable analysis confirmed that cytoplasmic APE1/Ref-1 localization is a predictor of survival. Cytoplasmic expression of APE1/Ref-1 is increased in HCC and is associated with a lower degree of differentiation and a shorter survival time, pointing to the use of the cytoplasmic localization of APE1/Ref-1 as a prognostic marker for HCC.