HEV-Ag ELISA assay is a reliable diagnostic test in resource-limited areas. HEV genotype 1 (HEV-1) infections are either self-limited or progress to fulminant hepatic failure (FHF) and death if anti-HEV therapy is delayed. Limited data is available about the diagnostic utility of HEV Ag on HEV-1 infections. Herein wWe aimed to study the kinetics of HEV Ag during HEV-1 infections at different stages, i.e., acute HEV infection, recovery, and progression to FHF. Also, we evaluated the diagnostic utility of this marker to predict the outcomes of HEV-1 infections. Plasma of acute hepatitis E (AHE) patients were assessed for HEV RNA by RT-qPCR, HEV Ag, and anti-HEV IgM by ELISA. The kinetics of HEV Ag was monitored at different time points; acute phase of infection, recovery, FHF stage, and post-recovery. Our results showed that the level of HEV Ag was elevated in AHE patients with a significantly higher level in FHF patients than recovered patients. We identified a plasma HEV Ag threshold that can differentiate between self-limiting infection and FHF progression with 100% sensitivity and 88.89% specificity. HEV Ag and HEV RNA have similar kinetics during the acute phase and self-limiting infection. In the FHF stage, HEV Ag and anti-HEV IgM have similar patterns of kinetics which could be the cause of liver damage. In conclusion, the HEV Ag assay can be used as a biomarker for predicting the consequences of HEV-1 infections which could be diagnostically useful for taking the appropriate measures to reduce the complications, especially for high-risk groups.
Recently, IL-12 emerged as a critical player in type 2 diabetes complications. We previously reported that ischemia-induced angiogenesis is compromised in type 2 diabetic mice. In this study, we determined that IL-12 disruption rescued angiogenesis and arteriogenesis in type 2 diabetic mice. To induce type 2 diabetes, wild-type (WT), p40IL-12 (p40), and p35IL-12 (p35) mice were fed a high-fat diet (HFD) for 12 weeks. Body weight, glucose test tolerance, and insulin test tolerance were assessed. After 12 weeks of an HFD, the femoral artery was ligated and blood flow recovery was measured every week for 4 weeks. WT, p40, and p35 mice fed an HFD become obese after 12 weeks and exhibit glucose intolerance and insulin resistance. Blood flow recovery was fully restored in 2 to 3 weeks after femoral artery ligation in all groups of mice fed a normal diet. However, after 12 weeks of an HFD, blood flow recovery was compromised in WT mice, whereas it was fully recovered in p40 and p35 mice. The mechanism of blood flow recovery involves an increase in capillary/arteriole density, endothelial nitric oxide synthase/Akt/vascular endothelial growth factor receptor 2 signaling, and a reduction in oxidative stress and inflammation. The disruption of IL-12 promotes angiogenesis and increases blood flow recovery in obese type 2 diabetic mice by an endothelial nitric oxide synthase/Akt/vascular endothelial growth factor receptor 2/oxidative stress-inflammation-dependent mechanism.
We previously determined that augmented EGFR tyrosine kinase (EGFRtk) impairs vascular function in type 2 diabetic mouse (TD2). Here we determined that EGFRtk causes vascular dysfunction through NADPH oxidase activity in TD2.
Mesenteric resistance arteries (MRA) from C57/BL6 and db−/db− mice were mounted in a wired myograph and pre-incubated for one hour with either EGFRtk inhibitor (AG1478) or exogenous EGF. The inhibition of EGFRtk did not affect the contractile response to phenylephrine-(PE) and thromboxane-(U46619) or endothelium-dependent relaxation (EDR) to acetylcholine in MRA from control group. However, in TD2 mice, AG1478 reduced the contractile response to U46619, improved vasodilatation and reduced p22phox-NADPH expression, but had no effect on the contractile response to PE. The incubation of MRA with exogenous EGF potentiated the contractile response to PE in MRA from control and diabetic mice. However, EGF impaired the EDR and potentiated the vasoconstriction to U46619 only in the control group. Interestingly, NADPH oxidase inhibition in the presence of EGF restored the normal contraction to PE and improved the EDR but had no effect on the potentiated contraction to U46619. Vascular function improvement was associated with the rescue of eNOS and Akt and reduction in phosphorylated-RhoKinase, NOX4 mRNA levels and NADPH oxidase activity. MRA from p47phox−/− mice incubated with EGF potentiated the contraction to U46619 but no effect to PE or ACh responses.
The present study provides evidence that augmented EGFRtk impairs vascular function by NADPH oxidase-dependent mechanism. Therefore, EGFRtk and oxidative stress should be potential targets to treat vascular dysfunction in TD2.
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