Deficiency of IRG1/ itaconate aggravates endotoxemia-induced acute lung injury by inhibiting autophagy in mice.

Itaconate, produced by aconitate decarboxylase 1 (ACOD1), which is encoded by immune-responsive gene 1 (Irg1), is one of the metabolites derived from the tricarboxylic acid cycle. It has been reported that exogenous itaconate plays an anti-inflammatory role in the progression of multiple diseases and pathological processes, including activated macrophage, ischemia-reperfusion injury, and acute lung injury. However, the role and specific mechanism of endogenous itaconate in endotoxemia-induced acute lung injury (ALI) remain unclear. The animal model of ALI in wild-type and Irg1-/- mice was constructed by LPS intraperitoneal injection. Ultrahigh-performance liquid chromatography-tandem mass spectroscopy (UPLC-MS/MS) analysis was performed to measure the quantity of endogenous itaconate. The protective effect of itaconate was investigated by the behavioral assessment and the levels of inflammatory cytokines. Acute lung injury was assessed by hematoxylin and eosin staining, total protein in BALF, and Evans blue leakage. Western blotting was used to detect the IRG1 expression and autophagic protein in the lung. We demonstrated that IRG1 was highly expressed in ALI and that endogenous itaconate was produced simultaneously and was 100 times higher. Using Irg1-/- mice, we found that endogenous itaconate was likely to exert an anti-inflammatory effect by activating NRF2 and promoting autophagy. Furthermore, autophagy was restrained by LPS but enhanced by 4-octyl itaconate (4-OI) pretreatment. Our study illustrated that a deficiency of IRG1/Itaconate aggravates ALI and that the IRG1/itaconate pathway protects against ALI. The protective mechanisms could be related to the facilitation of autophagy. Such findings may provide a theoretical foundation for the treatment of endotoxemia-induced ALI.

Epidemiology and evolution of novel deltacoronaviruses in birds in central China.

The variety and widespread of coronavirus in natural reservoir animals is likely to cause epidemics via interspecific transmission, which has attracted much attention due to frequent coronavirus epidemics in recent decades. Birds are natural reservoir of various viruses, but the existence of coronaviruses in wild birds in central China has been barely studied. Some bird coronaviruses belong to the genus of Deltacoronavirus. To explore the diversity of bird deltacoronaviruses in central China, we tested faecal samples from 415 wild birds in Hunan Province, China. By RT-PCR detection, we identified eight samples positive for deltacoronaviruses which were all from common magpies, and in four of them, we successfully amplified complete deltacoronavirus genomes distinct from currently known deltacoronavirus, indicating four novel deltacoronavirus stains (HNU1-1, HNU1-2, HNU2 and HNU3). Comparative analysis on the four genomic sequences showed that these novel magpie deltacoronaviruses shared three different S genes among which the S genes of HNU1-1 and HNU1-2 showed 93.8% amino acid (aa) identity to that of thrush coronavirus HKU12, HNU2 S showed 71.9% aa identity to that of White-eye coronavirus HKU16, and HNU3 S showed 72.4% aa identity to that of sparrow coronavirus HKU17. Recombination analysis showed that frequent recombination events of the S genes occurred among these deltacoronavirus strains. Two novel putative cleavage sites separating the non-structural proteins in the HNU coronaviruses were found. Bayesian phylogeographic analysis showed that the south coast of China might be a potential origin of bird deltacoronaviruses existing in inland China. In summary, these results suggest that common magpie in China carries diverse deltacoronaviruses with novel genomic features, indicating an important source of environmental coronaviruses closed to human communities, which may provide key information for prevention and control of future coronavirus epidemics.