Integrated untargeted fecal metabolomics and gut microbiota strategy for screening potential biomarkers associated with schizophrenia.

Schizophrenia (SZ) is a serious neurodevelopmental disorder. As the etiology of SZ is complex and the pathogenesis is not thoroughly understood, the diagnosis of different subtypes still depends on the subjective judgment of doctors. Therefore, there is an urgent need to develop early objective laboratory diagnostic biomarkers to screen different subtypes of patients as early as possible, and to implement targeted prevention and precision medicine to reduce the risk of SZ and improve patients' quality of life. In this study, untargeted metabolomics and 16S rDNA sequencing were used to analyze the differences in metabolites and gut microflora among 28 patients with two types of schizophrenia and 11 healthy subjects. The results showed that the metabolome and sequencing data could effectively discriminate among paranoid schizophrenia patients, undifferentiated schizophrenia patients and healthy controls. We obtained 65 metabolites and 76 microorganisms with significant changes, and fecal metabolite composition was significantly correlated with the differential genera (|r|>0.5), indicating that there was a regulatory relationship between the gut microbiota and the host metabolites. The gut microbiome, as an objective and measurable index, showed good diagnostic value for distinguishing schizophrenia patients from healthy people, especially with a combination of several differential microorganisms, which had the best diagnostic effect (AUC>0.9). Our results are conducive to understanding the complicated metabolic changes in SZ patients and providing valuable information for the clinical diagnosis of SZ.

Role of Innate Immunity in Pediatric Post-transplant Idiopathic Liver Fibrosis.

Pediatric post-transplant idiopathic liver fibrosis is an unexplained graft fibrosis that occurs in symptom-free children without acute rejection and surgical complications. Despite a lack of consensus on the subject, the development of pediatric post-transplant idiopathic liver fibrosis is believed to be the result of multiple potential factors, including ischemia-reperfusion injury, allogeneic acute and chronic rejection, viral hepatitis recurrence, opportunistic infection, and drug-induced liver damage. Among them, there is growing evidence that innate immunity may also have a unique role in this progression. This study reviews the features of pediatric post-transplant idiopathic liver fibrosis and discusses current studies illustrating the potential mechanisms of liver allograft tolerance induced by intrahepatic innate immunity, the role of components including Toll-like receptors (TLRs), interferons (IFN), dendritic cells (DC), natural killer cells (NK cells), NKT cells, neutrophils, and Kupffer cells, as well as their possibly relevant role in the development of pediatric post-transplant idiopathic liver fibrosis.

Co2+ anchored on surface-functionalized PET non-woven fabric and used as high efficiency monoatom-like catalyst for activating Oxone in water.

Fenton-like processes have emerged as most promising techniques for generating reactive oxygen-containing radicals to deal with increasing levels of environmental pollution. Developing novel catalysts with simple manufacturing requirements, excellent activity levels, and stability remains a long-term goal in terms of practical application. So herein, a new polyethylene terephthalate (PET) non-woven fabric based composite catalyst has been fabricated, using radiation-induced graft polymerization of a functionalized group to chelate Co2+ ions as heterogeneous catalysts in peroxymonosulfate (Oxone) activation. Several impact factors, including catalyst dosage, Oxone concentration, reaction temperature, pH value, Co2+ precipitation ratio (of Co@PET at different pH values), and highly concentrated NaCl have been investigated here. Notably, Co@PET has shown the lowest activation energy of any reported catalyst, for degrading RhB by activating Oxone. Interestingly, as experimental RhB and Oxone solutions were passed through single Co@PET sheets, the RhB was decomposed into a colorless solution in the penetration process. Based on radical trapping and quenching experiments, a channel was determined to dominate RhB degradation, and furthermore, Co@PET could be re-used for RhB degradation by activating Oxone. These results showed that Co@PET effectively provided improved Fenton-like catalytic performance and stability, and was suitable for practical applications.

Facile Synthesis of Novel V0.13Mo0.87O2.935 Nanowires With High-Rate Supercapacitive Performance.

Binary metal oxides composed of molybdenum-vanadium oxides are promising candidates for supercapacitors. Here, we report the synthesis of one-dimensional V0.13Mo0.87O2.935 nanowires through a facile one-step hydrothermal method. This nanowire presented a high specific capacitance of 394.6 F g-1 (1 mV s-1) as an electrode applied to the supercapacitor. Importantly, this electrode showed a perfect rate capability of 91.5% (2 to 10 A g-1) and a continuous verified outstanding cyclic voltammetry of 97.6% after 10,000 cycles. These superior electrochemical properties make the synthesized V0.13Mo0.87O2.935 nanowires a prospective candidate for high-performance supercapacitors.

Characterization of the NADP-malic enzymes in the woody plant Populus trichocarpa.

Plant NADP-malic enzyme (NADP-ME, EC 1.1.1.40) participates in a large number of metabolic pathways, but little is known about the NADP-ME family in woody plants or trees. Here, we characterized the tree Populus trichocarpa NADP-ME (PtNADP-ME) family and the properties of the family members. Five NADP-ME genes (PtNADP-ME1-PtNADP-ME5) were found in the genome of Populus. Semi-quantitative RT-PCR analysis show that the transcription levels of PtNADP-ME1 in lignified stems and roots are clearly higher than in other tissues, and PtNADP-ME2, PtNADP-ME3, PtNADP-ME4 and PtNADP-ME5 are broadly expressed in various tissues. PtNADP-ME gene expression was found to respond to salt and osmotic stresses, and NaCl salts upregulated the transcripts of putative plastidic ones (PtNADP-ME4 and PtNADP-ME5) significantly. Further, the NADP-ME activities of Populus seedlings increased at least two-fold under NaCl, mannitol and PEG treatments. Also, the expression of PtNADP-ME2 and PtNADP-ME3 increased during the course of leaf wounding. Each recombinant PtNADP-ME proteins were expressed and purified from Escherichia coli, respectively. Coomassie brilliant blue and NADP-ME activity staining on native polyacrylamide gels showed different oligomeric states of the recombinant PtNADP-MEs in vitro. Noticeably, the cytosolic PtNADP-ME2 aggregates as octamers and hexadecamers while the plastidic PtNADP-ME4 resembles hexamers and octamers. The four PtNADP-ME proteins except for PtNADP-ME1 have high activities on native polyacrylamide gels including different forms for PtNADP-ME2 (octamers and hexadecamers) or for PtNADP-ME4 (hexamers and octamers). High concentrations of NADP substrate decreased the activities of all PtNADP-MEs slightly, while the malate had no effect on them. The kinetic parameters (V (max), K (m), K (cat), and K (cat)/K (m)) of each isoforms were summarized. Our data show the different effects of metabolites (influx into tricarboxylic acid cycle or Calvin cycle) on the activity of the individual PtNADP-ME in vitro. According to phylogenetic analysis, five PtNADP-MEs are clustered into cytosolic dicot, plastidic dicot, and monocot and dicot cytosolic groups in a phylogenetic tree. These results suggest that woody Populus NADP-ME family have diverse properties, and possible roles are discussed.