We conducted a genome-wide association study of generalized vitiligo in the Chinese Han population by genotyping 1,117 cases and 1,429 controls. The 34 most promising SNPs were carried forward for replication in samples from individuals of the Chinese Han (5,910 cases and 9,916 controls) and Chinese Uygur (713 cases and 824 controls) populations. We identified two independent association signals within the major histocompatibility complex (MHC) region (rs11966200, Pcombined=1.48x10(-48), OR=1.90; rs9468925, Pcombined=2.21x10(-33), OR=0.74). Further analyses suggested that the strong association at rs11966200 might reflect the reported association of the HLA-A*3001, HLA-B*1302, HLA-C*0602 and HLA-DRB1*0701 alleles and that the association at rs9468925 might represent a previously unknown HLA susceptibility allele. We also identified one previously undescribed risk locus at 6q27 (rs2236313, Pcombined=9.72x10(-17), OR=1.20), which contains three genes: RNASET2, FGFR1OP and CCR6. Our study provides new insights into the genetic basis of vitiligo.
Liver fibrosis is a very common condition seen in millions of patients with various liver diseases, and yet no effective treatments are available owing to poorly characterized molecular pathogenesis. Here, we show that leukocyte cell-derived chemotaxin 2 (LECT2) is a functional ligand of Tie1, a poorly characterized endothelial cell (EC)-specific orphan receptor. Upon binding to Tie1, LECT2 interrupts Tie1/Tie2 heterodimerization, facilitates Tie2/Tie2 homodimerization, activates PPAR signaling, and inhibits the migration and tube formations of EC. In vivo studies showed that LECT2 overexpression inhibits portal angiogenesis, promotes sinusoid capillarization, and worsens fibrosis, whereas these changes were reversed in Lect2-KO mice. Adeno-associated viral vector serotype 9 (AAV9)-LECT2 small hairpin RNA (shRNA) treatment significantly attenuates fibrosis. Upregulation of LECT2 is associated with advanced human liver fibrosis staging. We concluded that targeting LECT2/Tie1 signaling may represent a potential therapeutic target for liver fibrosis, and serum LECT2 level may be a potential biomarker for the screening and diagnosis of liver fibrosis. (A) LECT2 inhibited the migration of EA.hy926 cell. Scale bar, 100 mm. (B) LECT2 inhibited tube formation of EA.hy926 cell. Scale bar, 200 mm. (C) Inhibition of LECT2 enhanced migration of EA.hy926 cell. Scale bar, 100 mm. (D) Inhibition of LECT2 enhanced tube formation of EA.hy926 cell. Scale bar, 200 mm. (E) LECT2 inhibited the migration of primary liver sinusoid endothelial cell (LSEC). Scale bar, 100 mm. (F) LECT2 inhibited tube formation of primary LSEC. Scale bar, 200 mm. (G) Liver tissues were immunohistochemically stained for CD31. Arrows indicate portal vessels, and arrowheads indicate capillarization of liver sinusoids. Scale bar, 200 mm. (H) The number of CD31-positive vessels surrounding the portal area was measured. (I) The CD31-positive capillarization of liver sinusoids was measured. (J) Liver tissues were immunohistochemically stained for CD31. Arrows indicate portal vessels, and arrowheads indicate capillarization of liver sinusoids. Scale bar, 200 mm. (K) The number of CD31-positive vessels surrounding the portal area was measured. (L) The CD31-positive capillarization of liver sinusoids was measured.
Pd-catalyzed decarboxylative cross-coupling of aryl iodides, bromides, and chlorides with potassium oxalate monoesters has been discovered. This reaction is potentially useful for laboratory-scale synthesis of aryl and alkenyl esters. Bulky, electron-rich bidentate phosphine ligands are preferred in the reaction, whereas Cu is not needed for decarboxylation. Theoretical calculations suggest a five-coordinate Pd(II) transition state for decarboxylation with an energy barrier of approximately 30 kcal/mol.
Nanozymes
that mimic peroxidase (POD) activity can convert H2O2 into bactericidal free radicals, which is referred
to as chemodynamic therapy (CDT). High glutathione (GSH) levels in
the infectious tissue severely limit the performance of CDT. Herein,
we report a near-infrared-controlled antibacterial nanoplatform that
is based on encapsulating tungsten sulfide quantum dots (WS2QDs) and the antibiotic vancomycin in a thermal-sensitive liposome.
The system exploits the photothermal sensitivity of the WS2QDs to achieve selective liposome rupture for the targeted drug delivery.
We determined that WS2QDs show a strong POD-like activity
under physiological conditions and the oxidase-like activity, which
can oxidate GSH to further improve the CDT efficacy. Moreover, we
found that increased temperature promotes multiple enzyme-mimicking
activities of WS2QDs. This platform exerts antibacterial
effects against Gram-positive Mu50 (a vancomycin-intermediate Staphylococcus aureus reference strain) and Gram-negative Escherichia coli and disrupts biofilms for improved
penetration of therapeutic agents inside biofilms. In vivo studies with mice bearing Mu50-caused skin abscess revealed that
this platform confers potent antibacterial activity without obvious
toxicity. Accordingly, our work illustrates that the photothermal
and nanozyme properties of WS2QDs can be deployed alongside
a conventional therapeutic to achieve synergistic chemodynamic/photothermal/pharmaco
therapy for powerful antibacterial effects.
One of the rising demands in the field of protein chemical synthesis is the development of facile strategies that yield the protein in workable quantities and homogeneity, with fewer handling steps. Although the native chemical ligation of peptide hydrazides has recently been shown to be useful for the chemical synthesis of proteins carrying acid-sensitive modification groups, previous hydrazide-based protein synthesis studies have used sequential ligation strategies. Here, we report a practical method for a "one-pot" native chemical ligation of peptide hydrazides that would circumvent the need for the isolation of the intermediate products. This method employed a fast and selective arylboronate oxidation reaction mediated by H2O2, which draws attention to the potential applications of the thus far under-exploited boron-based functionalities in protein chemical synthesis. To demonstrate the practicality and efficiency of the new one-pot method, we report its application to a scalable total synthesis of modified histones (with five analogues of H3 and H4 as examples) on a multi-milligram scale, with good homogeneity.
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