Tao Wang scite author profile

The spin–orbit interaction enables interconversion between a charge current and a spin current. It is usually believed that in a nonmagnetic metal (NM) or at a NM/ferromagnetic metal (FM) bilayer interface, the symmetry of spin–orbit effects requires that the spin current, charge current, and spin orientation are all orthogonal to each other. Here we demonstrate the presence of spin–orbit effects near the NM/FM interface that exhibit a very different symmetry, hereafter referred to as spin-rotation symmetry, from the conventional spin Hall effect while the spin polarization is rotating about the magnetization. These results imply that a perpendicularly polarized spin current can be generated with an in-plane charge current simply by use of a FM/NM bilayer with magnetization collinear to the charge current. The ability to generate a spin current with arbitrary polarization using typical magnetic materials will benefit the development of magnetic memories.

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In Vitro CRISPR/Cas9 System for Efficient Targeted DNA Editing

Liu

Wang

Wen

et al. 2015

mBio

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The clustered regularly interspaced short palindromic repeat (CRISPR)/CRISPR-associated protein 9 (Cas9) system, an RNA-guided nuclease for specific genome editing in vivo, has been adopted in a wide variety of organisms. In contrast, the in vitro application of the CRISPR/Cas9 system has rarely been reported. We present here a highly efficient in vitro CRISPR/Cas9-mediated editing (ICE) system that allows specific refactoring of biosynthetic gene clusters in Streptomyces bacteria and other large DNA fragments. Cleavage by Cas9 of circular pUC18 DNA was investigated here as a simple model, revealing that the 3′→5′ exonuclease activity of Cas9 generates errors with 5 to 14 nucleotides (nt) randomly missing at the editing joint. T4 DNA polymerase was then used to repair the Cas9-generated sticky ends, giving substantial improvement in editing accuracy. Plasmid pYH285 and cosmid 10A3, harboring a complete biosynthetic gene cluster for the antibiotics RK-682 and holomycin, respectively, were subjected to the ICE system to delete the rkD and homE genes in frame. Specific insertion of the ampicillin resistance gene (bla) into pYH285 was also successfully performed. These results reveal the ICE system to be a rapid, seamless, and highly efficient way to edit DNA fragments, and a powerful new tool for investigating and engineering biosynthetic gene clusters.

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A new esterase EstD2 isolated from plant rhizosphere soil metagenome

Lee

Hong

Malhotra

et al. 2010

Appl Microbiol Biotechnol

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Soil metagenome constitutes a reservoir for discovering novel enzymes from the unculturable microbial diversity. From three plant rhizosphere metagenomic libraries comprising a total of 142,900 members of recombinant plasmids, we obtained 14 recombinant fosmids that exhibited lipolytic activity. A selected recombinant plasmid, pFLP-2, which showed maximum lipolytic activity, was further analyzed. DNA sequence analysis of the subclone in pUC119, pELP-2, revealed an open reading frame of 1,191 bp encoding a 397-amino-acid protein. Purified EstD2 exhibited maximum enzymatic activity towards p-nitrophenyl butyrate, indicating that it is an esterase. Purified EstD2 showed optimal activity at 35 °C and at pH 8.0. The K(m) and K(cat) values were determined to be 79.4 μM and 120.5/s, respectively. The esterase exhibited an increase in enzymatic activity in the presence of 15% butanol and 15% methanol. Phylogenetic analysis revealed that the lipolytic protein EstD2 may be a member of a novel family of lipolytic enzymes. Several hypothetical protein homologs of EstD2 were found in the database. A hypothetical protein from Phenylobacterium zucineum HLK1, a close homolog of EstD2, displayed lipolytic activity when the corresponding gene was expressed in Escherichia coli. Our results suggest that the other hypothetical protein homologs of EstD2 might also be members of this novel family.

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A genomics-led approach to deciphering the mechanism of thiotetronate antibiotic biosynthesis

et al. 2016

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A genetic and bioinformatic analysis ofStreptomyces coelicolorgenes containing TTA codons, possible targets for regulation by a developmentally significant tRNA

Wang

et al. 2007

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The rarest codon in the high G+C genome of Streptomyces coelicolor is TTA, corresponding in mRNA to the UUA codon that is recognized by a developmentally important tRNA encoded by the bldA gene. There are 145 TTA-containing genes in the chromosome of S. coelicolor. Only 42 of these are represented in the genome of Streptomyces avermitilis, among which only 12 have a TTA codon in both species. The TTA codon is less represented in housekeeping genes and orthologous genes, and is more represented in functional-unknown, extrachromosomal or weakly expressed genes. Twenty one TTA-containing chromosomal genes in S. coelicolor were disrupted, including 12 of the 42 genes that are common to both S. avermitillis and S. coelicolor. None of the mutant strains showed any obvious phenotypic differences from the wild-type strain under tested conditions. Possible reasons for this, and the role and evolution of the observed distribution of TTA codons among Streptomyces genes were discussed.

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Interfacial control of Dzyaloshinskii-Moriya interaction in heavy metal/ferromagnetic metal thin film heterostructures

et al. 2016

Phys. Rev. B

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The interfacial Dzyaloshinskii-Moriya Interaction (DMI) in ultrathin magnetic thin film heterostructures provides a new approach for controlling spin textures on mesoscopic length scales. Here we investigate the dependence of the interfacial DMI constant on a Pt wedge insertion layer in Ta/CoFeB/Pt(wedge)/MgO thin films by observing the asymmetric spin wave dispersion using Brillouin light scattering. Continuous tuning of by more than a factor of three is realized by inserting less than one monolayer of Pt. The observations provide new insights for designing magnetic thin film heterostructures with tailored for controlling skyrmions and magnetic domain wall chirality and dynamics.

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Inactivation of Chloramphenicol and Florfenicol by a Novel Chloramphenicol Hydrolase

Wang

Lee

et al. 2012

Appl Environ Microbiol

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ABSTRACTChloramphenicol and florfenicol are broad-spectrum antibiotics. Although the bacterial resistance mechanisms to these antibiotics have been well documented, hydrolysis of these antibiotics has not been reported in detail. This study reports the hydrolysis of these two antibiotics by a specific hydrolase that is encoded by a gene identified from a soil metagenome. Hydrolysis of chloramphenicol has been recognized in cell extracts ofEscherichia coliexpressing a chloramphenicol acetate esterase gene,estDL136. A hydrolysate of chloramphenicol was identified asp-nitrophenylserinol by liquid chromatography-mass spectroscopy and proton nuclear magnetic resonance spectroscopy. The hydrolysis of these antibiotics suggested a promiscuous amidase activity of EstDL136. WhenestDL136was expressed inE. coli, EstDL136 conferred resistance to both chloramphenicol and florfenicol onE. coli, due to their inactivation. In addition,E. colicarryingestDL136deactivated florfenicol faster than it deactivated chloramphenicol, suggesting that EstDL136 hydrolyzes florfenicol more efficiently than it hydrolyzes chloramphenicol. The nucleotide sequences flankingestDL136encode proteins such as amidohydrolase, dehydrogenase/reductase, major facilitator transporter, esterase, and oxidase. The most closely related genes are found in the bacterial familySphingomonadaceae, which contains many bioremediation-related strains. Whether the gene cluster withestDL136inE. coliis involved in further chloramphenicol degradation was not clear in this study. While acetyltransferases for chloramphenicol resistance and drug exporters for chloramphenicol or florfenicol resistance are often detected in numerous microbes, this is the first report of enzymatic hydrolysis of florfenicol resulting in inactivation of the antibiotic.

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Divergent Biosynthesis of C-Nucleoside Minimycin and Indigoidine in Bacteria

Kong

Liu

et al. 2019

iScience

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SummaryMinimycin (MIN) is a C-nucleoside antibiotic structurally related to pseudouridine, and indigoidine is a naturally occurring blue pigment produced by diverse bacteria. Although MIN and indigoidine have been known for decades, the logic underlying the divergent biosynthesis of these interesting molecules has been obscure. Here, we report the identification of a minimal 5-gene cluster (min) essential for MIN biosynthesis. We demonstrated that a non-ribosomal peptide synthetase (MinA) governs “the switch” for the divergent biosynthesis of MIN and the cryptic indigoidine. We also demonstrated that MinCN (the N-terminal phosphatase domain of MinC), MinD (uracil phosphoribosyltransferase), and MinT (transporter) function together as the safeguard enzymes, which collaboratively constitute an unusual self-resistance system. Finally, we provided evidence that MinD, utilizing an unprecedented substrate-competition strategy for self-resistance of the producer cell, maintains competition advantage over the active molecule MIN-5′-monophosphate by increasing the UMP pool in vivo. These findings greatly expand our knowledge regarding natural product biosynthesis.

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Tao Wang

Observation of spin-orbit effects with spin rotation symmetry

In Vitro CRISPR/Cas9 System for Efficient Targeted DNA Editing

A new esterase EstD2 isolated from plant rhizosphere soil metagenome

A genomics-led approach to deciphering the mechanism of thiotetronate antibiotic biosynthesis

A genetic and bioinformatic analysis ofStreptomyces coelicolorgenes containing TTA codons, possible targets for regulation by a developmentally significant tRNA

Interfacial control of Dzyaloshinskii-Moriya interaction in heavy metal/ferromagnetic metal thin film heterostructures

Inactivation of Chloramphenicol and Florfenicol by a Novel Chloramphenicol Hydrolase

Divergent Biosynthesis of C-Nucleoside Minimycin and Indigoidine in Bacteria

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