BackgroundSiberian apricot (Prunus sibirica L.) has emerged as a novel potential source of biodiesel in China, but the molecular regulatory mechanism of oil accumulation in Siberian apricot seed kernels (SASK) is still unknown at present. To better develop SASK oil as woody biodiesel, it is essential to profile transcriptome and to identify the full repertoire of potential unigenes involved in the formation and accumulation of oil SASK during the different developing stages.ResultsWe firstly detected the temporal patterns for oil content and fatty acid (FA) compositions of SASK in 7 different developing stages. The best time for obtaining the high quality and quantity of SASK oil was characterized at 60 days after flowering (DAF), and the representative periods (10, 30, 50, 60, and 70 DAF) were selected for transcriptomic analysis. By Illumina/Solexa sequencings, approximately 65 million short reads (average length = 96 bp) were obtained, and then assembled into 124,070 unigenes by Trinity strategy (mean size = 829.62 bp). A total of 3,000, 2,781, 2,620, and 2,675 differentially expressed unigenes were identified at 30, 50, 60, and 70 DAF (10 DAF as the control) by DESeq method, respectively. The relationship between the unigene transcriptional profiles and the oil dynamic patterns in developing SASK was comparatively analyzed, and the specific unigenes encoding some known enzymes and transcription factors involved in acetyl-coenzyme A (acetyl-CoA) formation and oil accumulation were determined. Additionally, 5 key metabolic genes implicated in SASK oil accumulation were experimentally validated by quantitative real-time PCR (qRT-PCR). Our findings could help to construction of oil accumulated pathway and to elucidate the molecular regulatory mechanism of increased oil production in developing SASK.ConclusionsThis is the first study of oil temporal patterns, transcriptome sequencings, and differential profiles in developing SASK. All our results will serve as the important foundation to further deeply explore the regulatory mechanism of SASK high-quality oil accumulation, and may also provide some reference for researching the woody biodiesel plants.Electronic supplementary materialThe online version of this article (doi:10.1186/s13068-015-0213-3) contains supplementary material, which is available to authorized users.
A comprehensive survey of electronic structure and optical properties of rare-earth ions embedded in semiconductor nanocrystals (NCs) is of vital importance for their potential applications in areas as diverse as luminescent bioprobes, lighting, and displays. Er3+ -doped anatase TiO2 NCs, synthesized via a facile sol-gel solvothermal method, exhibit intense and well-resolved intra-4f emissions of Er3+ . Crystal-field (CF) spectra of Er3+ in TiO2 NCs are systematically studied by means of high-resolution emission and excitation spectra at 10-300 K. The CF analysis of Er3+ assuming a site symmetry of C(2v) yields a small root-mean-square deviation of 25.1 cm(-1) and reveals the relatively large CF strength (549 cm(-1) ) of Er3+, thus verifying the rationality of the C(2v) symmetry assignment of Er3+ in anatase TiO2 NCs. Based on a simplified thermalization model for the temperature-dependent photoluminescence (PL) dynamics from (4) S(3/2) , the intrinsic radiative luminescence lifetimes of (4) S(3/2) and (2) H(11/2) are experimentally determined to be 3.70 and 1.73 μs, respectively. Green and red upconversion (UC) luminescence of Er3+ can be achieved upon laser excitation at 974.5 nm. The UC intensity of Er3+ in Yb/Er-codoped NCs is found to be about five times higher than that of Er-singly-doped counterparts as a result of efficient Yb3+ sensitization and energy transfer upconversion (ETU) evidenced by its distinct UC luminescence dynamics. Furthermore, the origin of defect luminescence is revealed based on the temperature-dependent PL spectra upon excitation above the TiO2 bandgap at 325 nm.
Er(3+)-ion-doped anatase TiO(2) nanocrystals were prepared by simple wet chemical synthesis. Very sharp and intense near-infrared luminescence at approximately 1.53 microm was observed that originated from the lattice site of Er(3+) ions incorporated in TiO(2) nanocrystals. Based on the high-resolution emission and excitation spectra at 10 K, an efficient energy transfer from the TiO(2) host to Er(3+) ions was verified. The luminescence decay for the I13/24-->I15/24 transition at 1.53 microm showed nonexponential characteristics, indicating a nonradiative relaxation to the defects in the nanocrystals, and the intrinsic lifetime of the I13/24 state was determined to be 1.56 ms.
The aim of this study was to investigate the toxin gene profile and antimicrobial resistance of Staphylococcus aureus isolates from raw chicken in the People's Republic of China. In total, 289 S. aureus isolates were characterized by antimicrobial susceptibility testing, and genes encoding enterotoxins, exfoliative toxins, Panton-Valentine leukocidin, and toxic shock syndrome toxin were revealed by PCR. Overall, 46.0% of the isolates were positive for one or more toxin genes. A high proportion of toxin genes were pvl (26.6%), followed by sej (12.5%), sea (9.0%), seh (8.3%), seb (6.9%), sec (6.9%), sed (4.8%), sei (3.1%), and see (2.4%). None of the isolates harbored seg, tsst-1, or exfoliative toxin genes. In total, 29 toxin gene profiles were obtained, and pvl (10.7%) was the most frequent genotype, followed by sea (5.9%), seb (4.8%), and sej (4.2%). Furthermore, 99.7% of the strains were resistant to at least one of the tested antimicrobial agents, and 87.2% of them displayed multidrug resistance. Resistance was most frequently observed to trimethoprim-sulfamethoxazole and erythromycin (86.2% for each), followed by tetracycline (69.9%), amoxicillin-clavulanic acid (45.0%), and ampicillin (42.6%). None of the strains were resistant to vancomycin. This study indicates that S. aureus isolates from raw chicken harbored multiple toxin genes and exhibited multiple antimicrobial resistance, which represents a potential health hazard for consumers.
China is in a unique period of strategic opportunity for shale oil and gas development now. There are many favorable factors such as expanding domestic natural gas market, rich resources, stimulus from the government as well as experiences and advanced technologies imported from America. Stateowned large oil companies, such as SINOPEC and PetroChina as well as Yanchang Petroleum (a provincial government company), lead shale gas exploration in China. Local state-owned and private companies are also active players. Breakthroughs have been made in development of shale resources, especially shale gas. By the end of the "Twelfth Five-Year Plan", Jiaoshiba pilot project will become the first large shale gas field of China with an annual production capacity of about 5 bcm and annual shale gas output of 3.2 bcm. However, there are also big challenges facing shale resource development in China, such as complex geological conditions, technical bottlenecks and poor infrastructure. These difficulties can be overcome through strengthening resource assessment, technical innovation and international cooperation.
It is of great significance to realize green development of high-efficient and economical catalysts modified stably on the "white plastic" surface for grid-scale hydrogen production coupling plastic degradation by alkaline...
of the global, a series of European countries have proposed to directly develop seawater electrolysis for hydrogen production, which can reduce the strong dependence on resource-constrained freshwater, and avoid energy intensive desalination. [4] However, the hydrogen evolution reaction (HER) at the cathode and oxygen evolution reaction (OER) at the anode during water electrolysis are inhibited by sluggish kinetics, and efficient electrocatalysts are required to overcome the reaction energy barrier. [5] The noble metals Pt and Ir/Ru oxides are considered benchmark catalysts for the HER and OER. However, their high cost, scarcity, and poor stability limit their large-scale applications. [6] Therefore, it is an urgent to develop efficient, stable, and economically bifunctional electrocatalysts.Porous organic frameworks (POFs), covalent organic frameworks (COFs), and metal-organic frameworks (MOFs) have been widely employed as raw materials in water electrolysis. MOFs are novel porous materials with regular and adjustable pores, high porosity, and large specific surface areas (SSAs). Thus, MOFs provide advantages, such as a strong adsorption capacity, easy modification, and abundant unsaturated metal active sites. [7] However, MOF-based catalytic materials tend to accumulate in the actual catalysis process owing to their rigorous preparation conditions requiring high pressure and temperature, leading to unstable coordination bonds between the organic ligands and central metal atoms as well as unsatisfactory stability. Furthermore, the difficulty of large numbers of overlapping highly electronegative oxygen atoms with d orbitals from other metal ions over a large area also leads to a low charge transfer efficiency of MOF-based catalysts. [8] To address this, Lin et al. successfully prepared a Pt@MOF electrode at 100 °C for 72 h, which produced a large amount of hydrogen and durable catalysis water electrolysis for 6 h. [9] Chen et al. synthesized N-doped bimetallic FeCo-MOF combined with graphene through carbonization at 800 °C, resulting in an overpotential of only 262 mV at 10 mA cm −2 during the HER. [10] Kim et al. obtained an Fe-doped MOF CoV@CoO bifunctional catalyst through a solution growth process at 80 °C under vigorous stirring, followed by in situ growth of the MOF on the surface and a final calcination step in a muffle furnace Mild construction of highly efficient and durable practical electrodes for overall water splitting (OWS) at industrial-grade current density is currently a significant challenge. Herein, metal-organic framework (MOF) materials are grown in situ on the surface of carbon cloth (CC) at 25 °C, and quickly "interspersed" by cobalt-boron (Co-B) via electroless plating for 30 min to obtain a highly efficient and stable CoB@MOF@CC self-supporting electrode. Owing to the large specific surface area, abundant active sites, and porous structure, the MOF-based CC modified by bamboo leaf-like ultrathin CoB has remarkable electrochemical catalysis efficiency. The CoB@MOF@CC electrode exhibits...
A rate feed forward control-based sensor fusion is proposed to improve the closed-loop performance for a charge couple device (CCD) tracking loop. The target trajectory is recovered by combining line of sight (LOS) errors from the CCD and the angular rate from a fiber-optic gyroscope (FOG). A Kalman filter based on the Singer acceleration model utilizes the reconstructive target trajectory to estimate the target velocity. Different from classical feed forward control, additive feedback loops are inevitably added to the original control loops due to the fact some closed-loop information is used. The transfer function of the Kalman filter in the frequency domain is built for analyzing the closed loop stability. The bandwidth of the Kalman filter is the major factor affecting the control stability and close-loop performance. Both simulations and experiments are provided to demonstrate the benefits of the proposed algorithm.
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