The Cashmere goat is mainly used to produce cashmere, which is very popular for its delicate fiber, luscious softness and natural excellent warm property. Keratin associated protein (KAP) and bone morphogenetic protein (BMP) of the Cashmere goat play an important role in the proliferation and development of cashmere fiber follicle cells. Bacterial artificial chromosome containing kap6.3, kap8.1 and bmp4 genes were used to increase the production and quality of Cashmere. First, we constructed bacterial artificial chromosomes by homology recombination. Then Tol2 transposon was inserted into bacterial artificial chromosomes that were then transfected into Cashmere goat fibroblasts by Amaxa Nucleofector technology according to the manufacture's instructions. We successfully constructed the BAC-Tol2 vectors containing target genes. Each vector contained egfp report gene with UBC promoter, Neomycin resistant gene for cell screening and two loxp elements for resistance removing after transfected into cells. The bacterial artificial chromosome-Tol2 vectors showed a high efficiency of transfection that can reach 1% to 6% with a highest efficiency of 10%. We also obtained Cashmere goat fibroblasts integrated exogenous genes (kap6.3, kap8.1 and bmp4) preparing for the clone of Cashmere goat in the future. Our research demonstrates that the insertion of Tol2 transposons into bacterial artificial chromosomes improves the transfection efficiency and accuracy of bacterial artificial chromosome error-free recombination.
Animals ; Bone Morphogenetic Proteins ; genetics ; Chromosomes, Artificial, Bacterial ; DNA Transposable Elements ; Fibroblasts ; Goats ; genetics ; Keratins ; genetics ; Transfection

Objective To evaluate the performance of Beckman Coulter Enhanced troponin Ⅰ immunoassay system (including the limit of detection and total imprecision) and establish the 99th percentile of Enhanced troponin Ⅰ in apparently healthy Chinese people in Kunming and Wuhan.Methods Evaluated the limit of detection and total imprecision of Beckman Enhanced troponin Ⅰ according to protocols EP of Clinical Laboratory Standards Institute; chose apparently healthy people from Wuhan (average altitude of 27 m) which represents plain regions,and Kunming (average altitude of 1895 m) which represents plateau regions.760 subjects from Wuhan were selected,aging from 30 to 91,included 400 males and 360 females.A total of 192 subjects from Kunming were selected,aging from 30 and 77,60 patients,which included 60 male and 132 female cases.To calculate the 99th percentile of Enhanced troponin Ⅰ by region,age,and gender.Results The limit of detection of Beckman Enhanced troponin Ⅰ is 0.013 μg/L,the cTnI concentration is 0.025 μg/L at 10％ CV.The 99th percentile of Enhanced troponin Ⅰ of the total population in Wuhan is 0.036 μg/L,the 99th percentile of men and women are 0.038 μg/L and 0.035 μg/L respectively,the 99th percentile in the 30-69 years group and over 70 years group are 0.038 μg/L and 0.035 μg/L respectively.The 99th percentile of Enhanced troponin Ⅰ of the total population in Kunming is 0.040 μg/L.To keep the 2nd digit after decimal point for results from Wuhan and Kunming,the 99th percentile of Enhanced troponin Ⅰ of the apparently healthy Chinese in 0.04 μg/L,where the CV is 8.23％.The percentage of positive samples detected below the 99th percentile in the normal reference population in Wuhan is 94％.Conclusions The 99th percentile of Beckman Enhanced troponin Ⅰ of the Chinese apparently healthy people is 0.04 μg/L,where the total imprecision is 8.23％,and the detection performance reach the acceptable levels per the guideline.

Objective To prepare SDF-1 α-loaded nanoliposome ( SNP )-SonoVue complex and investigate its tracing abilities, sustained-release property and effect on migration of bone marrow mesenchymal stem cells (BMSCs). Methods The SNP was prepared to detect its physical characteristics including particle size,zeta potential, morphology, encapsulation efficiency and drug loading.SNP-SonoVue was constructed to detect the sustained release situation of SNP and SNP-SonoVue after low frequency ultrasound ( LIFU ) irradiation, and the connection of SNP-SonoVue was observed by fluorescence microscope. Effects of SNP-SonoVue on migration of BMSCs were detected to evaluate its bioactivity. BMSCs were divided into 6 groups,including Group A: SDF-1α+ 1% serum medium;Group B: SNP- SonoVue+ 1% serum culture medium;Group C:SNP-SonoVue+ 1% serum culture medium + LIFU ( 1 MHz,0.5 W/cm2, expose 30 s stop 30 s, 4 min);Group D: BNP-SonoVue+1% serum medium;Group E:BNP-SonoVue+1% serum medium+LIFU ( 1 MHz, 0.5 W/cm2, expose 30 s stop 30 s, 4 min),Group F:PBS+1% serum culture medium (control group). Its tracing abilitie were investigated in vitro. Results The average particle size of SNP was(220.4±9.9)nm,and the particle dispersion index(PDI) was(0.172± 0.015), the average zeta potential was ( 35.6 ± 1.7) mv. It was showed spherical dispersion by transmission electron microscopy. The encapsulation efficiency was up to 96.7% and the drug entrapment content was 481.76 ng/mg. Flow cytometric showed the suitable conditions for SNP-SonoVue preparation was that the ratio of SNP quality(mg) to Sono Vue microbubbles number(a) was20:(2.8×109)to40:(2.8× 109). Fluorescence microscopy showed that shells of SonoVue microbubbles connected with large numbers of SNP labeled with red fluorescent DiI. Drug release experiment showed that the cumulative SDF-1α release amount of SNP and SNP-SonoVue exposed to LIFU respectively were ( 68.61 ± 3.97 )% and ( 63.21 ± 5.68)% in vitro within 7 days, and the difference was not statistically significant ( P ＞ 0.05 ). Cell migration experiments confirmed that the transfer function of BMSCs in Group A, Ggroup B and group C was significantly higher than that in control group ( P ＜ 0.05 ), but there was no significant difference among the Group A, Ggroup B and group C ( P ＞0.05). In vitro development experiment showed that the SNP-SonoVue complex had obviously enhanced development effect. Conclusions SNP-SonoVue complex is successfully prepared. It has obviously enhanced development effect and can lead to migration of BMSCs.

Dioxins, polybrominated diphenyl ethers, and benzo(a)pyrene are common organic pollutants in food. They have been of concern to academics and government administrations due to high residue and persistence, easy accumulation and strong harmful effects. The National Research Council of the United States of America published Toxicity Testing in the 21st Century: A Vision and Strategy in 2007, which proposed a new concept of toxicity testing that toxicity testing should take full consideration of population exposure data and base on in vitro tests, human cell lines, toxicity pathways and high?throughput screening. Meanwhile, systems biology, bioinformatics and rapid assay technologies will be used to better understand toxicity pathways—the cellular response pathways that can lead to adverse health effects when sufficient perturbing induced by chemicals exposure. The new toxicity testing strategy has changed the traditional testing pattern and has brought a wide impact on the international relevant fields. The European Union, the World Health Organization, and the United States Environmental Protection Agency, the Food and Drug Administration, and the National Center for Toxicological Research have organized relevant discussions and exploratory studies to address the new toxicity testing concept and how to evaluate and utilize the results of traditional toxicity test researches. Compared to the discussion,‘whether to do it’, ten years ago, the question,‘how to do it’, has become the concern of the current discussion. Therefore, how to respond to the concept of toxicity testing and how to effectively utilize and excavate traditional toxicity test data have been the focus of multi?disciplines and interdisciplinary academia such as toxicology, food hygiene and environmental science. Therefore, this article provides an overview of the exposure levels of dioxin, polybrominated diphenyl ethers and benzo[a]pyrene, which are typical persistent organic pollutants in food in China and the current research status of toxic pathways based on whole animal experiments. The exposure level, toxic effect and toxicity mechanism of three contaminants are analyzed and summarized in order to provide basis for future results based on the 21st century toxicity test compared with traditional tests and data mining analysis of these two kinds of data. Meanwhile, it also lays the foundation for the establishment of a toxicity testing framework based on exposure characteristics, toxic pathways, and biomarkers.

Dioxins, polybrominated diphenyl ethers, and benzo(a)pyrene are common organic pollutants in food. They have been of concern to academics and government administrations due to high residue and persistence, easy accumulation and strong harmful effects. The National Research Council of the United States of America published Toxicity Testing in the 21st Century: A Vision and Strategy in 2007, which proposed a new concept of toxicity testing that toxicity testing should take full consideration of population exposure data and base on in vitro tests, human cell lines, toxicity pathways and high?throughput screening. Meanwhile, systems biology, bioinformatics and rapid assay technologies will be used to better understand toxicity pathways—the cellular response pathways that can lead to adverse health effects when sufficient perturbing induced by chemicals exposure. The new toxicity testing strategy has changed the traditional testing pattern and has brought a wide impact on the international relevant fields. The European Union, the World Health Organization, and the United States Environmental Protection Agency, the Food and Drug Administration, and the National Center for Toxicological Research have organized relevant discussions and exploratory studies to address the new toxicity testing concept and how to evaluate and utilize the results of traditional toxicity test researches. Compared to the discussion,‘whether to do it’, ten years ago, the question,‘how to do it’, has become the concern of the current discussion. Therefore, how to respond to the concept of toxicity testing and how to effectively utilize and excavate traditional toxicity test data have been the focus of multi?disciplines and interdisciplinary academia such as toxicology, food hygiene and environmental science. Therefore, this article provides an overview of the exposure levels of dioxin, polybrominated diphenyl ethers and benzo[a]pyrene, which are typical persistent organic pollutants in food in China and the current research status of toxic pathways based on whole animal experiments. The exposure level, toxic effect and toxicity mechanism of three contaminants are analyzed and summarized in order to provide basis for future results based on the 21st century toxicity test compared with traditional tests and data mining analysis of these two kinds of data. Meanwhile, it also lays the foundation for the establishment of a toxicity testing framework based on exposure characteristics, toxic pathways, and biomarkers.

Dioxins, polybrominated diphenyl ethers, and benzo(a)pyrene are common organic pollutants in food. They have been of concern to academics and government administrations due to high residue and persistence, easy accumulation and strong harmful effects. The National Research Council of the United States of America published Toxicity Testing in the 21st Century: A Vision and Strategy in 2007, which proposed a new concept of toxicity testing that toxicity testing should take full consideration of population exposure data and base on in vitro tests, human cell lines, toxicity pathways and high-throughput screening. Meanwhile, systems biology, bioinformatics and rapid assay technologies will be used to better understand toxicity pathways—the cellular response pathways that can lead to adverse health effects when sufficient perturbing induced by chemicals exposure. The new toxicity testing strategy has changed the traditional testing pattern and has brought a wide impact on the international relevant fields. The European Union, the World Health Organization, and the United States Environmental Protection Agency, the Food and Drug Administration, and the National Center for Toxicological Research have organized relevant discussions and exploratory studies to address the new toxicity testing concept and how to evaluate and utilize the results of traditional toxicity test researches. Compared to the discussion, 'whether to do it’, ten years ago, the question, 'how to do it’, has become the concern of the current discussion. Therefore, how to respond to the concept of toxicity testing and how to effectively utilize and excavate traditional toxicity test data have been the focus of multi-disciplines and interdisciplinary academia such as toxicology, food hygiene and environmental science. Therefore, this article provides an overview of the exposure levels of dioxin, polybrominated diphenyl ethers and benzo[a]pyrene, which are typical persistent organic pollutants in food in China and the current research status of toxic pathways based on whole animal experiments. The exposure level, toxic effect and toxicity mechanism of three contaminants are analyzed and summarized in order to provide basis for future results based on the 21st century toxicity test compared with traditional tests and data mining analysis of these two kinds of data. Meanwhile, it also lays the foundation for the establishment of a toxicity testing framework based on exposure characteristics, toxic pathways, and biomarkers.