Loop-Mediated Isothermal Amplification(LAMP) for Detection of Alicyclobacillus acidoterrestris in Foods

目的:利用环介导等温扩增技术建立食品中酸土环脂芽孢杆菌快速检测方法。方法:针对酸土环脂芽孢杆菌16S序列设计特异引物,再优选反应体系,用显色法检测实验结果。结果:该方法能够在63℃条件下1 H内检出食品中酸土环脂芽孢杆菌,所设计的引物有良好的特异性;灵敏度达6.7 Cfu/M l(弱阳性)。结论:该方法具有高效、特异性强和敏感性高等特点,可满足酸土环脂芽孢杆菌快速检测筛选的要求。Purpose: A loop-mediated isothermal amplification(LAMP) method was established for the detection of Alicyclobacillus acidoterrestris in foods.Methods: After optimization of the reaction conditions of LAMP including the concentrations of primers, reaction time and amplification temperature, the LAMP method was developed, and its sensitivity and specificity were evaluated.Results: The method was capable of rapidly and specifically detecting A.acidoterrestris in foods within 1 hour at a constant temperature of 63 ℃.The sensitivity of the method was 6.7 CFU/m L and the specificity was 100%.Conclusions: The LAMP method is efficient, highly sensitive and specific, and suitable for the rapid detection of A.acidoterrestris in various food samples.福建省漳州市自然科学基金项目(ZZ2012J16

Genomic Insights into the Formation of Human Populations in East Asia

厦门大学人类学研究所、厦门大学生命科学学院细胞应激生物学国家重点实验室王传超教授课题组与哈佛医学院David Reich教授团队合作，联合全球43个单位的85位共同作者组成的国际合作团队通过古DNA精细解析东亚人群形成历史。研究人员利用古DNA数据检验了东亚地区农业和语言共扩散理论，综合考古学、语言学等证据，该研究系统性地重构了东亚人群的形成、迁徙和混合历史。这是目前国内开展的东亚地区最大规模的考古基因组学研究，此次所报道的东亚地区古人基因组样本量是以往国内研究机构所发表的样本量总和的两倍，改变了东亚地区尤其是中国境内考古基因组学研究长期滞后的局面。 该研究是由王传超教授团队与哈佛医学院（David Reich教授）、德国马普人类历史科学研究所（Johannes Krause教授）、复旦大学现代人类学教育部重点实验室（李辉教授和金力院士）、维也纳大学进化人类学系（Ron Pinhasi副教授）、南洋理工大学人文学院（Hui-Yuan Yeh助理教授）、俄罗斯远东联邦大学科学博物馆（Alexander N Popov研究员）、西安交通大学（张虎勤教授）、蒙古国国家博物馆研究中心、乌兰巴托国立大学考古系、华盛顿大学人类学系、台湾成功大学考古所、加州大学人类学系等全球43个单位的85位共同作者组成的国际合作团队联合完成的。厦门大学人类学研究所、厦门大学生命科学学院细胞应激生物学国家重点实验室为论文第一完成单位。厦门大学人类学研究所韦兰海副教授、胡荣助理教授、郭健新博士后、何光林博士后和杨晓敏硕士参与了研究工作。The deep population history of East Asia remains poorly understood due to a lack of ancient DNA data and sparse sampling of present-day people1,2. We report genome-wide data from 166 East Asians dating to 6000 BCE-1000 CE and 46 present-day groups. Hunter-gatherers from Japan, the Amur River Basin, and people of Neolithic and Iron Age Taiwan and the Tibetan plateau are linked by a deeply-splitting lineage likely reflecting a Late Pleistocene coastal migration. We follow Holocene expansions from four regions. First, hunter-gatherers of Mongolia and the Amur River Basin have ancestry shared by Mongolic and Tungusic language speakers but do not carry West Liao River farmer ancestry contradicting theories that their expansion spread these proto-languages. Second, Yellow River Basin farmers at ～3000 BCE likely spread Sino-Tibetan languages as their ancestry dispersed both to Tibet where it forms up ～84% to some groups and to the Central Plain where it contributed ～59-84% to Han Chinese. Third, people from Taiwan ～1300 BCE to 800 CE derived ～75% ancestry from a lineage also common in modern Austronesian, Tai-Kadai and Austroasiatic speakers likely deriving from Yangtze River Valley farmers; ancient Taiwan people also derived ～25% ancestry from a northern lineage related to but different from Yellow River farmers implying an additional north-to-south expansion. Fourth, Yamnaya Steppe pastoralist ancestry arrived in western Mongolia after ～3000 BCE but was displaced by previously established lineages even while it persisted in western China as expected if it spread the ancestor of Tocharian Indo-European languages. Two later gene flows affected western Mongolia: after ～2000 BCE migrants with Yamnaya and European farmer ancestry, and episodic impacts of later groups with ancestry from Turan.We thank David Anthony, Ofer Bar-Yosef, Katherine Brunson, Rowan Flad, Pavel Flegontov,Qiaomei Fu, Wolfgang Haak, Iosif Lazaridis, Mark Lipson, Iain Mathieson, Richard Meadow,Inigo Olalde, Nick Patterson, Pontus Skoglund, Dan Xu, and the four reviewers for valuable comments. We thank Naruya Saitou and the Asian DNA Repository Consortium for sharing genotype data from present-day Japanese groups. We thank Toyohiro Nishimoto and Takashi Fujisawa from the Rebun Town Board of Education for sharing the Funadomari Jomon samples, and Hideyo Tanaka and Watru Nagahara from the Archeological Center of Chiba City who are excavators of the Rokutsu Jomon site. The excavations at Boisman-2 site (Boisman culture), the Pospelovo-1 site (Yankovsky culture), and the Roshino-4 site (Heishui Mohe culture) were funded by the Far Eastern Federal University and the Institute of History,Archaeology and Ethnology Far Eastern Branch of the Russian Academy of Sciences; research on Pospelovo-1 is funded by RFBR project number 18-09-40101. C.C.W was funded by the Max Planck Society, the National Natural Science Foundation of China (NSFC 31801040), the Nanqiang Outstanding Young Talents Program of Xiamen University (X2123302), the Major project of National Social Science Foundation of China (20&ZD248), a European Research Council (ERC) grant to Dan Xu (ERC-2019-ADG-883700-TRAM) and Fundamental Research Funds for the Central Universities (ZK1144). O.B. and Y.B. were funded by Russian Scientific Foundation grant 17-14-01345. H.M. was supported by the grant JSPS 16H02527. M.R. and C.C.W received funding from the ERC under the European Union’s Horizon 2020 research and innovation program (grant No 646612) to M.R. The research of C.S. is supported 30 by the Calleva Foundation and the Human Origins Research Fund. H.L was funded NSFC (91731303, 31671297), B&R International Joint Laboratory of Eurasian Anthropology (18490750300). J.K. was funded by DFG grant KR 4015/1-1, the Baden Württemberg Foundation, and the Max Planck Institute. Accelerator Mass Spectrometry radiocarbon dating work was supported by the National Science Foundation (NSF) (BCS-1460369) to D.J.K. and B.J.C. D.R. was funded by NSF grant BCS-1032255, NIH (NIGMS) grant GM100233, the Paul M. Allen Frontiers Group, John Templeton Foundation grant 61220, a gift from Jean-Francois Clin, and the Howard Hughes Medical Institute. 该研究得到了国家自然科学基金“中国东南各族群的遗传混合”、国家社科基金重大项目“多学科视角下的南岛语族的起源和形成研究”、厦门大学南强青年拔尖人才支持计划A类、中央高校基本科研业务费等资助

栅藻sraciborskiiwzkmt预处理产糖研究

以栅藻S.raciborskii WZKMT为原料,采取5种预处理方法进行微藻破壁和多糖抽提探究,研究发现以硫酸处理法效果最佳,其最优条件为20g/L底物浓度、140℃、40 min和4%硫酸（w/v）。此外,应用傅里叶变换红外光谱（FTIR）分析酸处理前后藻体细胞的结构变化。最优条件下,葡萄糖和木糖的收率（质量分数）分别为85.8%和99.7%,葡萄糖和木糖含量可分别高达18.55 g/L和11.17 g/L

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The effects of fermentation and direct conversion of ethanol were investigated by single and mixed culture of Trichoderma reesei CICC40359 and Penicillium decumbens LSM-1 with sugarcane bagasse. Fungi biomass, total sugars concentration, enzyme solid-sta

CONVERSION OF SUGARCANE BAGASSE TO SUGARS AND ETHANOL BY MIXED CULTURE SOLID-STATE FERMENTATION

The effects of fermentation and direct conversion of ethanol were investigated by single and mixed culture of Trichoderma reesei CICC40359 and Penicillium decumbens LSM-1 with sugarcane bagasse. Fungi biomass, total sugars concentration, enzyme solid-sta

多菌混合固态发酵产纤维素酶研究

采用多菌混合发酵可以提高纤维素酶的活力,为获得高活力的纤维素酶制剂,文中以碱处理后的甘蔗渣和麸皮作为发酵产酶培养基,采用响应面法对2株纤维素酶生产菌里氏木霉CICC40359和斜卧青霉SMX固态混合发酵条件进行了优化。结果发现在发酵温度为28℃,料水比（质量体积比）1∶2.5（g/mL）的条件下,当V（青霉）∶V（木霉）为3∶1,总接种量8%（mL/g）,培养基中m（蔗渣）∶m（麸皮）为2∶1,发酵3 d时,滤纸酶活有最大值达到101.825 FPU/g,这为后续优化工作的开展提供了依据,同时高酶活下发酵液中呈现高的糖质量分数为同步产酶发酵产乙醇提供了新思路

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木聚糖酶的分离纯化是对其进行酶学研究和分子改良研究的基础。利用实验室选育的黑曲霉菌株Aspergillus niger SM24/a进行木聚糖酶发酵,粗酶液经过（NH4）2SO4分级沉淀Bio-Gel P6除盐、UNO sphere Q阴离子交换和Enrich SEC70凝胶色谱层析四个步骤的分离纯化,成功获得了3种木聚糖酶蛋白定义为X-Ⅰ、X-Ⅱ和X-Ⅲ。随着纯化步骤的增加,各组分酶比活力得到显著提高,其数值分别为37.41、34.56和53.96 U/mg,纯化倍数分别为3.96、3.66和5.72。经质谱分析和蛋白氨基酸序列比对,初步认定X-Ⅰ属于糖基水解酶第十家族内切-β-1,4-木聚糖酶,X-Ⅱ和X-Ⅲ均属于糖基水解酶第十一家族木聚糖酶

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本实用新型公开了一种无人机自主动平台起降辅助装置，该装置包括矩形套筒、直流减速电机、直流减速电机螺杆、电机滑块、压缩弹簧、矩形滑块和鱼叉结构，矩形套筒设有矩形套筒顶盖及鱼叉结构伸出孔，直流减速电机固定安装在矩形套筒顶盖上，压缩弹簧一端与矩形套筒顶盖连接，另一端与矩形滑块连接，矩形滑块与鱼叉结构连接，矩形滑块沿直流减速电机螺杆滑动，直流减速电机驱动电机滑块，电机滑块沿直流减速电机螺杆滑动，推动矩形滑块，矩形滑块带动鱼叉结构缩回矩形套筒；直流减速电机反转驱动电机滑块沿相反方向滑动，鱼叉结构伸出矩形套筒。本实用新型驱动方式平稳性好，在起飞时保障无人机的飞行姿态及稳定性，可在鱼叉伸出状态下的任意角度直接降落

Isolation,Purification,and Identification of Xylanase from Aspergillus niger SM24/a

木聚糖酶的分离纯化是对其进行酶学研究和分子改良研究的基础。利用实验室选育的黑曲霉菌株Aspergillus niger SM24/a进行木聚糖酶发酵,粗酶液经过（NH4）2SO4分级沉淀Bio-Gel P6除盐、UNO sphere Q阴离子交换和Enrich SEC70凝胶色谱层析四个步骤的分离纯化,成功获得了3种木聚糖酶蛋白定义为X-Ⅰ、X-Ⅱ和X-Ⅲ。随着纯化步骤的增加,各组分酶比活力得到显著提高,其数值分别为37.41、34.56和53.96 U/mg,纯化倍数分别为3.96、3.66和5.72。经质谱分析和蛋白氨基酸序列比对,初步认定X-Ⅰ属于糖基水解酶第十家族内切-β-1,4-木聚糖酶,X-Ⅱ和X-Ⅲ均属于糖基水解酶第十一家族木聚糖酶