人冠状病毒HCoV-NL63和HCoV-HKU1常规RT-PCR与实时荧光定量RT-PCR检测方法的建立及应用比较

分别设计HCoV-NL63和HCoV-HKU1特异的引物与荧光标记探针,并合成含靶基因的模板RNA,建立常规RT-PCR方法与实时荧光定量RT-PCR方法,对其灵敏性、特异性和可重复性以及用于临床样本的适用性等进行平行比较评价.结果表明:这两种方法皆可对HCoV-NL63或HCoV-HKU1进行特异性诊断,其中荧光定量RT-PCR方法检测灵敏度均可达10拷贝/25μL反应体积,不同批次重复检测结果间的变异系数均小于5%.上述方法应用于158份临床鼻咽拭子标本,其中荧光定量RT-PCR方法检出6份HCoV-NL63阳性标本,5份HCoV-HKU1阳性标本,而常规RT-PCR方法则分别检出HCoV-NL63阳性与HCoV-HKU1阳性各3份.对常规RT-PCR方法获得的阳性样品进行序列分析证实上述方法的可靠性.本实验成功建立了可用于临床标本检测的人冠状病毒HCoV-NL63和HCoV-HKU1常规RT-PCR方法与实时荧光定量RT-PCR检测方法,并初步证实荧光定量RT-PCR检测方法检出率明显高于常规RT-PCR方法,这为开展HCoV-NL63和HCoV-HKU1的流行监测及临床早期诊断提供了有效技术手段.     

HSV-IgM人-鼠嵌合抗体制备及稳定细胞株构建工艺开发

为实现体外大规模制备单纯疱疹病毒HSV-IgM(HSV1,HSV2)人鼠嵌合抗体,本研究通过RNA连接酶介导的cDNA末端快速扩增(RNA ligase-mediated rapid amplification of cDNA ends,RLM-RACE)技术获取其对应杂交瘤细胞基因序列,构建嵌合抗体至真核表达载体,在CHO-S细胞中稳定表达所需目的蛋白。同时优化稳定细胞株筛选工艺,对细胞池构建阶段和单克隆筛选阶段的加压条件进行摸索与探究,最后目的抗体采用蛋白L亲和纯化法进行纯化并进行生物活性检测;最终成功制备899 kDa和909 kDa的稳定高表达重组IgM抗体(HSV1,HSV2)细胞株。结果表明,最适筛选压力为20P200M(一轮加压)和50P1000M(二轮加压);使用加压培养基进行单克隆筛选抗体表达量较高,HSV1-IgM和HSV2-IgM单克隆最终表达量分别为1620 mg/L和623 mg/L。本研究为HSV1和HSV2的IgM系列重组抗体质控品开发以及体外高表达分泌IgM亚型抗体提供理论与实践基础。     

陕西洛南盆地延岭旧石器地点发掘报告

延岭地点处于东秦岭洛南盆地南洛河第二级阶地上,属盆地西部“四十里梁塬”中部,紧邻支流县河。2012年10～11月对该地点进行发掘,揭露面积251 m²,在地表耕土层和平整土地扰动层、原生黄土和古土壤层出土石料、石核、石片、各类修理的石器、断块、碎屑等不同类型石制品856件。延岭地点加工石制品的主要原料为附近河流阶地砾石堆积中的砾石,以石英为主,石英岩次之,石英砂岩、砂岩、火成岩、硅质岩等偶有使用。剥片方式主要为锤击法,偶见砸击法。石制品以小型为主。石器组合包括刮削器、尖状器、石锥、凹缺器、薄刃斧和手镐。遗址地层光释光年代学研究显示该地点埋藏石制品的地层形成于中更新世晚期至晚更新世早期,其中距今12～7万年之间的晚更新世早期为石制品埋藏最为丰富的时段。     

Conservation of Chinese Theaceae species under future climate and land use changes

Aim

Climate and land use changes are two major pervasive and growing global causes of rapid changes in the distribution patterns of biodiversity, challenging the future effectiveness of protected areas (PAs), which were mainly designed based on a static view of biodiversity. Therefore, evaluating the effectiveness of protected areas for protecting the species threatened by climate and land use change is critical for future biodiversity conservation.

Location

China.

Methods

Here, using distributions of 200 Chinese Theaceae species and ensemble species distribution models, we identified species threatened by future climate and land use change (i.e. species with predicted loss of suitable habitat ≥30%) under scenarios incorporating climate change, land use change and dispersal. We then estimate the richness distribution patterns of threatened species and identify priority conservation areas and conservation gaps of the current PA network.

Results

Our results suggest that 36.30%–51.85% of Theaceae species will be threatened by future climate and land use conditions and that although the threatened species are mainly distributed at low latitudes in China under both current and future periods, the mean richness of the threatened species per grid cell will decline by 0.826–3.188 species by the 2070s. Moreover, we found that these priority conservation areas are highly fragmented and that the current PA network only covers 14.21%–20.87% of the ‘areas worth exploring’ and 6.91%–7.91% of the ‘areas worth attention’.

Main Conclusions

Our findings highlight the necessity of establishing new protected areas and ecological corridors in priority conservation areas to protect the threatened species. Moreover, our findings also highlight the importance of taking into consideration the potential threatened species under future climate and land use conditions when designating priority areas for biodiversity conservation.     

广藿香内生真菌Ogataea sp. RW-S10次级代谢产物研究

为挖掘广藿香(Pogostemon cablin)内生真菌活性代谢产物,采用多种柱色谱分离方法从广藿香内生真菌Ogataea sp.RW-S10的次级代谢产物中分离得到7个化合物,根据波谱数据分别鉴定为ogataearin (1)、phenylalaninol (2)、对羟基苯乙酮(3)、bis(dethio)bis(methylsulfanyl) gliotoxin (4)、N-苯乙基乙酰胺(5)、lumichrome (6)和dehydroxypaxilline (7),其中化合物1为新化合物。化合物1具有α-葡萄糖苷酶抑制活性,其IC₅₀值为39.38 μmol/L。     

雄性不育高粱线粒体与细胞核对热激的反应及其与育性关系的研究

由于我们发现热激(40℃)能诱导雄性不育高粱转变为雄性可育型的现象,故进一步探讨此现象的机理,研究了在热激条件下其细胞质(取其细胞质重要遗传物质——线粒体)中及细胞核中蛋白质的变化。试验结果,发现不育系的花粉母细胞期幼穗,在热激时细胞核中出现特异的80KD热激蛋白,且能被利福霉素、氯霉素所抑制。保持系在热激时细胞核中未出现此蛋白。80KD蛋白在结合部位存在的性质与其存在于细胞核中和线粒体中的现象是一致的。这种差异说明与雄性不育有关,且其原因是由细胞核与细胞质共同作用所致。     

Degradation of the gluconeogenic enzymes fructose-1,6-bisphosphatase and malate dehydrogenase is mediated by distinct proteolytic pathways and signaling events

The key gluconeogenic enzyme fructose-1,6-bisphosphatase (FBPase) is subjected to catabolite inactivation and degradation when glucose-starved cells are replenished with fresh glucose. In various studies, the proteasome and the vacuole have each been reported to be the major site of FBPase degradation. Because different growth conditions were used in these studies, we examined whether variations in growth conditions could alter the site of FBPase degradation. Here, we demonstrated that FBPase was degraded outside the vacuole (most likely in the proteasome), when glucose was added to cells that were grown in low glucose media for a short period of time. By contrast, cells that were grown in the same low glucose media for longer periods of time degraded FBPase in the vacuole in response to glucose. Another gluconeogenic enzyme malate dehydrogenase (MDH2) showed the same degradation characteristics as FBPase in that the short term starvation of cells led to a non-vacuolar degradation, whereas long term starvation resulted in the vacuolar degradation of this protein. The N-terminal proline is required for the degradation of FBPase and MDH2 for both the vacuolar and non-vacuolar proteolytic pathways. The cAMP signaling pathway and the phosphorylation of glucose were needed for the vacuolar-dependent degradation of FBPase and MDH2. By contrast, the cAMP-dependent signaling pathway was not involved in the non-vacuolar degradation of these proteins, although the phosphorylation of glucose was required.