一种金针菇核糖体失活蛋白的分离纯化研究

获得一种为研究其他菌类核糖体失活蛋白的对照品,并论述一种金针菇核糖体失活蛋白的分离纯化及其活性的研究结果。实验中采用了DEAE和CM-离子交换纤维素与Bio-Gel 100柱层析方法。从1 000 g新鲜金针菇中得到5.58 mg的核糖体失活蛋白-Velutin,并证明其具有明显的抑制蛋白质的翻译作用,同时简要介绍了它的应用及展望。分离纯化到具有活性的Velutin,分子量为13.8 ku。     

黑木耳核糖体失活蛋白的质谱分析

目的：对悬浮培养黑木耳菌丝体中分离纯化得到的核糖体失活蛋白进行质谱分析,测定其肽的指纹图谱。为用5′-RACE与3′-RACE方法,克隆和表达核糖体失活蛋白的基因,设计5′和3′末端的PCR引物。方法：使用HPLC和MALDI-TOF-MS（基质辅助激光解吸附电离飞行时间质谱）分析方法。结果：测定出肽的指纹图谱及三个随机肽段的氨基酸序列。结论：可根据所测肽段氨基酸序列设计5’-和3’-RACE的引物。     

核糖体单链失活蛋白在无细胞体系中的活性

核糖体单链失活蛋白是一类广泛分布于植物中的蛋白质,它能使真核细胞核糖体60S亚基失活。本文报道了一些核糖体单链失活蛋白的制备、纯化以及在兔网织红细胞裂解液中对蛋白质生物合成的抑制活性及它们对完整细胞的毒性。其中多数的核糖体单链失活蛋白是首次被分离纯化并对其毒性进行研究的。     

核糖体失活蛋白的结构功能与分布

核糖体失活蛋白是一类在植物中较广泛存在的毒蛋白。植物核糖体失活蛋白具有RNAN-糖苷酶活力,可作用于核糖体RNA,使核糖体失去蛋白质合成的功能。根据一级结构,核糖体失活蛋白可分为两种类型。Ⅰ型核糖体失活蛋白由一条链组成,分子量在25—30 kDa之间。Ⅱ型核糖体失活蛋白由两条以二硫键相连的链(A、B链)组成,分子量在60 kDa左右。B链可以与细胞表面含半乳糖的受体结合,有助于A链进入细胞,作用于核糖体。目前至少已从9个科31种植物中分离纯化了Ⅰ型RIP。Ⅱ型RIP较少,仅在6科8种植物中发现。除了具有RNA N-糖苷酶活性,还发现一些核糖体失活蛋白可以切割超螺旋双链DNA,产生缺口环状和线状DNA。此外,一种Ⅰ型RIP,克木毒蛋白还具有超氧化物歧化酶活性。     

麻疯树核糖体失活蛋白基因的克隆和表达

麻疯树(Jatropha curcas L.)核糖体失活蛋白(curcin)是存在于麻疯树种子中的一种毒性较强的蛋白,它与蓖麻毒蛋白和相思子毒蛋白的性质相似,属Ⅰ型核糖体失活蛋白.从麻疯树种子中分离得到一种分子量为28.2 kD的蛋白质,其对无细胞系统中蛋白质合成的抑制活性较强,IC50为(0.19±0.01)nmol/L,具有RNA N-糖苷酶活性.依据curcin的N端部分氨基酸设计简并引物,通过RT-PCR和5'-RACE技术从未成熟种子总RNA中克隆到curcin全长cDNA序列.该cDNA全长由1 173个碱基组成,包含一个编码293个氨基酸的前体蛋白,前42个氨基酸为信号肽.推测的多肽序列与测定的蛋白质N端序列相同,与多种己发表的Ⅰ型核糖体失活蛋白和Ⅱ型核糖体失活蛋白的A链有一定的同源性.将curcin的编码区与表达载体pQE-30相连后,转入大肠杆菌(Escherichia coil)M15菌株中得到了有效的表达.将表达的融合蛋白纯化后发现,它具有抑制无细胞系统蛋白质合成的能力.     

麻疯树核糖体失活蛋白基因的克隆和表达

麻疯树(Jatropha curcas L.)核糖体失活蛋白(curcin)是存在于麻疯树种子中的一种毒性较强的蛋白,它与蓖麻毒蛋白和相思子毒蛋白的性质相似,属Ⅰ型核糖体失活蛋白。从麻疯树种子中分离得到一种分子量为28.2kD的蛋白质,其对无细胞系统中蛋白质合成的抑制活性较强,IC_(50)为(0.19±0.01)nmol/L,具有RNA N-糖苷酶活性。依据curcin的N端部分氨基酸设计简并引物,通过RT-PCR和5′-RACE技术从未成熟种子总RNA中克隆到curcin全长cDNA序列。该cDNA全长由1 173个碱基组成,包含一个编码293个氨基酸的前体蛋白,前42个氨基酸为信号肽。推测的多肽序列与测定的蛋白质N端序列相同,与多种已发表的Ⅰ型核糖体失活蛋白和Ⅱ型核糖体失活蛋白的A链有一定的同源性。将curcin的编码区与表达载体pQE-30相连后,转入大肠杆菌(Escherichia coil)M15菌株中得到了有效的表达。将表达的融合蛋白纯化后发现,它具有抑制无细胞系统蛋白质合成的能力。     

蘑菇核糖体失活蛋白的研究进展

着重对近年蘑菇的核糖体失活蛋白研究的进展予以综述,在叙述每种核糖体失活蛋白的分离、纯化方法的同时,讨论了它们的生理生化性质、作用机制及可能的应用等。     

栝楼籽中一种新的具有蛋白质生物合成抑制活性的多肽——Trichokirin-S1的分离、纯化和性质

改进了常规的核糖体失活蛋白的分离纯化方案 ,首先采用抽提蛋白体的方法 ,提高了分离效果 ,然后再经硫酸铵分级沉淀、FPLCMonoS阳离子交换层析和Superose12凝胶过滤层析等步骤 ,从栝楼种子中分离到一种新的多肽———trichokirin S1。经MALDI TOFMS质谱分析测得其分子量为 114 2 6。该肽的N端氨基酸序列为PRRKEG GSFDECCSE ,与一种存在于南瓜籽中的小分子核糖体失活蛋白 β moschin具有很高的同源性。trichokirin S1对核糖体失活的机制与天花粉蛋白 (TCS)一致 ,是rRNAN 糖苷酶催化型的 ,对兔网织红细胞裂解液系统蛋白质生物合成有较强的抑制作用 ,IC50 为 0 .71nmol L ,因而有可能开发成免疫毒素的高效“弹头”。     

核糖体失活蛋白及核糖体拓扑结构的研究进展

天花粉毒蛋白使核糖体失活的分子机制是它有ＲＮＡＮ－糖苷酶的作用。从樟树种子中纯化的两种新的核糖体失活蛋白（ＲＩＰ）——辛纳毒蛋白和克木毒蛋白也都具有ＲＮＡＮ－糖苷酶和依赖超螺旋结构的核酸内切酶活性。辛纳毒蛋白还有杀虫活性;克木毒蛋白还有超氧化物歧化酶活性。被ＲＮＡＮ－糖苷酶失活的核糖体用硼氢化钠还原或氨基酸加成反应可部分地复活,这表明失活的核糖体ＲＮＡ上产生的一个活泼醛基对其失活起着重要作用。工作中建立了荧光标记在凝胶上测定小分子ＲＮＡ序列和定性测定糖蛋白的两种新方法。     

研究: 核糖体失活蛋白及其在黄瓜中的表达分析

核糖体失活蛋白是一类具有高度特异性rRNA N-糖苷酶活性的蛋白,它们能够使原核或真核细胞的核糖体失活因而具有细胞毒性．由于其独特的生物学性质,核糖体失活蛋白被认为在农业和医学中都有着巨大的应用潜力．我们之前的研究表明,黄瓜的基因组中共包含2个2类核糖体失活蛋白基因,分别命名为CumsaAB1和CumsaAB2．以蓖麻毒蛋白Ricin为代表,2类核糖体失活蛋白通常由2条二硫键连接的肽链组成：具有N-糖苷酶活性的A链与具有凝集素活性的B链．本文研究了黄瓜中核糖体失活蛋白的表达情况．亚细胞定位研究表明CumsaAB1经过蛋白分泌通路表达于细胞外,这与蛋白质序列分析显示的CumsaAB1包含一个信号肽而不含转膜区域相一致．对黄瓜的不同生长阶段的不同组织中的转录水平分析表明,CumsaAB1在大部分组织中以极低的水平表达,而CumsaAB2表达水平则明显更高,尤其在第一片真叶阶段和刚开花的植物中．最后,我们使用分子模拟对黄瓜中核糖体失活蛋白的结构及糖结合位点进行了分析．本研究对黄瓜中核糖体失活蛋白的亚细胞定位、表达水平和可能的蛋白质结构进行了研究,为其进一步的生物学功能研究提供了重要信息．     

Curcuminoids as inhibitors of thioredoxin reductase: A receptor based pharmacophore study with distance mapping of the active site

Curcumin is the yellow pigment of turmeric that interacts irreversibly forming an adduct with thioredoxin reductase (TrxR), an enzyme responsible for redox control of cell and defence against oxidative stress. Docking at both the active sites of TrxR was performed to compare the potency of three naturally occurring curcuminoids, namely curcumin, demethoxy curcumin and bis-demethoxy curcumin. Results show that active sites of TrxR occur at the junction of E and F chains. Volume and area of both cavities is predicted. It has been concluded by distance mapping of the most active conformations that Se atom of catalytic residue SeCYS498, is at a distance of 3.56 from C13 of demethoxy curcumin at the E chain active site, whereas C13 carbon atom forms adduct with Se atom of SeCys 498. We report that at least one methoxy group in curcuminoids is necessary for interation with catalytic residues of thioredoxin. Pharmacophore of both active sites of the TrxR receptor for curcumin and demethoxy curcumin molecules has been drawn and proposed for design and synthesis of most probable potent antiproliferative synthetic drugs.     

A Unique Protease Cleavage Site Predicted in the Spike Protein of the Novel Pneumonia Coronavirus (2019-nCoV) Potentially Related to Viral Transmissibility

正Dear Editor,In December 2019, a novel human coronavirus caused an epidemic of severe pneumonia(Coronavirus Disease 2019,COVID-19) in Wuhan, Hubei, China(Wu et al. 2020; Zhu et al. 2020). So far, this virus has spread to all areas of China and even to other countries. The epidemic has caused 67,102 confirmed infections with 1526 fatal cases     

Comparative morphology of the carpel in the Liliaceae: Hewardieae, Petrosavieae, and Tricyrteae

The young pistils in the melanthioid tribes, Hewardieae, Petrosavieae and Tricyrteae, are uniformly tricarpellate and syncarpous. They lack raphide idioblasts. All are multiovulate, with bitegmic ovules. The Petrosavieae are marked by the presence of septal glands and incomplete syncarpy. Tepals and stamens adhere to the ovary in the Hewardieae and the Petrosavieae but not in the Tricyrteae. Two vascular bundles occur in the stamens of the Hewartlieae and Tricyrtis latifolia. Ventral bundles in the upper part of the ovary of the Hewardieae are continuous with compound septal bundles and placental bundles in the lower part. Putative ventral bundles occur in the alternate position in the Tricyrteae and putative placental bundles in the opposite. position in the Petrosavieae. The dichtomously branched stigma in each carpel of the Tricyrteae is supplied by a bifurcated dorsal bundle.     

鸡传染性法氏囊病病毒研究进展

传染性法氏囊病(Infection bursal disease, IBD)是由鸡传染性法氏囊病毒(Infectious bursal disease virus, IBDV)引起的鸡和火鸡的一种高度接触性传染病,给世界各国的禽养殖业带来了巨大损失.自IBDV发现至今新的变异株不断出现,分子结构的改变导致病毒致病力的改变及宿主对疫苗应答的改变,使得传统的疫苗已不能控制其流行,因此各国学者对其基因组结构和功能进行了广泛深入的研究,并积极研制新型有效的疫苗以达到防治的目的.     

Development of a Novel Reverse Transcription Loop-Mediated Isothermal Amplification Method for Rapid Detection of SARS-CoV-2

In conclusion, the novel visual RT-LAMP assay is a simple, rapid, and sensitive approach for detection of SARS-CoV-2, and it is ready for application in primary care and community hospitals or health care centers, and even patients' own houses in response to the current SARS-CoV-2 epidemic because the assay does not require sophisticated equipment and skilled personnel. Furthermore, it is also ready to be used in fields for screening samples from wild animals and environments to facilitate the identification of potential intermediate hosts that mediate the cross-species transmission of SARS-CoV-2 from bats to humans.     

Perinatal Vertical Transmission of Chikungunya Virus in Ruili,a Town on the Border between China and Myanmar

正Dear Editor,Chikungunya virus (CHIKV), an arbovirus in the family of Togaviridae, genus Alphavirus, is transmitted by the A.aegyptii or A. albopictus mosquito, and causes disease in humans characterized by fever, rash, and arthralgia (Silva and Dermody 2017; Suhrbier 2019). It was first reported in 1953 in Tanzania, and caused only a few outbreaks and sporadic cases in Africa and Asia in last century. However, in the epidemic in 2004, CHIKV acquired mutations that conferred enhanced transmission by the A. albopictus mosquito(Schuffenecker et al. 2006). Since then, it has successively caused outbreaks in Africa, the Indian Ocean, South East Asia, the South America, and Europe (Zeller et al. 2016).     

Enterovirus 71 3C proteolytically processes the histone H3 N-terminal tail during infection

Highlights
1. The N-terminal tail of histone H3 is specifically cleaved during EV71 infection.
2. Viral protease 3C is identified as a protease responsible for proteolytically processing the N-terminal H3 tail.
3. Our finding reveals a new epigenetic regulatory mechanism for Enterovirus 71 in virus-host interactions.