油桐尺蠖核型多角体病毒结构多肽的分析

本文采用不连续系统的垂直板SDS—PAGE对油桐尺蠖核型多角体病毒(Buzura suppressaria Guenee Nuclear Polyhedrosis Virus简称BsNPV)的多角体蛋白、病毒粒子的结构多肽进行了分析。结果表明,经EDTA和热处理的多角体蛋白仅有一条主带,其分子量为31×10~3±1000d;病毒粒子至少有23种结构多肽,其分子量的范围在13—107×10~3d之间。用PAS染色测定多角体蛋白、病毒粒子中的糖蛋白,结果呈阴性反应。     

蜀柏毒蛾核型多角体病毒结构多肽及基因组酶切分析

对蜀柏毒蛾核型多角体病毒(Parocneria orienta Nuclear polyhedrovirus,简称PaorNPV)形态结构、结构多肽、限制性内切酶图谱等特性进行了研究.采用不连续系统垂直板SDS-PAGE分析了PaorNPV的多角体蛋白、病毒粒子结构多肽.应用5种限制性内切酶对PaorNPV基因组DNA进行了酶切分析.结果表明:经热处理的多角体蛋白仅有一条带,分子量为31.5 kD,不经热处理的多角体蛋白有三条带,分子量分别为31.5 kD、29.1 kD、28.6 kD;病毒粒子包含有25种结构多肽,分子量范围在17.6-114.6 kD之间.PaorNPV DNA经BamH I.EcoR I、HindⅢ、Pst I和Xho I酶切分别产生9、12、12、12和14条片段.基因组大小平均为124.6 kb.     

棉铃虫质型多角体病毒的某些生物物理和生物化学特性

本文对棉铃虫质型多角体病毒中国江苏分离株的生物物理和生物化学特性进行了研究,棉铃虫CPV通过其寄主幼虫大量增殖,经蔗糖梯度超离心纯化,CPV粒子由碱液溶解多角体释出,其沉降系数为403.9S,分子量为41.9×10~6,CPV多角体蛋白的主要组份为一种,分子量为27,000;CPV粒子结构蛋白则由六种多肽组成,经聚丙烯酰胺凝胶等电聚焦电泳,CPV多角体蛋白和CPV粒子均包含10种以上的多肽组份,经双向电泳,(PV粒子结构蛋白包含15种以上的多肽组份,CPV多角体蛋白氨基酸组成中不含半胱氨酸,其碱性氨基酸与酸性氨基酸比值为1.005,用SDS-热酚法提取所得CPV核酸,其解链温度为83侧;其碱基组成,A=U,G=C,说明CPV核酸是双链RNA,其G+C％为43％,在1％琼脂糖凝胶和3％聚丙烯酰胺凝胶中电泳,CPV RNA分别可分得11和13条基因片段,各片段大小为0.51～2.45×10~6,总分子量为17.94×10~6,电镜研究显示了CPV RNA在0.3μ,0.6μ1.0μ处有3个分布峰。     

两株蓖麻蚕核型多角体病毒的比较研究

本文描述来源不同的两株菌麻蚕多角体病毒的形态特征和理化特性。一株为较长期饲喂马桑叶的蓖麻蚕从自然罹死的幼虫和蛹中分离的多角体病毒（简称ArscsNPV);另一株为饲喂蓖麻叶的蓖麻蚕从幼虫分离的核型多角体病毒（简称ArscsNPV);另一株为饲喂蓖麻叶的蓖麻蚕从幼虫分离的核型多角体病毒（简称ArNPV)。两株核型多角体病ArNPV多角体大小约1．2－2．0μm最大的可达2．9μm。两株NPV病毒粒子均为杆状,ArscsNPV病毒粒子大小平均为310×50nm;ArNPV病毒粒子大小为350×50nm。两株NPV均为多粒包埋型。两株NPV的多角体蛋白均为单一组分,ArscsNPV多角体蛋白分子量为27．5kd;ArNPV多角体蛋白分子量为28kd。两株NPV的病毒粒子结构多肽均含有21条多肽,其中各多肽分子量有所差异。ArscsNPV的病毒粒子多肽分子量范围为11－130kd;ArNPV病毒粒子多肽分子量范围为11－96kd,其中有11种多肽了量彼此相同包括两种主要多肽（54kd和33kd）。用SDS－苯酚提取的病毒核酸,经实验证明均为双链DNA型使用几种内切酶酶解,求得两株NPV的核酸分子量,ArscsNPV为52．4×10^6d;ArNPV为73．5×10^6d。     

粘虫核型多角体病毒包涵体蛋白的性质及其对几种肿瘤细胞生长的抑制作用

SDS-PAG电泳分析表明粘虫核型多角体病毒(Leucaia separata Nuclear Polyhedrosis Virus,简称LsNPV)的包涵体蛋白由几种多肽组成,其中分子量为32kD的主带为多角体的主要结构多肽。经Sephaceyl S-200柱层析纯化后分析了其氨基酸组成,证明此包涵体蛋白是一种以疏水氨基酸为主要组成的特异性蛋白。我们发现32kD蛋白对Hela、HLAMP、HICAM等三种肿瘤细胞的生长有不同程度的抑制,用~3H-TdR标记核酸合成代谢的Hela细胞的放射活性证实了这种观察。     

扁刺蛾核型多角体病毒的形态结构与某些生化特性的测定

扁刺蛾核型多角体病毒是一种单粒包埋型的杆状病毒,在扫描电镜下呈不规则多面体。病毒多角体大小不一致,平均直径为0.59μ。病毒粒子为340×85nm. 经SDS—PAGE分析,病毒的多角体蛋白主带分子量为29500道尔顿;病毒粒子的结构蛋白具有25条多肽,分子量为17.8～69.5×10~4道尔顿。病毒多角体蛋白氨基酸组成中富含Asp和Glu,而His、Cys、Met的含量却很低。病毒DNA的分子量为67.89×10~6道尔顿。     

薄荷伪造桥虫NPV感染斜纹夜蛾幼虫分离的一种新NPV特性的研究

用薄荷伪造桥虫核型多角体病毒(Argroyamma agnata NPV)(以下简称Aa NPV)在室内感染斜纹夜蛾(Prodenia litura)幼虫,从死虫体内分离到一种NPV。经电镜观察,多角体蛋白分析、病毒核酸的限制性内切酶酶解分析等研究,证明此多角体直径为1.5—2.6/μm,病毒粒子为杆状,其大小为100—150×420nm,病毒粒子为多粒包埋型。提纯的多角体蛋白只有一种多肽,分子量为33,500d,提纯的病毒粒子的结构多肽至少有15种,其分子量范围为15,600     

烟青虫质型多角体病毒的形态及某些理化特性

本文对烟青虫(Heliothis assulta)质型多角体病毒(CPV)的形态大小以及某些理化特性进行了研究。烟青虫CPV多角体为正五角形的十二面体,大小为0.8-4.6μm;CPV 粒子为外形呈六角形或球形的廿面体,大小为62nm。CPV多角体蛋白的主要多肽为一种,分子量23000,为非糖蛋白。 用SDS-酚法提取的CPV基因,经Rnase I和Dnase I处理后在1%琼脂糖凝胶上电泳,结果表明 其基因是双链RNA,并由10个基因片段组成。各片段大小为0.3-2.68X10⁶,总分子量为15.85x10⁶。本文所报道的烟青虫质型多角体病毒在国内外尚属首次。     

文山松毛虫质型多角体病毒形态结构及理化性质的研究

对文山松毛虫质型多角体病毒的形态结构及理化特性进行了研究,多角体大部分为六边形,少数为四边形及近园形,其大小在0.47～2.45μ之间,平均为1.1μ。病毒粒子呈球形,无囊膜,致密的核芯区由一层外壳包裹,直径为60nm。病毒粒子表面有12个刺突,放大图象可见其亚单位排列。多角体蛋白的主要成分为一种,分子量为26200道尔顿,多角体蛋白氨基酸组成中不含半胱氨酸;其碱性氨基酸与酸性氨基酸之比为1:2.16。病毒粒子结构蛋白含五条多肽组分。用SDS-热酚法提取所得核酸,其热变性紫外吸收OD_(260)值增加51.6％。抗核酸酶S_1。Tm值为86℃。在1％琼脂糖凝胶电泳中可分为9个片段,而在5％PAGE中,则可分为10个片段。各片段大小在0.66×10~6～2.85×10~6道尔顿之间,总分子量为15.35×10~6。电镜分析研究显示了CPV RNA在0.4μ、0.8μ和1.2μ处有三个分布峰。     

家蚕核型多角体病毒及核衣壳的纯化和其结构蛋白的凝胶电泳分析

 用差速离心和蔗糖密度梯度离心提纯了家蚕核型多角体病毒及其核衣壳,并用SDS聚丙烯酰胺凝胶(均一胶和梯度胶)电泳分析了它们的结构蛋白。测量使用游标卡尺,计算使用微型计算机。凝胶用很染色方法染色。 结果表明,家蚕核型多角体病毒长381.2±17.81纳米,直径88.86±9.605纳米;核衣壳长328.9±5.917纳米,直径41.36±1.167纳米。两种凝胶电泳所得数据显示病毒粒子至少含有20组分子量不同的结构多肽,含量较多的是P31、P40、P28和P20。P45和一些小分子多肽看来主要存于囊膜上。P31的分子量与多角体蛋白相同,我们的实验表明它可能是病毒粒子和核衣壳的结构组分。     

Purification and characterization of a lectin from the beetle, Allomyrina dichotoma

A lectin was purified from the hemolymph of Allomyrina dichotoma larvae by affinity chromatography on acid-treated Sepharose 4B. The purified lectin showed two protein bands on polyacrylamide gel electrophoresis. These two lectin bands (allo A-I and -II) were separated by DEAE-Cellulofine column chromatography. By gel filtration on Sephadex G-100, the molecular weights of allo A-I and -II were estimated to be 65,000 and 66,500, respectively. On the other hand, by SDS-polyacrylamide gel electrophoresis after cross-linking of subunits with glutaraldehyde, they are estimated to be 38,000 and 39,000, respectively. On SDS-polyacrylamide gel electrophoresis, it was proved that both allo A-I and -II lectin consisted of two subunits, respectively. The molecular weights were 17,500 and 20,000 for allo A-I, and 19,000 and 20,000 for allo A-II. The isoelectric points of allo A-I and -II were estimated to be 6.4 and 5.9, respectively. On double immunodiffusion, allo A-I and -II gave single precipitin lines, which fused completely with each other, against the antibody to crude allo A. The hemagglutinating activity of allo A-I and -II was inhibited only by beta-linked D-galactose such as lactose and lactulose.     

Comparison of the Structure of C- and N-Polyhedrins from Two Occluded Viruses Pathogenic for Orgyia pseudotsugata

C-and N-polyhedrins from a cytoplasmic polyhedrosis virus (a double-stranded RNA virus) and a nuclear polyhedrosis virus (a DNA virus), respectively, of Orgyia pseudotsugata were compared. Although both polyhedrins appear to stabilize their respective virions and have similar molecular weights, they differed in amino acid composition, tryptic peptide elution profiles from a cation-exchange resin, and N-terminal amino acid sequence and showed no antigenic relatedness. This suggests that these two proteins originated independently of one another.     

小鹅瘟病毒纯化及其理化特性的研究

详细描述了小鹅瘟病毒(Goslin—plague virus,GPV)扬州株的浓缩和纯化过程,并论述了其理化特性。试验证明,GPV在氯化铯中主要病毒区带的浮密度为11.31～1.35g/ml,电镜下可见空壳和实心两种病毒粒子,大小20～22nm,沉降系数90.5S。用Sepharose 4B柱层析纯化的病毒,等电点为4.3。GPV有3种结构多肽,即Vp1、Vp2和Vp3,分子量分别为85 000,61 000,57 500道尔顿,其中Vp3为主要结构多肽,纯化的病毒粒子能使鹅胚致死。     

A novel protein accumulated during maturation of the pods of the plantImpatiens balsamina

A high molecular weight protein has been isolated as a major polypeptide comprising 85% of the total extractable proteins in the fruit pericarp of the plantImpatiens balsamina. The protein has been purified to homogeneity following fractionation of the crude cell supernatant with ammonium sulphate, chromatography on Sepharose 4B and Sephacryl-S-300. This protein appeared to be a homo-tetramer consisting of subunits, Mr 75 K. Amino acid analysis showed the presence of more acidic amino acids, with an isoelectric point 5.8. The interaction of this protein with filamentous actin, both from rabbit muscle and Mung bean embryo was monitored by transmission electron microscopy, light scattering analysis, viscometry and sedimentation assay. This protein inhibited appreciably the polymerization of G-actin to F-actin.     

美国白蛾核型多角体病毒超氧化物歧化酶基因的序列分析和表达

根据测序结果 ,HcNPVsod的核苷酸序列与BmNPVsod的完全一致 ,与AcNPVsod的核苷酸序列相比 ,同源性达到 97 2 % ;推测HcNPVsod编码 1 51个氨基酸 ,与BmNPVsod的完全一致 ,与AcNPVsod编码的氨基酸相比 ,有三个氨基酸的差别。按基酸序列分析表明 ,HcNPVSOD蛋白中含有对SOD结构和活性必需的氨基酸残基 ,在HcNPVsod中均是保守的。SOD活性测定表明酶活为 1 47 0 9U/mL菌液     

A virus-inactivating protein isolated from the digestive juice of the silkworm, Bombyx mori

A protein that can precipitate nuclear polyhedrosis virus (NPV) in vitro was isolated from the digestive juice of silkworm larvae (Bombyx mori) by the procedures of gel filtration and ion-exchange and hydroxylapatite column chromatography. The SDS-polyacrylamide gel electrophoretic and the ultracentrifugal analyses showed that the purified substance was a homogenous simple protein. The molecular weight of the purified protein was 27,000–28,000 and the sedimentation coefficient was 2.61 S. This protein had an additional activity to inactivate NPV of B. mori in vitro, somewhat analogous to serological neutralization by serum proteins. Electron microscope observations showed that amorphous materials could be found on the surface of envelopes and that the nucleocapsids disappeared.     

Characterization of Nuclear Polyhedrosis Virus DNAs

The nuclear polyhedrosis virus DNAs characterized and compared in this study consist of the singly-enveloped nucleocapsids (SNPV) of Trichoplusia ni and the bundles of nucleocapsids common to a single envelope (MNPV) from Spodoptera frugiperda and Rachiplusia ou. The SNPV and MNPV DNAs are very similar in hydrodynamic properties and molecular weights. In addition, the NPV DNAs are similar in size to those extracted from the granulosis viruses that infect T. ni and S. frugiperda. As isolated from purified virus or directly from occluded virus, the nuclear polyhedrosis virus DNAs consist of a mixture of about 20 to 30% double-stranded covalently closed molecules and approximately 60% relaxed circles, with less than 10% in linear duplex form. The molecular weights of all nuclear polyhedrosis virus DNAs as compared in this study are slightly smaller than those of T4 bacteriophage DNA and perhaps slightly smaller than those of the granulosis virus DNAs. The best estimates of these molecular weights by neutral sucrose sedimentation for the nuclear polyhedrosis viruses range from 90 to 100 x 10(6) relative to a size of 108 x 10(6) for T4 DNA. The base compositions of the nuclear polyhedrosis viruses that infect T. ni and S. frugiperda are compared with the respective insect host DNAs.     

Characterization of an extremely basic protein derived from granulosis virus nucleocapsids

Nucleocapsids were isolated from purified enveloped nucleocapsids of Plodia interpunctella granulosis virus by treatment with Nonidet P-40. When analyzed on sodium dodecyl sulfate-polyacrylamide gels, the nucleocapsids consisted of eight polypeptides. One of these, a major component with a molecular weight of 12,500 (VP12), was selectively extracted from the nucleocapsids with 0.25 M sulfuric acid. Its electrophoretic mobility on acetic acid-urea gels was intermediate to that of cellular histones and protamine. Amino acid analysis showed that 39% of the amino acid residues of VP12 were basic: 27% were arginine and 12% were histidine. The remaining residues consisted primarily of serine, valine, and isoleucine. Proteins of similar arginine content also were extracted from the granulosis virus of Pieris rapae and from the nuclear polyhedrosis viruses of Spodoptera frugiperda and Autographa californica. The basic polypeptide appeared to be virus specific because it was found in nucleocapsids and virus-infected cells but not in uninfected cells. VP12 was not present in polypeptide profiles of granulosis virus capsids, indicating that it was an internal or core protein of the nucleocapsids. Electron microscopic observations suggested that the basic protein was associated with the viral DNA in the form of a DNA-protein complex.