荨麻蛱蝶核型多角体病毒在病虫脂肪体中的形态发生

本文叙述了一种在高山草原地区较低温度下感染荨麻蛱蝶(Vanessa urticae)的核型多角体病毒的形态发生过程。荨麻蛱蝶幼虫经其病毒多角体感染5日后出现明显变化:细胞核膨大,核仁消失,核内出现清晰区及病毒发生基质。在病毒发生基质的周围,核衣壳大量产生。核衣壳是从这些病毒发生基质四周的模样结构碎片上获得套膜,装配成病毒粒子。随后病毒粒子逐渐进入多角体蛋白中,形成了成熟的单粒包埋型的多角体。观察结果表明,在较低温度下生长的荨麻蛱蝶NPV与在常温下生长的其它NPV有着类似的形态发生过程。     

中国对虾非包涵体杆状病毒在体内的感染与发生

在感染发病成虾的肝胰腺和中肠上皮细胞的胞核内,出现大量病毒发生基质,核衣壳,套膜和完全的病毒粒子。病毒粒子为短杆状,两端呈钝园形,平均大小约为２５０－３００×ｌ１０ｎｍ,在核内无包涵体形成。在胞质内发现伴随病毒拉子并具有双层膜的蛋白质结构,这种结构建议称为该病毒的“封入体”。同时,我们认为这种无包涵体的杆状病毒,有可能应归属于杆状病毒科的第三个亚组。     

核多角体病毒在昆虫细胞系内的装配方式

本文对AcNpV、HaNPV和EsNPV在各自敏感细胞系内的装配过程作了研究。除在复制时间上稍有差别外,均具以下特点：核衣壳装配与病毒基质(Vs)和发夹结构(HC)有密切的关系,有些核衣壳尚需经剪切加工;有两种表型子代病毒,封存体(OB)和未埋入型病毒(NOV);前者在核内完成装配,后者可在核内、核膜上、胞质内或细胞膜上完成套膜装配,且与细胞膜系统密切相关;AcNPV复制晚期出现不完全装配现象．     

人巨细胞病毒在SL_7细胞中的形态发生

人巨细胞病毒(HCMV)AD_(169)株接种SL_7细胞后三至四天,可见核衣壳在核内装配,通过核膜芽生,从核周间隙移行至胞浆的囊泡中,形成完整的病毒。感染后四天核内可见许多核衣壳与纽网状物紧密结合形成典型的包含体,因此包含体可能是病毒复制的场所。此时浆内出现电子密度均一的物质,称CMV致密体。免疫电镜显示致密体缺乏核衣壳,但具有病毒相同的抗原性。它可能是装配和包裹核衣壳的结构蛋白。CMV和致密体在感染细胞中以同一方式从细胞中释放。     

用免疫金颗粒标记鉴定舞毒蛾核型多角体病毒的抗原

用免疫电镜金颗粒标记技术准确、快速地对舞毒蛾(Lymantria dispar)核型多角体病毒抗原进行了定位和鉴定.舞毒娥病毒的多克隆抗体与同源的多角体抗原之间存在着强烈的亲和性,但与不同源的松柏锯角叶蜂(Neodiprion sertifer)病毒多角体抗原仅有极微弱的交叉反应.舞毒蛾病毒粒子和核衣壳抗原也能与同源的多克隆抗体作用.在被病毒感染的舞毒蛾脂肪体细胞核中,成熟的多角体被金颗粒重重标记,其外缘的游离病毒粒子和核衣壳亦被标记,但亲和力较弱.在被感染的脂肪体细胞核和质内发现一种与多角体蛋白晶体不同源的菱形结晶体.     

鸭病毒性肠炎病毒强毒株的形态发生学与超微病理学研究

应用透射电镜和超薄切片技术,研究鸭病毒性肠炎病毒(duck enteritis virus,DEV)CH强毒株人工感染成年鸭后,病毒在宿主细胞内的形态发生及各组织器官的超微结构变化.结果表明,感染后不同时间剖杀及发病后死亡鸭的肝、肠、脾、胸腺、法氏囊等组织器官中,均观察到典型的疱疹病毒粒子.病毒主要的靶细胞为淋巴细胞、网状内皮细胞、成纤维细胞、巨噬细胞、血管内皮细胞、肠道上皮细胞、肠道平滑肌细胞和肝细胞等.DEV的核衣壳有空心型、致密核心型、双环型和内壁附有颗粒型四种形态,存在胞核和胞浆两种装配方式.病毒核衣壳可在核内获得皮层,通过核内膜获得囊膜成为成熟病毒;也可通过内外核膜进入胞浆,在其中获得皮层,然后在各种质膜上获得囊膜,最后成熟病毒释放到细胞外.伴随着病毒的复制、装配和成熟,细胞中出现多种核内和胞浆包涵体、核内致密病毒核酸颗粒、微管和中空短管以及胞浆内膜包裹的电子致密小体、双层管等病毒相关结构.超微研究表明,组织细胞有坏死和凋亡两种变化.坏死细胞肿胀甚至破裂,线粒体肿胀空泡化,粗面内质网扩张,核糖体脱落,有的细胞器甚至完全崩解,染色质或固缩或溶解.凋亡细胞则染色质聚集,胞浆凝聚深染,细胞膜上有大量空泡,并有凋亡小体形成.细胞坏死与凋亡往往同时存在,疾病发生过程中,脾、胸腺、法氏囊以及小肠固有层中的淋巴细胞凋亡数量明显增多.     

棉铃虫核多角体病毒在中肠及其它组织中增殖过程的电镜观察

应用电子显微镜技术观察了核多角体病毒在棉铃虫体内的增殖方式。在中肠细胞内增殖的核衣壳极少被囊膜包围,也很少形成多角体。它们能大量地释放到体腔,迅速感染其他敏感组织。在其他敏感组织内增殖的核衣壳大部分被囊膜包围形成病毒粒子,且随机包涵在多角体中形成核多角体。     

山楂粉蝶NPV的形态发生及其宿主细胞器的超微病理变化

应用电子显微技术,对山楂粉蝶核型多角体病毒感染三龄幼虫后,该病毒在体内的形态发生过程及其宿主细胞病理超微结构的变化等进行了观察与分析。结果表明：病毒感染７２～１６８ｈ后,山楂粉蝶幼虫中肠上皮细胞内出现病毒发生基质、核衣壳、套膜、丝状纤维或称前多角体蛋白。病毒粒子、病毒束,以及病毒束嵌入多角体蛋白,装配成完全的病毒多角体。在相应的中肠上皮细胞内,细胞器如线粒体、粗面内质网、核糖体、溶酶体等均发生显著的病理变化。同时还应指出的是内质网呈指纹图谱型,板层体与示髓样小体等膜状结构的病理变化比较特殊。     

苜蓿丫纹夜蛾核型多角体病毒囊膜内核衣壳排列图式的电镜观察

核型多角体病毒有单核衣壳包埋型和多核衣壳包埋型之分,单核衣壳包埋型是在一个病毒囊膜内只包含一个核衣壳,而多核衣壳包埋型的特点是在一个病毒囊膜内包含有２个以上的核衣壳,由于多个核衣壳成束地被包装在同一个病毒囊膜内,又称病毒束［１,２］。Ｈｕｎｔｅｒ等表明在干果斑螟核型多角体病毒中,病毒囊膜内包含２～２３个核衣壳［３］。Ｆｒａｓｅｒ将苜蓿丫纹夜蛾核型多角体病毒接种于秋粘虫细胞系,超薄切片电镜观察,病毒囊膜内包含的核衣壳数变动于２～１７粒,但未研究其核衣壳在病毒囊膜内的排列结构［４］。本研究用苜蓿丫纹…     

光,电镜观察小鼠呼吸道合胞病毒性肺炎的免疫病理改变

Ｂａｌｂ／ｃ小鼠经鼻吸入呼吸道合胞病毒（ＲＳＶ）悬液感染成ＲＳＶ肺炎。于感染第５天后连续隔日取肺,光镜与透射电镜检查。感染第５～７天,肺组织病理改变最严重,多数小鼠表现为间质淋巴细胞（ＬＣ）套状浸润,肺泡隔增宽;少数小鼠出现间质内大量ＬＣ浸润与肺泡内大量单个核细胞渗出的两种病理改变。病毒包涵体出现于肺泡上皮细胞内,细胞受感染后发生肿胀、坏死。Ⅰ型细胞核周胞质内有核衣壳复制,表面病毒芽生形成长短不等的丝状体。第９天,肺泡隔增宽与间质ＬＣ浸润逐渐减轻。第１２天,病毒包涵体明显减少。     

The movement and invasion of an insect baculovirus in tracheal cells of the armyworm, Pseudaletia unipuncta

The hypertrophy nuclear polyhedrosis virus of the armyworm, Pseudaletia unipuncta, causes a unique gradient of infected cells to form on the trachea. The movement and invasion of the virus apparently were not through adjacent intercellular membranes. The enveloped viruses emerged from the initially infected cell into an area between the cell plasma membrane and basal lamina, and then entered the uninfected tracheal cell either by lateral attachment and fusion of the viral envelope and the plasma membrane or by viropexis. The two methods of viral invasion into the cell suggest the presence of at least two phenotypically different enveloped viruses. Viropexis was initiated with an alignment of the peplomer spikes with regularly spaced, short radial striations on the inner coat of the plasma membrane. At a late state in viropexis, the viral envelope fused with the vacuole membrane, and an opening developed below the site of membrane fusion through which the nucleocapsid might enter the cytoplasm. Some nucleocapsids in membrane-lined vesicles resulting from viropexis appeared to be in a state of dissolution. Naked nucleocapsids were found along the nuclear envelope and within the nucleoplasm. No uncoating of the nucleocapsids was observed at the nucleopores, but uncoating seemed to occur in the nucleoplasm. Nucleocapsids were also found in the cytoplasm of nonsusceptible fat body cells, in which virus replication was not observed.     

Ultrastructural analysis of the replication cycle of pseudorabies virus in cell culture: a reassessment.

We reinvestigated major steps in the replicative cycle of pseudorabies virus (PrV) by electron microscopy of infected cultured cells. Virions attached to the cell surface were found in two distinct stages, with a distance of 12 to 14 nm or 6 to 8 nm between virion envelope and cell surface, respectively. After fusion of virion envelope and cell membrane, immunogold labeling using a monoclonal antibody against the envelope glycoprotein gE demonstrated a rapid drift of gE from the fusion site, indicating significant lateral movement of viral glycoproteins during or immediately after the fusion event. Naked nucleocapsids in the cytoplasm frequently appeared close to microtubules prior to transport to nuclear pores. At the nuclear pore, nucleocapsids invariably were oriented with one vertex pointing to the central granulum at a distance of about 40 nm and viral DNA appeared to be released via the vertex region into the nucleoplasm. Intranuclear maturation followed the typical herpesvirus nucleocapsid morphogenesis pathway. Regarding egress, our observations indicate that primary envelopment of nucleocapsids occurred at the inner leaflet of the nuclear membrane by budding into the perinuclear cisterna. This nuclear membrane-derived envelope exhibited a smooth surface which contrasts the envelope obtained by putative reenvelopment at tubular vesicles in the Golgi area which is characterized by distinct surface projections. Loss of the primary envelope and release of the nucleocapsid into the cytoplasm appeared to occur by fusion of envelope and outer leaflet of the nuclear membrane. Nucleocapsids were also found engulfed by both lamella of the nuclear membrane. This vesiculation process released nucleocapsids surrounded by two membranes into the cytoplasm. Our data also indicate that fusion between the two membranes then leads to release of naked nucleocapsids in the Golgi area. Egress of virions appeared to occur via transport vesicles containing one or more virus particles by fusion of vesicle and cell membrane. Our data thus support biochemical data and mutant virus studies of (i) two steps of attachment, (ii) the involvement of microtubules in the transport of nucleocapsids to the nuclear pore, and (iii) secondary envelopment in the trans-Golgi area in PrV infection.     

Nonoccluded baculovirus- and filamentous virus-like particles in the spotted cucumber beetle,diabrotica undecimpunctata (coleoptera: chrysomelid)

Nonoccluded baculovirus-and filamentous virus-like particles were found in nuclei of hemocytes or midgut cells of field-collected spotted cucumber beetles. Each type of particle was associated with a different type of virogenic stroma containing various viral components similar to those referred to as capsid, nucleocapsid, viroplasm, and viral envelope in other known baculovirus infections. Nucleocapsids of the virus which occured only in hemocytes were rod-shaped particles approximately 230 nm long and 52 nm wide and were enveloped singly by a trilaminar unit membrane. Enveloped and partly enveloped particles appeared to be released from the nucleus to the cytoplasm by budding through the nuclear envelope acquiring additional membranes. The nucleocapsids of the virus which occurred only in nuclei of midgut cells were filamentous particles with an average diameter of 25 nm and variable length up to 2 μm. Some extremely long particles were bent almost 360° near the middle, resulting in a hairpin-like configuration. The particles were always enveloped singly. No particles budding through the nuclear envelope were observed.     

Nuclear membrane changes in herpes simplex virus-infected BHK-21 cells as seen by freeze-fracture.

The freeze-fracture technique, which produced high-resolution replicas of large internal faces of membranes, was used for an ultrastructural study of the nuclei of herpes simplex virus-infected BHK-21 cells and mock-infected controls. Crystalline arrays of viral nucleocapsids were found in the nucleoplasm of infected cells, and numerous nuclear membrane "blebs" and protrusions were observed. The numerous areas of membrane distortions were not found to contain nuclear pores. In addition, specific areas of normal protein intramembranous particles are deleted from certain areas of the nuclear membrane as a result of herpes simplex virus, type 2, infection.     

Effects of the Epap granulovirus on its host,Epinotia aporema (Lepidoptera: Tortricidae)

The bean shoot borer, Epinotia aporema, is a major pest of soybeans in Argentina. Larvae of this pest are attacked by a granulovirus (EpapGV) that is the most important cause of sporadic epizootics in E. aporema populations. We studied the pathology of this virus in last-instar larvae using light and electron microscopy, and evaluated the effect of the disease on larval growth and development. EpapGV caused a polyorganotropic infection. No nucleocapsids were observed in the nuclei of infected cells prior to nuclear membrane disruption. Nevertheless, granulin was detected in the nucleus by immuno-gold staining, indicating that late gene expression occurred prior to nuclear membrane disruption. Establishment of the virogenic stroma led to complexes of continuous parallel convoluted membranous sheets. Nucleocapsids were enveloped in these areas to form virions, which were then occluded. Apparently as part of the cell-to-cell spread of infection, nucleocapsids were observed enclosed in large numbers within membrane-bound vesicles located between the cells and basal lamina. Larvae infected by EpapGV suffered a retardation of development and typically failed to pupate, but exhibited a weight increase greater than that of healthy E. aporema.     

Baculovirus VP80 protein and the F-actin cytoskeleton interact and connect the viral replication factory with the nuclear periphery

Recently, we showed that the Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) VP80 protein is essential for the formation of both virion types, budded virus (BV) and occlusion-derived virus (ODV). Deletion of the vp80 gene did not affect assembly of nucleocapsids. However, these nucleocapsids were not able to migrate from the virogenic stroma to the nuclear periphery. In the current paper, we constructed a baculovirus recombinant with enhanced-green fluorescent protein (EGFP)-tagged VP80, allowing visualization of the VP80 distribution pattern during infection. In baculovirus-infected cells, the EGFP-VP80 protein is entirely localized in nuclei, adjacent to the virus-triggered F-actin scaffold that forms a highly organized three-dimensional network connecting the virogenic stroma physically with the nuclear envelope. Interaction between VP80 and host actin was confirmed by coimmunoprecipitation. We further showed that VP80 is associated with the nucleocapsid fraction of both BVs and ODVs, typically at one end of the nucleocapsids. In addition, the presence of sequence motifs with homology to invertebrate paramyosin proteins strongly supports a role for VP80 in the polar transport of nucleocapsids to the periphery of the nucleus on their way to the plasma membrane to form BVs and for assembly in the nuclear periphery to form ODVs for embedding in viral occlusion bodies.     

家蚕浓核症病毒感染昆虫细胞系的电镜观察

本实验首次用中国株家蚕浓核症病毒感染三株昆虫细胞系:油桐尺蠖卵巢细胞系(BS-484)、甘兰夜蛾卵巢细胞系(NIAS—MB—19)和秋粘虫卵巢细胞系(IPLB—SF—21)。结果仅在BS—484细胞中观察到病毒感染引起的细胞病变效应。电镜观察发现在感染的BS—484中,细胞核明显膨大,其中核仁活性化,数目增多,同时还观察到核仁膨大和分裂现象。感染5—6天,可看到成熟病毒粒子于核内形成。在感染的细胞质中,线粒体肥大且失去脊,粗面内质网变成小泡体,其内积累大量核糖核蛋白体。许多细胞器空泡化或退化,细胞质中出现一些包含退化细胞器的大型自身吞噬体。     

Transformation of Golgi membrane into the envelope of herpes simplex virus in rat anterior pituitary cells

Envelopment of herpes simplex virus type-1 (HSV-1) was investigated in relation to membrane differentiation in dissociated anterior pituitary cells. The number of cells stained positively with anti-HSV-1 serum was increased from 16 h to 31 h post infection. During this period, electron microscopy revealed that a number of nucleocapsids (unenveloped particles) were accumulated in the Golgi area, where they frequently became surrounded by a double membrane of short Golgi cisternae or by one with a Golgi associated endoplasmic reticulum lysosome (GERL)-like structure. The inner membrane of the cisterna surrounding the nucleocapsids showed regional specialization which was characterized by increased thickness and electron opacity. Acid phosphatase activity, a marker for GERL or trans Golgi cisternae, appeared in the cytoplasmic short cisternae surrounding the nucleocapsids, whereas glucose-6-phosphatase activity, a marker for the nuclear envelope or for endoplasmic reticulum, was not demonstrated in such cisternae. Monoclonal antibody against glycoprotein gD revealed that gD was localized in the trans Golgi membrane as well as in the envelope of the virion. The antibody-binding sites were highly concentrated in the area where Golgi membranes showed increased opacity. Furthermore, nucleocapsids were surrounded exclusively by gD-positive cisternal (Golgi or Golgi-derived) membranes. Thus, our results indicate that the envelope of HSV is derived from trans Golgi cisterna (GERL), and that some viral components, including gD, destined for the envelope may be assembled initially in the Golgi membrane, which is thereby transformed into the envelope of the virus.     

Nuclear alterations in a baculovirus-like infection of midgut epithelial cells in the stick insect, Bacillus rossius

In the epithelial cell nuclei of the posterior part of the midgut of the stick insect, Bacillus rossius, a symptomless virus infection is most commonly found. The virus particles consist of rod-shaped DNP nucleocapsids singly enveloped by a membrane and often packed in a pseudocristalline pattern along their major axis; occlusion bodies of any kind are not formed. On the basis of size, structural characteristics, and localization, the virus is thought to be a baculovirus-like virus. The viral infection, which is asynchronous in different nuclei, causes the formation of electron-light virogenic areas, the swelling of the nucleus, the nuclear chromatin lysis, the production of highly variable numbers of virus particles and, eventually, the extrusion of the whole infected nucleus into the gut lumen. Cellular DNA synthesis does not seem to be stimulated by the virus, RNA synthesis is apparently maintained as long as some cellular chromatin is present in the infected nucleus. Nucleolar segregation invariably occurs at late stages of infection, while major cytoplamic alterations have not been noticed until nuclear elimination and cell death occur.