小鹅瘟病毒核酸链型与结构蛋白分析

采用简易方法从鹅胚中分离纯化的小鹅瘟病毒(GPV)样品相当纯净,以致在电镜下呈晶格排列。用负染色技术观察病毒的形态结构,病毒直径为18～20nm,无囊膜。病毒颗粒含有4种结构蛋白,其分子量分别为88、78、66和51kd。根据病毒的核酸链型分析,小鹅瘟病毒含有单链核酸。此结果支持了小鹅瘟病毒属于细小病毒属的结论。     

鹅源鸭瘟病毒和小鹅瘟病毒在同一宿主系统增殖的观察

本文首次报道了鹅源鸭瘟病毒(DPV—Ⅰ)和鸭胚化小鹅瘟病毒(GPV—Ⅰ)能同时在同一鸭胚内复制增殖,未发现干扰作用,在理论上说明某些不相关的两种病毒可在同一宿主增殖,实践上为利用同一鸭胚研制二联疫苗提供了依据。研究结果表明:1.DPV—Ⅰ和GPV—Ⅰ联合感染同一鸭胚后,其尿囊液在电镜下见两种病毒,DPV—Ⅰ呈园形或椭园形,有囊膜,直径为38—109nm,GPV-Ⅰ呈园形,无囊膜,直径为18—25nm;2.含毒尿囊液使鸭胚成纤维细胞(DEF)单层发生细胞病变作用(CPE),证实存在DPV-Ⅰ,而用小鹅瘟微量免疫扩散(MID)试验,又能检出GPV-Ⅰ抗原;3.含毒尿囊液免疫鹅的血清中存在抗两种病毒的(?)和抗体和GPV沉淀抗体;4.含毒尿囊液免疫的成鹅对DPV强毒攻击有相当免疫力,免疫鹅血清能中和GPV,使其失去对鸭胚的致病力;5.GPV-Ⅰ单独或与DPV-Ⅰ联合感染DEF单层后,均未见在细胞上复制。     

马传染性贫血病毒美洲流行株与我国弱毒疫苗株鉴别诊断方法的研究

马传染性贫血病毒(Equine infectious anemia virus,EIAV)是反转录病毒科慢病毒属的成员,是马传染性贫血病的病原.二十世纪七十年代我国就研制出马传染性贫血驴白细胞弱毒疫苗,成为世界第一个成功地应用该疫苗控制了我国的马传贫的发生[1].而且我国的马传贫弱毒疫苗对异源的美国、古巴和阿根廷等毒株也有很高的保护率[2].因此将我国的马传贫驴细胞弱毒疫苗推向国际市场成为可能.然而目前制约该苗出口的技术问题是现行的OIE推荐的琼脂扩散实验和ELISA等血清学方法不能鉴别自然感染马与我国弱毒疫苗免疫马,针对这个关键问题,本试验采用PCR方法初步建立了一种能够鉴别美洲(美国和阿根廷)流行毒株感染马和我国弱毒疫苗免疫马的实验室检测方法,为我国疫苗能在世界范围内应用提供了配套技术.     

应用免疫金银技术检测猪瘟病毒兔化弱毒株感染细胞

在应用免疫金银染色技术成功地对猪瘟病毒弱毒疫苗Thiveral株（CSFV．T株）感染的PK－15细胞进行检测的基础上,通过改进免疫金银反应的条件,进一步提高了免疫金银法的检测灵敏度和特异性。目前已将该技术应用到对猪瘟病毒兔化弱毒疫苗株（CSFVC株）感染细胞的检测,获得较为满意的实验结果。免疫金银染色技术的应用为研究CSFV在细胞中增殖的规律提供更为灵敏的检测手段,并且可望为猪瘟疫苗生产中的滴度测定提供一种简便有效的手段。     

EIAV弱毒疫苗免疫马外周血单核细胞IL-2表达水平的研究

目的:通过定量监测马传染性贫血病毒(EIAV)弱毒疫苗免疫马外周血单核细胞(PBMC)IL-2表达水平的变化特征,探讨EIAV弱毒疫苗的免疫保护机制。方法:用实时定量RT-PCR技术建立了马外周血PBMCIL-2表达水平的定量检测方法。在不同的时间点定期对4组(疫苗免疫组、健康对照组、强毒攻毒组和EIAV自然感染组)12匹马的外周血PBMCIL-2表达水平进行了检测,同时观察了临床症状及体温变化等指标。疫苗株免疫动物8个月后用强毒攻毒,观察了攻毒前后IL-2表达水平的变化。结果:(1)疫苗免疫马外周血PBMCIL-2的表达量显著高于健康对照组及自然感染组(P<0.01),且免疫后攻毒IL2继续升高,4匹疫苗免疫马均获得完全保护;(2)强毒攻毒对照组IL2表达量随疾病进展波动,发热期明显下降。结论:首次证明EIAV弱毒疫苗可诱导马外周血PBMC表达高水平的IL-2,提示IL-2在疫苗的免疫保护应答中发挥了重要作用;IL-2表达水平还与EIAV感染后的疾病进展密切相关。     

反向遗传学技术在猪瘟病毒研究中的应用

猪瘟目前在许多国家流行并对养猪业造成巨大损失。虽然常规疫苗(如中国猪瘟兔化弱毒疫苗,即C株)在猪瘟防控中发挥巨大作用,但近年来在猪瘟防控中出现的新情况,如非典型感染、持续性感染及免疫失败等;同时目前世界上许多国家正开展的猪瘟扑灭计划使得弱毒疫苗的应用受到很大限制。因此,加强猪瘟病毒在致病机理、传播机制等方面的研究以及加快新型猪瘟疫苗的开发是当务之急。近年来,反向遗传学技术的发展为猪瘟病毒基因功能研究和疫苗制备方面开辟了新思路。以下回顾了反向遗传操作技术在猪瘟病毒基因功能研究与标记疫苗株构建方面的研究进展,同时提出了该领域目前面临的问题,并对其未来发展方向进行了展望。     

马传染性贫血病毒弱毒疫苗致弱及免疫保护机制研究进展

马传染性贫血病毒(equine infectious anemia virus, EIAV)弱毒疫苗是中国科学家在20世纪70年代研制成功的世界上首例慢病毒疫苗,是迄今为止唯一在临床大规模应用的慢病毒弱毒疫苗。EIAV弱毒疫苗的成功应用不仅消除了该疫病对马业的威胁,而且在学术上突破了慢病毒不能免疫的理论。该疫苗克服了灭活疫苗免疫原性差的难点,能有效地提供对同源和异源毒株的免疫保护。因此,在分子水平上阐明EIAV弱毒疫苗的减毒机理和免疫保护机制对于研究慢病毒免疫保护具有极其重要的科学意义。作者所在的研究团队多年来一直从事EIAV弱毒疫苗的致弱机理及其诱导免疫保护机制的研究,解析了EIAV弱毒疫苗及其强毒株的基因组进化特征、揭示了疫苗致弱规律和疫苗有效组成、提出了"EIAV弱毒疫苗可能起源于EIAV准种的一个小分支"的假说;发现EIAV弱毒疫苗可有效激活天然免疫和特异性免疫,早期诱导的高水平细胞免疫与免疫保护呈正相关;证明了疫苗株的抗原多样性组成是其诱导保护性免疫应答的关键因素。相关研究成果拓展了慢病毒疫苗研究理论和实践认知,可为其他慢病毒尤其是HIV-1免疫原的设计以及免疫保护理论提供有价值的参考。     

马传染性贫血病毒美洲流行株与我国弱毒疫苗株鉴别诊断方法的研究

马传染性贫血病毒(Equine infectious anemia virus,EIAV)是反转录病毒科慢病毒属的成员,是马传染性贫血病的病原。二十世纪七十年代我国就研制出马传染性贫血驴白细胞弱毒疫苗,成为世界第一个成功地应用该疫苗控制了我国的马传贫的发生[1]。而且我国的马传贫弱毒疫苗对异源的美国、古巴和阿根廷等毒株也有很高的保护率[2]。因此将我国的马传贫驴细胞弱毒疫苗推向国际市场成为可能。然而目前制约该苗出口的技术问题是现行的OIE推荐的琼脂扩散实验和ELISA等血清学方法不能鉴别自然感染马与我国弱毒疫苗免疫马,针对这个关键问题,本试验…     

T细胞IFN-g表达水平检测方法的建立及其在马传染性 贫血疫苗免疫机理研究中的应用

[目的]马传染性贫血病毒(EIAV)弱毒疫苗致弱机制和免疫保护机理的研究可以为慢病毒疫苗的研究提供重要的模型.为探讨IFN-γ表达水平与疫苗保护性免疫的关系,本研究旨在建立一种准确、有效地检测EIAV感染马不同T细胞亚型表达IFN-γ水平的方法.[方法]我们将分离的马传贫弱毒疫苗免疫马(FDDV)、强毒感染马(LV)和健康马的外周血单核细胞(PBMC),体外分别经病毒(FDDV)和PMA/Inomycin激活、 BFA 阻断蛋白分泌、荧光标记马的特异性表面抗体和IFN-γ抗体等过程后,进行流式检测.[结果]疫苗免疫马产生的特异性IFN-γ水平为CD4 1.7(0.9%/CD8 6.1(1.2%,而强毒组则为CD4 0.6(0.1%/CD8 2.4(0.9%.[结论]本研究建立的多荧光参数流式细胞术同时检测细胞内IFN-γ染色和淋巴细胞亚型的方法,具有良好的特异性,稳定性和重复性.为研究EIAV弱毒疫苗免疫保护机制奠定了基础.     

我国28种鹅膏菌主要肽类毒素的检测分析*

利用高效液相色谱(HPLC)技术对产于我国的28种鹅膏菌的主要肽类毒素(鹅膏毒肽和鬼笔毒肽)进行了检测分析,并和采于欧洲(德国)的毒鹅膏Amanita phalloides作对照,结果表明,3种东亚所特有的鹅膏菌(灰花纹鹅膏、致命鹅膏和黄盖鹅膏白色变种)和欧洲毒鹅膏所含毒素种类多、含量高,其子实体菌盖部位主要毒素总量分别达到12583.7μg/g、8152.6μg/g、1058.2μg/g、7456.2μg/g干重子实体,这4种鹅膏菌可称之为剧毒鹅膏菌。其它25种鹅膏菌中有10种检测出含有微量鹅膏毒肽,含量在19.5μg/g-151.2μg/g之间。在4种剧毒鹅膏菌中,子实体组织部位不同,毒素含量以及鹅膏毒肽和鬼笔毒肽在其中的分布也不一样,菌盖中的毒素含量最高,菌柄的毒素含量次之,菌托中的毒素含量最低;对于灰花纹鹅膏、致命鹅膏和黄盖鹅膏白色变种,无论在菌盖、菌柄和菌托中,鹅膏毒肽类毒素的含量都高于鬼笔毒肽类毒素,尤其以α-amanitin的相对含量最高;而在欧洲毒鹅膏中,菌盖、菌柄和菌托中都以鬼笔毒肽为主,尤其以phallacidin的相对含量最高,并且从菌盖至菌柄到菌托,鬼笔毒肽的相对含量依次增加。     

Survival of Dusky Canada Goose Goslings in Relation to Weather and Annual Nest Success

Abstract The dusky Canada goose (Branta canadensis occidentalis) population has been in long-term decline, likely due to reduced breeding productivity, but gosling survival of this population had not been examined. We studied gosling survival in broods of radiomarked adult females on the western Copper River Delta, Alaska, USA, during 1997–1999 and 2001–2003. Survival estimates for dusky Canada goose goslings to 45 days (x̄ = 0.32) were below estimates from most previous studies of geese. Daily survival of goslings increased with age and decreased with date of hatch. Precipitation during the first 3 days post-hatch was negatively related to gosling survival and this effect increased with date. Annual estimates of gosling survival were positively correlated with annual estimates of nest success, suggesting overlap in factors affecting nest and gosling survival. Nest success probably also directly affected gosling survival, because survival decreased with hatch date and more broods hatched from renests during years with low nest success. Gosling survival appears to play an important role in limiting current productivity of this population. Management directed at increasing nest success would likely also improve gosling survival. We recommend additional research directed at examining sources of gosling mortality and the link between nest success and gosling survival.     

Feedback dynamics of grazing lawns: coupling vegetation change with animal growth

We studied the effects of grazing by Black Brant (Branta bernicla nigricans) geese (hereafter Brant) on plant community zonation and gosling growth between 1987 and 2000 at a nesting colony in southwestern Alaska. The preferred forage of Brant, Carex subspathacea, is only found as a grazing lawn. An alternate forage species, C. ramenskii, exists primarily as meadow but also forms grazing lawns when heavily grazed. We mowed plots of ungrazed C. ramenskii meadows to create swards that Brant could select and maintain as grazing lawns. Fecal counts were higher on mowed plots than on control plots in the year after plots were mowed. Both nutritional quality and aboveground biomass of C. ramenskii in mowed plots were similar to that of C. subspathacea grazing lawns. The areal extent of grazing lawns depends in part on the population size of Brant. High Brant populations can increase the areal extent of grazing lawns, which favors the growth of goslings. Grazing lawns increased from 3% to 8% of surface area as the areal extent of C. ramenskii meadows declined between 1991 and 1999. Gosling mass was lower early in this time period due to density dependent effects. As the goose population stabilized, and area of grazing lawns increased, gosling mass increased between 1993 and 1999. Because larger goslings have increased survival, higher probability of breeding, and higher fecundity, herbivore-mediated changes in the distribution grazing lawn extent may result in a numerical increase of the population within the next two decades.     

Goose parvovirus structural proteins expressed by recombinant baculoviruses self-assemble into virus-like particles with strong immunogenicity in goose

Goose parvovirus (GPV), a small non-enveloped ssDNA virus, can cause Derzsy’s disease, and three capsid proteins of VP1, VP2, and VP3 are encoded by an overlapping nucleotide sequence. However, little is known on whether recombinant viral proteins (VPs) could spontaneously assemble into virus-like particles (VLPs) in insect cells and whether these VLPs could retain their immunoreactivity and immunogenicity in susceptible geese. To address these issues, genes for these GPV VPs were amplified by PCR, and the recombinant VPs proteins were expressed in insect cells using a baculovirus expression system for the characterization of their structures, immunoreactivity, and immunogenicity. The rVP1, rVP2, and rVP3 expressed in Sf9 cells were detected by anti-GPV sera, anti-VP3 sera, and anti-His antibodies, respectively. Electron microscopy revealed that these rVPs spontaneously assembled into VLPs in insect cells, similar to that of the purified wild-type GPV virions. In addition, vaccination with individual types of VLPs, particularly with the rVP2-VLPs, induced higher titers of antibodies and neutralized different strains of GPVs in primary goose and duck embryo fibroblast cells in vitro. These data indicated that these VLPs retained immunoreactivity and had strong immunogenicity in susceptible geese. Therefore, our findings may provide a framework for development of new vaccines for the prevention of Derzsy’s disease and vehicles for the delivery of drugs.     

鹅圆环病毒感染性克隆的构建及其转染试验

设计带BamHⅠ酶切标记位点的引物,PCR扩增鹅圆环病毒(Goose circovirus,GoCV)全长基因组,将2个基因组顺式连接插入到pGEM-T Easy载体中,获得GoCV全长基因组头尾串联二聚体感染性克隆质粒pGEMT-2GoCV。EcoRⅠ酶切线性化pGEMT-2GoCV,与脂质体混合转染GoCV阴性鹅胚和雏鹅,常规PCR检测发现GoCV在转染鹅体内增殖,鹅胚转染组于孵出第2周和第4周检出血清阳性,且其中一个个体于4周龄扑杀时检出法氏囊阳性,雏鹅转染组于转染后2周检出血清阳性。试验进一步对扩增片段进行了BamHⅠ标记位点的检测,并应用GoCV实时荧光定量PCR方法对转染阳性样品进行了定量,结果显示阳性法氏囊组织中病毒含量为1.57×106拷贝/mg,阳性血清含病毒拷贝数在3.52×104～5.92×105拷贝/μL。综上,本试验构建的GoCV全长基因组头尾串联二聚体感染性克隆DNA可以转染鹅胚和雏鹅并增殖出带标记的GoCV克隆。     

Growth of Greater White-Fronted Goose Goslings Relates to Population Dynamics at Multiple Scales

The abundance of greater white-fronted geese (Anser albifrons frontalis) on the Arctic Coastal Plain (ACP) of northern Alaska, USA, has more than tripled since the late 1990s; however, recent rate of annual population growth has declined as population size increased, which may indicate white-fronted geese on the ACP are approaching carrying capacity. We examined rates of gosling growth in greater white-fronted geese at 3 sites on the ACP during 2012–2014 to assist with predictions of future population trends and assess evidence for density-dependent constraints on recruitment. We marked goslings at hatch with individually coded webtags and conducted brood drives during early August to capture, measure, and weigh goslings. Annual estimates of gosling mass at 32 days old (range = 1,190–1,685) indicate that goslings had obtained >60% of asymptotic size. This rate of growth corresponds with that of other goose species and populations with access to high-quality forage and no limitations on forage availability, and is consistent with the overall increase in abundance of white-fronted geese at the ACP scale. Contrary to most previous investigations, age-adjusted mass of goslings did not decline with hatch date. Goslings grew faster in coastal areas than at inland freshwater sites. Taken together, these findings suggest forage was not limiting gosling growth rates in either ecosystem, but forage was of greater quality in coastal areas where goose foraging habitat is expanding because of permafrost subsidence. Spatial patterns of gosling growth corresponded with local-scale patterns of population density and population change; the areas with greatest rates of gosling growth were those with the greatest population density and rates of population increase. We found little evidence to suggest forage during brood rearing was limiting population increase of white-fronted geese on the ACP. Factors responsible for the apparent slowing of ACP-wide population growth are likely those that occur in stages of the annual cycle outside of the breeding grounds. Published 2021. This article is a U.S. Government work and is in the public domain in the USA.     

Climate change,phenology, and habitat degradation: drivers of gosling body condition and juvenile survival in lesser snow geese

Nesting migratory geese are among the dominant herbivores in (sub) arctic environments, which have undergone unprecedented increases in temperatures and plant growing days over the last three decades. Within these regions, the Hudson Bay Lowlands are home to an overabundant breeding population of lesser snow geese that has dramatically damaged the ecosystem, with cascading effects at multiple trophic levels. In some areas the overabundance of geese has led to a drastic reduction in available forage. In addition, warming of this region has widened the gap between goose migration timing and plant green‐up, and this ‘mismatch’ between goose and plant phenologies could in turn affect gosling development. The dual effects of climate change and habitat quality on gosling body condition and juvenile survival are not known, but are critical for predicting population growth and related degradation of (sub) arctic ecosystems. To address these issues, we used information on female goslings marked and measured between 1978 and 2005 (4125 individuals). Goslings that developed within and near the traditional center of the breeding colony experienced the effects of long‐term habitat degradation: body condition and juvenile survival declined over time. In newly colonized areas, however, we observed the opposite pattern (increase in body condition and juvenile survival). In addition, warmer than average winters and summers resulted in lower gosling body condition and first‐year survival. Too few plant ‘growing days’ in the spring relative to hatch led to similar results. Our assessment indicates that geese are recovering from habitat degradation by moving to newly colonized locales. However, a warmer climate could negatively affect snow goose populations in the long‐run, but it will depend on which seasons warm the fastest. These antagonistic mechanisms will require further study to help predict snow goose population dynamics and manage the trophic cascade they induce.     

鹅细小病毒和番鸭细小病毒核酸疫苗重组质粒的构建及表达

将鹅细小病毒（GPV）和番鸭细小病毒（MPV）主要结构蛋白（VP2－VP3）基因克隆到核酸疫苗质粒pIRESlneo载体上,构建了核酸疫苗重组质粒pIGVP1和pIMVP,通过脂质体转染法分别将重组质粒到鹅胚成纤维细胞和番鸭胚成纤维细胞中,核酸疫苗重组质粒pIGVP1和pIMVP分别转染鹅胚成纤维细胞和番鸭成纤维细胞中,于转染后72h收取细胞,细胞裂解液裂解后,经Western blot检测其表达产物可出现特异性反应带,证明表达产物具有很好的反应原性。