麻疹疫苗生产用毒株沪191增殖的动力学研究

通过延长麻疹病毒生产中感染的基质细胞培养时间并连续收获病毒,获得麻疹病毒生产的动力学曲线;通过工艺放大阶段的病毒增殖动力学研究,提高麻疹病毒产量。采用直接接种和间接接种法,接种不同感染量(MOI)的病毒,将转瓶培养单次收获改为转瓶培养多次收获,滴定整个培养期间每次收获液的病毒滴度,观察感染的细胞培养维持状况并计算病毒产量。结果表明,直接接种病毒培养期为20~25d,共收获病毒14~17次;间接接种病毒培养期24d,共收获病毒29次。通过延长感染细胞培养时间和连续收获病毒,获得病毒繁殖的动力学曲线。通过麻疹毒株的增殖动力学研究获得了麻疹疫苗生产毒株沪191增殖动力学相关参数。     

福建省2012-2020年麻疹野毒株分子流行病学分析

为了解2012-2020年福建省麻疹野毒株病毒核蛋白N基因及H基因的变化,探讨其流行规律,本研究收集2012年-2020年福建省各地市级麻疹风疹网络实验室检测麻疹病毒核酸阳性的麻疹疑似病例咽拭子标本开展病毒分离,应用RT-PCR方法扩增MV的N基因羧基末端450个核苷酸片段并进行序列测定,通过与WHO推荐24个麻疹病毒基因型参考株、中国S(Shanghai,上海)191疫苗株、H1a中国代表株（China93-2）进行对比分析,从2012-2020年共收到1217例麻疹核酸检测阳性的疑似麻疹病例的病原学标本中,共分离出83株麻疹病毒野毒株,其中76株为H1a亚型,5株B3基因型,2株D8基因型。H1a亚型可分为2个独立谱系Lineage1～2,MV H1a基因型毒株间核苷酸及氨基酸同源性为99.82%～99.98%和99.91%～100%。2018年及2019年福建省首次分离到B3基因型麻疹病毒及D8基因型麻疹病毒为输入性基因型,B3基因型毒株高度同源,D8基因型毒株同源性100%。H1a基因型为福建省本土野毒株优势基因亚型,不同地区不同年代存在同一野毒株持续循环,同一地区同一年份也具...     

甲型肝炎病毒H2快速复制株在人二倍体细胞中的增殖研究

研究甲型肝炎病毒H₂快速复制株在人二倍体细胞中的生长特性,并缩短甲肝病毒的培养周期。将甲型肝炎病毒H₂株感染人二倍体细胞（KMB17细胞株）,采用高病毒感染复数（MOI）将病毒培养时间从26d缩短至10d后收获病毒,并通过连续传代进行适应研究,建立H₂株快速复制毒种库,在不同培养时间检测病毒抗原、感染性滴度,绘制病毒生长曲线,进行传代稳定性验证和病毒形态学的观察。甲肝H₂株快速复制病毒株在KMB17细胞上培养10d后收获,连续传代从第5代至第9代,抗原含量均在512～2 048之间,感染性滴度均在8.33 lgCCID₅₀/mL±0.125lgCCID₅₀/mL,H₂株快速繁殖至5代病毒和9代病毒在电镜下观察到多为成熟的实心颗粒。在5批次的重复试验中,病毒培养至10d、16d、22d时,收获的病毒感染性滴度无显著差异（P>0.005）。筛选后的甲型肝炎病毒H₂株的快速复制株缩短了甲肝病毒的培养时间,且保持较...     

细胞培养结合实时荧光RT-PCR法快速检测甲肝病毒滴度的研究

目的建立一种细胞培养与实时荧光RT-PCR相结合的快速检测甲肝病毒滴度的方法。方法根据甲肝病毒(HAV)L-A-1株5'端基因组序列,设计了2条基因特异性引物及一条探针,建立实时荧光RT-PCR法,结合细胞培养检测甲肝病毒滴度,并与ELISA检测法进行比较。结果实验中建立的方法能特异检测甲肝病毒,细胞培养8d检测病毒滴度为lg107.0CCID50/mL。同一样本重复检测3次,批内样本Ct值的变异系数最大为0.89%,批间样本Ct值变异系数最大为1.66%。建立的细胞培养结合实时荧光RT-PCR法(细胞培养8 d)与细胞培养ELISA法(细胞培养28 d)检测甲肝病毒滴度结果差异无统计学意义(P0.05)。结论该方法具有快速、灵敏、特异等优点,应用于疫苗常规检测有良好前景。     

麻疹病毒全长cDNA构建及其感染性的研究

为发展新型疫苗和改造目前使用的麻疹病毒疫苗,以麻疹病毒疫苗株为模板,构建了具有感染性的麻疹病毒cDNA克隆.用RT-PCR分6段扩增出麻疹病毒全长基因,通过酶切、拼接构建麻疹病毒疫苗株CC-47的全长正链cDNA序列,并精确地置于T7启动子控制下与丁型肝炎病毒核酶序列之前.克隆麻疹病毒CC-47株蛋白N、P、L编码区质粒并置于T7启动子控制下,用4个质粒共转染哺乳动物细胞,在表达T7 RNA聚合酶的重组痘苗病毒VTF7-3的作用下进行病毒拯救.经免疫荧光、PCR等方法检测证实,获得了具有感染性的麻疹病毒.所拯救的病毒在哺乳动物细胞连续传3代后,仍能检出病毒抗原和核酸.     

甲型肝炎病毒Vero细胞适应株的选育研究

将甲肝患者粪便中分离的甲型肝炎病毒在Vero细胞中进行适应性培养 ,选育高滴度适应株应用于甲肝灭活疫苗研究。在Vero细胞上连续传代 ,测抗原滴度和感染性滴度 ,满意后按WHO推荐的甲型肝炎灭活疫苗规程进行灭活疫苗试制研究。经Vero细胞 14次适应性传代后 ,病毒抗原滴度可高达 1∶2 5 6 0 ,感染性滴度为 8.2 3LogC CID50 /ml。试制的灭活疫苗HPSEC检测在 2 80nm时仅有一个高峰 ,SDS PAGE电泳 ,在 2 2kD、2 6kD和 33kD处有三条蛋白带 ,和HAVVP3、VP2和VP1的位置相同。ICR小鼠效力试验表明疫苗剂量 16 0 0EU/ml与Merck疫苗5 0U效果相似。通过研究获得了Vero细胞甲肝病毒适应株YN5株 ,初步证明可作为甲型肝炎灭活疫苗的候选毒株。     

浙江省麻疹病毒分离株的基因特性与免疫原性研究

为了研究浙江省1999～2003年麻疹病毒分离株的抗原性变化以及基因特性,阐明其基因特性与麻疹流行的关系,以及抗原性变化对疫苗免疫效果的影响.我们从麻疹患者含漱液中分离麻疹病毒株,制备大鼠免疫血清,与疫苗株沪191和Edmonston株等进行交叉中和试验,测定各毒株之间抗原比;并采集儿童麻疹疫苗免疫前后血清,分别测定其对不同毒株的中和抗体滴度;采用RT-PCR法扩增麻疹毒株血凝素蛋白(H)及核蛋白(N)基因,进行核苷酸序列测定.结果浙江99-1和浙江02-2株与沪191株之间的抗原比分别为3.0和7.3;儿童免疫后血清对浙江02-2株的麻疹中和抗体平均几何滴度(GMT)为15.03,明显低于沪191疫苗株(GMT为68.12);浙江省1999～2003年麻疹分离株之间,H基因氨基酸同源性为99.8%,N基因氨基酸同源性为98.5%～100.0%;与沪191疫苗株的H基因和N基因相比较,分离株与其在氨基酸水平上同源性分别为95.5%～95.7%和95.9%～96.3%.从基因进化树显示,1999～2003年浙江省分离到的麻疹毒株属于H1基因型,但与疫苗株沪191在抗原性和基因特性上已存在明显的差异.     

麻疹病毒融合蛋白(F)和血凝素(HA)在痘苗病毒中的表达

将麻疹病毒F和HA基因插入到痘苗病毒中,分别处于痘苗启动子P7.5与P11控制下,获得重组病毒vLmF和vCmH。用抗F多肽抗体和HA单抗进行ELISA检测,结果表明,两株重组病毒均能表达相应的麻疹蛋白。蛋白印迹显示重组病毒表达产物在分子大小,蛋白切割和糖化方面与麻疹病毒糖蛋白一致。两株重组病毒分别免疫家兔都能产生较高滴度的麻疹抗体,这些抗体具有中和作用和血溶抑制作用。此外,vCmH产生的抗体还具有血凝抑制作用。     

SARS病毒NS-1株稳定性及培养条件的研究

用SARS病毒NS-1株接种Vero细胞,37℃培养,于培养1、2、3、4d收获病毒液,分别置-70℃冻融和4℃释放,于不同时期取样进行病毒滴定。结果显示,SARS病毒NS-1株各代次培养特性和形态学变化完全相同,有较好的抗原特异性,病毒滴度稳定,4℃保存125d,滴度下降2．25lgCCID50／ml,-70℃保存6个月,滴度未见明显下降。SARS病毒NS-1株未经冻融或释放,1d收获的病毒滴度比2、3、4d收获的病毒滴度低,经冻融或释放,1、2、3、4d收获的病毒滴度无明显区别,病毒收获时的病毒滴度与形态学变化成正相关。不同接种条件收获的病毒液,病毒滴度无明显区别。SARS NS-1株有较好的遗传稳定性和保存稳定性,培养2d,4℃释放收获病毒液,细胞悬液与病毒混合接种更简单,易操作,更适合疫苗规模生产。     

浙江省麻疹病毒的基因特征分析

目的分析浙江省流行的麻疹病毒(MV)的基因特征,为更好地防控麻疹提供科学参考。方法从GenBank检索并下载浙江省所有麻疹病毒株、中国麻疹疫苗株和WHO推荐参考株的血凝素蛋白(H)和核蛋白(N)的基因组序列,利用MEGA 6.0软件进行比对分析,构建种系进化树,确定浙江省麻疹病毒流行的基因型别,并进行同源性和基因变异分析。结果浙江省麻疹病毒以H1基因型为主(27株),其他基因型为辅(2株B3型)。H1a亚型(21/27)占绝对优势,其次为H1b亚型(6/27)。浙江省所有毒株间H蛋白的氨基酸同源性为96.9%~100.0%,与疫苗株Shanghai-191和Changchun-47的同源性均为95.0%~96.0%。浙江省所有毒株间N蛋白羧基末端的氨基酸同源性为82.7%~100.0%,与疫苗株Shanghai-191的同源性为85.8%~89.5%,与疫苗株Changchun-47的同源性为87.3%~91.0%。结论麻疹病毒H1基因型为浙江省麻疹流行的优势株,与现行参考疫苗株(A基因型)差异较大,因此针对麻疹病毒H1基因型疫苗的研制是今后浙江省麻疹病毒防控的关键。     

Extent of measles virus spread and immune suppression differentiates between wild-type and vaccine strains in the cotton rat model (Sigmodon hispidus)

Infection of humans with wild-type measles virus leads to strong immune suppression and secondary infections, whereas immunization with an attenuated vaccine strain does not. Using the cotton rat model (Sigmodon hispidus), we investigated whether vaccine and wild-type viruses differ in viral spread and whether this is correlated with inhibition of of proliferation of spleen cells ex vivo after mitogen stimulation. After intranasal infection of cotton rats with wild-type and vaccine strains, it was found that wild-type virus replicates better in lung tissue, spreads to the mediastinal lymph nodes, and induces a more pronounced and longer-lasting inhibition of proliferation of spleen cells ex vivo after mitogen stimulation than does vaccine virus. To induce the same degree of proliferation inhibition, 1,000-fold less wild-type virus was required than vaccine virus. With this system, the virulence of various measles virus isolates and recombinant viruses was tested. Four (in humans and/or monkeys) highly pathogenic virus strains were immunosuppressive, whereas viruses of vaccine virus genotype A were not. Using virus pairs which, due to passage on fibroblasts versus lymphoid cells or due to a point mutation in the hemagglutinin (N481 --> Y), differed in their usage of the two receptor molecules CD46 and CD150 on human cells, it was found that viruses using exclusively CD150 in vitro spread to mediastinal lymph nodes and induced strong immune suppression. These data demonstrate that important parameters of virulence seen in humans, such as viral spread and immune suppression, are reflected in the cotton rat model.     

Response of Children to Inactivated Measles Vaccine Prepared in Bovine Renal Cell Culture

Formalin-inactivated, alum-adsorbed measles vaccine was readily prepared from virus grown in calf kidney cell culture infected with the Sugiyama strain of measles virus which had been adapted to this cell culture. The vaccine induced no side reaction of any consequence in vaccinated children, but demonstrated antigenic capacity in children as well as guinea pigs, comparable to that of currently used killed measles vaccines prepared from virus grown in monkey kidney or chick embryo tissue cultures. The host system employed for the preparation of this vaccine has an advantage over monkey kidney or chick embryo tissue cultures which are currently used for manufacture of killed measles vaccine. Bovine kidneys are much easier to obtain and cultivate. Of importance is the fact that calf kidneys are practically free of latent virus, whereas monkey kidneys and chick embryos frequently harbor latent viruses.     

Morbilliviruses use signaling lymphocyte activation molecules (CD150) as cellular receptors

Morbilliviruses comprise measles virus, canine distemper virus, rinderpest virus, and several other viruses that cause devastating human and animal diseases accompanied by severe immunosuppression and lymphopenia. Recently, we have shown that human signaling lymphocyte activation molecule (SLAM) is a cellular receptor for measles virus. In this study, we examined whether canine distemper and rinderpest viruses also use canine and bovine SLAMs, respectively, as cellular receptors. The Onderstepoort vaccine strain and two B95a (marmoset B cell line)-isolated strains of canine distemper virus caused extensive cytopathic effects in normally resistant CHO (Chinese hamster ovary) cells after expression of canine SLAM. The Ako vaccine strain of rinderpest virus produced strong cytopathic effects in bovine SLAM-expressing CHO cells. The data on entry with vesicular stomatitis virus pseudotypes bearing measles, canine distemper, or rinderpest virus envelope proteins were consistent with development of cytopathic effects in SLAM-expressing CHO cell clones after infection with the respective viruses, confirming that SLAM acts at the virus entry step (as a cellular receptor). Furthermore, most measles, canine distemper, and rinderpest virus strains examined could any use of the human, canine, and bovine SLAMs to infect cells. Our findings suggest that the use of SLAM as a cellular receptor may be a property common to most, if not all, morbilliviruses and explain the lymphotropism and immunosuppressive nature of morbilliviruses.     

The cytochemical marking of lymphocyte subpopulations in determining the immunoreactivity status of children vaccinated with a live measles vaccine

In 54 children aged 1.5-2 years, immunized with the same batch of live measles vaccine prepared from strain, the relative and absolute numbers of different lymphocyte subpopulations were determined in parallel by means of two cytochemical reactions: for acid alpha-naphthyl acetate esterase and acid phosphatase in their dynamics. According to the data obtained in these reactions, the determination of lymphocyte subpopulations by two cytochemical methods in the same blood sample yielded similar results indicating that immunization with attenuated measles virus strain induced a rise in the number or zero lymphocytes and was accompanied by the decrease of the immunoregulatory index (T-helper/T-suppressor ratio), most pronounced in children with a high level of antibody formation.     

Studies on live rubella vaccine. V. Quantitative aspects of interference between rubella, measles and mumps viruses in their trivalent vaccine

Rubella vaccine combined with measles and mumps vaccines was administered in a single injection to children of 1 to 5 years of age. All three vaccines were serologically effective, and the clinical reactions caused by measles vaccine were considerably alleviated, when 6 x 10(3) PFU of rubella and 10(4) TCD50 per dose of mumps vaccines were combined with 5 x 10(4) TCD50 of measles vaccine. When a larger amount of mumps vaccine (3 x 10(5) TCD50/dose) was used, it caused interference with the rubella and measles viruses, i.e., the antibody response to rubella virus became poor and the incidence of clinical reactions to measles virus decreased. On the other hand, when 5 x 10(5) TCD50/dose of measles vaccine was combined with 10(4) TCD50/dose of mumps vaccine, the clinical reactions to measles virus were decreased but were almost the same as those induced by this vaccine alone.     

Evaluation of live trivalent vaccine of measles AIK-C strain, mumps Hoshino strain and rubella Takahashi strain, by virus-specific interferon-gamma production and antibody response

A trivalent measles-mumps-rubella live virus vaccine, containing measles AIK-C strain, mumps Hoshino strain, and rubella Takahashi strain, was evaluated in 229 children, aged 1 to 5 years. The vaccine induced a high seroconversion rate: 221 (98.7%) out of 224 subjects initially seronegative for measles virus, 167 (93.3%) out of 179 initially seronegative for mumps virus, and 212 (99.1%) out of 214 initially seronegative for rubella virus. It also induced a sufficient cellular immunity against each of the three viruses in over 90% of the subjects, as judged by virus-specific interferon-gamma (IFN-gamma) production. Virus-specific IFN-gamma production was observed 10 days after vaccination by stimulation with measles virus and rubella virus and 14 days after vaccination by stimulation with mumps virus. Mumps-virus-specific IFN-gamma production was observed in 7 out of 12 recipients without seroconversion for mumps virus. And measles-virus-specific IFN-gamma production was demonstrated in one out of three recipients without seroconversion for measles virus. A significant correlation was observed between the serum antibody and IFN-gamma production six weeks after vaccination for measles virus (r = 0.201, P less than 0.01) and for mumps virus (r = 0.174, P less than 0.05) but not for rubella virus (r = -0.045, P less than 0.05). The incidence of febrile reactions of greater than or equal to 37.5 C was quite low, 14.4%, and that of greater than or equal to 39 C occurred in only 1.3% of the recipients. These results suggested that the trivalent vaccine induced sufficient humoral and cellular immunity and yet resulted in no more untoward reaction than observed from the measles vaccine alone.     

辽宁省2016‒2017年H3N2亚型流感病毒 HA1基因特征分析

摘要：目的 了解2016?2017年辽宁省H3N2亚型流感病毒基因变异情况及流行株与疫苗株的匹配情况。方法 采用逆转录聚合酶链反应（RT-PCR）对分离得到的H3N2亚型流感毒株的HA1基因进行扩增,扩增片段经测序与近年来WHO推荐的北半球疫苗株进行比对和基因特征分析。结果 进化分析表明,2016?2017年H3N2亚型流感病毒与近三年的疫苗株均不在同一分支上;基因特性分析中,所有病毒均在A、B抗原决定簇上发生了两处以上的变异;19株病毒的受体结合位点131位氨基酸发生了新的变异;20株病毒中有1株突变产生了新的半胱氨酸,提示可能有新的二硫键产生;糖基化位点并未检测到新的突变。结论 2016?2017年辽宁省H3N2亚型流感病毒的抗原性及基因特性均发生了一定的变化,但变异程度不大,应密切关注疫苗株对流感病毒的免疫效果及流感毒株的变异情况。     

Comparison of Subacute Sclerosing Panencephalitis and Measles Viruses: an Electron Microscope Study

The ultrastructure of CV-1 cells infected with subacute sclerosing panencephalitis (SSPE) viruses was compared with that of CV-1 cells infected with the wild or Edmonston strain of measles virus. Both SSPE viruses and the measles viruses produced two types of nucleocapsid structures: smooth filaments, 15 to 17 nm in diameter, and granular filaments, 22 to 25 nm. The smooth and granular filaments produced by SSPE and measles virus did not differ in appearance. In CV-1 cells infected with SSPE viruses, smooth filaments formed large intranuclear inclusions and granular filaments occupied a large area of the cytoplasm, but always spared the area under the cell membrane. Particles budding from the surface of these cells contained no nucleocapsids. In CV-1 cells infected with measles virus, only small aggregates of smooth filaments were seen in the nuclei. Granular filaments in the cytoplasm predominantly occupied the area under the cell membrane, and were aligned beneath the cell membrane in a parallel fashion and assembled into budding particles. These differences between SSPE and measles virus may be regarded as quantitative, but they do distinguish SSPE viruses from measles virus. Moreover, the formation of large nuclear inclusions filled with smooth filaments appears to be a characteristic process of SSPE, but not of measles, since this type of inclusion is invariably seen in SSPE brain tissues, brain cultures derived from them, and CV-1 cells infected with SSPE viruses.