安徽野生和自繁恒河猴血液生化指标的测定与分析

目的测定人工饲养条件下安徽野生和自繁恒河猴的血液生化指标,并比较分析两种来源的恒河猴,雌、雄猴间以及感染BV阳性与阴性恒河猴生化指标的差异性。方法采用全自动生化分析仪对安徽野生和自繁恒河猴的14个血液生化指标进行测定,并用统计学方法比较了相同性别的野生猴与自繁猴以及感染BV阳性与阴性恒河猴血液生化值的差异性。结果野生猴与自繁猴雄性的生化指标普遍高于雌性,野生猴碱性磷酸酶、甘油三脂和谷氨酰基转移酶雌雄间差异显著;自繁猴碱性磷酸酶、白蛋白、血清Ca、甘油三脂、肌酐和谷氨酰基转移酶雌雄间差异有显著性。除谷草转氨酶、尿素氮和血清总胆固醇外,感染BV阳性较感染BV阴性的恒河猴所得生化指标高。结论野生猴与自繁猴,雌雄间猴以及感染BV阳性与阴性猴的血液生化指标有一定的差异性。     

中国恒河猴Mamu-A*01基因筛查及其对抗原肽p11C的特异性CTL反应

目的 筛查中国恒河猴Mamu-A*01基因,比较中国恒河猴和印度恒河猴的Mamu-A*01基因序列和功能是否相同.方法 PCR方法检测128只中国恒河猴,用特异性引物扩增Mamu-A*01基因,将PCR扩增后的产物克隆测序后与印度恒河猴的Mamu-A*01基因进行同源比对;酶联免疫斑点检测 (ELISPOT) 方法分别检测5只Mamu-A*01基因阳性和5只阴性恒河猴针对SIV、SHIV抗原肽p11C的特异性CTL反应.结果 共筛查出5 只Mamu-A*01基因阳性恒河猴 (3.91%),经测序分析后与印度恒河猴的同源性可达99.1 %.这5只均为SIV/SHIV感染恒河猴,其中四只SIV感染的猴的ELISPOT结果显示针对p11C的高频CTL反应,斑点数在500-1400/106 PBMCs之间,而另1只SHIV感染的恒河猴及5只阴性猴没有斑点出现.结论 中国恒河猴含有Mamu-A*01基因,基因频率有区域性差异,中国恒河猴的Mamu-A*01可提呈特异性抗原肽p11C.     

SARS冠状病毒感染恒河猴的病毒、血清学检测研究

[目的]对感染SARS-CoV的恒河猴进行病毒、血清学等指标检测及研究,确定模型动物成功感染,并为SARS发病机制,疫苗评价,药物筛选确定参考指标。[方法]SARSCo-V经鼻腔接种8只恒河猴,在感染的第1天开始到5、7、10、15、20、30和60天分别安乐死时,不同时间取咽拭子、血液和脏器,进行病毒分离,RT-PCR检测和抗体测定。[结果]用巢式RT-PCR在感染后每天提取的咽拭子标本中检测SARS-CoV的RNA,以细胞培养冠状病毒为阳性对照,以正常恒河猴咽拭子为阴性对照,在8只动物病毒接种第5天开始可检测到大小为797bp的目的条带,阳性检出最长可持续到第15天。进一步用病毒分离实验对PCR结果进行确证,8只动物中的5只恒河猴接种5天的咽拭子标本中,经Vero细胞培养,细胞产生了典型细胞病变(CPE),提示SARS冠状病毒能感染恒河猴并有病毒的复制和排毒。IFA方法证实为SRAS-CoV抗原存在。SARS-CoV感染恒河猴后,可以检测出免疫反应。在SARS冠状病毒接种前和接种后第5、8、11、15、19、23、26、30、34、每隔4-7天以及安乐死时采血,制备血清测定抗体,8只恒河猴接种病毒前均血清中SARS冠状病毒特异性抗体IgG为阴性,10天后安乐处死的5只感染猴在11-15天开始,至安乐死时,均为阳性。IgG阳性的5只恒河猴均有一定的中和抗体产生,且对SARS病毒感染细胞有一定的保护性。感染SARS病毒猴后与正常猴比较,其细胞杀伤效应明显增强。感染SARS-CoV的恒河猴不仅出现与SARS患者类似的临床和病理学改变,也在一定时期内排毒,出现特异免疫反应,这些指标均可作为药物筛选、疫苗评价等方面的重要参数。     

安徽恒河猴的微生物学和寄生虫学检测

对安徽省实验猕猴中心的安徽恒河猴进行了微生物（包括病毒和病原菌）和寄生虫检测。对恒河猴的病毒检测结果发现,猕猴疱疹病毒1型（BV）和猴痘病毒（SPV）抗体的阳性率分别为20．7％（6／29）和10．0％（2／20）,20只恒河猴中没有发现猴反转录D型病毒（SRV）、猴免疫缺陷病毒（SIV）和猴T细胞趋向性病毒Ⅰ型（STLV—1）的抗体。5只受检的人工繁育的安徽恒河猴没有感染沙门菌、皮肤病原真菌、志贺菌和结核分枝杆菌的这四种病原菌。肉眼检测恒河猴体表,未发现体外寄生虫。39份人工繁殖的恒河猴粪便样品的总寄生虫感染率为38．5％,检测到溶组织内阿米巴和5种蠕虫（粪类圆线虫、猴结节线虫、绦虫、钩虫、蛔虫）,感染率最高的是粪类圆线虫和猴结节线虫。本次调查表明,安徽恒河猴无特殊疾病,健康状况基本良好,可以建立普通级的实验恒河猴,实现安徽恒河猴的实验动物化。     

云南地区恒河猴MHC部分基因频率及多态性的分析

目的不同种群恒河猴（Macaca mulatta）主要组织相容性复合体（major histocompatibility complex,MHC）基因的差异性,很大程度上影响了用其作为动物模型的实验研究结果的稳定性、可靠性和可重复性。清晰了解云南地区恒河猴种群免疫遗传学背景对于运用该种群开展各项研究非常重要。恒河猴基因Mamu（Macaca mulatta）-A＊01就被公认与猴免疫缺陷病毒（SIV）的感染与延缓病程相联系。Mamu-Ⅱ类等位基因Mamu-DRB1＊0306、0309有研究表明也与SIV感染后的病程发展有关。方法针对目前研究热点的Mamu-A＊01基因及Ⅱ类Mamu-DRB1＊0306、0309基因,采用序列特异性引物-聚合酶链式反应方法（PCR-SSP）,对云南地区的140只恒河猴（其中92只来源于云南景东野外自然繁殖群、48只来源于本灵长类中心自繁群）进行检测。并对阳性样本用部分测序结合单链构象多态性分析（SSCP）的方法加以验证。结果Mamu-A＊01检测结果为阴性。Mamu-DRB1＊0306、0309基因频率分别为32%及45%。结论初步显示云南地区恒河猴种群Mamu-A＊01基因可能缺失或基因频率很低,但存在Mamu-DRB1＊0306、0309基因。初步证明SSCP方法代替大规模测序是可行的,为云南地区恒河猴在AIDS研究中的应用提供了部分依据,一定程度上填补了该种群的遗传背景资料。     

恒河猴STLV-1血清抗体流行病学研究

目的调查我国恒河猴STLV-1流行病学特征.方法用免疫荧光法和蛋白印迹法对537只野捕恒河猴,365只繁殖猴和44只D型逆转录病毒抗体阳性猴作了STLV-1血清抗体检查.结果 10岁以上恒河猴的STLV-1抗体阳性率(15.5%)高于10岁以下的恒河猴(6.2%);雌猴的STLV-1抗体阳性率(17.5%)高于雄猴(5%);D型逆转录病毒抗体阳性猴群的STLV-1抗体阳性率(34.1%)高于野捕猴群(8.8%).结论在我国的野生和饲养恒河猴群中广泛存在STVL-1血清抗体阳性动物,其抗体阳性率与动物的年龄和性别有关.     

恒河猴离乳幼猴B病毒动态监测

目的调查恒河猴离乳幼猴BV感染的动态变化,探讨早期控制的可能。方法采用BV全病毒为抗原的ELISA试剂盒,对两批离乳后群养的54只恒河猴幼猴每月采血检测BV感染情况,连续检测13个月。结果随月龄的增加,BV感染率上升,其中12月、1月、2月、3月、4月BV阳性猴数量相对增加较明显。结论幼猴性成熟期之前BV感染率超过70％且呈现出一定的变化规律,春、冬季BV的感染率相对较高,应早期加强BV的有效预防控制,降低BV的感染,提高猴群质量。     

气管插管法接种H5N1病毒感染恒河猴及系统组织病毒检测

目的测试气管插管法接种高致病性禽流感病毒H5N1感染恒河猴的优势效果及疾病分析,为有效感染恒河猴、制备H5N1疾病模型提供实验依据。方法使用人源H5N1病毒液经气管插管滴入恒河猴上呼吸道进行感染,观察感染恒河猴的临床表现,每天采集咽拭子、鼻灌洗液,在感染前2d感染后第3、5、7天采血,感染后第3和7天分别解剖1只恒河猴,取支气管淋巴结、肠淋巴结、鼻甲、心、肝、脾、肺、肾、肠、气管、脑及血液进行病毒分离、核酸载量检测和血常规测定。结果感染后第2天恒河猴出现食欲下降,活动减少,并伴有一过性体温升高,白细胞数和淋巴细胞数下降。咽拭子、鼻灌洗液、肺、心、气管、脑、肝、肾、肠和血液中都能分离到H5N1病毒。结论气管插管法接种H5N1病毒能有效感染恒河猴,并在猴体内多组织中分离、检测到病毒,为制备完善的H5N1模型和检测指标确定、进一步研究H5N1病毒的致病机制等奠定了基础。     

人工驯养条件下食蟹猴B病毒抗体水平变化规律研究

目的研究人工驯养条件下食蟹猴B病毒抗体水平变化规律,便于有效控制自繁食蟹猴的BV感染率。方法随机选取409只对不同月龄自繁食蟹猴,采用BVELISA法进行BV抗体监测。结果新生仔猴刚出生时均携带不同程度的BV抗体,但随着月龄的增加,BV抗体水平开始下降,至5月龄时BV抗体阳性率降至最低（12．3％）,之后BV抗体水平逐渐升高。结论人工驯养条件下食蟹猴B病毒抗体水平呈由高到低再升高的趋势,5月龄时断奶可最大限度地获得BV抗体阴性猴。     

SARS-CoV中和抗体保护恒河猴等感染SARS-CoV研究

[目的]阐明SARS病毒感染后能否再次感染,疫苗产生的抗体中长期保护效果,被动免疫是否真正安全有效等,为防治SARS提供实验依据。[方法]实验分4组,分别为一组(SARS恒河猴恢复组):用感染SARS-CoV发病12月后的4只恒河猴,均有中和抗体产生。二组(SARS食蟹猴恢复组):用感染SARS-CoV发病12月后的3只食蟹猴,均有中和抗体产生。三组(SARS血清输入恒河猴组):3只恒河猴,病毒接种时中和抗体阴性。病毒接种两天后输入抗体阳性血清(恒河猴血清,感染获得,效价为:1:128),用量10ml/只,分别经肌肉和静脉输入,各5ml。四组(恒河猴SARS-CoV感染组):2只恒河猴,病毒接种时中和抗体阴性。SARSCo-V经鼻腔接种,在感染的第1天开始到7天安乐死时,不同时间取咽拭子、血液和脏器,进行病毒分离,RT-PCR检测和中和抗体测定。[结果]一组(SARS恒河猴恢复组):接种SARS-CoV后未见发热等异常临床表现。血清生化无ALT、LDH、CK、总蛋白和血清白蛋白异常。3只猴在接种病毒后的咽拭子中,RT-PCR分别未检出、第1天检出、第1-3天中检出病毒。第2、5、7天咽拭子中、7天安乐死时血、肺、肝、脾和淋巴结等组织中病毒分离均为阴性。2只猴肺组织病理学检查见轻度肺炎。二组(SARS食蟹猴恢复组):接种3只未见任何不良临床表现,血清生化5项正常。3只猴在接种病毒后的咽拭子标本中,RT-PCR分别未检出SARS病毒、在第1-2天检出、在第1-3天中检出病毒。第2、5、7天咽拭子中、7天安乐死时血、肺、肝、脾和淋巴结等组织中病毒分离均为阴性。3只猴肺组织病理学检查见轻度肺炎等。三组(SARS血清输入恒河猴组):3只恒河猴在病毒接种的第2-5天时有一过性的体温升高,3940℃。血清生化5项正常。3只猴在接种病毒后的咽拭子标本中,RT-PCR分别在第1-3、第1-4天和第1-2天检出SARS病毒。2只猴第7天咽拭子中病毒分离阳性。另外1只在第2、5、7天咽拭子中、7天安乐死时血、肺、肝、脾和淋巴结等组织中病毒分离均为阴性。3只猴肺组织病理学检查见轻度肺炎等。四组(SARS恒河猴SARS-CoV感染组):2只猴病毒接种后,第2-4天时有一过性的体温升高,3940℃。2只进行接种病毒后1-7天安乐死时,RT-PCR在恒河猴的咽拭子标本中连续检出SARS病毒。在第2、5天咽拭子中、7天安乐死时肺组织中病毒分离阳性。2只猴肺等组织病理学检查发现肺组织表面局部有轻度发灰实变现象,可见到间质性肺炎病变,内皮细胞受损,出血和水肿。大多数肺泡没有完整的内衬细胞残留,肺泡间隔变宽并被以吞噬细胞为主的单核炎症细胞浸润,同SARS肺炎改变。实验表明,前期感染产生中和抗体的恒河猴、食蟹猴再次感染病毒,和模型对照猴比较,动物肺组织等只出现轻微或无病理变化,RT-PCR检出时间大大缩短,病毒培养未能分离出病毒,所有这些指标,均证实中和抗体有明显的保护作用,是有效的。被动免疫从结果来看,有一定的作用,但保护作用弱。     

Experimental infection of rhesus and pig-tailed macaques with macaque rhadinoviruses

The recognition of naturally occurring rhadinoviruses in macaque monkeys has spurred interest in their use as models for human infection with Kaposi sarcoma-associated herpesvirus (human herpesvirus 8). Rhesus macaques (Macaca mulatta) and pig-tailed macaques (Macaca nemestrina) were inoculated intravenously with rhadinovirus isolates derived from these species (rhesus rhadinovirus [RRV] and pig-tailed rhadinovirus [PRV]). Nine rhadinovirus antibody-negative and two rhadinovirus antibody-positive monkeys were used for these experimental inoculations. Antibody-negative animals clearly became infected following virus inoculation since they developed persisting antibody responses to virus and virus was isolated from peripheral blood on repeated occasions following inoculation. Viral sequences were also detected by PCR in lymph node, oral mucosa, skin, and peripheral blood mononuclear cells following inoculation. Experimentally infected animals developed peripheral lymphadenopathy which resolved by 12 weeks following inoculation, and these animals have subsequently remained free of disease. No increased pathogenicity was apparent from cross-species infection, i.e., inoculation of rhesus macaques with PRV or of pig-tailed macaques with RRV, whether the animals were antibody positive or negative at the time of virus inoculation. Coinoculation of additional rhesus monkeys with simian immunodeficiency virus (SIV) isolate SIVmac251 and macaque-derived rhadinovirus resulted in an attenuated antibody response to both agents and shorter mean survival compared to SIVmac251-inoculated controls (155.5 days versus 560.1 days; P < 0.019). Coinfected and immunodeficient macaques died of a variety of opportunistic infections characteristic of simian AIDS. PCR analysis of sorted peripheral blood mononuclear cells indicated a preferential tropism of RRV for CD20(+) B lymphocytes. Our results demonstrate persistent infection of macaque monkeys with RRV and PRV following experimental inoculation, but no specific disease was readily apparent from these infections even in the context of concurrent SIV infection.     

SHIV-KB9感染中国恒河猴动物模型的建立

目的为了进一步确证SHIV-KB9感染中国恒河猴的病毒浓度范围,测试动物对病毒的适应性,明确该动物模型的可重复性。方法实验前采集猴血清并进行血清学检查。选出4只无SIV、STLV、SRV/D和B病毒感染的恒河猴,分别用10倍系列稀释的病毒液静脉感染实验猴,使用流氏细胞术、血常规、病毒分离、DNA-PCR和RT-PCR等方法确定实验猴是否被感染,以及感染后恒河猴体内病毒复制和免疫细胞损伤情况。结果实验猴的血浆病毒载量、病毒分离结果、CD4＋/CD8＋比值和CD4＋T细胞数等证实,4.8×105 copies/mL以上浓度的SHIV-KB9病毒液能成功感染中国恒河猴。结论本研究进一步明确了SHIV-KB9感染中国恒河猴的有效病毒浓度范围,确定了SHIV-KB9病毒感染中国恒河猴的病毒学、免疫学的测定指标,成功的建立了SHIV-KB9/中国恒河猴动物模型。     

Correlation of kidney weight and volume and selected skeletal parameters to sex in the adult rhesus monkey (Macaca mulatta)

This report outlines a comparison of renal weight and volume and selected skeletal parameters to sex in 22 adult male and 156 adult female rhesus macaques. Means and standard deviations for kidney weight and volume, body weight, and radiographic measurements for both males and females are reported. Ninety-five percent confidence intervals and P-values for the mean differences between the sexes for these parameters were also compiled. Male monkeys were larger, but had kidneys of similar size to those of the females. Joint distributions of the radiographic measurements of the first lumbar vertebra and the skull showed that males were larger in both measurements. The distributions of these parameters were clearly separate in males and females, while joint distributions of kidney weight and volume for males and females overlapped almost completely. We found that, regardless of age, sex, weight, or skeletal size, all normal adult rhesus monkeys generally have similar-sized kidneys.     

RT-SHIV感染中国恒河猴及体内传代

目的了解RT-SHIV感染中国恒河猴的感染特点,研究RT-SHIV在中国恒河猴中传代特点;建立RT-SHIV中国恒河猴动物模型,为评价HIV-1药物有效性提供动物平台。方法选择4只健康恒河猴,其中两只动物经上肢静脉感染RT-SHIV病毒,感染急性期采取外周血分离CD8-PBMC,扩增病毒,将新制备的病毒静脉感染另外两只中国恒河猴,通过监测血浆病毒载量,CD4＋/CD8＋比值,CD4＋T淋巴细胞和B淋巴细胞的绝对数,了解实验猴的感染状态,同时分析病毒RT基因变异情况。结果 4只动物均获得系统性感染,且传代动物急性期表现更为强烈,RT基因在感染和传代的过程中共观察到3个氨基酸的改变。结论本研究为RT-SHIV中国恒河猴模型的建立提供了基础信息。     

人工饲养恒河猴麻醉与非麻醉状态下血液学、血液生化、血流变指标的测定与比较

目的测定人工饲养条件下48只健康恒河猴在非麻醉状态下及30只健康恒河猴在麻醉状态下的血液生化、血液常规、血液流变学指标,并分析两种状态下恒河猴血液生化、血液常规、血液流变值的差异及相互关系.方法应用全自动血液细胞分析仪和全自动血液生化分析仪,自动清洗旋转型粘度计测定及分析麻醉和非麻醉状态下健康恒河猴血液生化、血液常规、血液流变值.结果血液生化值麻醉组比非麻醉组明显低(P<0.01)的项目有GGT、AST、CREAT、TBIL、DBIL、P3+、TF;较明显低(P<0.05)的项目有ALT、ALP、LDH、HBDH;明显高(P<0.01)的项目有UA、Ca2+、CK-MB、ALB,较明显高(P<0.05)的项目有TPROT.血常规值麻醉组比非麻醉组明显低(P<0.01)的项目有RBC、Hct、MCV、MPV、RDW、NEUTRO,明显高(P<0.01)的项目有MCH、MCHC、PLT、LYM、MEDIAN.血液流变值麻醉组比非麻醉组明显低(P<0.01)的项目有全血低切粘度,全血中切粘度,全血高切粘度,血浆粘度,红细胞压积,还原低切,血沉K值,聚集指数;明显高(P<0.01)的项目有变形指数,电泳指数.结论本文测定并比较了人工饲养条件下健康恒河猴在麻醉和非麻醉状态下血液生化、血液常规、血液流变值,讨论分析了两组数值之间的差异和原因,了解应激反应和麻醉剂对动物生理方面的影响.     

Sexual behaviour and paternity in three captive groups of rhesus monkeys (Macaca mulatta)

Each offspring born into three captive groups of rhesus monkeys (Macaca mulatta) during the spring of 1981 was assigned (1) a most probable behavioural father and (2) a subset of all possible behavioural fathers, on the basis of intensive observations of sexual activity during the 1980 fall breeding season. These predictions were then compared with true paternity determined by electrophoretic and serological analyses of polymorphic blood proteins of mothers, infants, and all adult and subadult males. Coincidence between the assignments of paternity based upon behavioural and biochemical data occurred no more frequently than chance would allow. Furthermore, there were no significant relationships between biochemical and behavioural rankings of overall reproductive success. It was concluded that conventional estimates of sexual activity during the breeding season are not a reliable indicator of true paternity and relative reproductive success in rhesus macaques.     

Life history variables of wild troops of formosan macaques (Macaca cyclopis) in Kenting,Taiwan

A study on population dynamics of wild Formosan macaques (Macaca cyclopis) in Kenting, southern Taiwan, was conducted from March 1985 to August 1990. At first, only one monkey troop was studied. It fissioned in 1987 and both of the daughter troops have been observed since then. Total number of animals increased from 10 to 29 over the years, but the sizes of individual troops have never been more than 20. Seasonality in breeding has been detected: copulations were concentrated in the period from November to January and 75% of all the 28 births occurred between April and June. Time of birth by parous females without offspring from the preceding year was earlier than that of lactating females. Young females gave their first births at 4 or 5 years of age. Total birth rate over the study period was 0.8 infant per female per year. Hunting was the main cause of death while natural mortality rate was low for the animals. There was only one adult male in each troop for most of the time. Troop males in the two daughter troops have been replaced two or three times in the three years by some solitary males that moved around in the area. The reproductive parameters of Formosan macaques in Kenting were found to be more similar to that of rhesus monkeys than to Japanese macaques. And a case of higher reproductive success in a high-ranking matriline was reported.     

Detection of a unique genotype of monkey B virus (Cercopithecine herpesvirus 1) indigenous to native Japanese macaques (Macaca fuscata)

The Japanese macaque or snow monkey (Macaca fuscata) is an autochthonous monkey in Japan. It has long been assumed that the monkey population was not infected with Cercopithecine herpesvirus 1 (monkey B virus [BV]) since cases of human BV infection have never been reported in Japan. Although serologic testing of captive snow monkeys in Japan revealed antibodies to BV, it was thought that native Japanese macaques had either been infected with herpes simplex virus from humans or with BV from other imported macaque species. To clarify this issue, we performed polymerase chain reaction (PCR) analysis to amplify BV sequences from trigeminal ganglia of 30 Japanese macaque monkeys that were seropositive for BV. Sequences from two BV genes, UL27 (360 bp) and UL19 (1.0 Kbp), from 3 of 30 monkeys were amplified. Results of restriction fragment length polymorphism analysis and DNA sequencing of the fragments provided evidence that native Japanese macaques are infected with BV. Phylogenetic analysis indicated that these monkeys harbor their own genotype of BV that is different from other known BV genotypes, and provided additional evidence supporting the co-evolution of BV and macaques.     

Molecular clones of SIVsm and SIVagm: experimental infection of macaques and African green monkeys

We have investigated the ability of biologically-active proviral molecular clones of SIVsm and SIVagm to infect rhesus macaques, pig-tail macaques, and African green monkeys. Two clones of SIVsm were individually inoculated into four rhesus and four pig-tail macaques. All eight macaques became infected, and two have experienced a significant decline in absolute numbers of circulating CD4+ cells. None of three African green monkeys were infected by an SIVsm molecular clone. However, one of four African green monkeys did become infected by SIVsm after receiving lymphocytes directly from an SIVsm-infected rhesus macaque. A molecular clone of SIVagm infected three of four macaques and three of three African green monkeys. None of the three infected macaques had a significant decline in circulating CD4+ cells. Interestingly, infection of pig-tail macaques (but not rhesus macaques) with uncloned SIVagm induced a significant drop in circulating CD4+ cells. These data suggest that molecular clones of SIVsm and SIVagm can be used in experimental models of AIDS for the evaluation of viral gene functions and for the study of in vivo genetic variation.