SHIV1157ipd3N4细胞适应株的制备及其生物特性

目的体外制备SHIV1157ipd3N4病毒中国恒河猴细胞适应株,在细胞水平和中国恒河猴体内评价其生物学特性。方法用SHIV1157ipd3N4病毒阴道感染中国恒河猴,在血浆病毒载量高峰期采血分离外周血单核淋巴细胞（PBMCs）,与正常中国恒河猴PBMCs共培养。定期测定培养液中的P24抗原水平。当病毒复制达高峰期时收集培养上清,分装并冻存。测定病毒RNA载量、P24抗原浓度和TCID50。静脉感染中国恒河猴,研究该批次SHIV1157ipd3N4在体内的病毒学、免疫学指标变化及变异情况,分析其基本的生物学特性。结果本研究共制备了243 mL SHIV1157ipd3N4病毒原液,gp120序列分析表明病毒未发生变异,CCR5的嗜性也未发生改变。病毒载量为1.586×108 copies/mL,P24抗原水平为1.16×103 pg/mL,TZM-bl细胞测定病毒的TCID50为3.16×103/mL。1 mL SHIV1157ipd3N4静脉成功感染中国恒河猴G1004V,高峰期病毒载量达到1.0×106 copies/mL以上。结论此次制备的SHIV1157ipd3N4细胞适应株生物学特性稳定,适合作为毒种库构建SHIV1157ipd3N4/中国恒河猴模型。     

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。     

CXCR4嗜性SHIVKU-1病毒静脉感染中国恒河猴初步研究

目的了解SHIVKU一1静脉途径感染中国恒河猴的感染特点及进展规律。方法两只健康中国恒河猴,静脉感染SHIVKU-1病毒,定期采样检测血浆病毒载量、CD4＋／CD8＋比值、CD4＋T细胞绝对数变化和血清中抗SHIVKU-1特异性IgG抗体水平。多色流式技术分析外周血、腹股沟淋巴结和十二指肠粘膜固有层CD4＋T淋巴细胞记忆细胞亚群变化。结果两只实验猴成功感染SHIVKU-1病毒,一直到感染后3个月均保持稳定水平的病毒载量。外周血CD4＋T淋巴细胞下降明显,CD4＋／CD8＋T细胞比值严重倒置。CD4＋Tcm细胞比例在经历了感染早期的下降后,大幅升高,尤其是外周血和淋巴结。CD4＋Tem则在粘膜固有层中增加明显。结论SHIVKU．1静脉途径成功感染了中国恒河猴,为SHIV／中国恒河猴疾病及评价模型的建立奠定了良好的基础,为今后使用此模型评价抗病毒药物或疫苗提供了条件。     

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。     

C亚型SHIVCHN19P4强毒株在中国恒河猴体内的传代研究

目的研究C亚型SHIVCHN19P4强毒株在中国恒河猴体内传代中病毒学和免疫学等反应的变化特点,分离制备SHIVCHN19P4中国恒河猴传代适应株病毒。方法选择4只健康成年恒河猴,其中两只经后肢静脉感染SHIVCHN19P4病毒,60 d后,分别采集EDTA抗凝全血静脉途径传代至另两只猴,使用流式细胞术、PCR、结合抗体检测和序列分析等方法研究传代动物病毒学、免疫学和序列变异特点。选择性从传代动物感染急性期外周血中分离PBMC,CD8＋T细胞敲除后与正常PBMC共培养分离病毒。结果 4只传代动物均获得系统性感染,且传代后病毒毒力明显增强,序列分析发现SHIVCHN19P4病毒序列在传代过程中发生适应性改变;同时,成功分离制备SHIVCHN19P4传代适应性病毒株。结论 SHIVCHN19P4在中国恒河猴体内适应性传代研究为进一步建立C亚型SHIV强毒株/SAIDS模型奠定了良好的实验基础,为研究C亚型HIV-1流行株致病特点以及预防性黏膜疫苗和杀微生物的有效性评价提供了数据支持。     

ELISPOT方法检测SIVmac239感染猴特异性细胞免疫水平

目的为了完善现有的SIV／恒河猴模型,掌握恒河猴被SIV感染后体内细胞免疫应答状态,为评价HIV疫苗提供方法和数据上的参考,我们测定了SIV感染猴体内病毒特异性的细胞免疫水平。方法实验前选出4只无SIV、sTLV、SRV／D和B病毒感染的恒河猴,用SIVmac239病毒液静脉感染实验猴,使用RT-PCR、流氏细胞术和ELISPOT等方法,监测SIVmac239病毒在恒河猴体内复制情况、感染猴的外周免疫损伤情况和细胞免疫情况,持续测定一年。结果实验结果显示IFN-γ ELISPOT方法能有效的评估实验猴的细胞免疫情况,IFN—YELISPOT结果和CD4＋T细胞数无相关性,与血浆病毒载量稍有相关。结论本实验明确了SIVmac239感染中国恒河猴体内CTL的基本趋势和范围,了解了外周血病毒载量、外周免疫损伤与细胞免疫状况之间的联系,完善了SIV／SAIDS模型评价指标,为使用此模型评价抗病毒药物或疫苗提供了基础条件。     

B亚型SHIV_（SF162p3）中国恒河猴小剂量多次阴道黏膜感染

目的模拟HIV性传播感染特点进行中国恒河猴阴道黏膜小剂量多次感染研究,为我国艾滋病疫苗有效性评价提供新的模型构建思路。方法选用20-30TCID50剂量的SHIVSF162p3病毒阴道黏膜途径感染六只成年雌性中国恒河猴,共感染13次,每次攻毒间隔4～7 d。采取测定血浆病毒载量和外周血CD4＋∶CD8＋。结果 6只中国恒河猴经13次病毒攻击后,经检测均建立系统性感染,血浆病毒载量呈阳性;CD4＋∶CD8＋均有下降。结论成功建立了中国恒河猴阴道黏膜小剂量多次感染模型,为艾滋病研究提供了新的更接近于自然感染状态的模型建立模式。     

SHIV病毒在猴体内的复制与传代

目的为建立SHIV艾滋病动物模型提供毒力较强的病毒株,将新合成的SHIV XJ02170病毒适应猴体,并增强其毒力。方法实验前采集猴血清并进行血清学检查和PCR检测。选出13只无SIV,STLV1,SRV D和B病毒感染的猴。第一批实验,将SHIV前病毒DNA质粒经肌肉注射到猴体内,每只500μg;SHIV病毒液,经静脉注射到猴体内,每只2ml。病毒质粒和病毒液各接种2只猴。当第一批猴体检出病毒后,10ml感染猴的全血,抗凝后静脉注射到第二批猴体内,当第二批猴检出病毒后再将10ml感染猴的全血静脉注射到第三批猴体内,连续传代4次。每批实验均定期采集血液标本,分别用肝素和EDTA抗凝,进行病毒分离;病毒基因PCR检测;CD4,CD8测定;病毒抗体检测。结果SHIV XJ02170病毒和SHIV XJ02170前病毒DNA质粒在猴体内的传代中均能分离出病毒;从传代猴的血浆和外周血单核细胞(PBMC)中检出了病毒DNA和RNA基因;CD4,CD8测定结果显示有暂时性倒置现象,后变为正常倒置与正常交替出现;在传代的猴血清中检测出特异性HIV病毒抗体。结论SHIV XJ02170病毒与SHIV XJ02170前病毒DNA质粒,均能在恒河猴体内复制。     

体内CD8^＋T细胞剔除对无症状期SHIV感染猴的影响

目的 CD8＋T细胞在一些病毒感染疾病的免疫反应中起着重要的作用,但CD8＋T细胞在HIV无症状期的作用尚不明确,本研究通过体内CD8＋T细胞剔除,研究CD8＋T细胞对SHIV感染猴的影响,进一步了解艾滋病的发病机制。方法选择8只SHIV病毒感染的恒河猴,均处于无症状期,随机分成两组,实验组4只恒河猴在0、3、7 d注射抗CD8＋T抗体cM-T807,不同的时间取外周血、腹股沟淋巴结。流式细胞术测定恒河猴外周血和淋巴结中CD8＋T细胞数目,Real-time RT-PCR法测定实验猴血浆病毒载量,并使用IFN-γElispot方法测定其对猴细胞免疫的影响。结果 CD8＋T细胞敲除后,4只猴的病毒载量都转阳,但反应性不一,HIV-1的靶细胞CD4＋T细胞有轻微下降,后反弹,与病毒载量无相关性;CD8敲除猴的感染情况（血浆病毒载量和CD4细胞）比SHIV病毒急性感染轻,这与ELIPOT结果一致。结论 CD8＋T细胞在HIV无症状期发挥重要的作用,但其作用具有个体差别。     

恒河猴二次接种H5N1亚型禽流感病毒

对恒河猴进行二次接种H5N1亚型禽流感病毒试验,并对二次接毒的结果进行观察,评估初次接毒对恒河猴二次接毒效果的影响.首次接种试验中,3、4、5号恒河猴用环甲膜穿刺注射方法接种含有H5N1亚型禽流感病毒的尿囊液,6号猴接种不含病毒的尿囊液.90d后,再次用环甲膜穿刺注射方法二次接种,4、5、6号猴接种7mlTCID50浓度为104.875病毒的尿囊液,3号猴接种7ml不含病毒的尿囊液.进行抗体等检测,并分别于72h无痛处死3、4、6号猴,第7d无痛处死5号猴,进行肺的病毒检测及病理观察.结果显示,3、4、5号猴至试验结束时体内依然有较高的抗H5N1亚型禽流感病毒抗体水平,6号猴没有抗体;通过RT-PCR以及免疫组化染色进行病毒检测,均只在6号猴肺部检出病毒,且6号猴肺部病理损伤最为严重.由此可以得出初步结论:在初次感染H5N1亚型禽流感病毒后90d,临床症状已基本恢复正常的恒河猴体内仍然有较高水平的抗体,此时,恒河猴抵抗H5N1亚型禽流感病毒二次感染的能力显著提高.     

Dynamics of envelope evolution in clade C SHIV-infected pig-tailed macaques during disease progression analyzed by ultra-deep pyrosequencing

Understanding the evolution of the human immunodeficiency virus type 1 (HIV-1) envelope during disease progression can provide tremendous insights for vaccine development, and simian-human immunodeficiency virus (SHIV) infection of non-human primate provides an ideal platform for such studies. A newly developed clade C SHIV, SHIV-1157ipd3N4, which was able to infect rhesus macaques, closely resembled primary HIV-1 in transmission and pathogenesis, was used to infect several pig-tailed macaques. One of the infected animals subsequently progressed to AIDS, whereas one remained a non-progressor. The viral envelope evolution in the infected animals during disease progression was analyzed by a bioinformatics approach using ultra-deep pyrosequencing. Our results showed substantial envelope variations emerging in the progressor animal after the onset of AIDS. These envelope variations impacted the length of the variable loops and charges of different envelope regions. Additionally, multiple mutations were located at the CD4 and CCR5 binding sites, potentially affecting receptor binding affinity, viral fitness and they might be selected at late stages of disease. More importantly, these envelope mutations are not random since they had repeatedly been observed in a rhesus macaque and a human infant infected by either SHIV or HIV-1, respectively, carrying the parental envelope of the infectious molecular clone SHIV-1157ipd3N4. Moreover, similar mutations were also observed from other studies on different clades of envelopes regardless of the host species. These recurring mutations in different envelopes suggest that there may be a common evolutionary pattern and selection pathway for the HIV-1 envelope during disease progression.     

Molecularly cloned SHIV-1157ipd3N4: a highly replication- competent, mucosally transmissible R5 simian-human immunodeficiency virus encoding HIV clade C Env

Human immunodeficiency virus type 1 (HIV-1) clade C causes >50% of all HIV infections worldwide, and an estimated 90% of all transmissions occur mucosally with R5 strains. A pathogenic R5 simian-human immunodeficiency virus (SHIV) encoding HIV clade C env is highly desirable to evaluate candidate AIDS vaccines in nonhuman primates. To this end, we generated SHIV-1157i, a molecular clone from a Zambian infant isolate that carries HIV clade C env. SHIV-1157i was adapted by serial passage in five monkeys, three of which developed peripheral CD4(+) T-cell depletion. After the first inoculated monkey developed AIDS at week 137 postinoculation, transfer of its infected blood to a na?ve animal induced memory T-cell depletion and thrombocytopenia within 3 months in the recipient. In parallel, genomic DNA from the blood donor was amplified to generate the late proviral clone SHIV-1157ipd3. To increase the replicative capacity of SHIV-1157ipd3, an extra NF-kappaB binding site was engineered into its 3' long terminal repeat, giving rise to SHIV-1157ipd3N4. This virus was exclusively R5 tropic and replicated more potently in rhesus peripheral blood mononuclear cells than SHIV-1157ipd3 in the presence of tumor necrosis factor alpha. Rhesus macaques of Indian and Chinese origin were next inoculated intrarectally with SHIV-1157ipd3N4; this virus replicated vigorously in both sets of monkeys. We conclude that SHIV-1157ipd3N4 is a highly replication-competent, mucosally transmissible R5 SHIV that represents a valuable tool to test candidate AIDS vaccines targeting HIV-1 clade C Env.     

TLR7 agonist,N6-LS and PGT121 delayed viral rebound in SHIV-infected macaques after antiretroviral therapy interruption

Toll-like receptor 7 (TLR7) agonist and PGT121 (broadly neutralizing antibody, bnAb) administration previously delayed viral rebound and induced SHIV remission. We evaluated the impact of GS-986 (TLR7 agonist) and dual bnAbs on viral rebound after antiretroviral therapy (ART) interruption. Rhesus macaques inoculated with SHIV-1157ipd3N4 were initiated on daily suppressive ART from Day 14 post SHIV inoculation. Active arm animals (n = 8) received GS-986, N6-LS and PGT121 after plasma viral suppression, starting from week 14. GS-986 induced immune activation and SHIV-specific T cell responses but not viral expression in all the active arm animals. After ART interruption, median time to viral rebound was 6 weeks in the active and 3 weeks in the control arm (p = 0.024). In this animal model, the administration of the combination of GS-986 and dual bnAbs was associated with a modest delay in viral rebound. This strategy should be further evaluated to better understand the underlying mechanisms for the induction of virus-specific immune responses and delay in viral rebound.     

SHIV-1157i及衍生病毒的研究进展

C亚型是世界上流行的HIV-1主要亚型,带有HIV-1 C亚型env区的SHIV和相应的非人灵长类模型是研究人类艾滋病的有效工具。SHIV-1157i及其衍生病毒能够成功地通过黏膜途径感染恒河猴和猪尾猴,并诱发艾滋病类似症状,而且恒河猴缓慢的发病进程与人类感染HIV-1相似。因此,掌握SHIV-1157i及其衍生病毒感染恒河猴的发病规律并探索其机制,将对研究人类HIV-1感染和发病机制,以及评价HIV-1 C亚型env区为靶点的艾滋病候选疫苗具有重要意义。