PCR技术在猴免疫缺陷病毒(SIV)感染模型中的应用

目的(1)建立RT PCR方法,定性测定SIV感染猴血浆中病毒RNA,比较其与传统血浆病毒分离方法的敏感性;(2)建立DNA PCR方法,检测SIV感染猴外周血淋巴细胞(PBMCs)中的前病毒DNA。(3)检验DNA PCR和RNA PCR方法在猴SAIDS模型应用中的实用性和可操作性。方法用SIVmac251静脉感染恒河猴,定期采血,从血浆中提取病毒RNA,以RNA为模板通过RT PCR法扩增,凝胶电泳定性;从感染猴PBMC中提取带有整合的SIV前病毒DNA的细胞基因组DNA,巢式PCR扩增,凝胶电泳定性。结果DNA PCR和RNA PCR经两轮扩增后均得到一长度为477bp的特异条带,测序鉴定确为目的片段。9只实验猴感染SIV后7d,RNA PCR结果为79阳性,DNA PCR结果为100%阳性,而血浆病毒分离只有59阳性;此后一直到感染后的42d,RNA PCR和DNA PCR的结果一直为100%阳性,而血浆病毒分离阳性率在感染后35d下降到49,到42d时下降为零。结论PCR方法比病毒分离方法的敏感性高。尤其是DNA PCR,既可检测具有活跃病毒复制的受感染细胞,又可检测那些携带病毒处于转录休眠期的细胞,所以在感染的早期和中后期———血浆病毒水平较低的情况下或病毒处于潜伏感染的阶段,它作为猴艾滋病(SAIDS)模型病毒学指标之一有其必要性和重要性。这个指标的检测方法应该是较血浆病毒RNA检测更为敏感。     

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.     

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。     

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。     

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。     

RT-SHIV中国恒河猴适应株细胞水平生物学特性分析

目的体外增值、制备动物感染来源的RT-SHIV病毒中国恒河猴适应株,比较PBMCs和CEMx174两种细胞制备出病毒的差异,同时用TZM-bl、CEMx174、PBMC三种细胞滴定测定病毒TCID50。方法用RT-SHIV病毒静脉感染中国恒河猴,定期采血测定血浆病毒载量,当病毒载量达高峰时采血分离外周血单核淋巴细胞（PBMCs）,与正常恒河猴PBMCs或CEMx174细胞共培养,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,滴定病毒的TCID50。结果本研究共制备了78 mL PBMCs来源的RT-SHIV病毒和85 mL CEMx174细胞来源的RT-SHIV病毒。RT基因序列和原始序列的相似度为99%,仅在第254和265位的氨基酸发现突变。RT-SHIV（PBMC）和RT-SHIV（CEMx174）病毒载量分别为1.641×108 copies/mL和8.375×108 copies/mL,P24抗原水平分别为20.745 ng/mL和4.28 ng/mL,TZM-bl、CEMx174、PBMC细胞测定病毒的TCID50分别为3.16×105 TCID50/mL和1×104 TCID50/mL,5×102 TCID50/mL和5×105 TCID50/mL,5×102 TCID50/mL和5×103 TCID50/mL。结论 PBMCs细胞来源制备的病毒较CEMx174制备的病毒具有更高的感染性。     

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。     

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。     

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。     

中国HIV阳性参比品库的建立以及HIV不同生物标志物的意义

为建立HIV阳性样品库并分析HIV不同生物标志物的意义,从我国不同地区以及不同人群中收集HIV感染者或可疑感染者血浆,对其进行HIV抗体、抗原、核酸以及基因型的检测,并用WB试剂对其进行抗体的确认检测。结果显示,该样品库共有样品190份,均为HIV阳性,含有我国流行的主要基因型,即B′、BC、AE和B亚型;HIV抗体S/CO值小于10者占11.1%,在10~15之间者占63.2%,大于15的占25.8%;病毒载量在50~103copies/mL者占7.9%,在103~105copies/mL者占82.2%,大于105copies/mL者占10.0%。而且抗体S/CO值大于10者,均为HIV抗体确认阳性,小于10者仅有61.9%为抗体确认阳性,但核酸均大于50copies/mL,而且抗体不确定样品的病毒载量均大于105copies/mL,但抗体不确定的8份样品中仅有4份样品为P24抗原阳性。结果提示该样品库样品来自于HIV感染的不同时期,可用于对HIV的不同试剂进行评价;而且核酸的检测可有助于对HIV早期感染的明确诊断。     

High viral load in the cerebrospinal fluid and brain correlates with severity of simian immunodeficiency virus encephalitis

AIDS dementia and encephalitis are complications of AIDS occurring most frequently in patients who are immunosuppressed. The simian immunodeficiency virus (SIV) model used in this study was designed to reproducibly induce AIDS in macaques in order to examine the effects of a neurovirulent virus in this context. Pigtailed macaques (Macaca nemestrina) were coinoculated with an immunosuppressive virus (SIV/DeltaB670) and a neurovirulent molecularly cloned virus (SIV/17E-Fr), and more than 90% of the animals developed moderate to severe encephalitis within 6 months of inoculation. Viral load in plasma and cerebrospinal fluid (CSF) was examined longitudinally to onset of AIDS, and viral load was measured in brain tissue at necropsy to examine the relationship of systemic and central nervous system (CNS) viral replication to the development of encephalitis. In all animals, plasma viral load peaked at 10 to 14 days postinfection and remained high throughout infection with no correlation found between plasma viremia and SIV encephalitis. In contrast, persistent high levels of CSF viral RNA after the acute phase of infection correlated with the development of encephalitis. Although high levels of viral RNA were found in the CSF of all macaques (six of six) during the acute phase, this high level was maintained only in macaques developing SIV encephalitis (five of six). Furthermore, the level of both viral RNA and antigen in the brain correlated with the severity of the CNS lesions. The single animal in this group that did not have CNS lesions had no detectable viral RNA in any of the regions of the brain. The results substantiate the use of CSF viral load measurements in the postacute phase of SIV infection as a marker for encephalitis and CNS viral replication.     

Viral RNA Levels and env Variants in Semen and Tissues of Mature Male Rhesus Macaques Infected with SIV by Penile Inoculation

HIV is shed in semen but the anatomic site of virus entry into the genital secretions is unknown. We determined viral RNA (vRNA) levels and the envelope gene sequence in the SIVmac 251 viral populations in the genital tract and semen of 5 adult male rhesus monkeys (Macaca mulatta) that were infected after experimental penile SIV infection. Paired blood and semen samples were collected from 1–9 weeks after infection and the monkeys were necropsied eleven weeks after infection. The axillary lymph nodes, testes, epididymis, prostate, and seminal vesicles were collected and vRNA levels and single-genome analysis of the SIVmac251 env variants was performed. At the time of semen collection, blood vRNA levels were between 3.09 and 7.85 log10 vRNA copies/ml plasma. SIV RNA was found in the axillary lymph nodes of all five monkeys and in 3 of 5 monkeys, all tissues examined were vRNA positive. In these 3 monkeys, vRNA levels (log10 SIVgag copies/ug of total tissue RNA) in the axillary lymph node (6.48±0.50) were significantly higher than in the genital tract tissues: testis (3.67±2.16; p<0.05), epididymis (3.08±1.19; p<0.0001), prostate (3.36±1.30; p<0.01), and seminal vesicle (2.67±1.50; p<0.0001). Comparison of the SIVmac251 env viral populations in blood plasma, systemic lymph node, and genital tract tissues was performed in two of the macaques. Visual inspection of the Neighbor-Joining phylograms revealed that in both animals, all the sequences were generally distributed evenly among all tissue compartments. Importantly, viral populations in the genital tissues were not distinct from those in the systemic tissues. Our findings demonstrate striking similarity in the viral populations in the blood and male genital tract tissues within 3 months of penile SIV transmission.     

Temporal Analyses of Virus Replication, Immune Responses, and Efficacy in Rhesus Macaques Immunized with a Live, Attenuated Simian Immunodeficiency Virus Vaccine

Despite evidence that live, attenuated simian immunodeficiency virus (SIV) vaccines can elicit potent protection against pathogenic SIV infection, detailed information on the replication kinetics of attenuated SIV in vivo is lacking. In this study, we measured SIV RNA in the plasma of 16 adult rhesus macaques immunized with a live, attenuated strain of SIV (SIVmac239Δnef). To evaluate the relationship between replication of the vaccine virus and the onset of protection, four animals per group were challenged with pathogenic SIVmac251 at either 5, 10, 15, or 25 weeks after immunization. SIVmac239Δnef replicated efficiently in the immunized macaques in the first few weeks after inoculation. SIV RNA was detected in the plasma of all animals by day 7 after inoculation, and peak levels of viremia (10⁵ to 10⁷ RNA copies/ml) occurred by 7 to 12 days. Following challenge, SIVmac251 was detected in all of the four animals challenged at 5 weeks, in two of four challenged at 10 weeks, in none of four challenged at 15 weeks, and one of four challenged at 25 weeks. One animal immunized with SIVmac239Δnef and challenged at 10 weeks had evidence of disease progression in the absence of detectable SIVmac251. Although complete protection was not achieved at 5 weeks, a transient reduction in viremia (approximately 100-fold) occurred in the immunized macaques early after challenge compared to the nonimmunized controls. Two weeks after challenge, SIV RNA was also reduced in the lymph nodes of all immunized macaques compared with control animals. Taken together, these results indicate that host responses capable of reducing the viral load in plasma and lymph nodes were induced as early as 5 weeks after immunization with SIVmac239Δnef, while more potent protection developed between 10 and 15 weeks. In further experiments, we found that resistance to SIVmac251 infection did not correlate with the presence of antibodies to SIV gp130 and p27 antigens and was achieved in the absence of significant neutralizing activity against the primary SIVmac251 challenge stock.     

TGF-beta in intestinal lymphoid organs contributes to the death of armed effector CD8 T cells and is associated with the absence of virus containment in rhesus macaques infected with the simian immunodeficiency virus

SIV-infected macaques exhibit distinct rates of progression to AIDS and despite significant increases in CD8+ T cells, immune cells fail to control and eradicate SIV in vivo. Here, we investigated the interplay between viral reservoir sites, CD8+ T-cell activation/death and outcome. Our data provide strong evidence that mesenteric (Mes) lymph nodes represent major reservoirs not only for SIV-infected macaques progressing more rapidly toward AIDS but also in controllers. We demonstrate that macaques progressing faster display greater expression of TGF-beta and Indoleamine 2,3 dioxygenase in particular in intestinal tissues associated with a phosphorylation of the p53 protein on serine 15 in CD8+ T cells from Mes lymph nodes. These factors may act as a negative regulator of CD8+ T-cell function by inducing a Bax/Bak/Puma-dependent death pathway of effector/memory CD8+ T cells. Greater T-cell death and viral dissemination was associated with a low level of TIA-1+ expressing cells. Finally, we provide evidence that abrogation of TGF-beta in vitro enhances T-cell proliferation and reduces CD8+ T-cell death. Our data identify a mechanism of T-cell exhaustion in intestinal lymphoid organs and define a potentially effective immunological strategy for the modulation of progression to AIDS.     

Immunodeficiency in the absence of high viral load in pig-tailed macaques infected with Simian immunodeficiency virus SIVsun or SIVlhoest

Simian immunodeficiency virus (SIV) is known to result in an asymptomatic infection of its natural African monkey host. However, some SIV strains are capable of inducing AIDS-like symptoms and death upon experimental infection of Asian macaques. To further investigate the virulence of natural SIV isolates from African monkeys, pig-tailed (PT) macaques were inoculated intravenously with either of two recently discovered novel lentiviruses, SIVlhoest and SIVsun. Both viruses were apparently apathogenic in their natural hosts but caused immunodeficiency in PT macaques. Infection was characterized by a progressive loss of CD4(+) lymphocytes in the peripheral blood and lymph nodes, generalized lymphoid depletion, a wasting syndrome, and opportunistic infections, such as Mycobacterium avium or Pneumocystis carinii infections. However, unlike SIVsm/mac infection of macaques, SIVlhoest and SIVsun infections in PT macaques were not accompanied by high viral loads during the chronic disease stage. In addition, no significant correlation between the viral load at set point (12 weeks postinfection) and survival could be found. Five out of eight SIVlhoest-infected and three out of four SIVsun-infected macaques succumbed to AIDS during the first 5 years of infection. Thus, the survival of SIVsun- and SIVlhoest-infected animals was significantly longer than that of SIVagm- or SIVsm-infected macaques. All PT macaques maintained strong SIV antibody responses despite progression to SIV-induced AIDS. The development of immunodeficiency in the face of low viremia suggests that SIVlhoest and SIVsun infections of macaques may model unique aspects of the pathogenesis of human immunodeficiency virus infection in humans.     

Immunization of macaques with single-cycle simian immunodeficiency virus (SIV) stimulates diverse virus-specific immune responses and reduces viral loads after challenge with SIVmac239

Genetically engineered simian immunodeficiency viruses (SIV) that is limited to a single cycle of infection was evaluated as a nonreplicating AIDS vaccine approach for rhesus macaques. Four Mamu-A*01(+) macaques were inoculated intravenously with three concentrated doses of single-cycle SIV (scSIV). Each dose consisted of a mixture of approximately equivalent amounts of scSIV strains expressing the SIV(mac)239 and SIV(mac)316 envelope glycoproteins with mutations in nef that prevent major histocompatibility complex (MHC) class I downregulation. Viral loads in plasma peaked between 10(4) and 10(5) RNA copies/ml on day 4 after the first inoculation and then steadily declined to undetectable levels over the next 4 weeks. SIV Gag-specific T-cell responses were detected in peripheral blood by MHC class I tetramer staining (peak, 0.07 to 0.2% CD8(+) T cells at week 2) and gamma interferon (IFN-gamma) enzyme-linked immunospot (ELISPOT) assays (peak, 50 to 250 spot forming cells/10(6) peripheral blood mononuclear cell at week 3). Following the second and third inoculations at weeks 8 and 33, respectively, viral loads in plasma peaked between 10(2) and 10(4) RNA copies/ml on day 2 and were cleared over a 1-week period. T-cell-proliferative responses and antibodies to SIV were also observed after the second inoculation. Six weeks after the third dose, each animal was challenged intravenously with SIV(mac)239. All four animals became infected. However, three of the four scSIV-immunized animals exhibited 1 to 3 log reductions in acute-phase plasma viral loads relative to two Mamu-A*01(+) control animals. Additionally, two of these animals were able to contain their viral loads below 2,000 RNA copies/ml as late as 35 weeks into the chronic phase of infection. Given the extraordinary difficulty in protecting against SIV(mac)239, these results are encouraging and support further evaluation of lentiviruses that are limited to a single cycle of infection as a preclinical AIDS vaccine approach.     

nef gene is required for robust productive infection by simian immunodeficiency virus of T-cell-rich paracortex in lymph nodes

The pathogenesis of AIDS virus infection in a nonhuman primate AIDS model was studied by comparing plasma viral loads, CD4(+) T-cell subpopulations in peripheral blood mononuclear cells, and simian immunodeficiency virus (SIV) infection in lymph nodes for rhesus macaques infected with a pathogenic molecularly cloned SIVmac239 strain and those infected with its nef deletion mutant (Deltanef). In agreement with many reports, whereas SIVmac239 infection induced AIDS and depletion of memory CD4(+) T cells in 2 to 3 years postinfection (p.i.), Deltanef infection did not induce any manifestation associated with AIDS up to 6.5 years p.i. To explore the difference in SIV infection in lymphoid tissues, we biopsied lymph nodes at 2, 8, 72, and 82 weeks p.i. and analyzed them by pathological techniques. Maximal numbers of SIV-infected cells (SIV Gag(+), Env(+), and RNA(+)) were detected at 2 weeks p.i. in both the SIVmac239-infected animals and the Deltanef-infected animals. In the SIVmac239-infected animals, most of the infected cells were localized in the T-cell-rich paracortex, whereas in the Deltanef-infected animals, most were localized in B-cell-rich follicles and in the border region between the paracortex and the follicles. Analyses by double staining of CD68(+) macrophages and SIV Gag(+) cells and by double staining of CD3(+) T cells and SIV Env(+) cells revealed that SIV-infected cells were identified as CD4(+) T cells in either the SIVmac239 or the Deltanef infection. Whereas the many functions of Nef protein were reported from in vitro studies, our finding of SIVmac239 replication in the T-cell-rich paracortex in the lymph nodes supports the reported roles of Nef protein in T-cell activation and enhancement of viral infectivity. Furthermore, the abundance of SIVmac239 infection and the paucity of Deltanef infection in the T-cell-rich paracortex accounted for the differences in viral replication and pathogenicity between SIVmac239 and the Deltanef mutant. Thus, our in vivo study indicated that the nef gene enhances SIV replication by robust productive infection in memory CD4(+) T cells in the T-cell-rich region in lymphoid tissues.     

Viral load in tissues during the early and chronic phase of non-pathogenic SIVagm infection

African green monkeys (AGMs) persistently infected with SIVagm do not develop AIDS, although their plasma viremia levels can reach those reported for pathogenic HIV-1 and SIVmac infections. In contrast, the viral burden in lymph nodes in SIVagm-infected AGMs is generally lower in comparison with HIV/SIVmac pathogenic infections, at least during the chronic phase of SIVagm infection. We searched for the primary targets of viral replication, which might account for the high viremias in SIVagm-infected AGMs. We evaluated for the first time during primary infection SIVagm dissemination in various lymphoid and non-lymphoid tissues. Sixteen distinct organs at a time point corresponding to maximal virus production were analyzed for viral RNA and DNA load. At days 8 and 9 p.i., viral RNA could be detected in a wide range of tissues, such as jejunum, spleen, mesenteric lymph nodes, thymus and lung. Quantification of viral DNA and RNA as well as of productively infected cells revealed that viral replication during this early phase takes place mainly in secondary lymphoid organs and in the gut (5 x 10(4)-5 x 10(8) RNA copies/10(6) cells). By 4 years p.i., RNA copy numbers were below detection level in thymus and lung. Secondary lymphoid organs displayed 6 x 10(2)-2 x 10(6) RNA copies/10(6) cells, while some tissue fragments of ileum and jejunum still showed high viral loads (up to 10(9) copies/10(6) cells). Altogether, these results indicate a rapid dissemination of SIVagm into lymphoid tissues, including the small intestine. The latter, despite showing marked regional variations, most likely contributes significantly to the high levels of viremia observed during SIVagm infection.     

Heterogeneity of the simian immunodeficiency virus (SIV) specific CD8(+) T-cell response in mucosal tissues during SIV primary infection

Virus-specific CD8(+) T cells play an important role in controlling viral replication during acute primary infection. At this early stage, mucosal tissues represent a major site of viral replication. Therefore, the presence of functional virus-specific CD8(+) effector T cells in the mucosa during primary infection is a key issue in the pathogenesis of infection. In order to evaluate the extent of this response, six rhesus macaques were infected with simian immunodeficiency virus (SIV)mac251 and sacrificed on day 28 following infection. The functional activity of SIV-effector CD8(+) T cells was evaluated by means of a gamma-IFN ELISpot assay with autologous cells expressing SIV env, gag, pol and nef genes as antigen-presenting cells. This evaluation was performed on PBMCs, spleen, peripheral lymph node, gut-associated lymph node and lamina propria lymphocytes isolated from different mucosal sites. In parallel, the cell-associated viral load was quantified in all these tissues. Five macaques had gamma-IFN SIV-specific CD8(+) T cells in PBMCs and/or lymph nodes. However, in these macaques, these CD8(+) T cells were only present in seven mucosal sites out of 24 tested (the lamina propria lymphocytes of the duodenum, jejunum, ileum and colon were evaluated separately for each animal), whereas they were detected in all corresponding gut-associated lymph nodes. In addition, the mean frequency of SIV-specific gamma-IFN-secreting CD8(+) T cells was 117 +/- 228 per 10(6) cells in the lamina propria vs. 958 +/- 1184 in gut associated lymph nodes (P = 0.001). No overall correlation was observed between the CD8(+) T-cell activity and the viral load: among the 17 mucosal sites in which the virus was isolated, no specific activity was detected in 13 sites. In conclusion, these data indicate that the frequencies of SIV-specific gamma-IFN-secreting CD8(+) T cells are low in the mucosa during early primary infection. This may be of importance with regard to the intense viral replication observed in the mucosa at this stage.