SHIV-XJ02170感染恒河猴后期的传代特点和env基因变异

目的研究SHIV-XJ02170在中国恒河猴感染后期传代过程中病毒和宿主的变化特点,并分析env基因的序列变异。方法将感染中国恒河猴G0401V后期（5年）的SHIV-XJ02170病毒垂直传代2只猴（G0401V→G0402V→0403V）,同时,剔除G0401V猴CD8＋T细胞使潜伏的病毒大量复制后传代1只猴（G0401V→G0404V）,应用流式细胞术、病毒载量测定、序列分析等方法研究该病毒在猴体内长期适应后的病毒和免疫学指标及序列变异特点。结果 G0401V在感染后期仍能稳定传代,且表现出毒力增强的特点。其传代猴G0402V在传代后41 d死亡,外周血CD4＋T淋巴细胞衰竭,仅为43个/mL,符合艾滋病感染猴快速进展型的特征。剔除体内CD8＋T细胞之后的传代猴G0404V的表现类似G0401V,即长期低水平的病毒血症水平。env基因序列分析发现SHIV-XJ02170在G0401V体内长期适应后发生了可遗传的序列变异,并引起糖基化位点的改变。结论 SHIV-XJ02170在猴体长期适应后的传代过程中表现出向强毒株过渡的特征,为进行SHIV-XJ02170感染性克隆的构建奠定了良好的实验基础。     

两株SIV_(mac)的滴定和特性

SIVmac251的MID100为32TCID,而SIVmac239的MID100高于320TCID。体内滴定感染成功的5只猴（SIVmac2513只,SIVmac2392只）和用ZMID100SIVmac251感染的7只猴感染后有全身淋巴结肿大,并出现规律性的血浆病毒血症和抗体反应。SIVmac251感染的7只恒河猴和2只食蟹猴的淋巴结和脾脏的病理组织学检查,显现规律的SIVmac感染后的组织学变化。上述结果表明两株SIVmac均能诱发SIVmac感染猴的系列表现和变化,可应用于抗艾滋病药物猴体疗效的评价。     

亚洲主要流行HIV-1 Gp120及其5个高变区多态性分析

HIV-1 Gp120及其5个高变区的多态性是HIV-1能够逃逸宿主免疫反应和耐药性的主要原因。下载了现有数据库中记载的包括B’、C、CRF01_AE、CRF07_BC和CRF08_BC 5种亚洲主要流行亚型和重组型的所有Gp120及其5个高变区序列,分析了HIV-1 Gp120及其5个高变区序列的长度多态性,糖基化位点数以及序列特征。结果显示,绝大部分的HIV-1 Gp120序列长度为496～515个氨基酸之间,这提示Gp120长度为496～515个氨基酸的HIV-1毒株可能是疫苗研究的理想毒株。比较5个高变区,V3区表现出了最低的长度多态性,几乎没有糖基化位点,表明受到较强的功能限制。不同亚型和重组型的V3区一致序列比较发现,所有的HIV-1亚型均表现为R5型。这提示阻断HIV-1病毒结合CCR5受体是治疗艾滋病的有效途径,R5型毒株可以作为艾滋病疫苗研究的理想毒株。另外,V1和V4区展现了很高的长度多态性,糖基化位点也较多;而V2和V5区的长度多态性和糖基化位点都较低。这些结果表明降低这4个高变区的多态性和糖基化位点数目可能解决HIV-1病毒对疫苗的逃逸,从而研究出真正有效的疫苗。     

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。     

模拟HIV性传播特点的SIVmac239恒河猴直肠黏膜感染

目的制备SIVmac239恒河猴(Macaca mulatta)细胞适应株病毒,模拟HIV性传播感染特点进行恒河猴直肠黏膜感染研究,探索引起系统性感染的病毒阈值水平与机体病毒、免疫学之间相关性,为我国艾滋病黏膜疫苗等生物制剂有效性评价提供新的模型构建思路。方法参照HIV性传播自然感染剂量范围,选用SIVmac239连续升高的3种剂量直肠黏膜途径感染两只恒河猴,采取多种方法进行病毒血症和免疫反应特点分析。结果两只恒河猴经2×101TCID50和2×102TCID50病毒滴度2次攻击后45d,经检测均未建立系统性感染,病毒特异性免疫反应均为阴性;第3次2×103TCID50病毒滴度攻击后,M296猴表现出典型的系统性感染特点,并诱导特异性免疫反应。结论确认了HIV性传播过程中的病毒剂量效应关系,为预防性生物制剂的猴体有效性评价提供了新的思路。同时,发现SIVmac239Gag区特异性的T细胞免疫反应在病毒控制过程中发挥了关键作用,对于新一代艾滋病黏膜疫苗的抗原选择具有指导性意义。     

2010?2011年全球季节性H3N2流感病毒表面蛋白基因的分子遗传特性分析

[目的]分析2010年1月至2011年9月间全球季节性H3N2流感病毒血凝素(Hemagglutinin,HA)和神经氨酸酶(Neuraminidase,NA)基因的演变和分子特征,为流感病毒的防制提供分子信息依据.[方法]搜集期间季节性H3N2流感病毒HA和NA基因的完整核苷酸序列,分别绘制两基因编码序列的进化树;推导出相应的氨基酸序列,统计不同毒株间氨基酸位点差异并分析重要功能位点的变化.[结果]在136条完整的片段4和131条片段6中,2条HA和l条NA序列源自猪群流感病毒,剩余的序列根据进化特征可被分为两群.相比疫苗毒株,发生在HA和NA蛋白抗原位点的平均差异数分别为5.33和2.01个,3个毒株分别在HA宿主受体结合位点和二硫键及NA耐药位点出现突变,多数毒株的糖基化位点增多.江苏毒株和广东毒株分别属于群l和群2,且两省毒株间在HA蛋白抗原位点的差异数从7到13个不等.[结论]2010年1月至2011年9月间的全球季节性H3N2病毒主要呈现两种基因进化特征.因抗原性差异对疫苗开发具有指导作用,而多数毒株的抗原性检测信息仍然未知,但从抗原位点和糖基化位点的变异情况来看,多数毒株的抗原性可能已经变化,为判断是否形成新的流行株,应开展进一步的抗原性检测;并且各地区卫生行政部门应根据耐药位点的变化,制定相应的抗病毒治疗措施.     

复杂的正选择压力驱动不同细胞嗜性HIV-1的进化

对HIV-1细胞嗜性的研究是理解HIV-1传播和发病机制的关键.通过对HIV-1B和C亚型的R5和X4型病毒的全基因组进行适应性进化分析,发现R5和X4病毒经历了不同的进化方式,并且不同的HIV-1基因受到不同的正选择压力,意味着复杂的自然选择压力驱动HIV-1的进化.分析HIV-1Gp120超变区上的正选择位点,发现相对于其他超变区,更多的正选择位点发生在B亚型X4病毒的V3区,B亚型R5病毒的V2区以及C亚型X4病毒的V1和V4区域.因为这些区域通常影响和决定HIV-1的细胞嗜性,更多的正选择发生在这些特定的超变区意味着作用于Gp120上的选择压力与Gp120的受体识别和结合功能有关.值得注意的是,无论是B和C亚型还是R5和X4型病毒,显著更多的正选择位点发生在Gp120的C3区域（33.3%～55.6%,P〈0.05）,意味着C3区对HIV-1的生存和适应比先前认识的更为重要.另外,在R5和X4病毒的env基因中,约有一半的正选择位点是相同的,尤其是Gp41上的第96,113和281位正选择位点均出现在所分析的4种病毒类型中.这些共同的正选择位点不仅意味着对病毒生存和适应的重要性,也意味着R5和X4存在交叉免疫源性位点的可能性,这对于AIDS疫苗的发展具有重要意义.     

羊瘙痒病小鼠适应株139A可突破种属屏障颅内感染金黄地鼠

羊瘙痒病感染因子可以根据疾病发生的潜伏期、临床病程、神经病理学特征以及PrPSc分子特征等分为不同的毒株,目前已经证实有20余种.在可传播性海绵状脑病的发病过程中存在着明显的种属屏障作用.将小鼠适应株139A颅内接种至金黄地鼠,以观测感染因子对种属屏障的突破及感染特征.在接种385～405天后,感染动物出现明显症状,与以往报道的金黄地鼠适应株263K不同,139A毒株发病动物出现严重的瘙痒,而无明显的共济失调.感染动物自出现明显症状到死亡的时间明显长于263K毒株感染金黄地鼠.进一步脑组织电镜和Western blot检测证实,存在有羊瘙痒病相关纤维和PrP-res.这证明小鼠适应株139A可突破种属屏障感染金黄地鼠.经系统比较,139A和263K毒株在潜伏期、主要临床症状和临床病程显示出明显的差异,而PrP-res的泳动位置和糖基化比率差异不大,仅139A毒株的单糖基化分子位置似乎略高于263K.动态观测处于潜伏期的接种动物脑组织羊瘙痒病相关纤维和PrP-res,发现PrPSc的出现明显早于临床症状.     

HSV-1感染对神经胶质瘤细胞神经生长因子及其受体表达的影响

神经生长因子(NGF)主要由神经胶质细胞产生,通过特异的靶细胞表面的神经生长因子受体介导产生生物学效应,与神经细胞的生长发育、分化和凋亡等密切相关。单纯疱疹病毒1型(HSV-1)作为一种嗜神经病毒,易造成神经细胞、神经胶质细胞凋亡或死亡。本实验以U251人神经胶质瘤细胞为研究对象,观察HSV-1感染致U251细胞凋亡的过程中NGF及其受体的变化情况。结果发现U251细胞是HSV-1的容许细胞;HSV-1感染致U251细胞凋亡过程中,NGF及其低亲和力受体p75NTR出现表达强度随时间先增强后减弱的趋势,而高亲和受体Tr-kA持续低表达。推测HSV-1感染致神经细胞凋亡中可能调控了神经营养因子的表达。     

一株H5N2亚型鹦鹉源禽流感病毒分子进化分析

2005年在广东进行流行病学调查时分离到一株鹦鹉源禽流感病毒,经鉴定为H5N2亚型禽流感病毒(A/Parrot/Guangdong/268/2005)。该毒株的HA裂解位点附近的氨基酸序列为RETRGLF,只含有一个碱性氨基酸,符合低致病性禽流感病毒的HA裂解位点附近氨基酸序列的分子特征;与H5N2亚型禽流感代表毒株相比,该毒株HA和NA基因的糖基化位点、HA基因的受体结合位点编码区、NA基因的耐药性位点均未发生变异。将该毒株全基因组序列与GenBank已公布的19株H5N2亚型禽流感病毒株的相应序列进行比较分析并绘制系统进化树后发现:其与低致病性禽流感毒株A/Pheasant/NJ/1355/1998(H5N2)-like的亲缘关系最近,位于以A/Chicken/Pennsylvania/1/1983(H5N2)为代表的美洲进化分支。     

Simian immunodeficiency virus mutants resistant to serum neutralization arise during persistent infection of rhesus monkeys.

We previously described the pattern of sequence variation in gp120 following persistent infection of rhesus monkeys with the pathogenic simian immunodeficiency virus SIVmac239 molecular clone (D.P.W. Burns and R.C. Desrosiers, J. Virol. 65:1843, 1991). Sequence changes were confined largely to five variable regions (V1 to V5), four of which correspond to human immunodeficiency virus type 1 (HIV-1) gp120 variable regions. Remarkably, 182 of 186 nucleotide substitutions that were documented in these variable regions resulted in amino acid changes. This is an extremely nonrandom pattern, which suggests selective pressure driving amino acid changes in discrete variable domains. In the present study, we investigated whether neutralizing-antibody responses are one selective force responsible at least in part for the observed pattern of sequence variation. Variant env sequences called 1-12 and 8-22 obtained 69 and 93 weeks after infection of a rhesus monkey with cloned SIVmac239 were recombined into the parental SIVmac239 genome, and variant viruses were generated by transfection of cultured cells with cloned DNA. The 1-12 and 8-22 recombinants differ from the parental SIVmac239 at 18 amino acid positions in gp120 and at 5 and 10 amino acid positions, respectively, in gp41. Sequential sera from the monkey infected with cloned SIVmac239 from which the 1-12 and 8-22 variants were isolated showed much higher neutralizing antibody titers to cloned SIVmac239 than to the cloned 1-12 and 8-22 variants. For example, at 55 weeks postinfection the neutralizing antibody titer against SIVmac239 was 640 while those to the variant viruses were 40 and less than 20. Two other rhesus monkeys infected with cloned SIVmac239 showed a similar pattern. Rhesus monkeys were also experimentally infected with the cloned variants so that the type-specific nature of the neutralizing antibody responses could be verified. Indeed, each of these monkeys showed neutralizing-antibody responses of much higher titer to the homologous variant used for infection. These experiments unambiguously demonstrate that SIV mutants resistant to serum neutralization arise during the course of persistent infection of rhesus monkeys.     

Neutralizing Antibodies in Sera from Macaques Immunized with Attenuated Simian Immunodeficiency Virus

Infection with attenuated simian immunodeficiency virus (SIV) in rhesus macaques has been shown to raise antibodies capable of neutralizing an animal challenge stock of primary SIVmac251 in CEMx174 cells that correlate with resistance to infection after experimental challenge with this virulent virus (M. S. Wyand, K. H. Manson, M. Garcia-Moll, D. C. Montefiori, and R. C. Desrosiers, J. Virol. 70:3724–3733, 1996). Here we show that these neutralizing antibodies are not detected in human and rhesus peripheral blood mononuclear cells (PBMC). In addition, neutralization of primary SIVmac251 in human and rhesus PBMC was rarely detected with plasma samples from a similar group of animals that had been infected either with SIVmac239Δnef for 1.5 years or with SIVmac239Δ3 for 3.2 years, although low-level neutralization was detected in CEMx174 cells. Potent neutralization was detected in CEMx174 cells when the latter plasma samples were assessed with laboratory-adapted SIVmac251. In contrast to primary SIVmac251, laboratory-adapted SIVmac251 did not replicate in human and rhesus PBMC despite its ability to utilize CCR5, Bonzo/STRL33, and BOB/gpr15 as coreceptors for virus entry. These results illustrate the importance of virus passage history and the choice of indicator cells for making assessments of neutralizing antibodies to lentiviruses such as SIV. They also demonstrate that primary SIVmac251 is less sensitive to neutralization in human and rhesus PBMC than it is in established cell lines. Results obtained in PBMC did not support a role for neutralizing antibodies as a mechanism of protection in animals immunized with attenuated SIV and challenged with primary SIVmac251.     

A single nonsynonymous mutation on ZIKV E protein-coding sequences leads to markedly increased neurovirulence in vivo

Zika virus (ZIKV) can infect a wide range of tissues including the developmental brain of human fetus. Whether specific viral genetic variants are linked to neuropathology is incompletely understood. To address this, we have intracranially serially passaged a clinical ZIKV isolate (SW01) in neonatal mice and discovered variants that exhibit markedly increased virulence and neurotropism. Deep sequencing analysis combining with molecular virology studies revealed that a single 67D (Aspartic acid) to N (Asparagine) substitution on E protein is sufficient to confer the increased virulence and neurotropism in vivo. Notably, virus clones with D67N mutation had higher viral production and caused more severe cytopathic effect (CPE) in human neural astrocytes U251 cells in vitro, indicating its potential neurological toxicity to human brain. These findings revealed that a single mutation D67N on ZIKV envelope may lead to severe neuro lesion that may help to explain the neurovirulence of ZIKV and suggest monitoring the occurrence of this mutation during nature infection may be important.     

Rapid progression to simian AIDS can be accompanied by selection of CD4-independent gp120 variants with impaired ability to bind CD4

Aspartate 368 on human immunodeficiency virus type 1 (HIV-1) gp120 forms multiple contacts with CD4; in mutagenesis studies, its replacement by asparagine and corresponding changes in simian immunodeficiency virus SIVmac (D385N) reduced binding with CD4. Nevertheless, simian immunodeficiency virus envelopes with D385N were prevalent in several studies. Extending these observations, we also found D385N to be dominant among env clones from two rhesus macaques that progressed rapidly to simian AIDS. These envelopes showed a CD4-independent phenotype as well as reduced affinity to CD4. Moreover, an adjacent change, G383R, which was frequently coselected with D385N, further decreased binding. An optical biosensor study demonstrated that the SIVmac239 gp120 bound to CD4 with kinetics similar to those of HIV-1. However, the gp120s with D385N and G383R showed a 40-fold reduction in affinity, with a drastic increase in dissociation rate, indicating an inherently unstable complex. This finding showed that rapid progression to simian AIDS may be accompanied by the selection of CD4-independent gp120 variants with impaired CD4 binding ability.     

An adenovirus-simian immunodeficiency virus env vaccine elicits humoral, cellular, and mucosal immune responses in rhesus macaques and decreases viral burden following vaginal challenge.

Six female rhesus macaques were immunized orally and intranasally at 0 weeks and intratracheally at 12 weeks with an adenovirus type 5 host range mutant (Ad5hr)-simian immunodeficiency virus SIVsm env recombinant and at 24 and 36 weeks with native SIVmac251 gp120 in Syntex adjuvant. Four macaques received the Ad5hr vector and adjuvant alone; two additional controls were naive. In vivo replication of the Ad5hr wild-type and recombinant vectors occurred with detection of Ad5 DNA in stool samples and/or nasal secretions in all macaques and increases in Ad5 neutralizing antibody in 9 of 10 macaques following Ad administrations. SIV-specific neutralizing antibodies appeared after the second recombinant immunization and rose to titers > 10,000 following the second subunit boost. Immunoglobulin G (IgG) and IgA antibodies able to bind gp120 developed in nasal and rectal secretions, and SIV-specific IgGs were also observed in vaginal secretions and saliva. T-cell proliferative responses to SIV gp140 and T-helper epitopes were sporadically detected in all immunized macaques. Following vaginal challenge with SIVmac251, transient or persistent infection resulted in both immunized and control monkeys. The mean viral burden in persistently infected immunized macaques was significantly decreased in the primary infection period compared to that of control macaques. These results establish in vivo use of the Ad5hr vector, which overcomes the host range restriction of human Ads for rhesus macaques, thereby providing a new model for evaluation of Ad-based vaccines. In addition, they show that a vaccine regimen using the Ad5hr-SIV env recombinant and gp120 subunit induces strong humoral, cellular, and mucosal immunity in rhesus macaques. The reduced viral burden achieved solely with an env-based vaccine supports further development of Ad-based vaccines comprising additional viral components for immune therapy and AIDS vaccine development.     

An env gene derived from a primary human immunodeficiency virus type 1 isolate confers high in vivo replicative capacity to a chimeric simian/human immunodeficiency virus in rhesus monkeys.

To explore the roles played by specific human immunodeficiency virus type 1 (HIV-1) genes in determining the in vivo replicative capacity of AIDS viruses, we have examined the replication kinetics and virus-specific immune responses in rhesus monkeys following infection with two chimeric simian/human immunodeficiency viruses (SHIVs). These viruses were composed of simian immunodeficiency virus SIVmac239 expressing HIV-1 env and the associated auxiliary HIV-1 genes tat, vpu, and rep. Virus replication was assessed during primary infection of rhesus monkeys by measuring plasma SIVmac p27 levels and by quantifying virus replication in lymph nodes using in situ hybridization. SHIV-HXBc2, which expresses the HIV-1 env of a T-cell-tropic, laboratory-adapted strain of HIV-1 (HXBc2), replicated well in rhesus monkey peripheral blood leukocytes (PBL) in vitro but replicated only to low levels when inoculated in rhesus monkeys. In contrast, SHIV-89.6 was constructed with the HIV-1 env gene of a T-cell- and macrophage-tropic clone of a patient isolate of HIV-1 (89.6). This virus replicated to a lower level in monkey PBL in vitro but replicated to a higher degree in monkeys during primary infection. Moreover, monkeys infected with SHIV-89.6 developed an inversion in the PBL CD4/CD8 ratio coincident with the clearance of primary viremia. The differences in the in vivo consequences of infection by these two SHIVs could not be explained by differences in the immune responses elicited by these viruses, since infected animals had comparable type-specific neutralizing antibody titers, proliferative responses to recombinant HIV-1 gp120, and virus-specific cytolytic effector T-cell responses. With the demonstration that a chimeric SHIV can replicate to high levels during primary infection in rhesus monkeys, this model can now be used to define genetic determinants of HIV-1 pathogenicity.     

Construction and characterization of recombinant VLPs and Semliki-Forest virus live vectors for comparative evaluation in the SHIV monkey model

For testing of recombinant virus-like particles (VLPs) in the SHIV monkey model, SIVmac239 Pr56gag precursor-based pseudovirions were modified by HIV-1 gp160 derived peptides. First, well-characterized epitopes from the HIV-1 envelope glycoprotein were inserted into the Pr56gag precursor by replacing defined regions that were shown to be dispensable for virus particle formation. Expression of these chimeric proteins in a baculovirus expression system resulted in efficient assembly and release of non-infectious, hybrid VLPs. In a second approach the HIV-1IIIB external glycoprotein gp120 was covalently linked to an Epstein-Barr virus derived transmembrane domain. Coexpression of the hybrid envelope derivative with the Pr56gag precursor yielded recombinant SIV derived Pr56gag particles with the HIV-1 gp120 firmly anchored on the VLP surface. Immunization of rhesus monkeys with either naked VLPs or VLPs adsorbed to alum induced substantial serum antibody titers and promoted both T helper cell and cytotoxic T lymphocyte responses. Furthermore, priming macaques with the corresponding set of recombinant Semliki-Forest viruses tended to enhance the immunological outcome. Challenge of the immunized monkeys with chimeric SHIV resulted in a clearly accelerated reduction of the plasma viremia as compared to control animals.     

Mutations that destabilize the gp41 core are determinants for stabilizing the simian immunodeficiency virus-CPmac envelope glycoprotein complex

The human and simian immunodeficiency viruses (HIV and SIV) envelope glycoprotein consists of a trimer of two noncovalently and weakly associated subunits, gp120 and gp41. Upon binding of gp120 to cellular receptors, this labile native envelope complex undergoes conformational changes, resulting in a stable trimer-of-hairpins structure in gp41. Formation of the hairpin structure is thought to mediate membrane fusion by placing the viral and cellular membranes in close proximity. An in vitro-derived variant of SIVmac251, denoted CPmac, has acquired an unusually stable virion-associated gp120-gp41 complex. This unique phenotype is conferred by five amino acid substitutions in the gp41 ectodomain. Here we characterize the structural and physicochemical properties of the N40(L6)C38 model of the CPmac gp41 core. The 1.7-A resolution crystal structure of N40(L6)C38 is very similar to the six-helix bundle structure present in the parent SIVmac251 gp41. In both structures, three N40 peptides form a central three-stranded coiled coil, and three C38 peptides pack in an antiparallel orientation into hydrophobic grooves on the coiled-coil surface. Thermal unfolding studies show that the CPmac mutations destabilize the SIVmac251 six-helix bundle by 15 kJ/mol. Our results suggest that the formation of the gp41 trimer-of-hairpins structure is thermodynamically coupled to the conformational stability of the native envelope glycoprotein and raise the intriguing possibility that introduction of mutations to destabilize the six-helix bundle may lead to the stabilization of the trimeric gp120-gp41 complex. This study suggests a potential strategy for the production of stably folded envelope protein immunogens for HIV vaccine development.     

In Vivo Replication Capacity Rather Than In Vitro Macrophage Tropism Predicts Efficiency of Vaginal Transmission of Simian Immunodeficiency Virus or Simian/Human Immunodeficiency Virus in Rhesus Macaques

We used the rhesus macaque model of heterosexual human immunodeficiency virus (HIV) transmission to test the hypothesis that in vitro measures of macrophage tropism predict the ability of a primate lentivirus to initiate a systemic infection after intravaginal inoculation. A single atraumatic intravaginal inoculation with a T-cell-tropic molecular clone of simian immunodeficiency virus (SIV), SIVmac239, or a dualtropic recombinant molecular clone of SIV, SIVmac239/1A11/239, or uncloned dualtropic SIVmac251 or uncloned dualtropic simian/human immunodeficiency virus (SHIV) 89.6-PD produced systemic infection in all rhesus macaques tested. However, vaginal inoculation with a dualtropic molecular clone of SIV, SIVmac1A11, resulted in transient viremia in one of two rhesus macaques. It has previously been shown that 12 intravaginal inoculations with SIVmac1A11 resulted in infection of one of five rhesus macaques (M. L. Marthas, C. J. Miller, S. Sutjipto, J. Higgins, J. Torten, B. L. Lohman, R. E. Unger, H. Kiyono, J. R. McGhee, P. A. Marx, and N. C. Pedersen, J. Med. Primatol. 21:99–107, 1992). In addition, SHIV HXBc2, which replicates in monkey macrophages, does not infect rhesus macaques following multiple vaginal inoculations, while T-cell-tropic SHIV 89.6 does (Y. Lu, P. B. Brosio, M. Lafaile, J. Li, R. G. Collman, J. Sodroski, and C. J. Miller, J. Virol. 70:3045–3050, 1996). These results demonstrate that in vitro measures of macrophage tropism do not predict if a SIV or SHIV will produce systemic infection after intravaginal inoculation of rhesus macaques. However, we did find that the level to which these viruses replicate in vivo after intravenous inoculation predicts the outcome of intravaginal inoculation with each virus.