Early immunopathology events in simian retrovirus, type 2 infections prior to the onset of disease

Immunopathology during early simian retrovirus type 2 (SRV-2) infection is poorly characterized. Here, viral dynamics, immune response and disease progression in transiently- or persistently-infected cynomolgus macaques are assessed. Viral nucleic acids were detected in selected lymphoid tissues of both persistently- and transiently-infected macaques, even after viral clearance from the periphery. Immunohistochemical staining of lymphoid tissues revealed alterations in a number of immune cell populations in both transiently- and persistently-infected macaques. The precise pattern depended upon the infection status of the macaque and the marker studied. Gross immunopathological changes in lymphoid tissues were similar between SRV infection and those observed for other simian retroviruses SIV and STLV, suggesting a common immunopathological response to infection with these agents.     

Development of a generic real-time PCR assay for simultaneous detection of proviral DNA of simian Betaretrovirus serotypes 1, 2, 3, 4 and 5 and secondary uniplex assays for specific serotype identification

Simian betaretroviruses (formerly Type D retroviruses; SRV) are a group of closely related retroviruses for which the natural host species are Asian monkeys of the genus Macaca. Five serotypes have been identified by classical neutralization assays and three additional untyped variants have been reported (SRV_Tsukuba, SRV-6, SRV-7). These viruses may be significant pathogens in macaque colonies, causing a broad spectrum of clinical disease secondary to viral-induced immune suppression. Undetected SRV infections in research macaques also represent a potential confounding variable in research protocols and a concern for human caretakers. Intensive testing efforts have been implemented to identify infected animals in established colonies. A real-time quantitative generic multiplex PCR assay was developed that is capable of simultaneous detection of proviral DNA of SRV serotypes 1, 2, 3, 4 and 5. This assay incorporates amplification of the oncostatin M (OSM) gene for confirmation of amplifiable DNA and allows quantitation of the number of proviral copies per cell analyzed in each multiplex reaction. Detection of multiple serotypes by PCR increases the efficiency and cost-effectiveness of SRV screening programs. A panel of SRV serotype-specific uniplex real-time PCR assays for discrimination among the five recognized serotypes is also described.     

Detection of SRV/D shedding in body fluids of cynomolgus macaques and comparison of partial gp70 sequences in SRV/D-T isolates

We previously reported the isolation of a novel subtype of SRV/D-Tsukuba (SRV/D-T) from two cynomolgus monkeys (Macaca facicularis) in the breeding colony of Tsukuba Primate Research Center (TPRC). We surveyed for SRV/D infection in the TPRC cynomolgus colony using SRV/D-specific PCR primer sets designed based on the entire gag region sequence. The only SRV/D subtype detected in the colony was SRV/D-T with a positive infection rate of 22.4% (n = 49). It has been reported that the mode of transmission of SRV/D is via contact with virus shed in the body fluids. In this report, to investigate the infection route of SRV/D-T in monkeys at TPRC, we performed virus isolation and PCR for detection of the SRV/D genome from peripheral blood mononuclear cells (PBMCs), plasma, saliva, urine, and feces. Virus isolation and PCR detection were positive in plasma, saliva, urine, and fecal samples from all monkeys on which virus was isolated from PBMCs. This suggests that the spread of SRV/D-T infection in TPRC is via contact with virus shed in saliva, urine, and/or feces. Also, comparison of sequences of gp70 on multiple SRV/D-T isolates revealed that there was little intra- and inter-monkey variation, suggesting that SRV/D-T is fairly stable.     

Development of real-time PCR assays for quantitation of simian betaretrovirus serotype-1, -2, -3, and -5 viral DNA in Asian monkeys

Simian betaretroviruses (SRV), formerly known as simian type D retroviruses, are endemic in many populations of Asian monkeys of the genus Macaca. Asian monkeys have been used extensively as animal models for preclinical HIV vaccine development, therapeutics, and other biomedical studies. SRV infection can sometimes lead to immune deficiency disease, which complicates such studies; thus, it is important to screen for SRV infection and remove infected animals from test populations. Real-time PCR assays were developed to specifically quantify SRV-1/3, SRV-2, and SRV-5 proviral DNA. The SRV provirus copy numbers were standardized relative to real-time PCR measurements of the rhesus macaque albumin gene. The primers and TaqMan probe sequences for the rhesus macaque (Indian origin) albumin gene also detect cynomolgus macaque and rhesus macaque (Chinese origin) albumin genes. The SRV primers and probes were designed to amplify gag gene sequences of SRV-1/3 (GeneBank accession number M11841), SRV-2 (GeneBank accession number M16605), and SRV-5 (GeneBank accession number AF252389). The optimized reactions for detection of each SRV serotype and the macaque albumin gene had amplification efficiencies of greater than 90% with a linear range spanning 1 x 10(1) to 2.5 x 10(6) copies per reaction. The R(2) values of all standard curves were greater than 0.995. Of 40 animals housed in quarantine, four animals were positive for SRV-1/3 with 28, 5450, 9780, and 14,500 copies of provirus per 10(6) PBMCs, and one animal was positive for SRV-2 with provirus copy number of 7790 per 10(6) PBMCs. All of 40 animals appeared to be seronegative and had normal CD4(+) and CD8(+) T-cell counts. These quantitative real-time PCR assays enhance the detection and quantitation of SRV infection and will facilitate the elimination of this virus from macaque colonies.     

Virological and serological characterization of SRV-4 infection in cynomolgus macaques

The nature of SRV-4 infection in cynomolgus macaques remains unclear to date. Here, we report the monitoring of 24 cynomolgus monkeys that were naturally infected with SRV-4 for virus isolation, proviral load and antibody. The results indicated that the SRV-4 antibody status was statistically correlated to environmental temperature.     

New Simian β Retroviruses from Rhesus Monkeys (Macaca Mulatta) and Langurs (Semnopithecus Entellus) from Rajasthan, India

Natural infection of feral Indian rhesus monkeys (Macaca mulatta) by a new simian β retrovirus, provisionally called simian retrovirus-7 (SRV-7) is described. The virus is capable of in vitro replication in primary human peripheral blood lymphocytes (PBL) and B and T cell lines. We have earlier reported a novel SRV, SRV-6 from Indian langurs (Semnopithecus entellus). Additional sequence analyses from gp20 transmembrane (TM) env genes of SRV-6 and SRV-7 place them in a separate cluster, related to but distinct from known exogenous SRVs and also close to the simian endogenous β retrovirus, (SERV) from African baboon. Phylogenetic analyses of pol gene of SRV-7 place it closer to SERV when the stop codons of the SERV genes are removed. On the other hand, additional sequence data from gp70, surface glycoprotein (SU) region of the env gene of SRV-6 suggest it is more closely related to known exogenous SRVs, (SRV-1 to 3). It is also related to the endogenous langur virus, Po-1-Lu. We hypothesize that SRV-6 and SRV-7 probably originated from a progenitor exogenous SRV which recombined with an endogenous SERV in the TM env and pol genes during evolution, based on the phylogenetic analyses. Genbank Accession numbers of the new sequences: SRV-6 TM (gp20) env: AF401239, SRV-6 SU (gp70) env: AY598468, SRV-7 pol region: AY594212, SRV-7 TM env (gp20): AY594213.     

The endogenous langur type D retrovirus PO-1-Lu and its exogenous counterparts in macaque and langur monkeys

PO-1-Lu, the endogenous type D retrovirus of langurs (Trachypithecus obscurus) has previously been considered a progenitor to the prototype type D retrovirus, Mason Pfizer monkey virus (M-PMV/SRV-3), that became established in macaque monkeys (Macaca spp.) following a zoonosis. This study reevaluates this hypothesis to include other exogenous SRVs. New sequence information from the gp70(SU)-encoding region of PO-1-Lu shows striking similarity to the newly identified exogenous langur retrovirus, SRV-6, recently isolated from the Hanuman Langur (Semnopithecus entellus). An unrooted, bootstrapped neighbor-joining tree derived from env gene nucleotide sequences shows PO-1-Lu and SRV-6 appear more closely related genetically to SRV-2 than SRV-1 or SRV-3 (M-PMV). This is also reflected in our observations that the M-PMV envelope glycoprotein precursor gPr86(Env) and gp70(SU) were antigenically distinct from PO-1-Lu, although the gp22(TM) glycoproteins were antigenically cross-reactive. The potential that SRV-6 represents an exogenous form of PO-1-Lu that has arisen following a recent zoonosis is discussed.     

Simian retrovirus receptor and neutralization mechanism by antibodies to the envelope glycoprotein.

Type D simian retroviruses (SRV) cause an acquired immunodeficiency syndrome (AIDS) in monkeys. Results of infection with SRV range from complete recovery with absence of viremia to a viremic state, which produces AIDS-like symptoms and culminates in death. These varied outcomes render the interaction of the host and SRV an attractive model for the study of immunosuppressive retrovirus resulting in different pathologic consequences. We describe here the isolation and determination of the molecular weight of the receptor for SRV. We demonstrate that a cell receptor with the same molecular weight is bound by the envelope protein of all five serotypes of SRV. We also show that the receptor recognizes a region containing amino acids 142-167 of the envelope protein of SRV serotype 1 (SRV-1). In addition, we show that a different region of SRV serotype 2 (SRV-2) envelope protein containing amino acids 93-106, interacts with a cell receptor of identical molecular weight. Furthermore, polyclonal and monoclonal antibodies that are directed to envelope epitopes 142-167 of SRV-1 or to 93-106 of SRV-2, specifically neutralize only the respective viral serotype. Our results indicate that the neutralization of SRV infectivity by antibodies is achieved through blocking the interaction between the virus and its cell receptor.     

Distribution of type D retrovirus sequences in tissues of macaques with simian acquired immune deficiency and retroperitoneal fibromatosis

Horizontally acquired SAIDS retrovirus type 2 (SRV-2), a type D retrovirus related to the Mason-Pfizer monkey virus, has been associated with the simian acquired immunodeficiency syndrome (SAIDS) including retroperitoneal fibromatosis (RF) in several macaque species at two primate research centers. Virus specific gene sequences are present in lymphoid and RF tissues but not in muscle tissue of diseased macaques or in any tissues of uninfected normal monkeys. Serologic and restriction endonuclease mapping techniques have defined unique SRV-2 strains in the Celebes (SRV-2C) and rhesus (SRV-2R) macaques at the Oregon Regional Primate Center, SRV-2 is related to both MPMV and SAIDS type 1 retroviruses and it has no detectable molecular homology with the human AIDS retroviruses.     

Transmission of simian acquired immunodeficiency syndrome with a type D retrovirus: immunological aspects

Simian acquired immunodeficiency syndrome (SAIDS) was transmitted to four of four rhesus macaques with blood from rhesus macaques naturally infected with a type D retrovirus, simian retrovirus-2 (SRV-2). Three of the four blood recipients died with SAIDS at 13, 15, and 26 weeks postinoculation. The fourth animal is alive with SAIDS. All four test monkeys became viremic and produced antiviral antibody. None of the inoculated monkeys produced measureable neutralizing antibody to SRV-2. The survivor produced higher levels of antiviral antibody than the monkeys that died. Phytohemagglutinin and concanavalin A reactivity of peripheral blood lymphocytes was depressed from weeks 6 to 12 after inoculation. Clinical findings included development of splenomegaly in all four monkeys, and diarrhea in two monkeys. Blood counts remained within the normal range except for a depression in the number of polymorphonuclear lymphocytes in two monkeys. Hematocrits were decreased in two monkeys just prior to their death. All four test monkeys developed lymph node atrophy and bone marrow hypoplasia. Total proteins and immunoglobulin production were normal. This report provides evidence that SRV-2, as well as other type D retroviruses, causes SAIDS in macaque species.     

Polymerase chain reaction detection of type D simian retrovirus proviral DNA from infected macaques

A simple polymerase chain reaction (PCR) approach was developed for detection of Type D simian retrovirus (SRV) serogroup 2 proviral DNA using peripheral blood lymphocytes (PBLs) obtained from infected macaques. PCR primer pairs were developed against serogroup 2 envelope (env) gene sequence, and fidelity of PCR fragment amplification was determined using molecularly cloned SRV serogroup 2 (D2/RHE/OR) DNA, and genomic DNA from Raji cells independently infected with different SRV serogroups. One primer pair exhibiting high fidelity was then utilized for PCR detection of serogroup 2 proviral DNA from PBLs, and from cells sorted into immune cell subpopulations by fluorescent-activated cell sorting (FACS). Enυ PCR fragments were readily detected from as few as 10⁴ PBLs or immune cell subpopulations. In addition, highly specific PCR primers against serogroups 1 and 3 were utilized to detect proviral DNA from Raji cells infected with SRV serogroups. In all cases, primers designed to amplify serogroups 1,2, and 3 proviral DNA were specific for their intended serogroup. This primer information and development of a PCR approach for detection of specific SRV proviral DNA will be of potential utility as a rapid surveillance tool in monitoring type D simian retrovirus infection within Asian macaque colonies.     

A novel type D simian retrovirus naturally infecting the Indian Hanuman langur (Semnopithecus entellus)

As a simian species, the langurs are not known to harbor simian retroviruses, except for one report on a simian Type D endogenous retrovirus from the spectacled langur (Trachypithecus obscurus) from Malaysia. The present report describes for the first time natural infection of the common Hanuman langur (Semnopithecus entellus) from India by a novel simian retrovirus (SRV). The new SRV is phylogenetically related to but distinct from the three molecularly characterized serotypes, SRV 1-3, of the five known serotypes of SRVs, based on sequence analyses from the 3'orf and env regions of the viral genome. The novel SRV isolated from the Indian Hanuman langur is provisionally named SRV-6.     

Synthetic peptides of envelope proteins of two different strains of simian AIDS retrovirus (SRV-1 and SRV-2) represent unique antigenic determinants for serum neutralizing antibodies.

There are at least three distinct serotypes of simian type D retrovirus (SRV) which exhibit extensive serological cross-reactivity, but no cross-reactivity exists at the level of serum neutralizing antibodies. Amino acid sequence analysis and hydrophobicity plots of SRV-1 and SRV-2 envelope proteins were compared in order to identify unique potential antigenic determinants to which respective neutralizing antibodies may be directed. Peptides representing residues 147-162 of SRV-1 and 96-102 of SRV-2 were synthesized and assessed for their immunoreactivity. Free peptide inhibition of strain-specific serum (rhesus) neutralizing antibodies to SRV-1 and SRV-2 was demonstrated using the SRV-1 147-162 peptide and the SRV-2 peptide, 96-102, respectively. Inhibition of serum neutralizing activity by these peptides was also strain-specific, showing no cross-inhibition. SRV-1 147-162 conjugated to a protein carrier and cross-linked to Sepharose beads specifically adsorbed neutralizing antibodies from SRV-1 immune rhesus sera. The antibodies eluted from the immunoadsorbent possessed SRV-1 neutralizing activity, but showed no effect on the infectivity of SRV-2. Peptide SRV-1 147-162 also exhibited the capacity to bind specifically with a mouse monoclonal antibody which neutralizes the infectivity of SRV-1. Mice immunized with a recombinant SRV-1 envelope protein or with whole, inactivated SRV-1 produced antibodies which bound the SRV-1 147-162 conjugate, but not the protein carrier itself. Mouse antibodies to the SRV-1 147-162 conjugate exhibited specific binding with both native SRV-1 and with recombinant SRV-1 envelope protein. These findings provide strong evidence that SRV-1 147-162 and SRV-2 96-102 constitute at least two unique antigenic determinants, or parts thereof, which participate in the strain-specific neutralizing antibody response. Moreover, the findings indicate that the SRV-1 neutralizing antibodies produced by monkeys and at least a certain population of neutralizing antibodies produced by mice recognize the same epitope of SRV-1.     

Histologic lesions in cynomolgus monkeys (Macaca fascicularis) naturally infected with simian retrovirus type D: comparison of seropositive, virus-positive, and uninfected animals

Simian retrovirus (SRV) type D is a common cause of simian acquired immunodeficiency syndrome (SAIDS), a usually fatal immunosuppressive disease of macaques. Associated gross and histologic lesions have been well described for the rhesus macaque (Macaca mulatta) in experimental and natural infections. However, morphologic changes induced by this virus at the gross and light-microscopic level have not been documented in the cynomolgus macaque (Macaca fascicularis). In 1996, sporadic cases of anemia, weight loss, and diarrhea were noted in a colony of cynomolgus macaques in our research facility. Out of 28 animals, 24 tested positive for SRV by serology or virus isolation. Animals could mainly be classified into 1 of 2 categories: 1) positive for virus isolation but negative for SRV antibody and 2) negative for virus isolation but antibody positive. During the process of eliminating the virus from the colony, a complete postmortem examination was performed on the 24 infected animals that had to be culled. Twelve SRV-negative animals were available as controls. Minimal to mild follicular lymphoid infiltrates were seen in various organ systems in 75% of the negative animals, compared with moderate to marked infiltrates in 83% of infected animals. Lymphoid infiltrates were more common in the brain, bone marrow, and salivary gland of viremic animals and were rare to nonexistent in seropositive or negative animals. Lymphoid hyperplasia was present in 38% of the infected animals, whereas lymphoid depletion was seen in 47% of the infected animals. Overall, lesions were of greater severity in viremic animals than in virus-negative or seropositive animals. Overall, infected animals had lower, statistically significant hematocrit and lymphocyte values. Viremic animals had significantly lower hematocrit, white blood cell, lymphocyte, and neutrophil values than did controls. Only 1 out of 24 infected animals had clinical signs that were consistent with the definition of SAIDS, and none had evidence of opportunistic infections. Lesions were similar to those already reported in other species of macaques, but the absence of severe illness that was consistent with SAIDS in most viremic animals suggests that there may be a different manifestation of disease in the cynomolgus.     

Malaria infection induces rapid elevation of the soluble Fas ligand level in serum and subsequent T lymphocytopenia: possible factors responsible for the differences in susceptibility of two species of Macaca monkeys to Plasmodium coatneyi infection

The intraerythrocytic stage of the simian malaria parasite Plasmodium coatneyi (CDC strain) was intravenously inoculated into two species of macaques with different susceptibilities to infection with this parasite, including four Japanese macaques (Macaca fuscata) and three cynomolgus macaques (M. fascicularis). The Japanese macaques infected with P. coatneyi developed severe clinical manifestations similar to those of severe human malaria and eventually became moribund, while the infected cynomolgus macaques, natural hosts of the parasite, exhibited no severe manifestation of disease except anemia and finally recovered from the infection. In the infected Japanese macaques, peripheral CD4(+) and CD8(+) T-cell populations were markedly decreased and fragmentation of chromosomal DNA in peripheral blood mononuclear cells was detected during the terminal period of infection, suggesting that apoptotic cell death was responsible at least in part for the T lymphocytopenia. Furthermore, soluble Fas ligand levels in sera of the infected Japanese macaques increased gradually to a markedly high level of 28. 83 +/- 10.56 pg/ml (n = 4) when the animals became moribund. On the other hand, none of the infected cynomolgus monkeys exhibited either T lymphocytopenia or elevated soluble Fas ligand level. These findings suggest that differences in immune response between the two species of macaque tested accounted for the contrasting outcomes after infection with the same isolate of malarial parasite, and in particular that a profound T lymphocytopenia due to Fas-derived apoptosis played a role in the fatal course of malaria in the infected Japanese macaques.     

Immunobiological properties of a recombinant simian retrovirus-1 envelope protein and a neutralizing monoclonal antibody directed against it.

We previously reported that an area encompassing amino acids 147-162 of the envelope region of the simian (type D) retrovirus serotype 1 (SRV-1) constitutes an antigenic site for the binding of murine and rhesus neutralizing antibodies. Neutralizing antibodies to SRV-2 are directed to a different area, encompassing residues 96-102 of SRV-2. This paper presents data on the activity of an SRV-1 recombinant envelope protein (rEP) and of monoclonal hybridoma cell line, C11B8, produced from murine spleen cells immunized with SRV-1 rEP. Purified monoclonal antibodies from C11B8 bind to the SRV-1 rEP and to both SRV-1 and SRV-2. However, the monoclonal antibody exhibits strain specificity in the capacity to neutralize SRV-1 infection in vitro. Thus, C11B8 neutralizes SRV-1 infection but fails to neutralize four other known serotypes of the virus. C11B8 also binds to an SRV-1 synthetic peptide representing residues 142-167, which encompasses the previously defined antigenic site of recognition for neutralizing antibodies to SRV-1. This paper also contains evidence that the SRV-1 rEP construct binds the site for SRV-1 attachment to the cell receptor. This is indicated by the ability of SRV-1 rEP to compete with SRV-1 (but not with SRV-2) and inhibit its infectivity in vitro. In addition, SRV-1 rEP inhibits the neutralizing activity of C11B8 against SRV-1 infection in vitro. SRV-1 rEP has no inhibitory effect on rhesus neutralizing antibodies to SRV-2. Taken together, the above findings indicate that immunity conferred at the level of neutralizing antibodies during SRV infection is strain-specific and involves the recognition of envelope sequences unique to each strain.     

白介素17 受体mRNA 在恒河猴中的分布

目的:阐述白介素17 受体(IL-17R)mRNA 在恒河猴不同组织中的分布与丰度。方法:建立实时荧光定量PCR 方法,检测免疫、消化和生殖等系统的各组织中IL-17RA mRNA 的水平,并检测了肠道IL鄄17RC mRNA 的水平及恒河猴、非洲绿猴和食蟹猴PBMC 中IL-17RA 和IL-17RC mRNA 的表达水平。结果:IL-17RA mRNA 在所有检测过的组织中均有表达,但不同器官系统的表达水平存在显著差异(P<0.05);IL-17RC mRNA 在大肠中的表达水平高于小肠;恒河猴PBMC 中IL-17RA mRNA 水平显著高于非洲绿猴(5 倍)和食蟹猴(3 倍),但PBMC 中IL-17RC mRNA 水平在3 种动物中均低于检测下限。结论:IL-17RA 广泛分布于恒河猴各种组织中,表达水平存在明显的组织差异和种属差异。     

Rhesus and pig-tailed macaque parvoviruses: identification of two new members of the erythrovirus genus in monkeys

We have previously reported the identification of a novel simian parvovirus in cynomolgus monkeys, which causes severe anemia in immunosuppressed cynomolgus monkeys and is currently being studied as an animal model for human B19 infection. We now report two similar outbreaks of anemia in rhesus and pig-tailed macaques associated with two distinct but similar simian parvoviruses (pig-tailed macaque and rhesus parvovirus). Both viruses have been cloned and over 5000 nucleotides sequenced from each virus. The viruses show marked similarities to other members of the Erythrovirus genus in the Parvoviridae family.     

Characterization of T cell epitopes on the envelope glycoprotein of simian retrovirus 1 and 2 (SRV-1 and SRV-2) in several mouse strains.

Various mouse strains were immunized with either SRV-1 or SRV-2 virus adsorbed on alum. Seven to 14 days later spleen cells were removed, and spleen cells were cultured with varying amounts of SRV-1 virus and SRV-2 virus, or varying amounts of selected SRV-1 and SRV-2 synthetic envelope peptides to determine their ability to initiate T cell proliferative responses. Our studies demonstrated that all mouse strains tested gave strong proliferative responses with SRV-2 virus. In contrast, SRV-1 virus induced T cell proliferative responses only in H-2k mouse strains. This apparent major histocompatibility complex (MHC)-restriction of SRV-1 virus-induced T cell proliferation correlates with the increased pathogenicity of SRV-1 virus in rhesus monkeys. The SRV envelope peptide 233-249 which is shared by both SRV-1 and SRV-2 virus initiates strong proliferative responses in both SRV-1 and SRV-2 virus immunized mice. The SRV-2 envelope peptide 96-102 initiates significant proliferative responses in SRV-2 immunized mice, and constitutes both a T and B cell epitope. The SRV-2 envelope peptide 127-152 has a 70% homology with the C-terminal region of SRV-1 peptide 142-167. The ability of SRV-2 peptide 127-152 to initiate T cell proliferation in SRV-1 virus immunized mice and the failure of the SRV-1 peptide 142-162 to initiate proliferation suggests that the region encompassing residues 160-167 must represent a T cell epitope in mice immunized with SRV-1 virus.