Regulation of the visna virus long terminal repeat in macrophages involves cellular factors that bind sequences containing AP-1 sites

Multiple, Independent T Cell Lymphomas Arising in an Experimentally FIV-Infected Cat during the Terminal Stage of Infection

Our laboratory has serially reported on the virologic and immunopathologic features of a cohort of experimental feline immunodeficiency virus (FIV)-infected cats for more than eight years. At 8.09 years post infection (PI), one of these animals entered the terminal stage of infection, characterized by undulating hyperthermia, progressive anorexia, weight loss, and pancytopenia; the animal was not responsive to therapeutic interventions, necessitating euthanasia six weeks later (8.20 years PI). Subsequent analyses indicated that neoplastic lymphocytes infiltrated multiple cervical lymph nodes and a band-like region of the mucosal lamina propria within a segment of the intestine. Immunohistochemistry and T cell clonality testing determined that the nodal and intestinal lesions were independently arising from CD3 T cell lymphomas. In-situ RNA hybridization studies indicated that diffuse neoplastic lymphocytes from the cervical lymph node contained abundant viral nucleic acid, while viral nucleic acid was not detectable in lymphocytes from the intestinal lymphoma lesion. The proviral long terminal repeat (LTR) was amplified and sequenced from multiple anatomic sites, and a common clone containing a single nucleotide polymorphism was determined to be defective in response to phorbol myristate acetate (PMA)-mediated promoter activation in a reporter gene assay. This assay revealed a previously unidentified PMA response element within the FIV U3 region 3’ to the TATA box. The possible implications of these results on FIV-lymphoma pathogenesis are discussed.

Clinical Relevance of Total HIV DNA in Peripheral Blood Mononuclear Cell Compartments as a Biomarker of HIV-Associated Neurocognitive Disorders (HAND)

The pathogenesis of HIV-associated neurocognitive disorders is complex and multifactorial. It is hypothesized that the critical events initiating this condition occur outside the brain, particularly in the peripheral blood. Diagnoses of HIV-induced neurocognitive disorders largely rely on neuropsychometric assessments, which are not precise. Total HIV DNA in the peripheral blood mononuclear cells (PBMCs), quantified by PCR, correlate with disease progression, which is a promising biomarker to predict HAND. Numerous PCR assays for HIV DNA in cell compartments are prone to variation due to the lack of standardization and, therefore, their utility in predicting HAND produced different outcomes. This review evaluates the clinical relevance of total HIV DNA in circulating mononuclear cells using different published quantitative PCR (qPCR) protocols. The rationale is to shed light on the most appropriate assays and sample types used to accurately quantify HIV DNA load, which predicts severity of neurocognitive impairment. The role of monocytes as a vehicle for trafficking HIV into the CNS makes it the most suitable sample for determining a HAND associated reservoir. Studies have also shown significant associations between monocyte HIV DNA levels with markers of neurodamage. However, qPCR assays using PBMCs are cheaper and available commercially, thus could be beneficial in clinical settings. There is need, however, to standardise DNA extraction, normalisation and limit of detection.

Detailed analysis of the promoter activity of an attenuated lentivirus

In spite of an eradication campaign that eliminated clinical cases of caprine arthritis encephalitis virus-induced arthritis in the Swiss goat population, seroconversions are still observed. In the affected flocks, viruses belonging mainly to the small ruminant lentivirus A4 subtype are regularly isolated. These viruses are considered attenuated, except in the mammary gland, where high viral loads and histopathological lesions have been observed. We previously characterized and sequenced such field isolates, detecting several potentially attenuating mutations in their LTR. Here we present a detailed analysis of the promoter activity of these genetic elements, which was comparable to those of virulent isolates. An AP-1 binding site was shown to be crucial for promoter activity in reporter gene assays and also in the context of a replicating molecular clone. Other sites, such as AML(vis) and a conserved E-box, appeared to be less crucial. Analysis of a unique AP-4 site showed a clear discrepancy between results obtained with reporter gene assays and those with mutated viruses. Within the limits of this in vitro study, we did not find evidence pointing to the LTR as the genetic correlate of attenuation for these viruses. Finally, the limited replication of SRLV A4 in mammary cell culture could not explain the suggested mammary tropism. In contrast, and in view of the abundance of macrophages in the mammary gland, it is the striking replication capacity of SRLV A4 in these cells, unaffected by all LTR mutations tested, which may explain the apparent mammary tropism of these viruses.

Generation of a molecular clone of an attenuated lentivirus, a first step in understanding cytopathogenicity and virulence

Small ruminant lentiviruses infect goats and sheep, inducing clinical disease in a minority of infected animals. Following an eradication campaign, clinical cases may disappear in a population. The complete elimination of these lentiviruses is however difficult to achieve and the spreading of less virulent strains often parallels the elimination of their virulent counterparts. Here, we characterized three such strains isolated from a flock in the post-eradication phase. We completely sequenced their genomes, showing that one of the isolates was most probably the product of a recombination event between the other two viruses. By comparing the sequences of these isolates with those of virulent strains, we found evidence that particular LTR mutations may explain their attenuated phenotype. Finally, we constructed an infectious molecular clone representative of these viruses, analyzing its replication characteristics in different target cells. This clone will permit us to explore the molecular correlates of cytopathogenicity and virulence.

Expanding possibilities for intervention against small ruminant lentiviruses through genetic marker-assisted selective breeding

Small ruminant lentiviruses include members that infect sheep (ovine lentivirus [OvLV]; also known as ovine progressive pneumonia virus/maedi-visna virus) and goats (caprine arthritis encephalitis virus [CAEV]). Breed differences in seroprevalence and proviral concentration of OvLV had suggested a strong genetic component in susceptibility to infection by OvLV in sheep. A genetic marker test for susceptibility to OvLV has been developed recently based on the TMEM154 gene with validation data from over 2,800 sheep representing nine cohorts. While no single genotype has been shown to have complete resistance to OvLV, consistent association in thousands of sheep from multiple breeds and management conditions highlight a new strategy for intervention by selective breeding. This genetic marker-assisted selection (MAS) has the potential to be a useful addition to existing viral control measures. Further, the discovery of multiple additional genomic regions associated with susceptibility to or control of OvLV suggests that additional genetic marker tests may be developed to extend the reach of MAS in the future. This review will cover the strengths and limitations of existing data from host genetics as an intervention and outline additional questions for future genetic research in sheep, goats, small ruminant lentiviruses, and their host-pathogen interactions.

Diversity of caprine arthritis-encephalitis virus promoters isolated from goat milk and passaged in vitro

Transcriptional regulation in retroviruses resides in the U3 region of the proviral long terminal repeat (LTR). Transcription binding sites (TBS) in the U3 region of proviral sequences derived from the milk of 17 goats infected with caprine arthritis-encephalitis virus (CAEV) were analysed by nested PCR and sequencing. U3 sequences shared a high degree of homology (86-99%) and were closely related to isolates previously ascribed to small ruminant lentivirus subtype B1. Multiple putative AP-1, AP-4, Ets-1, Stat-1 and TATA binding protein (TBP) sites were highly conserved (>85% of isolates), as were single AML(vis), GAS, IRF-1, NFAT and TAS sites. A 10 nucleotide insertion of undetermined relevance was identified in the U3 region of two isolates. To study the stability of TBS within the CAEV U3 region through in vitro passage, milk-derived isolates of CAEV from three infected dams were cultured in goat synovial membrane (GSM) cells; in one isolate the viral U3 region was completely stable during in vitro passage, in a second isolate the viral U3 region accumulated multiple deletions, single nucleotide polymorphisms and insertions, while a third isolate had an intermediate degree of promoter stability. Promoter mutations arising during in vitro passage did not affect most of the conserved putative TBS identified in CAEV.

Important mammalian veterinary viral immunodiseases and their control

This paper offers an overview of important veterinary viral diseases of mammals stemming from aberrant immune response. Diseases reviewed comprise those due to lentiviruses of equine infectious anaemia, visna/maedi and caprine arthritis encephalitis and feline immunodeficiency. Diseases caused by viruses of feline infectious peritonitis, feline leukaemia, canine distemper and aquatic counterparts, Aleutian disease and malignant catarrhal fever. We also consider prospects of immunoprophylaxis for the diseases and briefly other control measures. It should be realised that the outlook for effective vaccines for many of the diseases is remote. This paper describes the current status of vaccine research and the difficulties encountered during their development.

Characterization of new small ruminant lentivirus subtype B3 suggests animal trade within the Mediterranean Basin

Small ruminant lentiviruses (SRLVs) represent a group of viruses infecting sheep and goats worldwide. Despite the high heterogeneity of genotype A strains, which cluster into as many as ten subtypes, genotype B was believed to be less complex and has, so far, been subdivided into only two subtypes. Here, we describe two novel full-length proviral sequences isolated from Sarda sheep in two Italian regions. Genome sequence as well as the main linear epitopes clearly placed this cluster into genotype B. However, owing to long-standing segregation of this sheep breed, the genetic distances that are clearly >15 % with respect to B1 and B2 subtypes suggest the designation of a novel subtype, B3. Moreover the close relationship with a gag sequence obtained from a Turkish sheep adds new evidence to historical data that suggest an anthropochorous dissemination of hosts (small ruminants) and their pathogens (SRLV) during the colonization of the Mediterranean from the Middle East.

A deletion in the R region of long terminal repeats in small ruminant lentiviruses is associated with decreased pathology in the lung

A particular variant of the maedi visna virus (MVV) that although present in blood causes no clinical signs in infected sheep has been described. This variant carries a 13-14 nucleotide deletion in the R region of the proviral long terminal repeats. The hypothesis that this specific deletion may be associated with low pathogenicity has been investigated by comparing the distribution of proviral sequences, the histopathological lesions and the expression of viral proteins in the brain, lungs and udders of sheep naturally infected with viral strains carrying the deletion. Provirus could be demonstrated in most of the tissues examined from sheep infected with either type of virus, and the tissue-derived virus carried the typical deletion in the study flock animals. Histopathological analysis revealed that the lungs were significantly less affected in the animals infected with virus carrying the deletion. Concomitantly, viral expression was significantly reduced in the lungs of these animals. The findings suggest that the reduced pathogenicity of MVV with the specific deletion in the R region is not due to a restriction in the availability of specific tissues to infection, but is associated with a reduced capacity for viral expression in the lungs.

TNFα and GM-CSF-induced activation of the CAEV promoter is independent of AP-1

Caprine arthritis encephalitis virus transcription is under the control of the viral promoter within the long terminal repeat. Previous studies with the closely related maedi visna lentivirus have indicated that viral transcription is dependent upon the AP-1 transcription factor. Other studies have indicated a potential role for the cytokines TNFalpha and GM-CSF in CAEV pathogenesis by increasing viral loads in infected tissues. The hypotheses that AP-1 transcription factors are necessary for transcriptional activation of the CAEV promoter and that CAEV transcriptional activation results from treatment with the cytokines GM-CSF and TNFalpha were tested with a stably transduced U937 cell line. Here, we found that TNFalpha and GM-CSF activated CAEV transcription in U937 cells. However, this activation effect was not blocked by SP600125, an inhibitor of Jun N-terminal kinase. SP600125 effectively prevented Jun phosphorylation in cells subsequently treated with cytokines. The cytokines TNFalpha and GM-CSF therefore activate CAEV transcription, and this effect occurs independently of AP-1. A set of progressive deletion mutants was utilized to show that TNFalpha-induced expression depends on an element or elements within the U3 70-bp repeat.

A novel deletion in the LTR region of a Greek small ruminant lentivirus may be associated with low pathogenicity

Greek small ruminant lentivirus (SRLV) strains remain relatively uncharacterized at the molecular level, despite the fact that lentiviral diseases of small ruminants are known to be widespread in the country. In the present study, we investigated the sequence diversity of the LTR region in Greek SRLV strains from sheep with and without disease symptoms, since sequence differences within this genomic area have been shown to lead to SRLVs with distinct replication rates. The AP-4 and AML (vis) motifs and the TATA-box were highly conserved among Greek strains, whereas the two AP-1 sites exhibited some substitutions. Pairwise comparisons with reference strains revealed that Greek LTR sequences were closer to the ovine strains (25.7% average divergence) rather than the caprine strain CAEV (59.1% average divergence). The most striking difference observed between the two groups of animals was a 13-14 nucleotide deletion in the strains obtained from the asymptomatic sheep. The deletion was located within the R region of LTR, which was also found to be much less homologous (39.6% average divergence) than the U3 and U5. Taken together, our data suggest that the R region of LTR may be involved in virus transcriptional activation. Furthermore, a specific deletion within this region may, at least in part, be associated with low pathogenicity of some SRLV strains.

Restricted species tropism of maedi-visna virus strain EV-1 is not due to limited receptor distribution

The distribution of receptors for maedi-visna virus (MVV) was studied using co-cultivation assays for virus fusion and PCR-based assays to detect the formation of virus-specific reverse transcription products after virus entry. Receptors were present on cell lines from human, monkey, mouse, chicken, quail, hamster and ovine sources. Thus, the distribution of the receptor for MVV is more similar to that of the amphotropic type C retroviruses than to that of other lentiviruses. The receptor was sensitive to proteolysis by papain, but was resistant to trypsin. Chinese hamster ovary (CHO) and lung cells (V79 TOR) did not express functional receptors for MVV. The receptor was mapped to either chromosome 2 or 4 of the mouse using somatic cell hybrids. This allowed several candidates (e.g. MHC-II, CXCR4) that have been proposed for the MVV receptor to be excluded.

LuSIV cells: a reporter cell line for the detection and quantitation of a single cycle of HIV and SIV replication

A single cycle of viral replication is the time required for a virus to enter the host cell, replicate its genome, and produce infectious progeny virions. The primate lentiviruses, human immunodeficiency virus (HIV) and simian immunodeficiency virus (SIV), require on average 24 h to complete one cycle of replication. We have now developed and characterized a reporter assay system in CEMx174 cells for the quantitative measurement of HIV/SIV infection within a single replication cycle. The SIV(mac)239 LTR (-225 --> +149) was cloned upstream of the firefly luciferase reporter gene and this reporter plasmid is maintained in CEMx174 cells under stable selection. This cell line, designated LuSIV, is highly sensitive to infection by primary and laboratory strains of HIV/SIV, resulting in Tat-mediated expression of luciferase, which correlates with viral infectivity. Furthermore, manipulation of LuSIV cells for the detection of luciferase activity is easy to perform and requires a minimal amount of time as compared to current HIV/SIV detection systems. The LuSIV system is a powerful tool for the analysis of HIV/SIV infection that provides a unique assay system that can detect virus replication prior to 24 h and does not require virus to spread from cell to cell. Thus these cells can be used for the study of replication-deficient viruses and the high throughput screening of antivirals, or other inhibitors of infection.

The long terminal repeat is a determinant of cell tropism of maedi-visna virus

Maedi-visna virus (MVV) is a lentivirus of sheep, mainly affecting the lungs and the central nervous system. Long terminal repeat (LTR) sequence variability is common in tissue culture-derived isolates of MVV as well as those of other lentiviruses. The role of this sequence variation in MVV replication has not been explored. PCR amplification of the LTRs of an MVV isolate revealed two product sizes, the larger containing a 53 bp duplication. PCR products containing the two size variants of the LTRs were cloned into an infectious molecular clone of MVV and the resulting chimeric viruses were tested for growth in various cell types. The chimeric virus containing only one copy of the 53 bp sequence was found to grow more slowly in sheep choroid plexus cells, sheep fibroblasts and sheep synovial cells than the virus with the 53 bp duplication. Both viruses grew equally well in macrophages. These results indicate that the LTRs determined the extended cell tropism of MVV.

Differential replication of ovine lentivirus in endothelial cells cultured from different tissues

Blood-brain barrier dysfunction has been postulated to be important in the pathogenesis of HIV dementia. This study used an in vitro model of the blood-brain barrier to determine the effects of ovine lentivirus (OvLV) infection on endothelial cells. The replication of two American OvLV isolates and two lcelandic OvLV isolates in pure cultures of endothelial cells isolated from brain was compared to replication in endothelial cells from adipose, lung, and aorta. Inoculation with the two American isolates resulted in 100 times greater reverse transcriptase (RT) activity in supernatant of the microvascular endothelial cells (brain, lung, and adipose) than in the macrovascular endothelial cells (aorta). Conversely, inoculation with the two lcelandic isolates resulted in 100 times higher RT activity in aortic, lung, and adipose endothelial cells than in the brain endothelial cells. Transmission electron microscopy of the brain capillary endothelial cells infected with the American isolates revealed polarized viral budding from the lateral cell membrane and a loss of tight junctions. Replication of OvLV in brain capillary endothelial cells could play a role in the pathogenesis of lentiviral encephalitis by altering blood-brain barrier integrity.

Regulation of the long terminal repeat in visna virus by a transcription factor related to the AML/PEBP2/CBF superfamily

The long terminal repeats of maedi visna virus strain 1514 contain a consensus AP-1 binding site which has been shown to be important in controlling virus transcription. However, this consensus site is absent in strain EV-1. Here, we have compared the ability of oligonucleotides corresponding to LTR sequences from EV-1 with those from 1514 to bind transcription factors in competitive gel retardation assays and activate reporter gene expression. The experiments demonstrated no observable binding of AP-1 to the EV-1-derived sequences and significant differences in the abilities of the 1514 and EV-1 sequences to activate transcription. However, both viral sequences interacted with a second, previously undetected, transcription factor. This factor gave specific gel shifts which were competed by an oligonucleotide containing the consensus sequence for the AML/PEBP2/CBF family of transcriptional factors, but not by control AP-1 or OCT-1 oligonucleotides. The factor was therefore denoted AML (vis). A second AML (vis) site, noted upstream of the TATA box proximal AP-1 site, gave single shifts which were competed by the downstream AML (vis) oligonucleotide. Both sites were functional in transfection assays. In gel shift retardation assays, polyclonal antisera directed against known runt domain proteins were able to supershift part of the AML (vis) binding activity in nuclear extracts from physiologically relevant cell types. The results thus suggest that the AML (vis) binding factor belongs to the AML/PEBP2/CBF family of transcription factors and may be important in controlling virus replication in these and other strains of ruminant lentiviruses.

Retroviruses and bone diseases

In 1980, retroviruses were shown to be pathogenic to humans, and experimentation on animals involving retroviruses as causal agents of tumors and degenerative diseases of bone, brain, and lung gained interest. Osteopetrosis, which can be either inherited in rodents or retrovirally induced in cats, is exemplary. Because of replication cycle, retroviruses can be propagated not only as infectious agents but also as cellular genes. If a retroviral infection occurs in germ line cells, the viral genes, which must integrate in the host's DNA, can be passed on to the progeny and inherited as Mendelian characteristics. Therefore, a retroviral etiology could account for diseases that present either as sporadic (infectious) or familial (inherited), although they may be similar in their clinical manifestations. This approach led to the finding of 2 new human retroviruses: 1 in a patient who had sporadic benign osteopetrosis, and the other in a patient who had sporadic paraarticular osteoma. In both patients, the retrovirus was isolated from mononuclear blood cells, not from bone cells, because of the links between bone and the immune system. A systematic search for retroviruses in patients who have sporadic bone disease, which also may appear as inherited disease, has yet to be performed. Patients with sporadic disease could be managed by antiretroviral agents such as Zidovudin.

Differential effects of ras and jun family members on complex retrovirus promoter activities

Infection by complex retroviruses such as Visna-maedi, HIV1, HTLV-I and HFV is generally not followed by particle production, but rather by a more or less prolonged latency period. Knowledge of the mechanisms triggering an infectious cycle from the latent provirus(es) is of great importance in comprehending the appearance of the disease. It is currently admitted that cellular factors regulate viral expression. In this paper, we report the ability of ras, c-jun, jun-B and jun-D to diversely stimulate the LTR promoter activity of these retroviruses. Transient transfection assays using a luciferase reporter gene linked to LTR show that the Visna-maedi virus LTR, despite high intrinsic activity, is stimulated by Ha-ras and c-jun. The HTLV-I and HIV1 LTR were identically stimulated by ras, but differently by c-jun. In contrast, jun-B and jun-D were weaker activators, since they respectively stimulated only HTLV-I LTR and HIV1 LTR. HFV LTR remains unresponsive to either of these factors.

The genome of feline immunodeficiency virus

Feline immunodeficiency virus (FIV) is a member of the genus Lentivirus of the family Retroviridae. FIV can infect T lymphocytes and monocytes/macrophages in vitro and in vivo, and causes an acquired immunodeficiency syndrome-like disease in cats. Several isolates of FIV from geographically distant countries have been molecularly cloned. There is considerable heterogeneity especially in Env gene among the FIV isolates and they can be divided into two or more subgroups. Like other lentiviruses, FIV has a complex genome structure. Gag gene encodes matrix, capsid and nucleocapsid proteins, and Pol gene encodes protease, reverse transcriptase, dUTPase and integrase. The dUTPase is not present in the primate lentiviruses but present in the non-primate lentiviruses. Env gene encodes surface and transmembrane envelope glycoproteins. In addition to the structural and enzymatic proteins, at least three more genes (Vif, ORF A, Rev) are present in FIV. Vif is related to the infectivity of the cell-free viruses. Rev functions in the stability and transport of incompletely spliced viral RNAs from the nucleus to cytoplasm and is indispensable for virus replication. Although the Tat protein of the primate lentiviruses is essential for virus replication, ORF A (putative Tat gene) of FIV is not essential for virus replication in established feline T lymphoblastoid cell lines. However, the ORF A gene product is related to the efficient replication of the virus in primary peripheral blood lymphocytes. In the long terminal repeat (LTR) of FIV, there are many putative binding sites for enhancer/promoter proteins. Among these binding sites, the putative AP-1 site is important for basal promoter activity of the LTR and responsible for the T cell activation signal through protein kinase C, however the site is not required for the virus replication in established feline T lymphoblastoid cell lines. Comparative study of the molecular biology of lentiviruses revealed that the genome structure, splicing pattern and functional enhancer protein-binding sites of FIV are more similar to those of the ruminant lentiviruses than those of the primate lentiviruses.

Involvement of FOS and JUN in the activation of visna virus gene expression in macrophages through an AP-1 site in the viral LTR

Gene expression of visna virus is highly restricted in monocytes, but is induced when monocytes differentiate into macrophages. A previous study on differential regulation of visna virus gene expression revealed that a specific AP-1 site in the long terminal repeat of the viral DNA is required for phorbol-ester-induced gene expression in macrophages (Gabuzda, Hess, Small, and Clements, Mol. Cell. Biol., 9, 2728-2733). In the present investigation, we examined the association of two DNA binding proteins, the proto-oncogene proteins FOS and JUN, with this AP-1 site in the visna virus LTR. We demonstrated that the concentrations of these two proteins and their mRNAs increased in U937 cells after phorbol ester induction. Furthermore, the binding of cellular proteins from the U937 nuclear extracts to this AP-1 site was significantly decreased in the presence of antibodies to JUN and FOS. In vitro-translated JUN protein also binds to this AP-1 sequence, and this binding is enhanced by the FOS protein. These results indicate that JUN and FOS are directly involved in the differential regulation of visna virus gene expression.

Regulation of gene expression directed by the long terminal repeat of the feline immunodeficiency virus

The long terminal repeat (LTR) of a retrovirus contains sequence elements that constitute a promoter for controlling viral gene expression in infected cells. We have examined regulation of LTR-directed gene expression in feline immunodeficiency virus (FIV), a T-lymphocytopathic lentivirus associated with a fatal AIDS-like disease in domestic cats. Two independent virus isolates, designated FIV-Petaluma and FIV-PPR, have been molecularly cloned and show greater than 85% sequence homology. Both clones (termed pF34 and pPPR) produce infectious virus after transfection of permissive feline cells. Basal promoter activity of the LTRs was measured in various cell lines in transient expression assays using plasmids containing the viral LTR linked to the bacterial chloramphenicol acetyltransferase gene. Both LTRs were strong promoters in several cell lines, although in some cell lines the pF34 LTR had four- to fivefold higher basal activity than the pPPR LTR. FIV LTR mutations affecting the first AP4 site, AP1 site, ATF site, or NF-kappa B site resulted in decreased basal activity of the FIV promoter. Mutational analysis also revealed a negative regulatory element. In cotransfection experiments, both pF34 proviral DNA and pPPR proviral DNA appeared to transactivate either the pF34 LTR or the pPPR LTR; however, levels of transactivation were very low. Cotransfection of both LTRs with FIV subgenomic clones containing various viral open reading frames resulted in low level or no transactivation. The LTRs of both FIV clones responded to cell activation signals in human T-lymphoid cells (Jurkat) treated with phytohemagglutinin and phorbol-12-myristate-13-acetate. Promoter function of both FIV LTRs was also enhanced in cells treated with either forskolin, an inducer of intracellular cyclic-AMP (c-AMP), or dibutyryl c-AMP. Analysis of site-specific mutants showed that a potential AP1 site in the U3 domain of the LTR was required for T-cell activation responses mediated by protein kinase C, whereas a putative ATF site was the target for c-AMP-induced responses mediated by protein kinase A. These studies revealed that cellular transcription factors play a significant role in regulation of FIV gene expression.

Induction of the HTLV-I LTR by Jun occurs through the Tax-responsive 21-bp elements

The HTLV-I LTR is known to be induced by a variety of cellular signals. Tax protein is one potent viral trans-activator of LTR-directed transcription. We demonstrate here that Jun is another transcription factor that can strongly modulate the activity of this LTR. Using deletion and competition studies, the minimal portion of the LTR for Jun activation was found to coincide with the Tax-responsive 21-bp elements. In binding experiments, nuclear factors that bound to the HTLV-I 21-bp sequence were competed by an excess of AP-1 motif oligonucleotide. Although the Tax-responsive elements do not contain a strictly conserved AP-1 motif, these findings suggest that they function as AP-1 sites. We found, however, that in cells depleted for AP-1 activity (F9 teratocarcinoma), Tax activation of the HTLV-I LTR was maintained. Thus while Jun/AP-1 may be involved in the basal expression of the HTLV-I LTR, it may not be essential for Tax-mediated activation.

Differentiation of the U937 macrophage cell line removes an early block of HSV-1 infection

In the human macrophage-like cell line U937, which is resistant to infection with herpes simplex virus type 1 (HSV-1), it was previously shown that resistance can be overcome by inducing differentiation of the cells by treatment with phorbol 12-myristate 13-acetate (PMA). The present data show that differentiation, and not PMA treatment alone, enabled HSV-1 replication, because vitamin D3 and mezerein were also able to cause U937 cells to differentiate to a state permissive for HSV-1 infection. Additionally, a portion of the undifferentiated cells underwent a productive infection when treated with PMA 2 days after infection, suggesting persistence of HSV-1 in these cells. The nonpermissiveness of the undifferentiated cells was further defined. Resistance did not involve differences in virus uptake, because the amounts of viral DNA in the infected cells and nuclei of differentiated and undifferentiated U937 cells were not significantly different early after infection. However, only very low levels of RNA for HSV-1 immediate-early, early, and late genes could be detected in the undifferentiated U937 cells by Northern blot analysis compared with the differentiated U937 cells. These data suggest that the primary block in HSV-1 replication in undifferentiated U937 cells occurred after transport of the viral DNA to the cell nucleus but prior to steady-state accumulation of viral RNA for immediate-early genes.

Human and ovine lentiviral infections compared

Maedi-visna virus (MVV) of sheep was the first lentivirus to be isolated. The genomic organization of MVV is very similar to that of human immunodeficiency virus (HIV) with several genes regulating the expression of the viral genome. Viral replication is severely restricted in the host and some cells apparently contain the genetic information in a DNA provirus form with little or no expression of viral antigens. This seems to be a major factor in causing the "slowness" of lentiviral infections and the persistence of the virus in the host since the immune system may not recognize the provirus-containing cells. The target cells for HIV and MVV are similar although T4 lymphocytes are not specifically destroyed in maedi-visna. There are also certain similarities in the pathological changes in both diseases, both in the central nervous system, the lungs and the lymphatic system. Although the severe final immunodeficiency state characteristic of AIDS has not been observed in maedi-visna, the basic biological features of the MVV and its interaction with host cells are so similar to HIV infection, that we consider ovine maedi-visna useful animal model for the human lentivirus infections.

Human immunodeficiency virus type 1 infection of U937 cells promotes cell differentiation and a new pathway of viral assembly

The differentiation of U937 monoblastoid cells after human immunodeficiency virus type 1 (HIV-1) infection was studied using the following approaches: reverse transcriptase activity measurement, immunofluorescence labeling, and electron microscopy. For comparison, uninfected U937 cells were induced to differentiate from monocyte to macrophage by phorbol 12-myristate 13-acetate (PMA) or retinoic acid (RA) treatment. Both infected and drug-treated cells showed important and similar ultrastructural cell modifications, with a phenotype that decreased in monocyte specificity and increased in that of macrophages. When U937 cells were induced to differentiate upon HIV-1 infection, a very different pathway of viral production was observed. Production and accumulation of the virus in a vacuolar compartment of intracytoplasmic origin and escape to the antiviral lysosomal activity could explain virus persistence. This makes the cell system a good model with which to study the relationship between HIV-1 production and cell differentiation.

Nucleotide sequence and transcriptional analysis of molecular clones of CAEV which generate infectious virus

The lentivirus caprine arthritis-encephalitis virus (CAEV) is closely related by nucleotide sequence homology to visna virus and other sheep lentiviruses and shows less similarity to the other animal and human lentiviruses. The genomic organization of CAEV is very similar to that of visna virus and the South African ovine maedi visna virus (SA-OMVV) as well as to those of other primate lentiviruses. The CAEV genome includes the small open reading frames (ORF) between pol and env which are the hallmarks of the lentivirus genomes. The most striking difference in the organization of CAEV is in the env gene. The Env polyproteins of visna virus and the related SA-OMVV contain 20 amino acids between the translational start and the signal peptide not present in CAEV. In addition to nucleotide sequence analysis, the transcriptional products of CAEV were determined by Northern analysis. The viral mRNA present in cells transfected with the infectious clone reveal a pattern characteristic of the mRNAs observed in other lentivirus infections. The putative tat ORF of CAEV could be identified by genomic location and amino acid homology to the visna virus tat gene. However, the CAEV rev gene could not be identified in a similar fashion. Thus, to determine the location of the rev ORF cDNA clones were obtained by PCR amplification of the mRNA from infected cells. To determine if a Rev response element was contained in the CAEV genome, secondary structural analysis of the viral RNA was performed. A stable stem loop structure which is similar in location, stability, and configuration to that determined for the Rev response element of HIV was found.

Immunopathology of lentiviral infections in ungulate animals

The immunopathogenesis of lentiviral lesions in sheep and goats requires continuous replication of the virus in tissues of the animal. This entails escape from various defense mechanisms of the host. Viral expression occurs mainly in tissue-specific macrophage populations and viral proteins produced by the cells induce and combine with antibodies to form immune complexes. These may be pathogenic locally. Infected macrophages also present lentiviral antigens to T lymphocytes and this results in a cascade of cellular responses including proliferation and accumulation of CD8 cells. Cytokines including interferon(s) are produced by lymphocytes and these enhance the antigen-presenting capacity of the macrophages. These lymphoproliferative cellular responses vary from those in human immunodeficiency virus- and simian immunodeficiency virus-infected hosts, mainly because CD4 cells of sheep and goats are not killed by the viruses. These cells, therefore, respond immunologically to viral antigens and this leads to active-chronic inflammation.

Lentiviruses are etiological agents of chronic diseases in animals and acquired immunodeficiency syndrome in humans

Lentiviruses are species-specific, exogenously transmitted retroviruses that have a unique ability to replicate continuously but at a restricted rate in host tissues. This property is thought to be related to the retroviral nature of the replication process (RNA to DNA to RNA) and to the ability of the viruses to do this in cells of the macrophage lineage. The viral genomes are expressed only in certain populations of macrophages and this is dependent on a number of interactive factors including the genus of the host, the age of the host, maturation/differentiation factors in macrophages, the strain of virus and regulatory factors in the virus and the regulatory factors in the virus and the macrophages. Macrophages permissive for virus replication are found in specific tissues and virus replication in the cells causes development of lesions in the particular tissues. The nature of the lesions varies from virus induced necrosis to immunopathology to possible toxic infects of monokines produced by the infected macrophages. Cats and primates have further complicating diseases caused by the remarkable sensitivity of their helper T lymphocytes to infection with their lentiviruses. Elimination of these cells leads to onset of various local and systemic diseases caused by opportunistic agents. Whereas equidae and small ruminant animals develop diseases related to infection in macrophage populations, felines, macaques and humans develop diseases related to both infection in their macrophages and elimination of their T lymphocytes.