Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0002871 (anemia)
 52,094 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In vivo, equine infectious anemia virus (EIAV) replicates in tissues rich in macrophages, and it is widely believed that the tissue macrophage is the principal, if not sole, cell within the host that replicates virus. No viral replication has been detected in circulating peripheral blood monocytes. However, proviral DNA can be detected in these cells, and monocytes may serve as a reservoir for the virus. In this study, an in vitro model was developed to clarify the role of monocyte maturation in regulating EIAV expression. Freshly isolated, nonadherent equine peripheral blood monocytes were infected with a macrophage-tropic strain of EIAV, and expression of EIAV was monitored in cells held as nonadherent monocytes and cells allowed to adhere and differentiate into macrophages. A 2- to 3-day delay in viral antigen expression was observed in the nonadherent cells. This restriction of viral expression in monocytes was supported by nuclear run-on studies demonstrating that on day 5 postinfection, the level of actively transcribed viral messages was 4.7-fold lower in monocyte cultures than in macrophage cultures. Electrophoretic mobility shift assays identified three regions of the U3 enhancer that interacted with nuclear extracts from normal equine macrophages. Each region contained the core binding motif of a family of transcription factors that includes the product of the proto-oncogene ets. Antibodies to the Ets family member PU.1 caused a supershifting of retarded bands in an electrophoretic mobility shift assay. Transfection studies of ets motif mutants demonstrated that the U3 ets sites were important in the regulation of EIAV transcription in macrophages. Interactions between the ets motif and nuclear extracts from freshly isolated, nonadherent monocytes, macrophages adherent for 1 or 2 days, or macrophages adherent for 5 days gave different patterns of retarded bands, although the binding specificities were similar with all three extracts. The different complexes formed by monocyte and macrophage nuclear extracts may explain the enhanced ability of mature macrophages to support EIAV expression.
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PMID:Monocyte maturation controls expression of equine infectious anemia virus. 808 67

The enhancer unit present in the retrovirus equine infectious anemia virus (EIAV) was previously shown to contain binding sites for proteins belonging to MDBP, PEA2, AP-1, and ets families. The EIAV ets motif matches the consensus sequence for both PEA3- and PU.1-binding sites. Here, we show by gel shift analysis that PU.1, present in nuclear extracts from monocyte and B-lymphocyte cell lines, binds to oligonucleotides containing the EIAV ets element. HeLa cells transiently transfected with a PU.1 expression plasmid expressed nuclear factors that formed complexes indistinguishable from those seen with monocyte extracts. Antibodies to PU.1 protein either supershifted or abolished formation of these complexes, depending on the PU.1 epitopes recognized. The binding of PU.1 to the EIAV ets motif in vitro correlated with transcriptional activity of the EIAV promoter in transfected monocyte cell lines. In HeLa cells, the product of PU.1 cDNA bound to the EIAV ets motif and activated transcription from the EIAV promoter. The PU.1-binding site was the primary determinant of EIAV promoter activity in cell lines that express PU.1. Nucleotide determinants of PU.1 binding and a consensus PU.1 binding sequence were defined in gel shift assays using a panel of mutated oligonucleotides. To our knowledge, this is the first report of a retroviral promoter controlled by PU.1.
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PMID:The PU.1/Spi-1 proto-oncogene is a transcriptional regulator of a lentivirus promoter. 838 10

The long terminal repeats (LTRs) from various cloned equine infectious anemia virus (EIAV) proviruses differ significantly, but all contain cis-acting DNA elements identical to MDBP-, PEA2-, AP-1-, and PU.1 (ets)-binding sites. A prototype EIAV LTR would contain one of each of these conserved elements. The LTR variations originate from the insertion of novel sequences between the PEA2 and AP-1 elements in the transcriptional enhancer unit. Viewed in this way, the LTR from provirus clone lambda 12 has an 11-bp insertion containing a PEA2 site and the LTR of the lambda 6 provirus has a 31-bp insertion/duplication containing PEA2, AP-1, and PU.1 sites. Two other LTRs were cloned by amplification of cDNAs from the persistently infected cell line, EIAV-FEA. A third LTR was generated by site-directed mutagenesis of one of the LTRs from EIAV-FEA cells. The latter three had a single base change in the element next to the TATA box that abolished PU.1 binding; however, the variable regions of these LTRs were shown by gel mobility shift assays to contain one or two PU.1 sites. One variable region was shown to have an octamer site overlapping its tandem PU.1 elements. Basal, PMA-activated, and Tat trans-activated transcriptional activities of the LTRs were compared in several different cell lines by transient transfection. The various promoters displayed different relative levels of activity depending on the cell line used and the condition of activation. This natural set of variant promoters may help define how changes in the components of the transcription complex influence transactivation by Tat. The diverse LTRs could endow their respective proviruses with a unique pattern of expression and activation in vivo.
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PMID:Protein interactions with DNA elements in variant equine infectious anemia virus enhancers and their impact on transcriptional activity. 841 61

Clinical studies have indicated that folate deficiency may enhance the development of various malignancies. In animal studies that examined the effect of folate deficiency on malignancies, conflicting results have been reported. In some studies, folate deficiency increased the development and growth of malignant tumors; in others, it decreased the development and growth of malignancies. We examined the effect of transient folate deficiency on the development of leukemia in mice infected with the anemia-inducing strain of Friend leukemia virus. Friend virus disease can be considered as a model for human acute leukemias that are preceded by a preleukemic period. These include leukemias that develop in patients who received previous chemotherapy and/or radiation therapy, as well as patients with chronic granulocytic leukemia or myelodysplasia. Folate deficiency around the time of Friend virus-infection delayed the onset but increased the incidence of leukemia. The rates of rearrangement of the Spi-1 (PU.1 ) oncogene by provirus integration and alteration of the p53 tumor-suppressor gene were the same in leukemia cell lines derived from folate-deficient mice as they were in cell lines from control mice. These results indicate that folate deficiency did not exert its enhancement of leukemogenesis through changes in either Spi-1 or p53, even though these two genes have been found to be the most frequently altered ones in Friend virus-induced leukemias. Our results suggest that folate deficiency may enhance the development of acute leukemia in patients who are at high risk for this disease.
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PMID:Folate deficiency delays the onset but increases the incidence of leukemia in Friend virus-infected mice. 935 75

Erythroleukemia induced by the anemia strain of Friend virus occurs in two stages. The first stage results in rapid expansion of pre-leukemic proerythroblasts (FVA cells) dependent on erythropoietin (Epo) for differentiation and survival in vitro. The second stage is characterized by emergence of erythroleukemic clones (MEL cells) which typically bear activation of the ets-oncogene, PU.1/spi.1, and loss of functional p53. We developed a Friend virus-sensitive, p53-deficient mouse model to investigate the biological advantage conferred by p53-loss during tumor progression. Here we report p53 was not required for cell survival or growth arrest during differentiation of FVA cells, nor was p53 required for induction of apoptosis upon Epo withdrawal. However, we detected induction of the p21Cip1 cyclin-dependent kinase inhibitor gene during differentiation, which was markedly enhanced in the presence of p53. p53-dependent expression of p21Cip1 occurred in the absence of an increase in p53 mRNA and protein levels and was specific for p21Cip1, since expression of gadd45, mdm-2, cyclin G and bax were unaffected by p53. In contrast, treatment of FVA cells with DNA damaging agents led to rapid accumulation of p53 protein resulting in transcription of multiple p53-regulated genes, leading to either apoptosis or growth arrest, depending on the agent used. These data demonstrate that p53-dependent activities during differentiation of preleukemic erythroblasts are distinct from those observed in response to genotoxic agents. We propose that enhancement of p53-dependent gene expression during differentiation may represent a tumor suppressor function which is necessary to monitor differentiation of preleukemic cells and which is selected against during tumor progression.
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PMID:Endogenous p53 regulation and function in early stage Friend virus-induced tumor progression differs from that following DNA damage. 976 22

The equine infectious anemia virus (EIAV) long-terminal repeat (LTR) has been identified as highly variable, both in infected horses and in cell culture. This nucleotide hypervariation is localized to the LTR enhancer region. The EIAV LTR has been implicated in controlling both the cell tropism and virulence of the virus and it is postulated that the enhancer-region hypervariation may be responsible for the LTR effects. Our previous studies have demonstrated that the presence of DNA motifs bound by the ets transcription-factor family member PU.1 are critically important for EIAV expression in equine macrophages. Here we identify and characterize the EIAV LTR enhancer motifs PEA-2, Lvb, Oct, and CRE, that bind to fibroblast nuclear extracts. Three of these four motifs, PEA-2, Oct, and CRE, were determined to be important for expression of the LTR in a fibroblast cell line that supports productive infection of EIAV. These motifs that are important for expression of the LTR in fibroblasts were found to be interdigitated between the PU.1 sites. We hypothesize that the combination of motif interdigitation and cell-specific usage of these motifs may be responsible for the observed EIAV LTR enhancer-region hypervariation.
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PMID:Cell specificity of the transcription-factor repertoire used by a lentivirus: motifs important for expression of equine infectious anemia virus in nonmonocytic cells. 1066 22

In vivo, tissue macrophages have been implicated as an important cell for the replication of equine infectious anemia virus (EIAV). Laboratory investigations of EIAV/macrophage interactions, however, have been hampered by the laborious blood monocyte isolation procedures. In addition, adherent equine macrophage cultures generally have poor long-term viability and are resistant to transfection. This report describes an adherent canine macrophage-like cell line, DH82, that supports the replication of EIAV. This cell line was easily transfectable and supported EIAV Tat transactivation of the LTR. Electrophoretic mobility shift assays were carried out to determine which transcription factor binding sites within the LTR enhancer region were bound by DH82 nuclear extracts. It was found that five different motifs were occupied. The ets motifs that are bound by PU.1 in primary macrophage nuclear extracts specifically interacted with DH82 nuclear extracts. In addition, the PEA-2, Lvb and Oct motifs that are occupied by fibroblast nuclear extracts were also bound by DH82 nuclear extracts. Finally, the methylation-dependent binding protein (MDBP) site that is bound by all nuclear extracts investigated to date demonstrated specific interactions with DH82 nuclear extracts. The observation that both macrophage-specific and fibroblast-specific motifs were utilized by DH82 nuclear extracts suggested that both macrophage-adapted and fibroblast-adapted EIAV could replicate in DH82 cells. Indeed, infectivity studies demonstrated that strains of virus that exclusively replicate in macrophages can replicate in DH82 cells and fibroblast-adapted strains of virus can also replicate in these cells. Finally, these cells could be transfected readily with the EIAV molecular clone, pSPeiav19-2, and virus spread was detected within the culture. In conclusion, this study has identified a useful cell line that should facilitate the study of EIAV expression and replication.
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PMID:DH82 cells: a macrophage cell line for the replication and study of equine infectious anemia virus. 1137 12

Binding of the transcription factor PU.1 to its DNA binding motif regulates the expression of a number of B-cell- and myeloid-specific genes. The long terminal repeat (LTR) of macrophage-tropic strains of equine infectious anemia virus (EIAV) contains three PU.1 binding sites, namely an invariant promoter-proximal site as well as two upstream sites. We have previously shown that these sites are important for EIAV LTR activity in primary macrophages (W. Maury, J. Virol. 68:6270-6279, 1994). Since the sequences present in these three binding motifs are not identical, we sought to determine the role of these three sites in EIAV LTR activity. While DNase I footprinting studies indicated that all three sites within the enhancer were bound by recombinant PU.1, reporter gene assays demonstrated that the middle motif was most important for basal levels of LTR activity in macrophages and that the 5' motif had little impact. The impact of the 3' site became evident in Tat transactivation studies, in which the loss of the site reduced Tat-transactivated expression 40-fold. In contrast, elimination of the 5' site had no effect on Tat-mediated activity. Binding studies were performed to determine whether differences in PU.1 binding affinity for the three sites correlated with the relative impact of each site on LTR transcription. While small differences were observed in the binding affinities of the three sites, with the promoter-proximal site having the strongest binding affinity, these differences could not account for the dramatic differences observed in the transcriptional effects. Instead, the promoter-proximal position of the 3' motif appeared to be critical for its transcriptional impact and suggested that the PU.1 sites may serve different roles depending upon the location of the sites within the enhancer. Infectivity studies demonstrated that an LTR containing an enhancer composed of the three PU.1 sites was not sufficient to drive viral replication in macrophages. These findings indicate that while the promoter-proximal PU.1 site is the most critical site for EIAV LTR activity in the presence of Tat, other elements within the enhancer are needed for EIAV replication in macrophages.
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PMID:PU.1 binding to ets motifs within the equine infectious anemia virus long terminal repeat (LTR) enhancer: regulation of LTR activity and virus replication in macrophages. 1501 63

The Rho GTPase Cdc42 regulates adhesion, migration, and homing, as well as cell cycle progression, of hematopoietic stem cells, but its role in multilineage blood development remains unclear. We report here that inducible deletion of cdc42 in cdc42-floxed mouse bone marrow by the interferon-responsive, Mx1-Cre-mediated excision led to myeloid and erythroid developmental defects. Cdc42 deletion affected the number of early myeloid progenitors while suppressing erythroid differentiation. Cdc42-deficient mice developed a fatal myeloproliferative disorder manifested by significant leukocytosis with neutrophilia, myeloid hyperproliferation, and myeloid cell infiltration into distal organs. Concurrently, Cdc42 deficiency caused anemia and splenomegaly accompanied with decreased bone marrow erythroid burst-forming units (BFU-Es) and colony-forming units-erythroid (CFU-Es) activities and reduced immature erythroid progenitors, suggesting that Cdc42 deficiency causes a block in the early stage of erythropoiesis. Cdc42 activity is responsive to stimulation by SCF, IL3, SDF-1alpha, and fibronectin. The increased myelopoiesis and decreased erythropoiesis of the knockout mice are associated with an altered gene transcription program in hematopoietic progenitors, including up-regulation of promyeloid genes such as PU.1, C/EBP1alpha, and Gfi-1 in the common myeloid progenitors and granulocyte-macrophage progenitors and down-regulation of proerythroid gene such as GATA-2 in the megakaryocyte-erythroid progenitors. Thus, Cdc42 is an essential regulator of the balance between myelopoiesis and erythropoiesis.
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PMID:Cdc42 critically regulates the balance between myelopoiesis and erythropoiesis. 1770 96

EVI1 is an oncogene inappropriately expressed in the bone marrow (BM) of approximately 10% of myelodysplastic syndrome (MDS) patients. This disease is characterized by severe anemia and multilineage myeloid dysplasia that are thought to be a major cause of mortality in MDS patients. We earlier reported on a mouse model that constitutive expression of EVI1 in the BM led to fatal anemia and myeloid dysplasia, as observed in MDS patients, and we subsequently showed that EVI1 interaction with GATA1 blocks proper erythropoiesis. Whereas this interaction could provide the basis for the erythroid defects in EVI1-positive MDS, it does not explain the alteration of myeloid differentiation. Here, we have examined the expression of several genes activated during terminal myelopoiesis in BM cells and identified a group of them that are altered by EVI1. A common feature of these genes is their regulation by the transcription factor PU.1. We report here that EVI1 interacts with PU.1 and represses the PU.1-dependent activation of a myeloid promoter. EVI1 does not seem to inhibit PU.1 binding to DNA, but rather to block its association with the coactivator c-Jun. After mapping the PU.1-EVI1 interaction sites, we show that an EVI1 point mutant, unable to bind PU.1, restores the activation of PU.1-regulated genes and allows a normal differentiation of BM progenitors in vitro.
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PMID:EVI1 Impairs myelopoiesis by deregulation of PU.1 function. 1920 46


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