Host cell range of T-lymphotropic feline leukemia virus in vitro

Abstract Abstract 4243 Feline Leukemia Virus subgroup C Receptor (FLVCR) was originally identified and cloned as a cell-surface protein receptor for feline leukemia virus subgroup C, causing pure red blood cell aplasia in cats. Recent studies have demonstrated that FLVCR is a heme exporter which is essential for erythropoiesis. The heme efflux via FLVCR was shown to be essential for erythroid differentiation in K562 cells as well as in CD34+ precursors cells1. Moreover, Keel and co-authors have reported that Flvcr-null mice die in utero due to the failure of fetal erythropoiesis; also post-natal mice lacking FLVCR showed severe anemia. In addition to the erythroid defect, Flvcr-null embryos display defective growth and developmental anomalies2. We have identified an alternative transcription start site giving rise to a novel FLVCR isoform (FLVCRb). Flvcr-b transcript completely lacks the first exon of the canonical isoform (FLVCRa) and code for a putative 6 transmembrane domain containing protein ubiquitously expressed. In vitro over-expression of FLVCRa and FLVCRb showed that the two proteins display different subcellular localization. As expected, FLVCRa is localized at the cell membrane while FLVCRb is in the mitochondrial compartment. The mitochondrial localization of this novel isoform is further confirmed by the identification of a N-terminal mitochondrial sorting presequence. The mitochondrion is the site in which heme biosynthesis occurs. Although all the enzymatic reactions involved in heme synthesis are well characterized, how heme is exported to the cytosol is largely unknown. Because of FLVCRa is a heme exporter at the cell membrane, we hypothesized that FLVCRb could be the mitochondrial heme exporter. According to this hypothesis, FLVCRb expression increased following the stimulation of heme biosynthesis in vitro, in correlation with the increase in hemoglobin production. The ability of FLVCRb to bind and export heme out of the mitochondria is still under investigation. To gain insights into the specific roles of the two isoforms, we have generated Flvcr mutant mice different from those previously reported2. Keel and co-author generated a mouse model in which both FLVCRa and FLVCRb have been deleted. In our mouse model, FLVCRa has been specifically deleted while FLVCRb is still expressed (FLVCRa-null mice). Flvcr-a +/− mice were grossly normal, fertile and indistinguishable from their wild-type littermates. When Flvcr-a +/− mice were intercrossed, no Flvcr-a homozygous knock-out newborns were obtained. The analysis of the embryos from timed Flvcr-a +/− intercrosses showed that the Flvcr-a homozygous knock-out genotype was lethal between E14.5 and the birth. E13.5 Flvcr-a-null embryos showed multifocal and extended hemorrhages, visible in the limbs, head and throughout the body wall, as well as subcutaneous edema. Imcomplete vasculogenesis in the Flvcr-a-null embryos was observed at E11.5, a developmental stage in which hemorrhages were not still evident. This suggests that hemorrhages arise from a defect in the development of embryonic vasculature. Moreover, FLVCRa-null embryos showed skeletal abnormalities as demonstrated by Alcian blue-alizarin red staining. Skeletal malformations were evident in the limb where digits did not form properly and in the head where Meckel's cartilage was incomplete. It is interesting to note that this kind of malformations also occurs in Diamond Blackfan Anemia (DBA) patients. Surprisingly, flow cytometric analyses of E14.5 fetal liver cells double-stained for Ter119 (erythroid-specific antigen) and CD71 (transferrin receptor) showed normal erythropoiesis in Flvcr-a-null embryos, in opposition to what occurs in the previously reported Flvcr-null mice2. Taken together, these data demonstrated that FLVCRb is sufficient to support fetal erythropoiesis when the expression of FLVCRa is loss, likely exporting heme out of the mithocondrion for hemoglobin synthesis. Moreover, the loss of FLVCRa leads to incomplete vasculogenesis, hemorrhages and skeletal malformations highlighting new roles of FLVCRa in these processes. 1. Quigley JG et al. Identification of a human heme exporter that is essential for erythropoiesis. Cell 2004 2. Keel SB et al. A heme export protein is required for red blood cell differentiation and iron homeostasis. Science 2008. Disclosures: No relevant conflicts of interest to declare.

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Characterization of Wolbachia Host Cell Range via the In Vitro Establishment of Infections

Applied and Environmental Microbiology ◽

10.1128/aem.68.2.656-660.2002 ◽

2002 ◽

Vol 68 (2) ◽

pp. 656-660 ◽

Cited By ~ 55

Author(s):

Stephen L. Dobson ◽

Eric J. Marsland ◽

Zoe Veneti ◽

Kostas Bourtzis ◽

Scott L. O'Neill

Keyword(s):

Tissue Culture ◽

Host Cell ◽

Culture Techniques ◽

Cadra Cautella ◽

Insect Rearing ◽

Cell Range ◽

In Vitro Establishment ◽

Infection Types ◽

Insect Cell Lines

ABSTRACT Maternally transmitted bacteria of the genus Wolbachia are obligate, intracellular symbionts that are frequently found in insects and cause a diverse array of reproductive manipulations, including cytoplasmic incompatibility, male killing, parthenogenesis, and feminization. Despite the existence of a broad range of scientific interest, many aspects of Wolbachia research have been limited to laboratories with insect-rearing facilities. The inability to culture these bacteria outside of the invertebrate host has also led to the existing bias of Wolbachia research toward infections that occur in host insects that are easily reared. Here, we demonstrate that Wolbachia infections can be simply established, stably maintained, and cryogenically stored in vitro using standard tissue culture techniques. We have examined Wolbachia host range by introducing different Wolbachia types into a single tissue culture. The results show that an Aedes albopictus (Diptera: Culicidae) cell line can support five different Wolbachia infection types derived from Drosophila simulans (Diptera: Drosophilidae), Culex pipiens (Culicidae), and Cadra cautella (Lepidoptera: Phycitidae). These bacterial types include infection types that have been assigned to two of the major Wolbachia clades. As an additional examination of Wolbachia host cell range, we demonstrated that a Wolbachia strain from D. simulans could be established in host insect cell lines derived from A. albopictus, Spodoptera frugiperda (Lepidoptera: Noctuidae), and Drosophila melanogaster. These results will facilitate the development of a Wolbachia stock center, permitting novel approaches for the study of Wolbachia infections and encouraging Wolbachia research in additional laboratories.

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Properties of Feline Leukemia Virus II. In Vitro Labeling of the Polypeptides 1

Journal of Virology ◽

10.1128/jvi.14.3.700-703.1974 ◽

1974 ◽

Vol 14 (3) ◽

pp. 700-703 ◽

Cited By ~ 2

Author(s):

Leland F. Velicer ◽

Donald C. Graves

Keyword(s):

Leukemia Virus ◽

Feline Leukemia Virus

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Retrovirus-induced feline pure red blood cell aplasia: pathogenesis and response to suramin

Blood ◽

10.1182/blood.v77.7.1442.bloodjournal7771442 ◽

1991 ◽

Vol 77 (7) ◽

pp. 1442-1451

Author(s):

JL Abkowitz

Keyword(s):

Blood Cell ◽

Red Blood Cell ◽

Mononuclear Cells ◽

Leukemia Virus ◽

Transcriptase Inhibitor ◽

Feline Leukemia Virus ◽

Erythroid Progenitors ◽

Marrow Cultures

Feline leukemia virus, subgroup C/Sarma (FeLV-C/Sarma) induces pure red blood cell aplasia in cats. Although erythroid (BFU-E and CFU-E) and granulocyte/macrophage (CFU-GM) progenitors are infected with this virus, only erythropoiesis is impaired. Two to 3 weeks before the onset of anemia, CFU-E become undetectable in marrow cultures while earlier erythroid progenitors (BFU-E) persist, suggesting that FeLV-C/Sarma (presumably via its envelope glycoprotein gp70) inhibits the differentiation of BFU-E to CFU-E in vivo. To correlate in vitro observations with the progression of disease, prospective studies were performed in six cats. These studies showed that at the time that the frequencies of CFU-E decreased in marrow cultures, BFU-E no longer responded to hematopoietic growth factor(s), although the responses of CFU-GM were unchanged. In further studies, anemic cats received suramin, a reverse-transcriptase inhibitor with other diverse effects. Within 4 to 14 days, erythropoiesis improved and up to 1,616 CFU-E were detected per 10(5) marrow mononuclear cells. However, progenitor cells remained infected, suggesting that suramin modulated erythroid differentiation without inhibiting progenitor infection. These observations led to the hypothesis that the gp70 of FeLV-C/Sarma impairs BFU-E differentiation by interference with ligand/receptor interactions or signal transduction pathways unique to erythroid cells. Understanding this mechanism should provide insights into the interactions controlling early erythropoiesis.

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Studies in feline long-term marrow culture: hematopoiesis on normal and feline leukemia virus infected stromal cells

Blood ◽

10.1182/blood.v80.3.651.bloodjournal803651 ◽

1992 ◽

Vol 80 (3) ◽

pp. 651-662

Author(s):

ML Linenberger ◽

JL Abkowitz

Keyword(s):

Stromal Cells ◽

Mononuclear Cells ◽

Clonal Selection ◽

Leukemia Virus ◽

Feline Leukemia Virus ◽

Erythroid Progenitors ◽

Gag Protein ◽

Cell Engraftment

To study the effects of feline leukemia virus (FeLV) on the hematopoietic microenvironment, a two-step feline long-term marrow culture (LTMC) system was developed and characterized. The adherent, stromal layer of these cultures is composed of fibroblastoid cells (50% to 80%), macrophages (10% to 30%), fat cells (10% to 20%), and large, polygonal cells that express muscle actin (1% to 2%). When fresh, enriched marrow mononuclear cells (MMNC) were added to 3-week-old irradiated stromal cultures, nonadherent erythroid progenitors (BFU-E) and granulocyte/macrophage progenitors (CFU-GM) could be detected for up to 5 and 12 weeks, respectively. LTMC stromal layers established from marrow cells from cats viremic with either a nonpathogenic strain of FeLV (FeLV-A/61E) or the anemogenic strain FeLV-C/Sarma were morphologically equivalent to uninfected LTMC stromal layers, although more than 80% of the stromal cells expressed FeLV gag protein. When FeLV-infected stromal cultures were recharged with uninfected MMNC, altered patterns of hematopoiesis were observed, compared with recharged, uninfected stromal cultures. In cultures with infected stroma, fewer nonadherent cells (NAC), nonadherent BFU-E, and nonadherent CFU-GM were detected during the first 4 to 5 weeks after recharge. In contrast, greater numbers of NAC and nonadherent CFU-GM were found from weeks 5 to 12 after recharge. When FeLV-infected stromal cultures were recharged with MMNC from a cat heterozygous for the X-chromosome-linked enzyme glucose-6-phosphate dehydrogenase (G-6- PD), the percentage of nonadherent CFU-GM expressing the domestic type G-6-PD isoenzyme remained stable over time (mean % domestic [%d], 53% +/- 3%), and was equivalent to that of nonadherent CFU-GM maintained in uninfected cultures (mean %d, 56% +/- 3%), indicating that clonal drift or clonal selection was not responsible for the enhanced maintenance of CFU-GM. Furthermore, as only 10% to 20% of recharged hematopoietic cells became infected with FeLV in vitro, it is unlikely that the altered pattern was due to progenitor infection. We hypothesize that the increase in NAC and nonadherent CFU-GM in FeLV-infected cultures resulted from enhanced growth factor production by stromal cells. The two-step LTMC system may facilitate the characterization of stromal- derived factors that affect progenitor cell engraftment and proliferation.

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Cell lines produce factors that induce fetal hemoglobin in human BFUe- derived colonies

Blood ◽

10.1182/blood.v80.10.2650.bloodjournal80102650 ◽

1992 ◽

Vol 80 (10) ◽

pp. 2650-2655

Author(s):

P Constantoulakis ◽

M Walmsley ◽

R Patient ◽

T Papayannopoulou ◽

T Enver ◽

...

Keyword(s):

Cell Lines ◽

Leukemia Virus ◽

Fetal Hemoglobin ◽

Feline Leukemia Virus ◽

In Vitro Translation ◽

Expression Cloning ◽

Bladder Cell ◽

Relative Production ◽

Established Cell

Established cell lines were screened for secretion of activities than can stimulate fetal hemoglobin (HbF) production in adult burst-forming unit-erythroid (BFUe) cultures. Conditioned media from four cell lines, a human teratocarcinoma, an osteosarcoma, a bladder cell carcinoma, and feline leukemia virus (FeLV) A-infected feline fibroblasts (FEF-A cells), consistently increased the relative production of fetal globin in BFUe-derived colonies. In vitro translation of RNA from these cells in Xenopus oocytes yielded products that increased the gamma to gamma+beta ratio in adult erythroid colonies. These results demonstrate that a variety of cell lines produce factors that stimulate the production of HbF in vitro. The genes of such factors could be isolated by expression cloning of cDNA from cell lines using the Xenopus oocyte system.

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Genetic and Biochemical Analyses of Receptor and Cofactor Determinants for T-Cell-Tropic Feline Leukemia Virus Infection

Journal of Virology ◽

10.1128/jvi.76.16.8069-8078.2002 ◽

2002 ◽

Vol 76 (16) ◽

pp. 8069-8078 ◽

Cited By ~ 15

Author(s):

Adam S. Lauring ◽

Heather H. Cheng ◽

Maribeth V. Eiden ◽

Julie Overbaugh

Keyword(s):

T Cell ◽

Host Cell ◽

Transmembrane Protein ◽

Leukemia Virus ◽

Direct Interaction ◽

Cell Receptor ◽

Cellular Protein ◽

Viral Envelope ◽

Feline Leukemia Virus ◽

Cofactor Binding

ABSTRACT Entry by retroviruses is mediated through interactions between the viral envelope glycoprotein and the host cell receptor(s). We recently identified two host cell proteins, FeLIX and Pit1, that are necessary for infection by cytopathic, T-cell-tropic feline leukemia viruses (FeLV-T). Pit1 is a classic multiple transmembrane protein used as a receptor by several other simple retroviruses, including subgroup B FeLV (FeLV-B), and FeLIX is a secreted cellular protein expressed from endogenous FeLV-related sequences (enFeLV). FeLIX is nearly identical to FeLV-B envelope sequences that encode the N-terminal half of the viral surface unit (SU), because these FeLV-B sequences are acquired by recombination with enFeLV. FeLV-B SUs can functionally substitute for FeLIX in mediating FeLV-T infection. Both of these enFeLV-derived cofactors can efficiently facilitate FeLV-T infection only of cells expressing Pit1, not of cells expressing the related transport protein Pit2. We therefore have used chimeric Pit1/Pit2 receptors to map the determinants for cofactor binding and FeLV-T infection. Three distinct determinants appear to be required for cofactor-dependent infection by FeLV-T. We also found that Pit1 sequences within these same domains were required for binding by FeLIX to the Pit receptor. In contrast, these determinants were not all required for receptor binding by the FeLV-B SU cofactors used in this study. These data indicate that cofactor binding is not sufficient for FeLV-T infection and suggest that there may be a direct interaction between FeLV-T and the Pit1 receptor.

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