Non-sialate inhibitor of influenza A/WSN/33 neuraminidase.

An N1 strain of influenza A virus neuraminidase (A/WSN/33 NA) was purified and used to screen for inhibitors. As a result, a well-known tuberculostatic, 4'-formylacetanilide thiosemicarbazone (or thiacetazone), was identified. Thiacetazone is a non-sialate compound and inhibits the enzyme in a noncompetitive manner with respect to the substrate sialic acid. Mechanistic studies indicate that the inhibition was due to the competition of thiacetazone with Ca2+, which maintains N1 neuraminidase in an active conformation. The Ki for the inhibition was estimated to be about 4 microM. Equilibrium exchange experiments revealed that when purified A/WSN/33 NA was incubated with 5 microM 45CaCl2, 2 mol of 45Ca2+ ion was exchanged into each mole of NA tetramer and subsequently displaced from the enzyme upon the introduction of the inhibitor. Inhibition of plaque formation by thiacetazone in an MDCK cell culture that had been infected with the influenza A/WSN/33 virus was demonstrated. Thiacetazone was highly specific for A/WSN/33 neuraminidase, since little effect was noted when it was tested against NAs from the other strains of influenza virus or from bacteria. This compound might represent a group of non-sialate inhibitors of influenza NA that bind to a noncatalytic or an allosteric site on the enzyme.

Inhibition of human immunodeficiency virus type 1 (HIV-1) replication by the dipyridodiazepinone BI-RG-587.

The dipyridodiazepinone human immunodeficiency virus type 1 (HIV-1)-specific reverse transcriptase (RT) inhibitor BI-RG-587 was tested for its ability to inhibit HIV-1 replication in both acutely and chronically infected cell lines. The ability of BI-RG-587 to inhibit steps in the virus replicative cycle other than reverse transcription was also assessed. BI-RG-587 was found to be a potent inhibitor of HIV-1 replication in acutely infected cells (50% inhibitory concentration [IC50] = 37.2 nM), and the sensitivity and kinetics of that inhibition was similar to the known RT inhibitor zidovudine (AZT). Even at 100x IC50, BI-RG-587 had no effect on gp120/CD4 interaction, syncytia formation, or envelope glycoprotein processing. In addition, no inhibition of viral replication or protein production was noted in a chronically infected cell line that produces viral products in an RT-independent manner. Finally, no inhibition of acute HIV-2 replication was noted, even with very high (2500x IC50 for HIV-1) concentrations of BI-RG-587. These results demonstrate that BI-RG-587 is a potent inhibitor of HIV-1 replication and that this inhibition occurs at the point of reverse transcription.

BI-RG-587 is active against zidovudine-resistant human immunodeficiency virus type 1 and synergistic with zidovudine.

A series of dipyridodiazepinones have been shown to be potent inhibitors of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase. The lead compound, BI-RG-587, had a 50% inhibitory concentration of 84 nM against HIV-1 reverse transcriptase activity. This compound reduced plaque formation of HIV-1 in HeLa cells expressing the CD4 receptor by 50% at 15 nM. BI-RG-587 at comparable concentrations inhibited the production of p24 antigen following the acute infection of CEM T-lymphoblastoid cells or primary human monocyte-derived macrophages with HIV-1. No inhibitory effects against HIV-2 or against three picornaviruses were detected. Zidovudine (3'-azido-3'-deoxythymidine [AZT])-susceptible and AZT-resistant isolates of HIV-1 were equally susceptible to BI-RG-587. AZT and BI-RG-587 exhibited synergistic inhibition of HIV-1BRU at all concentrations examined.

Natural killer cell suppression of Friend virus-induced preleukemic hemopoietic stem cells.

To determine whether hemopoietic cells infected with Friend polycythemia-inducing spleen focus-forming virus (SFFVp) are conserved or suppressed via natural surveillance in leukemia-resistant adult mice, we engrafted C57BL/6 recipients with isologous transgenic (donor origin marker) or natural killer (NK) cell-deficient B6 beige marrow cells exposed to SFFVp in vitro. Both groups of primary recipients were viremic and nonleukemic. Spleen cells from primary SFFVp-infected chimeras were engrafted into irradiated leukemia-susceptible secondary recipients to reveal dormant leukemia and grew as tumors of donor origin in 8 of 38 (21%) and 33 of 47 (70%) instances, respectively. Treatment of marrow donors and recipients with anti-asialo GM1 serum resulted in the depression of NK cell activity and the rapid development of dormant leukemia. We conclude that NK cells are an effective surveillance mechanism able to suppress SFFVp-induced preleukemic stem cells.

Friend virus-infected long-term bone marrow cultures produce colony stimulating factor dependent and independent granulocyte-macrophage progenitor cells for over four years in vitro.

C3H/HeJ mouse long-term bone marrow cultures infected at initiation with a cloned polycythemic strain of Friend spleen focus forming virus in a cloned N-tropic murine leukemia virus helper virus coat, persistently produced: colony-forming unit spleen (CFUs) for 55 weeks that formed macroscopic spleen colonies in syngeneic or allogeneic C57B10.Br/J mice; and L-cell or WEHI-3 cell conditioned medium-dependent granulocyte-macrophage colony forming unit culture (GM-CFUc); and morphologically normal granulocytes for over 245 weeks. Colony stimulating factor (CSF)-independent colony forming progenitor cells were first detectably produced in vitro at 75 weeks, and when subcultured generated karyotypically distinct permanent factor-independent tumorigenic cell lines. Nonadherent cells removed from long-term marrow cultures at 19 but not at 77 weeks reconstituted donor origin hematopoiesis in C57B10.Br/J mice as measured by B-cell lineage surface immunoglobin allotype. Nonadherent cells removed at 77 weeks produced lethal splenomegaly and marrow infiltration with culture origin cells in C57B10.Br/J mice. Despite generation of clonal malignant cell lines, L-cell DSF (CSF-1, M-CSF) responsive GM-CFUc that were simultaneously produced over 4 years in the same long-term marrow cultures, grew to 7 day colonies in semisolid medium and terminally differentiated. Thus, adherent stromal cells in Friend virus-infected long-term bone marrow cultures simultaneously support CSF-responsive and malignant CSF-independent hematopoietic progenitor cells.

Expression of a retrovirus encoding human HPRT in mice.

Transmissible retroviruses encoding human hypoxanthine phosphoribosyltransferase (HPRT) were used to infect mouse bone marrow cells in vitro, and the infected cells were transplanted into mice. Both active human HPRT-protein and chronic HPRT-virus production were detected in hematopoietic tissue of the mice, showing transfer of the gene. These results indicate the possible use of retroviruses for somatic cell therapy.

Interleukin 3-dependent hematopoietic progenitor cell lines.

Several biological phenotypes of growth factor-dependent cell lines have been described in recent years, including those with T lymphocyte, neutrophil granulocyte, basophil/mast cell, B lymphocyte, and multipotential stem cell properties. The growth factors for each cell lineage are a subject of intense study. Continuous mouse bone marrow cultures infected with RNA type C viruses (retroviruses) produce nonadherent hematopoietic cells over a longer duration than control cultures. Marrow cultures derived from strains with spontaneously induced ecotropic endogenous retrovirus demonstrate a greater longevity than those from strains with no replicating virus. Cultures infected with murine leukemia virus also generate a greater number, compared with controls, of cloned permanent suspension cell lines dependent for growth on a 41,000-dalton glycoprotein (interleukin 3 [IL 3]). Some are multipotential with capacity for differentiation to erythroid, neutrophil, eosinophil, and basophil/mast cell types. Other cloned IL 3-dependent cell lines are committed to a single pathway. Studies with Friend spleen focus-forming virus indicate that the first effect in the marrow culture is mediated through a subset of adherent hematopoietic stem cells. Bone marrow culture-derived IL 3-dependent cell lines provide a model with which to study the role of viral genes in the control of differentiation and self-renewal capacity of hematopoietic stem cells.

Demonstration of permanent factor-dependent multipotential (erythroid/neutrophil/basophil) hematopoietic progenitor cell lines.

Multipotential hematopoietic progenitor cell lines have been established from nonadherent cell populations removed from continuous mouse bone marrow cultures. Clonal sublines of lines B6SUtA or B6JUt derived from single cells formed mixed colonies containing erythroid cells, neutrophil-granulocytes, and basophil/mast cells in semisolid medium containing erythropoietin and conditioned medium from pokeweed mitogen-stimulated spleen cells. Each of several subclones of cell line Ro cl formed colonies containing eosinophils, neutrophil-granulocytes, and basophil/mast cells in semisolid medium. Multipotentiality was maintained in vitro for over 2 1/2 years. In contrast, cell line 32D formed basophil/mast cell colonies with no detectable differentiation to other pathways. Multipotential cell lines did not produce detectable spleen colonies (CFUs) in vivo, nor did intravenous inoculation of up to 5 X 10(7) cells protect lethally irradiated mice from bone marrow failure. Newborn and adult mice inoculated with 5 X 10(7) cells showed no detectable leukemia or solid tumors after one year. Both multipotential and committed basophil/mast cell lines demonstrated absolute dependence upon a source of a growth factor(s) found in medium conditioned by WEHI-3 cells. These cell lines should be of value in studies of the regulation of hematopoietic stem cell differentiation in vitro.

Pool size of pluripotential hematopoietic stem cells increased in continuous bone marrow culture by Friend spleen focus-forming virus.

Continuous mouse bone marrow cultures were infected with Friend murine leukemia virus. Production of nonadherent (NA) and adherent cells, granulocyte-macrophage colony-forming unit(s) of progenitor cells (GM-CFUc), pluripotential hematopoietic stem cells (CFUs), the self-renewal potential (Rs) of CFUs, and generation of factor-dependent (FD) multipotential and committed permanent stem cell cloned lines were measured. Uninfected marrow cultures from C57BL/6J, C57BL/6JUt, B6.S, C3H/HeJ, (C57BL/6J x DBA/2J)F1, CD- 1 Swiss, or N:NIH(S) mice generated NA cells, GM-CFUc, and CFUs for 20-41 weeks; cultures infected with Rauscher or other helper viruses generated them for 35-45 weeks. GM-CFUc and CFUs production in SFFV-positive cultures persisted for over 65 weeks and exceeded control levels by twentyfold to fiftyfold. The Rs of CFUs in SFFV-positive cultures was not detectably increased above control cultures. Multipotential (erythroid-neutrophil-mast cell-basophil-eosinophil) permanent FD cell clones were derived from control and SFFV-positive cultures. Thus SFFV amplifies the stem cell pool in vitro without detectably increasing the Rs capacity of CFUs.

Role of stromal and hematopoietic stem cells in Friend spleen focus forming virus effects in continuous bone marrow culture.

Replication of the Friend spleen focus forming virus (SFFV) in C3H/HeJ or C57BL/6J mouse continuous bone marrow cultures is associated with an increased cumulative production of pluripotential/hematopoietic stem cells (CFUs), granulocyte-macrophage progenitor cells (GM-CFUc), and total granulocytes, compared to uninfected or helper virus infected control cultures. The site(s) of action of the virus are not known. To determine whether viral effect(s) occurred in adherent stromal and/or non-adherent hematopoietic stem cells, purified cell populations, comprised exclusively of cells from each compartment, were separated from C57BL/6J (Fv-1bb) or C3H/HeJ (Fv-1nn) marrow cultures and were left uninfected or were infected with host range replication restricted B-tropic or N-tropic helper pseudotype viruses of SFFV respectively. Cell populations were then mixed to establish continuous hematopoiesis in allogeneic or syngeneic combinations. Virus host range restriction between compartments was maintained in allogeneic reconstituted cultures which showed active hematopoiesis for 16-17 weeks and no significant differences between: (1) virus infected and uninfected groups or (2) groups comprised of stromal cells from one or the other strain. Thus, these data indicate that the prolongation of hematopoiesis in undisturbed long-term marrow cultures by SFFV occurs through an interaction of adherent hematopoietic stem cells with the marrow stroma.

Extended self-renewal capacity of pluripotent hemopoietic stem cells: association with persistent Friend spleen focus-forming virus.

The pluripotential hemopoietic stem cells (CFU-S) of genetically resistant Fv2rr adult C57BL/6 (B6) mice can be persistently infected by Friend virus (FV) when exposed to defective spleen focus-forming virus (SFFV) and helper virus (LLV) at the time of transplantation into heavily irradiated syngeneic recipients (that is, B6 leads to B6 isologous chimeras). Whereas normal and LLV+ marrow were depleted of CFU-S after three serial transplantations at 14-day intervals, SFFV+ donor marrow exhibited prolonged self-renewal capacity. SFFV+ CFU-S from B6. Fv2rr chimeric mice gave rise to normal erythroid and myeloid progenitor cells and were easily detected and quantified over 17 serial marrow transfers equivalent to 260 cumulative days. Marrow cellularity on day 14 of each transfer remained constant during the entire transplantation time. When SFFV fell below detectable levels at passage 15, CFU-S self-renewal exhibited rapid and total decline. Since the frequency of LLV-infected cells in late marrow transfers rose during the period of CFU-S decline, we conclude that SFFV is directly associated with the triggering of CFU-S self-renewal. It is also suggested that this proliferative event may be a prerequisite for the development of FV-induced leukemia.

In vitro quantitation of lethal and physiologic effects of total body irradiation on stromal and hematopoietic stem cells in continuous bone marrow cultures from Rf mice.

The role of stromal-supportive cells in hematopoietic stem cell responses to irradiation is poorly understood. The effects of in vivo total body irradiation (TBI) and interval from TBI to explant of marrow on: stromal cell proliferation in vitro; stromal cell support of hematopoiesis in continuous bone marrow culture; and generation of WEHI-3 growth factor (GF)-dependent lines of hematopoietic progenitor cells were evaluated. Continuous marrow cultures from non-irradiated control RfM/UN, C57BL/6J, C3H/HeJ, and N:NIH (Swiss) mice generated pluripotential hematopoietic stem cells (CFUs) and committed granulocyte-macrophage progenitor cells (GM-CFUc) for over 20 weeks. Explant of marrow at 2, 4, 5, or 6 months after single fraction TBI (300-800 rad) was associated with decreased longevity of hemopoiesis (2-12 weeks), and a decrease in the proliferative capacity of fibroblastic adherent-stromal colony forming cells (CFUf) as measured by colony size at 14 days and number of colonies per 10(6) cells plated. In contrast, explant of marrow 8 to 24 months after TBI produced cultures with longevity that was indistinguishable from age-matched control cultures (19-24 weeks). Marrow from irradiated first and second generation recipients of serially transferred marrow demonstrated a similar 7-month in vivo recovery period; however, the plateau maximum duration of hemopoiesis did not return to control levels. Purified stromal cell cultures were prepared by corticosteroid-deprivation of explanted marrow for 28 days and were then engrafted in vitro with marrow from C57BL/6J or RfM/UN mice that had been irradiated 1 month previously. Hemopoiesis in these cultures was restored, and they produced GM-CFUc and granulocytes for 15-24 weeks. Thus, healthy stroma supported growth of recently irradiated hemopoietic cells in vitro. Nonadherent cells removed from the above continuous marrow cultures generated clonal non-leukemogenic WEHI-3 GF-dependent hemopoietic progenitor cell lines with a frequency concordant with radiation effects on culture longevity, and this was increased by the presence of purified healthy stromal cultures. Indirect effects of x-irradiation on hemopoietic stem cells through damage and repair in the stromal cell compartment can be effectively studied with the present bone marrow culture system.

Persistence and pathogenicity of defective Friend spleen focus-forming virus. Decreased transplantability of hemopoietic cells as a marker for preleukemic change.

A latent form of persistent infection can be established in susceptible adult mice inoculated with a preparation of defective Friend spleen focus-forming virus (SFFV) purified free from standard leukemia-inducing helper virus (LLV-F). SFFV persistence was initially observed using an in vivo rescue technique in which SFFV could be directly rescued to form splenic foci of malignant erythropoiesis in mice. At approximately 30 d after virus inoculation however, SFFV could not be rescued after inoculation of LLV-F indicating that persistently infected (i.e., SFFV+) mice were either immume to exogenous helper virus or able to express SFFV-associated defective-interfering (DI) function(s). Persistent infection by SFFV was further documented using an in vitro rescue technique and ultimately resulted in the induction by SFFV of erythroleukemia in the absence of polycythemia or overt virus production. However, SFFV rescued by LLV-F from persistently infected normal and transformed hemopoietic cells was able to induce polycythemia in adult mice suggesting that this is a helper controlled property of the Friend virus complex. Transplantable SFFV-induced erythroleukemic cells could be retrieved from persistently infected yet histologically normal mice. The duration of SFFV persistence in normal spleen tissue suggests that the SFFV provirus resides in either a long-lived or pluripotent hemopoietic cell. Further, certain changes occurred, presumably in the membranes of persistently infected cells, which preceded the overt development of Friend leukemia and facilitated the definition of an SFFV preleukemic phase. Cell surface alterations were revealed using cell transfer techniques. Hemopoietic cells harboring a rescuable SFFV failed to proliferate when inoculated into lethally irradiated, syngeneic adult mice. In contrast, the transformed progeny of preleukemic cell populations and spleen cells transformed by FV complex (i.e., cells replicating both SFFV and LLV-F) were not rejected. This result suggests that histologically normal SFFV+ preleukemic cells express an antigen recognition site which is not present on overtly transformed cells and which may be a pertinent surveillance target for host anti-leukemogenic reactions.

Defective Friend spleen focus-forming virus: interfering properties and isolation free from standard leukemia-inducing helper virus.

Defective Friend spleen focus-forming virus (SFFV) is able to interfere with the ability of its naturally occurring leukemia-inducing helper virus (LLV-F) to induce XC plaque formation in several different strains of mouse embryo cells. This interference has been observed by using two different SFFV preparations, one contained in an NB-tropic stock of Friend virus (FV) complex, and the second present in a C57BL-adapted strain of FV complex containing an associated B-tropic LLV-F helper. The LLV-F in NB-tropic FV complex effectively induced XC plaques in C57BL/6 (Fv-1(bb); Fv-2(rr)) mouse embryo fibroblasts (MEF) only in the absence of coinfecting SFFV, indicating that Fv-2-associated resistance to SFFV-induced focus formation in vivo does not necessarily extend to the restriction of SFFV function(s) in vitro (i.e., in Fv-2(rr) C57BL MEF). SFFV interference appears to be an intracellular event since LLV-F can adsorb onto, penetrate, and rescue defective murine sarcoma virus (MSV) from transformed 3T3FL S(+)L(-) cells with equal efficiency in the presence and absence of SFFV. However, significantly fewer LLV-infected S(+)L(-) cells released LLV-F progeny if SFFV was present. These observations suggest that Friend SFFV may be classified as a defective, interfering (DI) particle. Further support for this conclusion has come from studies designed to investigate two physical properties of defective SFFV particles. SFFV layered onto a 0 to 20% sucrose sedimentation gradient was recovered as a symmetrical band of virus that sedimented more slowly than standard LLV-F particles. Pooled SFFV-containing gradient samples contained visualizable type C virus particles and occasionally small amounts of detectable LLV-F. In an attempt to determine the buoyant density of sedimentation gradient-purified SFFV, pooled SFFV samples were layered onto a 25 to 50% sucrose equilibrium density gradient and were centrifuged to equilibrium. Greater than 50% of the infectious SFFV originally layered onto this gradient was recovered and seen as a narrow symmetrical band with peak SFFV infectivity at a sucrose density of 1.14 g/ml. The observed difference between SFFV and LLV-F buoyant densities appears to be related to an inherent physical property of each virus. Mixtures of these two viruses express the buoyant density of that virus population which is in excess in fabricated FV complexes probably due to the formation of SFFV-LLV aggregates. Finally, gradient-purified SFFV failed to induce XC plaques in MEF and did not function to rescue MSV as expected since SFFV itself is replication defective.

Continuous replication of Friend virus complex (spleen focus-forming virus-lymphatic leukemia-inducing virus) in mouse embryo fibroblasts. Retention of leukemogenicity and loss of immunosuppressive properties.

Exposure of NIH Swiss mouse embryo fibroblasts (MEF) to infectious Friend virus (FV) complex [containing defective spleen focus-forming virus (SFFV) and endogenous NB-tropic leukemia-inducing helper virus (LLV-F)] resulted in the productive infection of these cells by both SFFV and LLV-F. Stocks of SFFV derived after extensive growth in this Swiss MEF cell culture system are fully leukemogenic in adult mice for the induction of erythroleukemia and spleen foci. In addition, in vitro-derived LLV-F, when isolated free of SFFV, is fully leukemogenic for the induction of lymphatic leukemia when inoculated into susceptible newborn BALB/c mice. The host range of in vitro-derived FV complex (i.e., FV-TC) for focus formation in vivo is NB-tropic. Unlike in vivo-derived FV complex, FV-TC does not suppress the responsiveness of murine thymocytes to concanavalin A (Con A) in vitro. Rather, FV-TC acts as a mitogen to nonspecifically stimulate the proliferation of BALB/c thymocytes. The mitogenicity of in vitro-derived FV complex is directly associated with the presence of type-C virus particles, is a heat-labile and UV-sensitive property of the virus, and may be primarily due to LLV since equivalent amounts of LLV with or without SFFV present are equally mitogenic. One in vivo passage of FV-TC resulted in the total loss of this mitogenic property with the reappearance of full immunosuppressive properties. This result demonstrates a clear association between in vivo growth of FV and its ability to suppress mouse thymocytes, and suggests that FV complex (SFFV-LLV) is not inherently immunosuppressive for these cells. While the mechanism of this interconversion between immunostimulatory and fully suppressive virus is unknown, both virus markers appear to be dependent upon the presence of infectious FV.