Hypoxia-inducible factor (HIF)-1α suppression in myeloma cells blocks tumoral growth in vivo inhibiting angiogenesis and bone destruction.

Hypoxia-inducible transcription factor-1 (HIF-1α) is overexpressed in multiple myeloma (MM) cells within the hypoxic microenvironment. Herein, we explored the effect of persistent HIF-1α inhibition by a lentivirus short hairpin RNA pool on MM cell growth either in vitro or in vivo and on the transcriptional and pro-angiogenic profiles of MM cells. HIF-1α suppression did not have a significant impact on MM cell proliferation and survival in vitro although, increased the antiproliferative effect of lenalidomide. On the other hand, we found that HIF-1α inhibition in MM cells downregulates the pro-angiogenic genes VEGF, IL8, IL10, CCL2, CCL5 and MMP9. Pro-osteoclastogenic cytokines were also inhibited, such as IL-7 and CCL3/MIP-1α. The effect of HIF-1α inhibition was assessed in vivo in nonobese diabetic/severe combined immunodeficiency mice both in a subcutaneous and an intratibial MM model. HIF-1α inhibition caused a dramatic reduction in the weight and volume of the tumor burden in both mouse models. Moreover, a significant reduction of the number of vessels and vascular endothelial growth factors (VEGFs) immunostaining was observed. Finally, in the intratibial experiments, HIF-1α inhibition significantly blocked bone destruction. Overall, our data indicate that HIF-1α suppression in MM cells significantly blocks MM-induced angiogenesis and reduces MM tumor burden and bone destruction in vivo, supporting HIF-1α as a potential therapeutic target in MM.

The effect of DFMO induced uptake of [3H] putrescine on human glioma cells.

Polyamine synthesis inhibitors, such as a-difluoromethylornithine (DFMO), inhibit tumor cell growth in vitro and in vivo. However, upon cessation of treatment, tumor growth resumes. We hypothesized that incorporation of radioactive polyamines might kill the growth-arrested cells. This hypothesis was previously tested in rat 9L brain tumor cells in which DFMO increased both the uptake and the retention of [3H] putrescine. In these rat cells, DFMO-induced retention of high-specific-activity [3H] putrescine for 20 days resulted in several logs killing. In the present studies all of the 5 different human glioma cell lines tested with DFMO treatment also showed enhanced uptake of exogenous [3H] putrescine, reduced cell counts and enhanced killing of colony forming cells (CSF). Extending the time of DFMO treatment of cells that had taken up high-specific-activity (80 Ci/mmol) [3H] putrescine further increased the killing. A 10-day extension resulted in a 10,000-fold reduction in cumulative cell growth. A 5-day extension resulted in a 2-3 log decrease in numbers of surviving CFC. These data further support the hypothesis and suggest that DFMO-induced cell cycle arrest enhances cellular retention of [3H] putrescine, increasing the effective internal radiation dose enough to cause proliferative death. In a clinical setting, the short (approximately 1 microm) path-length of the tritium beta particle should limit effects to the tumor cells and spare adjacent normal cells. These results support the concept that treatment with the combination of polyamine inhibitors and radioactive polyamines might be a useful adjunct to current therapies for glioblastoma multiforme.

Characterization of the stage in natural killer cell development in 14.5-day mouse fetal liver using adult bone marrow stroma.

Nonstimulated fetal liver (FL) from 14.5-day gestation mice had no natural killer (NK) cell activity and <3% expressed NK1.1. Even after short-term (3-4 day) culture of FL with the late-acting cytokines, interleukin (IL)-15 or IL-2, little or no NK activity was detected. However, longer-term (13 day) culture with IL-2 plus stroma derived from bone marrow (BM) of adult mice, resulted in extensive proliferation and differentiation to mature NK cells. Cell numbers began to increase after 4 days, and by day 13, they had increased 40-fold and 69% of the cells were NK1.1+ with high NK activity and 5%-10% were NK1.1- B220+. With stroma, but no IL-2, equivalent proliferation occurred, but differentiated cells were predominantly NK1.1- B220+, not NK cells. Culture for 13 days without stroma, but with either IL-2, IL-15, FLTK3-ligand (L) or stroma-conditioned medium, resulted in less than fivefold expansion, and minimal NK activity. Culture with combinations of FLTK3-L or ckit-L plus IL-15 or IL-2 increased both cell number and NK activity, but the increase in cell number was less than that seen with stroma plus IL-2. By limiting dilution assay on stroma plus IL-2, the precursor frequency was 1/(2660+/-292) whole FL cells and the absolute number, but not the frequency, increased during culture on stroma without IL-2. The NK cell progenitors were found in sorted NK1.1- and Sca-1+ c-kit+ lineage- subpopulations at a frequency of 1/(156+/-52.5). Together, these data suggest that the NK lineage cells in FL are primarily in early stages of development. They are highly proliferative, respond to early acting cytokines and express stem cell markers.

Bone marrow as a potential source of hepatic oval cells.

Bone marrow stem cells develop into hematopoietic and mesenchymal lineages but have not been known to participate in production of hepatocytes, biliary cells, or oval cells during liver regeneration. Cross-sex or cross-strain bone marrow and whole liver transplantation were used to trace the origin of the repopulating liver cells. Transplanted rats were treated with 2-acetylaminofluorene, to block hepatocyte proliferation, and then hepatic injury, to induce oval cell proliferation. Markers for Y chromosome, dipeptidyl peptidase IV enzyme, and L21-6 antigen were used to identify liver cells of bone marrow origin. From these cells, a proportion of the regenerated hepatic cells were shown to be donor-derived. Thus, a stem cell associated with the bone marrow has epithelial cell lineage capability.

Expression of murine CD34 by fetal liver NK cell progenitors.

Although 14.5-day murine fetal liver (FL) has few, if any, mature natural killer (NK) cells, culture of FL with recombinant human IL-2 (rhIL-2) and stroma from irradiated NK longterm bone marrow cultures (NK-LTBMC) allows proliferation and differentiation of NK cell progenitors. Using this system, NK cell progenitors were found in both CD34+ and CD34- sorted subpopulations of FL. The CD34 antigen was expressed by 14+/-1.3% of whole FL cells, while mature NK cells cultured from NK cell precursors in FL did not express the CD34 antigen. Anti-TER-119 mAb reacted with 84%+/-10.3% of the FL cells, and NK cell progenitors were enriched in the TER-119- subpopulation. After coculture with rhIL-2 and stroma, neither TER-119- nor TER-119+ cells expressed antigens associated with T cells (CD3, CD4, and CD8) or myeloid cells (Gr-1 and Mac-1). Only the TER-119 subpopulation generated NK1.1+ (77%) and B220+ (87%) cells. Within the TER-119 subpopulation, both CD34+ and CD34- cells generated cytolytic and NK1.1+ cells after culture. By a limiting dilution assay (LDA) of the Lin (i.e., negative for NK1.1, CD3, CD4, CD8, B220, Gr-1, and TER-119) CD34 positive or negative subpopulations, the calculated mean frequency of NK cell progenitors was about 1/100 for the CD34+Lin- subpopulation and about 1/(200-300) for the CD34-Lin- subpopulation. In kinetic studies, we found that NK1.1 antigen expression continued to increase with time in culture for both the CD34+Lin- and CD34-Lin- fractions. In contrast, the percentage of CD34+ cells decreased rapidly and produced CD34- cells, and the CD34- population remained CD34-. These data suggest that both CD34+ and CD34- subpopulations of FL can differentiate into NK cells when cocultured for 13 days with irradiated NK-LTBMC stroma and rhIL-2, and that CD34+ progenitors differentiate to CD34- precursors, which in turn differentiate to CD34- mature NK cells.

Lack of natural killer cell precursors in fetal liver of Ikaros knockout mutant mice.

The role of Ikaros in early stages of natural killer (NK) cell differentiation was investigated using an in vitro system that promotes proliferation and differentiation of NK cell precursors into mature NK1.1+ cells. Day 14.5 fetal liver cells from mice, either homozygous for Ikaros Null or dominant negative (DN) mutations, had severe 55- to 79-fold reductions in functional NK cell precursors. Although there was no statistically significant difference between values for +/+ and +/- Null mice, the mean precursor frequency for DN mutant (+/-) mice was significantly above that for DN -/- mice and below that for DN +/+ mice. The NK activity values for cells generated from the NK cell precursors followed the same respective relationships found for NK cell precursor frequencies. These data suggest that the deficiency of mature NK cells in Ikaros mutant mice is related to lack of functional precursors.

Constitutive systemic expression of IL-1Ra or soluble TNF receptor by genetically modified hematopoietic cells suppresses LPS induction of IL-6 and IL-10.

We have been developing both local and systemic gene therapy approaches to treat inflammatory and autoimmune diseases. To determine if systemic, constitutive expression of biologically active anti-inflammatory agents is therapeutic and/or has associated toxicity, mouse hematopoietic stem cells were infected with retroviral vectors carrying the genes for human IL-1 receptor antagonist (IL-1Ra), human soluble TNF receptor p75 (sTNFR), or the beta-galactosidase (lacZ) gene, and transplanted into lethally irradiated recipients. The serum levels of human IL-1Ra and human sTNFR in the long-term reconstituted mice, 2-7 months after transplantation, were 596 and 158 ng/ml respectively. The long-term expression of human IL-1Ra had minimal effects on the PBMC profile whereas human sTNFR expression increased the percentage of B220 and Mac.1 stained cells and decreased slightly the specific T cell subsets. The ability of these proteins to protect the transplanted mice from endotoxin treatment was determined by measuring serum interleukin-6 (IL-6) and interleukin-10 (IL-10) responses after LPS injection at 1.5, 3, 4.5 and 24 h after treatment. The IL-1Ra group showed diminished IL-10 levels and less mortality after injection of LPS. These results demonstrate that constitutive, systemic expression of IL-1Ra and sTNFR is able to confer partial protective effects following treatment with endotoxin. These results further demonstrate that gene transfer methods which result in systemic, long-term expression of immunodulatory proteins could be applied to the treatment of inflammatory diseases.

Durable mixed allogeneic chimerism and tolerance by a nonlethal radiation-based cytoreductive approach.

For over 40 years, the association between hemopoietic chimerism and donor-specific tolerance for allografts has been recognized. However, toxicity associated with lethal conditioning has prevented the clinical application of bone marrow (BM) chimerism to induce tolerance. We previously demonstrated that engraftment could be achieved with less than total recipient myeloablation (700 cGy) and that the incidence of engraftment correlated with the dose of total body irradiation (TBI). Administration of cyclophosphamide (CyP) on Day +2 reduced the minimum TBI dose sufficient to permit engraftment to 500 cGy. In the current study, addition of antilymphocyte globulin (ALG) to the TBI/CyP-based conditioning approach reduced the radiation required for engraftment to < or = 300 cGy. B10 (H-2b) mice conditioned with ALG on day -3, 300 cGy of TBI with transplantation of B10.BR (H-2k) or BALB/c (H-2d) BM on day 0, and CyP on day +2 exhibited evidence of donor chimerism (49.6 +/- 3.7% and 38.2 +/- 2.4%, respectively) in 97% of recipients. ALG eliminated CD4+ and CD8+ cells and decreased NK1.1+ cells in the peripheral circulation at the time of transplantation. Moreover, T and NK cells in the host BM were significantly decreased compared with cells of recipients conditioned with TBI alone. CyP delayed repopulation of host thymocytes, providing time for the establishment of donor chimerism before production of mature T cells. Chimeric animals exhibited stable multilineage chimerism and donor-specific tolerance to skin grafts and in in vitro assays. This model may provide a clinically acceptable approach for the induction of donor-specific transplantation tolerance.

Retroviral gene transfer and sustained expression of human arylsulfatase A.

Transduction of mouse hematopoietic stem cells and their progeny was studied using a recombinant retroviral vector (MFG-ASA) which incorporates the human arylsulfatase A gene (ASA; EC 3.1.6.8). Successful transduction was demonstrated in spleen colonies of mice that received bone marrow transplantation, cultured bone marrow-derived macrophages, visceral tissues and brain of long-term reconstituted mice, and also the spleen colonies of secondarily transplanted mice. The efficiency of transduction in primary spleen colonies was 90%. Expression of the ASA transgene exceeded endogenous levels in spleen colonies and in cultured macrophages by 50-100%. Enzyme activity in the visceral tissues of long-term reconstituted mice consistently showed elevated ASA activity, greater than three-fold in the spleen and lung of one animal. Increased activity of ASA also could be detected in secondary spleen colonies. These data demonstrate the usefulness of the MFG-ASA vector for efficient gene transfer and expression in mouse hematopoietic stem cells and their differentiated progeny. The presence of vector DNA in the brain 4 months after transplantation suggests a role for gene transfer and stem cell transplantation in the treatment strategies for metachromatic leukodystrophy.

Natural killer cell precursors in the CD44neg/dim T-cell receptor population of mouse bone marrow.

Natural killer (NK) cells develop from the nonadherent cell component of NK long-term bone marrow (BM) cultures (NK-LTBMC). Because these nonadherent cells are depleted of mature NK cells and T cells, but appear to enriched for NK precursors, they were used as a starting population to begin to define the NK precursors that function in NK-LTBMC. As the stromal cell component of NK-LTBMC has been shown to support interleukin (IL)-2-induced, CD44 dependent, NK cell development from nonadherent NK precursors, NK-LTBMC stroma was used in a limiting dilution assay (LDA) to quantitate the precursors. NK-LTBMC in 96-well plates were irradiated (20 Gy) to kill hematopoietic cells (including the NK precursors), seeded with limiting dilutions of the cells to be quantitated, cultured with 500 U/mL IL-2 for 13 days and assayed for development of NK activity by adding 51Cr-labeled YAC-1 cells to the wells and evaluating the release of 51Cr after 4 hours. Flow cytometric analysis, sorting, and quantitation of the nonadherent cell component of NK-LTBMC showed that NK precursors were concentrated in the CD44neg/dim subset that comprised 10% of the "lymphoid" gated cells. When the CD44neg/dim subset was sorted from BM of mice treated with 5-fluorouracil (5-FU) day before (-1FUBM), there were about 30% T cells, but no NK-1.1+ cells. When the T cells were removed by sorting and the CD44neg/dim, alphabeta, gammadelta T-cell receptorneg (TCR-) subpopulation was seeded onto irradiated stroma with IL-2, they proliferated, developed NK activity, became NK-1.1+ and CD44bright and remained alphabeta, gammadelta TCR-. The frequency of NK precursors in this population as estimated from the LDA was about 1/500.

Mixed allogeneic chimerism induced by a sublethal approach prevents autoimmune diabetes and reverses insulitis in nonobese diabetic (NOD) mice.

Evidence in experimental models suggests that many autoimmune diseases can be prevented by transplantation of bone marrow from disease-resistant donors. For potential clinical application, it would be important to avoid the morbidity and mortality associated with lethal conditioning and achieve mixed chimerism using less than complete recipient ablation. We report here for the first time that stable chimerism achieved in NOD mice using a sublethal radiation-based conditioning approach is sufficient to prevent beta-cell destruction and abrogate insulitis in prediabetic NOD mice. The percentage of NOD mouse recipients (8 wk of age) that engrafted with donor bone marrow correlated with the dose of irradiation and number of bone marrow cells transplanted. Engraftment of B10.BR bone marrow occurred in > or = 94% of animals receiving > or = 750 cGy of total body irradiation before bone marrow transplantation and > or = 30 x 10(6) bone marrow cells, while reproducible engraftment did not occur at radiation doses of less than 700 cGy and cellular doses of less than 30 x 10(6) bone marrow cells. All chimeric animals remained free of diabetes (n = 38) for 10 mo following bone marrow transplantation. Moreover, in all animals examined, no insulitis was present from 12 to 36 wk following reconstitution. In striking contrast, 61% (22 of 36) of NOD recipients that were conditioned but did not receive bone marrow developed acute diabetes by 12 mo. Insulitis was present in all remaining animals. These results suggest that allogeneic chimerism achieved using a sublethal conditioning approach can prevent the onset of diabetes and even reverse preexisting insulitis in NOD mice.

A nonlethal conditioning approach to achieve durable multilineage mixed chimerism and tolerance across major, minor, and hematopoietic histocompatibility barriers.

Reconstitution of lethally irradiated mice with a mixture of syngeneic and allogeneic (A+B-->A) bone marrow results in multilineage mixed allogeneic chimerism, donor-specific transplantation tolerance, superior immunocompetence and resistance to graft-vs-host disease. However, the morbidity and mortality associated with lethal irradiation would be a major limitation to the clinical application of chimerism to induce tolerance for solid organ grafts or treat other nonmalignant hematologic diseases. We report here that durable multilineage mixed allogeneic chimerism and donor-specific transplantation tolerance for skin and primarily vascularized allografts can be achieved across multiple histocompatibility barriers using a nonmyeloablative radiation-based approach. The percentage of B10 mouse recipients that engrafted directly correlated with the degree of disparity between donor and recipient and the dose of total body irradiation administered. Although the occurrence of engraftment following conditioning with doses of total body irradiation of > or = 600 cGy was similar for animals receiving bone marrow disparate at MHC or MHC, minor and hematopoietic (Hh-1) loci (67% vs 78%), the level of donor chimerism was significantly less when multiple histocompatibility barriers were present (94.6 +/- 3.8% vs 37.5 +/- 12.5%). Treatment of the recipient with cyclophosphamide 2 days following allogeneic bone marrow transplantation reduced the dose of radiation sufficient for reliable engraftment to only 500 cGy of total body irradiation, regardless of MHC and Hh-1 disparity. Donor chimerism was stable and present in all lineages, with production of lymphoid (T and B cell), NK, and myeloid (erythrocyte, platelet, granulocyte, and macrophage) cells. Mixed chimeras exhibited donor-specific tolerance in vitro, as assessed by mixed lymphocyte culture (MLR) and cytotoxicity (CML) assays, and in vivo to skin and primarily vascularized cardiac allografts. The observation that engraftment and tolerance can be achieved across multiple histocompatibility barriers using nonmyeloablative recipient conditioning may allow allogeneic bone marrow transplantation to be applied to nonmalignant disease states in which lethal conditioning cannot be justified, including the induction of donor-specific tolerance for solid organ transplantation and the treatment of hemoglobinopathies and enzyme deficiency states.

Prolonged systemic expression of human IL-1 receptor antagonist (hIL-1ra) in mice reconstituted with hematopoietic cells transduced with a retrovirus carrying the hIL-1ra cDNA.

This study was designed to test the feasibility and safety of long-term expression of high levels of secreted human interleukin-1 receptor antagonist (hIL-1ra) protein in mice by retroviral transduction of hematopoietic stem cells. The retroviral vector, CRIP-MFG-hIL-1ra (MFG-IRAP), carrying the hIL-1ra gene was used to infect mouse bone marrow (BM) which was subsequently injected into lethally irradiated mice. All of the mice survived and greater than 98% of the white blood cells (WBC) of these mice were of donor type from 2-13 months after transplantation. All of the mice had hIL-1ra protein in their sera (40-1200 ng of hIL-1ra/ml) at all assay periods for at least 15 months after transplantation. Bone marrow from seven of seven primary recipients produced at least one secondary recipient with sustained, high serum levels of hIL-1ra, indicating that hematopoietic stem cells had been successfully transduced. Although the hIL-1ra was biologically active when assayed in vitro, the mice appeared to be well and their WBC counts and hematocrit (HCT) were not significantly different from those of lethally-irradiated mice given BM cells infected with the same vector carrying the lacZ gene. There was also no evidence of alterations of white cell subpopulations. These results demonstrate that systemic production of biologically active hIL-1ra can be obtained by retrovirus-mediated gene transfer to hematopoietic stem cells and that this level of expression and secretion into the serum is compatible with normal BM engraftment, hematopoietic recovery and survival of the lethally irradiated recipient mice. These hIL-1ra-expressing mice represent a model to examine the functions of IL-1 and hIL-1ra and to determine the ability of hIL-1ra to reduce susceptibility to chronic diseases such as rheumatoid arthritis as well as effects of aging such as bone degeneration. The data further suggest that transduction and transplantation of hematopoietic stem cells is a potential method for delivery of hIL-1ra and other secreted therapeutic gene products for systemic diseases.

A minimal conditioning approach to achieve stable multilineage mouse plus rat chimerism.

Transplantation of untreated rat bone marrow into lethally irradiated (950 cGy) mouse recipients results in durable xenogeneic (rat-->mouse) chimerism and confers donor-specific transplantation tolerance for subsequent xenografts. The purpose of the present study was to characterize the minimal dose of total body irradiation (TBI) which would allow engraftment of rat bone marrow in mouse recipients. We report here that durable and stable lymphohaematopoietic cross-species chimerism can be achieved using a less than totally ablative radiation-based conditioning approach. The percentage of B10 mouse recipients which engrafted with rat bone marrow cells correlated with the dose of TBI. Engraftment of rat bone marrow stem cells occurred in all animals receiving 750 cGy prior to bone marrow transplantation, while no engraftment was detected at doses less than 650 cGy. Although most of the recipients were repopulated with mixed mouse and rat multilineage chimerism, some exhibited a predominance of rat cells. Although mixed xenogeneic rat/mouse chimeras prepared by lethal TBI produced only mouse derived RBC (red blood cells), chimeras prepared by sublethal conditioning produced both rat and mouse RBC. Only animals with detectable chimerism exhibited specific functional transplantation tolerance to donor xenoantigens, as assessed in vitro by mixed lymphocyte reaction assay. This model may offer an in vivo approach to study the role of species-specific growth factors in stem cell biology as well as the mechanisms for the induction of tolerance across species barriers.

Short-term myeloid reconstitution following TBI is not adversely affected by doses of FK506 that abrogate lethal GVHD.

Studies were undertaken to determine whether the doses of FK506 that are effective for acute GVHD prophylaxis following lethal irradiation and bone marrow transplantation (BMT) would also suppress myeloid cell reconstitution. FK506 (3 mg/kg/day) abrogated acute lethal graft versus host disease (GVHD) in lethally irradiated C57BL/10SnJ (H-2b) recipient mice given histoincompatible BM plus spleen cells from B10.BR (H-2k) donors and this dose was used in all of the studies. Endogenous and exogenous myeloid repopulation was studied in mice given daily injections of either FK506, an equivalent amount of carrier solvent or no treatment throughout the interval between total body irradiation (TBI) and the day of assay. Repopulation was studied after 400 or 500 cGy TBI (endogenous) and after 950 cGy TBI plus injection with syngeneic BM (exogenous). No consistent adverse effects of FK506 were seen during either exogenous or endogenous recovery. Parameters studied included hematocrit (Hct), WBC count, cells per humerus, spleen weight, splenic colony-forming units, % spleen or BM 59Fe uptake and colony forming cells per humerus. Similarly, when lethally irradiated secondary recipients were reconstituted with BM from FK506 treated primary recipients (lethal irradiation plus exogenous BM), no consistent effects were observed. These data suggest that FK506 given to prevent GVHD would not compromise the myeloid recovery that is critical for survival in the interval of time following shortly after BMT.

Role of CD44 in the development of natural killer cells from precursors in long-term cultures of mouse bone marrow.

The role of the adhesion molecule CD44 in the development of NK cells was analyzed in a mouse long-term bone marrow culture system. After 4 wk of culture (day 0), recombinant human IL-2 was added and 13 days later the cells generated were shown to have substantial cytotoxic activity against YAC-1 and to be enriched for NK cells, as assessed for NK-1.1 phenotype by flow cytometric analysis. Physical separation between stroma and precursors partially inhibited proliferation and, consequently, a lower number of cytotoxic cells were produced. Similar results were obtained when an anti-CD44 mAb was added together with IL-2 at day 0. The disruption of hyaluronic acid (HA), one of the ligands of CD44, by hyaluronidase or the competition for the binding of CD44 by soluble HA added with IL-2 on day 0 inhibited both proliferation and development of cytotoxicity to a greater degree than did anti-CD44. These results indicate that interaction of CD44 with HA plays an important role in the development of pre-NK cells into cytotoxic effector cells.

Purified murine hematopoietic stem cells function longer on nonirradiated W41/Wv than on +/+ irradiated stroma.

Mouse bone marrow (BM) was separated into low-density, lineage-negative, wheat germ agglutinin-positive (WGA+), Rhodamine-123 bright (Rhbright) or dim (Rhdim) cells to obtain populations that were highly enriched for committed progenitors (Rhbright cells) or for more primitive stem cells (Rhdim). When 2,500 Rhbright or Rhdim cells were seeded onto 6-week-old irradiated (20 Gy) long-term BM cultures (LTBMC), the nonadherent cell production from Rhbright cells was transient and ended after 5 weeks. Production from Rhdim cells did not begin until week 3, peaked at week 5, and ended at week 8, when the irradiated stroma seemed to fail. Termination of cell production from Rhdim cells did not occur in nonirradiated LTBMC from W41/Wv mice. During peak nonadherent cell production, 25% to 30% of the cells in the nonirradiated LTBMC from W41/Wv mice had donor cell markers. Two approaches were tested to try to enhance the proportion or number of donor cells. Addition of Origen-HGF at the time of seeding Rhdim cells caused a nonspecific increase in both host and donor cell production, but a specific increase in production of donor cells was obtained by seeding the cultures at 2 weeks rather than 6 weeks. Limiting dilution of Rhdim cells gave the same frequency of wells producing cells on both irradiated +/+ and nonirradiated W41/Wv or W/Wv cultures.

Generation of natural killer cells from long-term cultures of mouse bone marrow.

The features of a mouse long-term bone marrow culture (LTBMC) system that produces natural killer (NK) cell activity are described. Over a 4-week period in the NK-LTBMC, cellularity dropped from approximately 2.5 x 10(7) to 8 x 10(5) cells/25-cm2 flask. About 3 x 10(5) of these cells were loosely adherent. The cultures at this time contained about one-third the spleen colony forming units, one-tenth the granulocyte macrophage colony forming units and about one-third the transplantable NK progenitor activity of fresh bone marrow (BM), and no detectable NK cell activity. In the 4-week NK-LTBMC, IL-2-responsive precursor cells appeared to be selectively maintained and gave an 8-fold higher activity after culture with human recombinant IL-2 (rIL-2) than did fresh BM. The addition of 50-5,000 IU/ml of rIL-2 resulted, after a minimal 3-day lag, in progressively increased cellularity for as long as 13 days. The percentage and staining intensity of NK-1.1+ cells increased with time after addition of rIL-2. CD3 epsilon + cells were occasionally seen and B220+ cells were present in low numbers at day 7 and slowly increased through day 13. The stroma was necessary for IL-2-dependent development of NK activity.

Efficient transfer and sustained high expression of the human glucocerebrosidase gene in mice and their functional macrophages following transplantation of bone marrow transduced by a retroviral vector.

A recombinant retroviral vector (MFG-GC) was used to study the efficiency of transduction of the human gene encoding glucocerebrosidase (GC; D-glucosyl-N-acylsphingosine glucohydrolase, EC 3.2.1.45), in mouse hematopoietic stem cells and expression in their progeny. Transfer of the GC gene to CFU-S (spleen cell colony-forming units) in primary and secondary recipients was virtually 100%. In mice 4-7 months after transplantation, highly efficient transfer of the human gene to bone marrow cells capable of long-term reconstitution was confirmed by detection of one or two copies per mouse genome in hematopoietic tissues and in cultures of pure macrophages. Expression of the human gene exceeded endogenous activity by several fold in primary and secondary CFU-S, tissues from long-term reconstituted mice, and explanted macrophages cultures. These studies are evidence of the feasibility of efficient transfer of the GC gene to hematopoietic stem cells and expression in their progeny for many months after reconstitution. The results of this study strengthen the rationale for gene therapy as a treatment for Gaucher disease.