Thymidine incorporation is highly predictive of colony formation and can be used for high-throughput screening.

The primary goal of anticancer chemotherapy is to kill cancer cells. Therefore, it is of critical importance that any assay that is used to determine the toxicity of a potential anticancer drug accurately measures viability. While colony formation is widely regarded as the most accurate measure of viability following drug treatment, it is laborious, time consuming, and difficult to carry out with non-adherent cells. For these reasons, it is not suitable for moderate- to high-throughput screening applications. We sought to identify a convenient and reliable assay that would accurately reproduce colony formation results and be amenable to high-throughput applications. Here, we describe a modification of the 3H-thymidine incorporation assay that meets these criteria. The assay can be carried out in 96-well plates with minimal handling of reagents and media. It can be performed with non-adherent and adherent cell lines. Most importantly, LC50 values obtained with this assay show excellent agreement with colony formation results. Taken together, these advantages make the modified 3H-thymidine incorporation assay well suited for high-throughput viability assays in anticancer drug discovery and development.

Long-term persistence of canine hematopoietic cells genetically marked by retrovirus vectors.

In 1991 we reported gene transduction into autologous long-term repopulating marrow cells in dogs using amphotropic helper-free retrovirus vectors containing the bacterial neomycin phosphotransferase gene (neo) and the human adenosine deaminase gene (ADA). Two of the dogs are still alive and healthy now more than 5 years after transplantation of transduced autologous marrow cells. In one of the surviving dogs, polymerase chain reaction (PCR) analysis showed the neo and ADA genes to be present in peripheral blood granulocytes and lymphocytes up to the present time. The estimated percentage of neo-positive cells ranged from < 0.001% to 0.1%. ADA mRNA expression was detected by reverse transcriptase PCR (RT-PCR) in granulocytes 63 months after transplantation. The other surviving dog failed to show either persistence or expression of the transduced genes after 50 months. Three additional dogs have been transplanted according to the same transduction protocols and with the same retrovirus vectors, and persistence of the transduced neo gene has been documented in peripheral blood myeloid and lymphoid cells along with G418-resistant colony-forming unit-granulocyte/macrophage (CFU-GM) for now more than 2 years. These findings represent the longest follow-up of retrovirus-mediated gene transduction in any animal species. Long-term transduction efficiency, though, has remained low and will need to be improved for therapeutic application to be possible.

Myelosuppressive conditioning improves autologous engraftment of genetically marked hematopoietic repopulating cells in dogs.

We have studied the role of different conditioning regimens for engraftment of genetically marked hematopoietic repopulating cells in dogs. Peripheral blood (PB) and/or marrow cells collected after treatment with recombinant canine stem cell factor (rcSCF) or cyclophosphamide were transduced in a vector-containing long-term culture system. Three different vector-producing cell lines with similar viral titers were used. In two of them, the neo-containing LN vector was packaged either in the PA317 cell line with an amphotropic murine retrovirus envelope or the PG13 cell line with the gibbon ape leukemia virus (GALV) envelope. The MFG/GC vector produced in PA317 cells contained the human glucocerebrosidase gene. Nineteen dogs received either no conditioning (group A, n = 5), irradiation to both humeri with 1,000 cGy (group B, n = 5), a sublethal dose of cyclophosphamide 40 mg/kg (group C, n = 4), a sublethal dose of 200 or 300 cGy total body irradiation (TBI) (group D, n = 3), or an otherwise lethal dose of 920 cGy TBI (group E, n = 3) before intravenous (groups A, C, D, E) or intramedullary (group B) infusion of the transduced autologous hematopoietic cells. Transduction efficiency of hematopoietic cells at the time of infusion into the animals was similar among the different conditioning groups. Dogs were observed for at least 6 months. PB granulocytes were obtained at least every 3 weeks after transplant and analyzed by polymerase chain reaction for the presence of the transduced genes. The percentages of positive results in dogs more than 4 weeks after transplantation were 0% without conditioning, 5% with local irradiation, 18% with sublethal cyclophosphamide, 33% with sublethal TBI, and 17% with otherwise lethal TBI. Analyzing the influence of conditioning regimens by a generalized estimating equation (GEE) technique, which considered the use of different retrovirus vectors and the number of mononuclear cells infused as potential confounding variables, we found that engraftment of genetically marked repopulating cells was significantly improved (P < .001) in dogs receiving systemic conditioning with either otherwise lethal TBI, sublethal TBI, or sublethal cyclophosphamide compared to dogs with local irradiation only or no conditioning. Within the limitation of the experimental design, these data suggest that myeloablative or myelosuppressive conditioning improves engraftment of genetically marked hematopoietic repopulating cells.

Increased gene transfer into human hematopoietic progenitor cells by extended in vitro exposure to a pseudotyped retroviral vector.

Retroviral-mediated gene transfer is the most attractive modality for gene transfer into hematopoietic stem cells. However, transduction efficiency has been low using amphotropic Moloney murine leukemia virus (MoMLV) vectors. In this study, we investigated modifications of gene transfer using amphotropic MoMLV vectors in cell-free supernatant for their ability to increase the currently low transduction of both committed hematopoietic progenitors, granulocyte-macrophage colony-forming units (CFU-GMs), and their precursors, long-term culture-initiating cells (LTC-IC). First, based on the observation that bone marrow cells express more gibbon ape leukemia virus (GALV) receptor (Glvr-1) than amphotropic receptor (Ram-1), PG13/LN, which is a MoMLV vector pseudotyped with the GALV envelope, was compared with the analogous amphotropic envelope vector (PA317/LN). Second, progenitor cell transduction efficiency was compared between CD34 enriched and nonenriched progenitor populations. Third, the duration of transduction in vitro was extended to increase the proportion of progenitor cells that entered cell cycle and could thereby integrate vector cDNA. In 20 experiments, 1 x 10(6) marrow or peripheral blood mononuclear cells (PBMCs)/mL were exposed to identical titers of pseudotyped PG13/LN vector or PA317/LN vector in the presence of recombinant human interleukin-1 (IL-1), IL-3, IL-6, and stem cell factor (SCF; c-kit ligand) for 5 days. 50% of fresh vector supernatant was refed daily. Hematopoietic progenitor cells as measured by G418-resistant granulomonocytic colony (CFU-GM) formation were transduced more effectively with PG13/LN (19.35%) than with PA317/LN (11.5%, P = .012). In 11 further experiments, enrichment of CD34 antigen positive cells significantly improved gene transfer from 13.9% G418-resistant CFU-GM in nonenriched to 24.9% in CD34-enriched progenitor cells (P < .01). To analyze gene transfer after extended growth factor-supported long-term culture, 1 x 10(6) marrow cells/mL were cultured with IL-1, IL-3, IL-6, and SCF (50 ng/mL each) for 1, 2, and 3 weeks. Fifty percent of PG13/LN supernatant with growth factors was refed on 5 days per week. Five percent of marrow CFU-GM and 67% of LTC-IC were G418 resistant at 1 week (n = 4), 60% of CFU-GM and 100% of LTC-IC were resistant at 2 weeks (n = 2) and 74% of CFU-GM (n = 4) and 82% of LTC-IC (n = 2) were resistant at three weeks.(ABSTRACT TRUNCATED AT 400 WORDS)

Retrovirus-mediated gene transduction into canine peripheral blood repopulating cells.

Genetically marked peripheral blood progenitor cells were used to investigate their contribution to long-term hematopoietic reconstitution after autologous marrow and peripheral blood cell transplantation. After autologous marrow harvest and cryopreservation, canine peripheral blood progenitor cells were mobilized in three dogs by treatment with recombinant canine stem cell factor for 8 days. Peripheral blood mononuclear cells were collected and enriched for major histocompatibility complex (MHC) class II antigen-positive cells by avidin-biotin immunoadsorption, thereby enriching for repopulating cells. Subsequently, the cells were cocultivated for 24 hours on irradiated vector-producing packaging cells (PA317/LN), followed by an 11-day incubation in a vector containing long-term marrow culture system. On the day of transplantation, the animals were irradiated with 9.2 Gy total body irradiation (TBI), and transduced peripheral blood cells and untransduced cryopreserved marrow cells were infused within 2 hours of TBI. All three dogs engrafted. Two dogs are long-term survivors showing intermittently G418-resistant marrow-derived colony-forming unit granulocyte-macrophage colonies at a median of 1% and 2%, respectively (range, 1% to 10%), for now up to 48 weeks after transplantation. Neo-specific sequences were detected by polymerase chain reaction in peripheral blood granulocytes for now up to 65 weeks and in peripheral blood lymphocytes for up to 75 weeks after transplantation. Peripheral blood samples of the dogs were free of helper virus and no side effects from the transduction were observed. One of the three dogs died from chronic canine distemper sclerosing encephalitis on day 84, whereas the other two dogs are alive at 15 and 17 months. Our data show successful retroviral transduction of canine peripheral blood repopulating cells. Long-term persistence of marked myeloid and lymphoid cells after transplantation suggests that peripheral blood contains repopulating cells that contribute to long-term hematopoietic reconstitution after otherwise lethal TBI.

Retrovirus-mediated gene transduction into long-term repopulating marrow cells of dogs.

Amphotropic helper-free retrovirus vectors containing the bacterial neomycin phosphotransferase gene (neo) and the human adenosine deaminase gene (adenosine aminohydrolase, EC 3.5.4.4; ADA) were used to transduce canine marrow cells. In one approach, dogs were treated for 7 days with recombinant human granulocyte colony-stimulating factor to stimulate hematopoietic cell division. Bone marrow cells were collected and transduced by 24 hours of cocultivation on vector-producing cells followed by incubation in a vector-containing long-term marrow culture system for 4 days. Transduced autologous marrow (0.4 to 1.0 x 10(8) cells/kg) was infused into dogs administered otherwise lethal total body irradiation (TBI) of 920 cGy. Two of four dogs engrafted, and their marrows showed intermittently between 1% and 11% G418-resistant colony-forming unit granulocyte-macrophage (CFU-GM) colonies for up to 2 years after transplantation. In a different experimental approach, autologous marrow, obtained at the time of the PB neutrophil nadir 7 days after a single cyclophosphamide injection (40 mg/kg intravenously), was cocultivated for 24 hours on vector-producing cells and infused at doses of 0.06 to 0.18 x 10(8) cells/kg into dogs administered 920 cGy TBI. One of three dogs engrafted, and the marrow showed intermittently 1% to 10% G418-resistant CFU-GM colonies for at least 2 years. Culture results were confirmed by polymerase chain reaction (PCR) showing the presence of the neo gene in marrow cells, peripheral blood (PB) granulocytes, and PB and lymph node lymphocytes. Dilution experiments indicated that up to 10% of marrow, lymph node, and PB cells contained the neo gene, consistent with the culture results. Samples harboring the neo gene also contained the gene for human ADA. However, repeated analyses of PB and marrow cells for human ADA gene expression by starch gel electrophoresis were negative. PB samples of all dogs were free of helper virus, and no long-term side effects from the transduction were observed.

Biochemical characterization of a unique canine myeloid antigen.

In marrow transplantation, radioisotope-labeled monoclonal antibodies may provide a way to selectively deliver high doses of radiation to target tissues (marrow in the case of myeloid malignancies) without significant toxicity to other normal organs. This paper describes the production and characterization of a novel monoclonal antibody, DM5, that we have developed for use in an animal model of radiotherapy targeted to the marrow. DM5 recognizes three glycosylation variants, gp19,21,23DM5, of a polypeptide core that is expressed on canine cells of the myeloid lineage, but not on lymphoid cells. The antigen recognized by DM5 is not present on most progenitor cells as determined by CFU-GM assays of DM5 positive and negative cell populations.

Recombinant human granulocyte colony-stimulating factor accelerates hematopoietic recovery after DLA-identical littermate marrow transplants in dogs.

We studied whether treatment of dogs with recombinant human granulocyte colony-stimulating factor (rhG-CSF), after 920 cGy total body irradiation (TBI) and transplantation of 3.3 +/- 1.0 x 10(8) bone marrow cells per kilogram from a DLA-identical littermate, accelerated hematopoietic recovery and influenced the incidence of subsequent marrow graft failure or graft-versus-host disease (GVHD). Ten animals were treated with 100 micrograms rhG-CSF/kg/d from days 1 through 10 after TBI. Results were compared with those of historical control of 14 dogs not administered rhG-CSF. Neither group of dogs received GVHD prophylaxis. The median time to recovery of 1,000 neutrophils/mm3 was 8 days for dogs administered rhG-CSF compared with 14 days in controls (logrank test: P less than .03). The median time to reach 100 monocytes/mm3 was 17 days in G-CSF-treated dogs compared with 49 days in controls (P less than .002). The median time to attain 500 lymphocytes/mm3 was 15 days versus 31 days, respectively (P less than .01). The median time to reach 20,000 platelets/mm3 was 26 versus 20 days (P = .68). Graft failure occurred in 1 of 10 G-CSF-treated dogs versus 2 of 14 controls (two-tailed Fisher's exact test: P = 1.00). GVHD was seen in 4 of 9 rhG-CSF-treated dogs compared with 1 of 12 controls (P = .12). Two G-CSF-treated dogs died of GVHD versus none of the controls (P = .17). No unusual toxicities were seen in dogs receiving rhG-CSF. In summary, rhG-CSF significantly accelerated recovery of neutrophils, monocytes, and lymphocytes after DLA-identical littermate marrow transplantation without altering platelet recovery. Graft failure was not seen more often than in controls, but there was a trend toward an increased incidence of GVHD.

Effect of recombinant human granulocyte colony-stimulating factor on hematopoiesis of normal dogs and on hematopoietic recovery after otherwise lethal total body irradiation.

This study was designed to test whether recombinant human G-CSF (rh G-CSF) affects hematopoiesis in normal dogs and, if so, to test the effects of G-CSF in dogs given otherwise lethal total body irradiation (TBI). Rh G-CSF given subcutaneously at 10 or 100 micrograms/kg/d for 14 days to two normal dogs increased peripheral blood neutrophils eight to tenfold and monocytes four to sixfold above controls. Lymphocyte counts remained unchanged at the lower dose and increased threefold at the higher dose of rh G-CSF. No significant changes were observed in eosinophil, platelet, reticulocyte, or hematocrit levels. After 2 weeks of treatment with rh G-CSF, bone marrow displayed myeloid hyperplasia and left-shifted granulocytopoiesis. After discontinuation of rh G-CSF, peripheral leukocyte counts returned to control levels within three days. Five dogs administered 400 cGy TBI at 10 cGy/min from two opposing 60Co sources and no marrow infusion or growth factor, all developed profound pancytopenia and died between 17 and 23 days after TBI with infections secondary to marrow aplasia. Four of five dogs treated within two hours after 400 cGy TBI with 100 micrograms rh G-CSF/kg/d subcutaneously twice a day for 21 days showed complete and sustained endogenous hematopoietic recovery. In contrast, five dogs irradiated with 400 cGy TBI and treated with 100 micrograms rh G-CSF/kg/d starting on day 7 after TBI, all died between days 17 and 20 after TBI with infections secondary to marrow aplasia. Rh G-CSF, if administered shortly after irradiation, can reverse the otherwise lethal myelosuppressive effect of radiation exposure.

Stimulation of canine hematopoiesis by recombinant human granulocyte-macrophage colony-stimulating factor.

The effect of recombinant human granulocyte-macrophage colony-stimulating factor (rhGM-CSF) on canine hematopoiesis was evaluated. rhGM-CSF stimulated granulocyte-macrophage colony formation of canine marrow depleted of accessory cells up to tenfold. Stimulation of colony formation was abrogated by anti-rhGM-CSF antiserum or heat inactivation. rhGM-CSF also stimulated in vivo canine hematopoiesis both when given as continuous i.v. infusion and as intermittent s.c. injections. Neutrophil, monocyte, and lymphocyte counts were increased three- to eightfold above controls, whereas values for eosinophils, reticulocytes, and hematocrits were not changed. Bone marrow histology after 2 weeks of treatment with rhGM-CSF showed hypercellularity with myeloid hyperplasia and left-shifted granulocytopoiesis. After discontinuation of rhGM-CSF, peripheral leukocyte counts returned to control level within 3-7 days. Platelet counts decreased rapidly after starting rhGM-CSF, to 5000-15,000 platelets/mm3, and increased within 24 h after stopping rhGM-CSF treatment, whereas marrow histology after 2 weeks of rhGM-CSF application showed the normal number and morphology of megakaryocytes.

Improved retroviral transfer of genes into canine hematopoietic progenitor cells kept in long-term marrow culture.

Amphotropic helper-free retroviral vectors containing either the bacterial neomycin phosphotransferase gene (NEO) or a mutant dihydrofolate reductase gene (DHFR*) were used to infect canine hematopoietic progenitor cells. In previous experiments, successful transfer and expression of both genes in canine CFU-GM were achieved after 24-hour cocultivation with virus-producing cells. The average rate of gene expression was 10% (6% to 16%) as measured by the number of CFU-GM resistant to either the aminoglycoside G418 or methotrexate. In an attempt to increase the efficiency of gene transfer, marrow was cocultured for 24 hours with either NEO or DHFR* virus-producing packaging cells and then kept in long-term marrow culture fed three times with virus-containing supernatant (2 to 5 x 10(6) CFU/mL). After six days, cells were harvested and cultured in CFU-GM assay with and without a selective agent. The average rate of gene expression in CFU-GM in five independent experiments was 46% and ranged from 19% to 87%. In conclusion, the efficiency of gene transfer into canine hematopoietic progenitor cells has been increased fourfold by combining cocultivation with long-term marrow culture as compared with results obtained with cocultivation only.

Long-term culture of canine bone marrow cells.

Conditions that allow the growth of canine marrow cells in long-term marrow culture are described. The quality of the culture conditions was evaluated based on the weekly number of granulocyte-macrophage colony-forming units (CFU-GM) in the nonadherent cell fraction. Using this parameter, the highest number of CFU-GM was obtained when marrow cells were incubated at 37 degrees C in RPMI-1640 or McCoy's 5A medium supplemented with 20% prescreened horse serum without addition of hydrocortisone. CFU-GM colonies could be regularly grown out of the nonadherent cell fraction for 20-31 weeks, after recharging the cultures with 1.5 X 10(7) mononuclear autologous marrow cells 1 week after establishing the stromal cell layer.

Use of thymic grafts or thymic factors to augment immunologic recovery after bone marrow transplantation: brief report with 2 to 12 years' follow-up.

Thymus tissue implants, thymic epithelial cells obtained from third party donors sharing one HLA-A and -B locus with the recipient, or the thymic hormones thymosin fraction 5 and thymopentin were given to recipients of HLA-identical sibling bone marrow to prevent chronic graft-versus-host disease (GVHD) and accelerate immunologic reconstitution. The clinical courses of 17 patients receiving thymus tissue and 18 patients receiving thymic hormones were reported initially 5 years ago and showed no difference in the incidence of chronic GVHD or immunologic recovery from those of concurrent or historical controls. We report here for the first time nine new patients who received thymus tissue implants with modifications of the culture method to lower the number of lymphocytes in the transplanted tissue with the intent of reducing rejection of the thymus tissue grafts. The clinical outcomes and immunologic functions of these nine patients were similar to those of the recipients of the earlier thymus tissue implants. With follow-up now ranging from 2.2 to 12.3 years (median 6.7) for the total group, 16 patients are alive. Seven never developed chronic GVHD. Nine were treated for chronic GVHD, seven of whom recovered and are leading normal lives, one has chronic pulmonary insufficiency, and one is disabled from chronic GVHD. We conclude that thymus tissue grafts or thymic epithelial cells partially HLA-matched to the recipient, thymosin fraction 5, or thymopentin used as described were not effective in reducing the incidence of chronic GVHD, improving immunologic recovery, or altering long-term survival.

Facilitation of engraftment of DLA-nonidentical marrow by treatment of recipients with monoclonal antibody directed against marrow cells surviving radiation.

Past studies in dogs have suggested that marrow graft rejection was mediated by major histocompatibility complex (MHC) class II antigen-positive non-T cells that survived standard doses of total-body irradiation (TBI). We have now raised 4 monoclonal antibodies (mAbs) against marrow cells harvested 6 days after TBI. The mAbs are highly reactive (greater than 70%) with marrow cells surviving radiation and also bind strongly (greater than 50%) to normal marrow cells, lymphocytes, monocytes, and granulocytes. One of the mAbs (34-S3) reacted strongly with NK-like cells. In vitro treatment of marrow with mAb and rabbit complement (C') did not affect erythroid colony-forming unit (CFU-E) growth, whereas 2 of the 4 mAbs inhibited granulocyte-macrophage colony-forming unit (CFU-GM) growth, and all 3 mAbs tested suppressed autologous marrow engraftment. One of the mAbs, 69-S5 (IgG1), bound to a 95,000 dalton antigen. It crossreacted with human cells, but not with cells from Rhesus monkeys, baboons, and cats. We administered this mAb intravenously at 0.2 mg/kg/day on days -5 to 0 to dogs given 9.2 Gy TBI on day 0 followed by marrow grafts (less than or equal to 4 x 10(8) cells/kg) from DLA-nonidentical unrelated donors. Three of five dogs had sustained grafts. Increasing the dose of mAb ten-fold (2 mg/kg/day) resulted in graft failure (2 of 2 dogs). Treatment with a dose of 0.2 mg/kg/day from day -7 to -2 showed sustained engraftment in 7 of 10 dogs. This result is in contrast to sustained grafts in 3 of 36 dogs not given mAb, and in 1 of 7 dogs treated with an irrelevant mAb (P = 0.0002 and 0.04, respectively). We conclude that treatment of recipients with a mAb raised against marrow cells surviving radiation and not directed at major histocompatibility complex (MHC) class II antigens and NK-like cells can also facilitate engraftment of DLA-nonidentical canine marrow. These results may be relevant for the transplantation of HLA-incompatible marrow in man, particularly after in vivo T cell depletion, where graft failure is frequent.

Canine pluripotent hematopoietic stem cells and CFU-GM express Ia-like antigens as recognized by two different class II-specific monoclonal antibodies.

A previous study showed failure of autologous engraftment in lethally irradiated dogs when marrow was treated before infusion with anti-class II antibody 7.2 and complement. The current study extended this observation to a second monoclonal antibody (HB10a) that identifies a different determinant on Ia-like molecules. These results suggest the presence of Ia-like antigens on pluripotent hematopoietic stem cells or on "accessory cells" needed for sustained engraftment to occur. To distinguish between these two possibilities, stem cell-depleted Ia-positive peripheral blood leukocytes obtained by discontinuous albumin density gradient were added as probable source of accessory cells to the marrow inoculum that was depleted of Ia-positive cells by treatment with antibody 7.2 and complement. Eight of ten dogs failed to show engraftment, providing further support for the hypothesis that pluripotent stem cells and not accessory cells were affected by cytolytic treatment. To provide direct evidence for the presence of Ia-like antigens on canine pluripotent hematopoietic stem cells, autologous transplants were performed using 0.7 to 13 X 10(6) Ia (7.2)-positive marrow cells per kg obtained with the help of fluorescence-activated cell sorter. Of three evaluable dogs, two showed sustained and complete engraftment, indicating that Ia-like antigens, as recognized by anti-class II antibody 7.2, are expressed at least on part of canine pluripotent hematopoietic stem cells. Concurrent in vitro studies revealed that canine CFU-GM also expressed Ia-like antigens as recognized by the class II-specific monoclonal antibodies 7.2 and HB10a.

Regulation of immunoglobulin production after human marrow grafting. The role of helper and suppressor T cells in acute graft-versus-host disease.

The effect of acute graft-versus host disease (GVHD) on T4 and T8 lymphocyte regulation of in vitro immunoglobulin production was explored. The peripheral blood lymphocytes from 20 patients were studied sequentially in the first 100 days after sibling bone marrow grafting for hematologic malignancy or aplastic anemia. T and non-T lymphocytes were prepared from peripheral blood by Ficoll-Hypaque density gradient centrifugation and sheep erythrocyte rosetting. T cells were enriched for T4 or T8 cells and cocultured for six days with pokeweed mitogen and autologous non-T or T and non-T cells from unrelated normal individuals. Immunoglobulin production was assessed using a reverse hemolytic plaque assay. All three patients without acute GVHD had failure of non-T cells to secrete immunoglobulin, one had failure of helper T cell activity, and 2 developed suppressor T cells. Similarly, all six patients studied sequentially after the development of GVHD had non-T-cell failure, five developed helper T cell failure, and five had suppressor T cells. These data suggest no difference in lymphocyte function before or after the development of acute GVHD. When the T cells of these patients were split into T4 and T8 subpopulations and studied for immunoglobulin production there was helper T cell failure in 4 of 9 tests with enriched T4 populations. Five of 9 tests with T8 enriched populations showed suppressor activity. Suppressor T cell function was also seen in 4 of 9 tests with with T4-enriched populations. These data show that T cell function does not necessarily correlate with the surface phenotype during the first 100 days after grafting. A role for cytomegalovirus (CMV) infection in bringing out suppressor activity is suggested, because among patients without GVHD, 6 of 8 tests in CMV-positive patients showed suppressor cells compared with none of 4 tests in patients without CMV infection.

Enrichment (and depletion) of human suppressor cells with monoclonal antibodies and immunoglobulin-coated plates.

A cell separation method using immunoglobulin (Ig)-coated plates, originally devised for murine spleen cells, was modified and adapted for enrichment (and depletion) of cellular subpopulations from human peripheral blood. For the direct separation of B and T cells, F(ab')2 fragments of anti-human Ig were used to coat the plates. For indirect separation, the cells were first incubated with monoclonal antibodies to cell surface antigens and then separated in plates coated with anti-mouse Ig. Plates were first coated with poly-L-lysine to facilitate the adherence of anti-Ig antibodies, and finally with bovine serum albumin to mask free poly-L-lysine. Cells which did not react with the anti-Ig antibodies or which were nonadherent to the plate were pipetted off; cells which reacted with the anti-Ig antibodies or which were adherent were eluted after incubation with excess serum. T, non-T, T4+, T4-, T8+, and T8- lymphocytes were separated with high viability, purity, and yield. The method was used to study suppressor activity of a patient who was treated by bone marrow transplantation for myelofibrosis. Strong suppressor activity was associated with unfractionated peripheral blood mononuclear leukocytes, monocytes, T, T8+, and T4- cells but not with B, T8-, and T4+ cells.

T-cell subpopulations identified by monoclonal antibodies after human marrow transplantation. I. Helper-inducer and cytotoxic-suppressor subsets.

Peripheral blood helper-inducer and cytotoxic-suppressor T-cell subpopulations in patients receiving marrow transplants for the treatment of acute leukemia or severe aplastic anemia were quantitated on the fluorescence-activated cell sorter (FACS) using the monoclonal antibodies OKT4 and OKT8, respectively. The relative (percent) and absolute number of OKT4+ cells were severely and persistently depleted for up to 2.7 yr posttransplant. In contrast, the percent and absolute number of OKT8+ cells began to recover within the first 60 days of transplant and subsequently remained at normal or high levels for periods of up to 7.3 yr. There was no significant difference in percent or absolute numbers of OKT8+ cells for patients with or without acute graft-versus-host disease (GVHD). The reversal of the normal OKT4:OKT8 ratio (2:1) occurred regardless of whether the recipient was given an allogeneic, syngeneic, or autologous transplant and regardless of whether or not acute or chronic GVHD developed. The reversed ratio was due in the first 3 mo posttransplant to low numbers of OKT4+ cells and later to a combination of low numbers of OKT4+ and high numbers of OKT8+ cells. Normalization and then an increase in the number of OKT8+ cells correlated with increasing time posttransplant and not with resolution of acute GVHD.