T cell depleted haploidentical bone marrow transplantation for the treatment of children with severe combined immunodeficiency.

Severe combined immunodeficiency (SCID) is fatal in early childhood if unrecognized and if not treated. The aim was to determine the efficacy of T cell depleted bone marrow transplantation (TCD BMT) in the treatment of children with SCID. Eleven children diagnosed with SCID received histocompatible related donor bone marrow transplantation--HRD BMT (group I). Thirty seven children diagnosed with SCID who did not have histocompatible donors were treated with TCD haploidentical parental bone marrow transplantation (BMT) (group II). TCD was performed by in vitro soybean lectin agglutination followed by E-rosette depletion. Patients were longitudinally assessed for the presence and function of T and B lymphocytes. In group I all children survived. The mean age of children in this group at the time of HRD BMT was 15.4 months. All surviving patients normalized their specific T cell function. Two out of 11 require treatment with intravenous immunoglobulin i.v. Ig. In group II 17 out of 37 (46%) children survived. At the time of TCD BMT the mean age of survivors was 7.5 months, vs. 11.4 months in patients who died. Death was caused most commonly by opportunistic infections, Epstein-Barr virus induced lymphoproliferative disease (EBV-LPD), and graft versus host disease (GvHD). Seventeen out of 17 surviving patients recovered normal numbers of CD3+ cells and antigen specific T cell function. Five out of 17 never recovered their B cell function and require i.v. Ig injections. Early diagnosis, prevention or treatment of opportunistic infections, and enhancement of immune recovery will be necessary to improve survival in patients with SCID treated with TCD BMT.

The murine stromal cell line AFT024 acts specifically on human CD34+CD38- progenitors to maintain primitive function and immunophenotype in vitro.

A stromal cell line derived from murine fetal liver (AFT024) has been demonstrated to maintain long-term repopulating murine stem cells for up to 7 weeks in vitro. We evaluated the ability of AFT024 to maintain the immunophenotype and function of primitive human progenitors in vitro by comparing the cocultivation of CD34+CD38 cells on AFT024 with that on primary human stroma (HS). We have previously reported that within the CD34+CD38- population of bone marrow and cord blood, a highly primitive progenitor subpopulation can be identified functionally by its ability to generate colony forming unit-cells (CFU-Cs) in extended long-term culture (ELTC), that is, beyond 60 days of stromal cocultivation. Cocultivation of bone marrow and cord blood CD34+CD38-cells on AFT024 produced significantly greater cell expansion (p=0.0002) and CFU-C output (p=0.0007) during the ELTC period compared with culturing on HS. CFU-C production continued up to 9 weeks longer on AFT024 stroma. After 3 to 4 weeks of bulk culture on either AFT024 or HS, cells were replated in a limiting dilution to measure the number of cobblestone area-forming cells (CAFCs) maintained on each stroma. AFT024 maintained significantly more CAFCs than did HS (n=3, p=0.002). Fluorescence-activated cell sorter analysis of AFT024 and HS cocultures showed that both the frequency (p=0.018) and absolute number (p=0.027) of CD34+CD38- cells were significantly higher in cultures on AFT024 than in those on HS (n=9). The effects of AFT024 on preservation of primitive progenitors were not seen in transwell (noncontact) cultures. Thus, AFT024 acts by direct contact to maintain the phenotype and function of the most primitive and quiescent human progenitors currently identifiable by in vitro assays.

T lymphocytes with a normal ADA gene accumulate after transplantation of transduced autologous umbilical cord blood CD34+ cells in ADA-deficient SCID neonates.

Adenosine deaminase-deficient severe combined immunodeficiency was the first disease investigated for gene therapy because of a postulated production or survival advantage for gene-corrected T lymphocytes, which may overcome inefficient gene transfer. Four years after three newborns with this disease were given infusions of transduced autologous umbilical cord blood CD34+ cells, the frequency of gene-containing T lymphocytes has risen to 1-10%, whereas the frequencies of other hematopoietic and lymphoid cells containing the gene remain at 0.01-0.1%. Cessation of polyethylene glycol-conjugated adenosine deaminase enzyme replacement in one subject led to a decline in immune function, despite the persistence of gene-containing T lymphocytes. Thus, despite the long-term engraftment of transduced stem cells and selective accumulation of gene-containing T lymphocytes, improved gene transfer and expression will be needed to attain a therapeutic effect.

In vitro identification of single CD34+CD38- cells with both lymphoid and myeloid potential.

Human hematopoietic stem cells are pluripotent, ie, capable of producing both lymphoid and myeloid progeny, and are therefore used for transplantation and gene therapy. An in vitro culture system was developed to study the multi-lineage developmental potential of a candidate human hematopoietic stem cell population, CD34+CD38- cells. CD34+CD38- cells cocultivated on the murine stromal line S17 generated predominantly CD19(+) B-cell progenitors. Transfer of cells from S17 stroma to myeloid-specific conditions ("switch culture") showed that a fraction of the immunophenotypically uncommitted CD19- cells generated on S17 stroma had myeloid potential (defined by expression of CD33 and generation of colony-forming unit-cells). Using the switch culture system, single CD34+CD38- cells were assessed for their lymphoid and myeloid potential. Nineteen of 50 (38%) clones generated from single CD34+CD38- cells possessed both B-lymphoid and myeloid potential. 94.7% of the CD34+CD38- cells with lympho-myeloid potential were late-proliferating (clonal appearance after 30 days), demonstrating that pluripotentiality is detected significantly more often in quiescent progenitors than in cytokine-responsive cells (P = .00002). The S17/switch culture system permits the in vitro assessment of the pluripotentiality of single human hematopoietic cells.

Extended long-term culture reveals a highly quiescent and primitive human hematopoietic progenitor population.

Long-term culture-initiating cells (LTC-IC) are hematopoietic progenitors able to generate colony-forming unit-cells (CFU) after 5 to 8 weeks (35 to 60 days) of culture on bone marrow (BM) stroma and represent the most primitive progenitors currently detectable in vitro. We have recently reported that long-term cultures initiated with CD34+CD38- cells from BM or cord blood are able to continue generating CFU for at least 100 days, ie, beyond the standard LTC-IC period. In this report, single-cell cultures from cord blood and retroviral marking of cord blood and BM were used to study whether the subpopulation of CD34+CD38- cells able to generate CFU beyond 60 days ("extended long-term culture-initiating cells" or ELTC-IC) are functionally distinct from LTC-IC in terms of timing of initial clonal proliferation and generative capacity. All cord blood LTC-IC formed clones of greater than 50 cells by day 30. In contrast, cord blood ELTC-IC proliferated later in culture, 50% forming clones after day 30. Although efficient retroviral marking of LTC-IC was seen (25% to 45%), marking of ELTC-IC was inefficient (< 1%), consistent with a more quiescent progenitor population. There was a positive correlation between time of clonal proliferation and generative capacity. ELTC-IC generated threefold to fourfold more progeny than did LTC-IC (P < .002). These studies show that there is a functional hierarchy of progenitors in long-term culture which correlates with their level of quiescence. By extending the LTC-IC assay, a more primitive progenitor may be studied that may be functionally closer to the human long-term repopulation stem cell in vivo.

Transduction of human CD34+ hematopoietic progenitor cells by a retroviral vector expressing an RRE decoy inhibits human immunodeficiency virus type 1 replication in myelomonocytic cells produced in long-term culture.

Genetic modification of hematopoietic stem cells with a synthetic "anti-human immunodeficiency virus type 1 (HIV-1) gene" which inhibits replication of HIV-1 may allow production of mature lymphoid and monocytic cells resistant to HIV-1 growth after autologous transplantation. Because productive HIV-1 replication requires binding of the Rev protein to the Rev-responsive element (RRE) within the viral transcripts for the HIV-1 structural proteins, anti-HIV-1 gene products which interfere with Rev-RRE interactions may inhibit HIV-1 replication. One such strategy involves overexpression of the RRE sequences in transcripts derived from retroviral vectors to act as decoys to sequester Rev protein and prevent its binding to the RRE element in HIV-1 transcripts. We developed an in vitro model to test the efficacy of this gene therapy approach in primary human hematopoietic cells. Human CD34+ hematopoietic progenitor cells from normal bone marrow or umbilical cord blood were transduced with retroviral vectors carrying RRE decoy sequences as part of a long terminal repeat-directed transcript expressing the neo gene (L-RRE-neo) or with a control vector expressing only the neo gene (LN). The transduced progenitors were allowed to differentiate into mature myelomonocytic cells which were able to support vigorous growth of the monocytotropic isolate of HIV-1, JR-FL. HIV-1 replication was measured in unselected cell populations and following G418 selection to obtain uniformly transduced cell populations. Inhibition of HIV-1 replication in the unselected cell cultures was between 50.2 and 76.7% and was highly effective (99.4 to 99.9%) in the G418-selected cultures. Progenitors transduced by either the L-RRE-neo vector or the control LN vector were identical with respect to hematopoietic growth and differentiation. These findings demonstrate the ability of an RRE decoy strategy to inhibit HIV-1 replication in primary human myelomonocytic cells after transduction of CD34+ progenitor cells, without adverse effects on hematopoietic cell function.

Flt3 ligand induces proliferation of quiescent human bone marrow CD34+CD38- cells and maintains progenitor cells in vitro.

Flt3 is a class III tyrosine kinase receptor expressed on primitive human and murine hematopoietic progenitor cells (HPC). In previous studies using stroma-free short term assays, Flt3 ligand (FL) has been shown to induce proliferation of HPC at proportions similar to or less than c-kit ligand (steel factor, SF). Using long term stromal cocultivation assays, we studied the effects of FL on proliferation and differentiation of a highly primitive and cytokine nonresponsive subpopulation of human HPC, CD34+cd38- cells. Cell Proliferation was significantly greater with FL than with SF, when used individually or in combinations with interleukin-3 (IL-3) and/or IL-6. The effect of FL was greater on bone marrow (BM) CD34+CD38- cells than the more cytokine responsive cord blood CD34+CD38- cells. Little or no effect was seen with FL on more mature CD34+CD38+ cells from either BM or cord blood. The frequency of colony-forming units (CFU) and high proliferative potential-colony forming cells (HPP-CFC) during early culture ( < or = 30 days) was increased by both SF and FL to similar levels. However, in the LTC-IC period (35 to 60 days) and extended long-term culture initiating cell (ELTC-IC) period ( > 60 days), the frequency of CFU and HPP-CFC was significantly greater in cultures containing FL than those without FL (P < .0025). Fluorescence-activated cell sorter analysis of cultures after 21 days showed a significantly higher percentage of cells remained CD34+ in the combination of FL, IL-3, IL-6, and SF (F/3/6/S) than in 3/6/S (0.78% +/- 0.52% v 0.21% +/- 0.29% respectively, mean +/- SD). Cloning efficiency of BM CD34+CD38- cells was significantly increased by the addition of FL to the combination of 3/6/S (mean 11.7% v 0.5%, P < .0001). These data show that FL is able to induce proliferation of CD34+CD38-cells that are nonresponsive to other early acting cytokines and to improve the maintenance of progenitors in vitro.

Transduction of pluripotent human hematopoietic stem cells demonstrated by clonal analysis after engraftment in immune-deficient mice.

Gene transduction of pluripotent human hematopoietic stem cells (HSCs) is necessary for successful gene therapy of genetic disorders involving hematolymphoid cells. Evidence for transduction of pluripotent HSCs can be deduced from the demonstration of a retroviral vector integrated into the same cellular chromosomal DNA site in myeloid and lymphoid cells descended from a common HSC precursor. CD34+ progenitors from human bone marrow and mobilized peripheral blood were transduced by retroviral vectors and used for long-term engraftment in immune-deficient (beige/nude/XIS) mice. Human lymphoid and myeloid populations were recovered from the marrow of the mice after 7-11 months, and individual human granulocyte-macrophage and T-cell clones were isolated and expanded ex vivo. Inverse PCR from the retroviral long terminal repeat into the flanking genomic DNA was performed on each sorted cell population. The recovered cellular DNA segments that flanked proviral integrants were sequenced to confirm identity. Three mice were found (of 24 informative mice) to contain human lymphoid and myeloid populations with identical proviral integration sites, confirming that pluripotent human HSCs had been transduced.

A functional comparison of CD34 + CD38- cells in cord blood and bone marrow.

We present cell cycling and functional evidence that the CD34+CD38- immunophenotype can be used to define a rare and primitive subpopulation of progenitor cells in umbilical cord blood. CD34+CD38- cells comprise 0.05% +/- 0.08% of the mononuclear cells present in cord blood. Cell cycle analysis with the fluorescent DNA stain 7-aminoactinomycin D showed that the percentage of CD34+ cells in cycle directly correlated with increasing CD38 expression. CD34+CD38- cord blood cells were enriched for long-term culture-initiating cells (LTCIC; cells able to generate colony-forming unit-cells [CFU-C] after 35 to 60 days of coculture with bone marrow stroma) relative to CD34+CD38- cells. In an extended LTCIC assay, CD34+CD38- cells were able to generate CFU-C between days 60 and 100, clearly distinguishing them from CD34+CD38+ cells that did not generate CFU-C beyond day 40. When plated as single cells, onset of clonal proliferation was markedly delayed in a subpopulation of CD34+CD38- cells; clones (defined as > 100 cells) appeared after 60 days of culture in 2.9% of CD34+CD38- cells. In contrast, 100% of CD34+CD38+ cells formed clones by day 21. Although the CD34+CD38- immunophenotype defines highly primitive populations in both bone marrow and cord blood, important functional differences exist between the two sources. CD34+CD38- cord blood cells have a higher cloning efficiency, proliferate more rapidly in response to cytokine stimulation, and generate approximately sevenfold more progeny than do their counterparts in bone marrow.

Analysis of optimal conditions for retroviral-mediated transduction of primitive human hematopoietic cells.

We sought to define optimal conditions for retroviral-mediated transduction of long-lived human hematopoietic progenitors from bone marrow and peripheral blood. CD34+ cells were transduced by the LN and G2 retroviral vectors in the presence or absence of stromal support and with or without cytokine addition. After transduction, a portion of the cells was plated in methylcellulose colony-forming assay, with or without G418, to assess the extent of gene transfer into committed progenitors. The remaining cells from each experiment were transplanted into immunodeficient mice to allow analysis of transduction of long-lived progenitors. Human colony-forming cells contained within the murine bone marrow were analyzed after engraftment periods of 2 to 11 months. Cells were plated in a human-specific colony-forming assay with and without G418 to assess the extent of transduction of primitive progenitors. Individual human colonies were also analyzed by polymerase chain reaction for the presence of provirus. Bone marrow progenitors were efficiently transduced only when stroma was present, whereas mobilized peripheral blood progenitors were effectively transduced in the presence of either stroma or cytokines. Inclusion of the cytokines interleukin-3, interleukin-6, and stem cell factor did not further augment the extent of gene transfer in the presence of a stromal support layer. Additionally, human CD34+ progenitors from bone marrow or mobilized peripheral blood that had been transduced for 3 days in the absence of stroma failed to produce sustained, long-term engraftment of bnx mice. Mice transplanted with the same pools of human progenitors that had been transduced in the presence of stroma for 3 days had significant levels of human cell engraftment at the same timepoints, 7 to 11 months after transplantation. Our data show loss of long-lived human progenitors during 3-day in vitro transduction periods in the absence of stromal support. Therefore, the presence of bone marrow stroma has dual benefits in that it increases gene transfer efficiency and is essential for survival of long-lived human hematopoietic progenitors.

Leukocyte migration inhibition test in children with cow milk allergy.

The usefulness of the leukocyte migration inhibition factor (LIF) test to detect cow milk (CM) hypersensitivity was studied in 40 children with suspected allergy to CM. Hypersensitivity was carefully investigated by oral milk challenges, which gave a final confirmation of cow milk hypersensitivity in 12 subjects, and excluded it in the remaining 28 subjects. Leukocyte migration inhibition was measured using beta-lactoglobulin (BLG), alpha-lactalbumin (ALA), alpha-casein (ACA) and bovine serum albumin (BSA) as antigens. IgA and IgG antibodies to these antigens were measured by an enzyme-linked immunosorbent assay, and IgE antibodies to these antigens and to CM by radioallergosorbent test (RAST). Skin prick test with CM was performed in 38 subjects, and with BLG, ALA, ACA and BSA in 29 subjects. Leukocyte migration was more often inhibited by cow milk antigens in the CM challenge positive (CM+) subjects than in the challenge negative (CM-) subjects. Of the specific milk antigens, ALA was the most potent inhibitor, and gave a positive LIF test result in all CM+ subjects, and significantly (P less than 0.02) less often (15/24) in CM- subjects. Also in the skin prick test and RAST, ALA gave positive results more often than the other milk antigens. BLG, ACA and BSA had an inhibiting effect on leukocyte migration, but the difference between the CM+ and CM- subjects was not statistically significant. Two of the 12 CM+ subjects had no demonstrable IgE antibodies to CM proteins; both of them, however, had a positive LIF test with at least one of the CM antigens.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of calf thymus extract (TFX) on human T lymphocyte and neutrophil mobility and chemotactic response in vitro.

Calf thymus extract (TFX) was found to increase in vitro normal human T lymphocyte and granulocyte mobility, having no effect on their chemotactic response. TFX, when placed in the lower part of the chemotactic chamber was found to act as a chemotactic factor, even stronger than NHS and casein.

T lymphocyte mobility: defects and effects of ascorbic acid, histamine and complexed IgG.

T lymphocyte mobility is low in patients with low neutrophil mobility. Thymocytes move comparably with normal mature T lymphocytes. Histamine accelerates T lymphocyte mobility in healthy subjects, patients with defective lymphocyte mobility and thymocytes. Ascorbic acid increases lymphocyte mobility of healthy subjects and thymocytes. Inhibition of mobility of T- or Tmu-depleted T lymphocytes by complexed IgG casts doubt on previous reports that the T gamma cells do not move.