Thymic Repopulation by CD34+ Human Cord Blood Cells After Expansion in Stroma-Free Culture

Characteristics of hematopoietic stem cells of umbilical cord blood

Umbilical cord blood collected from the postpartum placenta and cord is a rich source of hematopoietic stem cells (HSCs) and is an alternative to bone marrow transplantation. In this review we wanted to describe the differences (in phenotype, cytokine production, quantity and quality of cells) between stem cells from umbilical cord blood, bone marrow and peripheral blood. HSCs present in cord blood are more primitive than their counterparts in bone marrow or peripheral blood, and have several advantages including high proliferation. With using proper cytokine combination, HSCs can be effectively developed into different cell lines. This process is used in medicine, especially in hematology.

In vitro expanded cells contributing to rapid severe combined immunodeficient repopulation activity are CD34+38-33+90+45RA-

Expansion of hematopoietic stem cells could be used clinically to shorten the prolonged aplastic phase after umbilical cord blood (UCB) transplantation. In this report, we investigated rapid severe combined immunodeficient (SCID) repopulating activity (rSRA) 2 weeks after transplantation of CD34(+) UCB cells cultured with serum on MS5 stromal cells and in serum- and stroma-free cultures. Various subpopulations obtained after culture were studied for rSRA. CD34(+) expansion cultures resulted in vast expansion of CD45(+) and CD34(+) cells. Independent of the culture method, only the CD34(+)33(+)38(-) fraction of the cultured cells contained rSRA. Subsequently, we subfractionated the CD34(+)38(-) fraction using stem cell markers CD45RA and CD90. In vitro differentiation cultures showed CD34(+) expansion in both CD45RA(-) and CD90(+) cultures, whereas little increase in CD34(+) cells was observed in both CD45RA(+) and CD90(-) cultures. By four-color flow cytometry, we could demonstrate that CD34(+)38(-)45RA(-) and CD34(+)38(-)90(+) cell populations were largely overlapping. Both populations were able to reconstitute SCID/nonobese diabetic mice at 2 weeks, indicating that these cells contained rSRA activity. In contrast, CD34(+)38(-)45RA(+) or CD34(+)38(-)90(-) cells contributed only marginally to rSRA. Similar results were obtained when cells were injected intrafemorally, suggesting that the lack of reconstitution was not due to homing defects. In conclusion, we show that after in vitro expansion, rSRA is mediated by CD34(+)38(-)90(+)45RA(-) cells. All other cell fractions have limited reconstitutive potential, mainly because the cells have lost stem cell activity rather than because of homing defects. These findings can be used clinically to assess the rSRA of cultured stem cells.

In vitro culture during retroviral transduction improves thymic repopulation and output after total body irradiation and autologous peripheral blood progenitor cell transplantation in rhesus macaques

Immunodeficiency after peripheral blood progenitor cell (PBPC) transplantation may be influenced by graft composition, underlying disease, and/or pre-treatment. These factors are difficult to study independently in humans. Ex vivo culture and genetic manipulation of PBPC grafts may also affect immune reconstitution, with relevance to gene therapy applications. We directly compared the effects of three clinically relevant autologous graft compositions on immune reconstitution after myeloblative total body irradiation in rhesus macaques, the first time these studies have been performed in a large animal model with direct clinical relevance. Animals received CD34(+) cell dose-matched grafts of either peripheral blood mononuclear cells, purified CD34(+) PBPCs, or purified CD34(+) PBPCs expanded in vitro and retrovirally transduced. We evaluated the reconstitution of T, B, natural killer, dendritic cells, and monocytes in blood and lymph nodes for up to 1 year post-transplantation. Animals receiving selected-transduced CD34(+) cells had the fastest recovery of T-cell numbers, along with the highest T-cell-receptor gene rearrangement excision circles levels, the fewest proliferating Ki-67(+) T-cells in the blood, and the best-preserved thymic architecture. Selected-transduced CD34(+) cells may therefore repopulate the thymus more efficiently and promote a higher output of naïve T-cells. These results have implications for the design of gene therapy trials, as well as for the use of expanded PBPCs for improved T-cell immune reconstitution after transplantation.

Production of human B cells from CD34+CD38- T- B- progenitors in organ culture by sequential cytokine stimulation

We investigated sequential cytokine addition on human hematopoietic stem cell (HSC) differentiation in murine fetal liver (FL), fetal spleen (FS) and bone marrow (BM) organ cultures (OC). Tissues were colonized with unpurified or FACS sorted CD34+CD38-CD10-CD19-CD3-CD8-CD4-(T- B-) cells from human cord blood (HUCB). CD19+ cell production and kinetics differed in each tissue. Fetal liver organ cultures (FLOC) inoculated with CD34+CD38-T-B- cells produced fewer CD19+ cells than fetal liver organ culture (FLOC) cultured with unpurified HUCB. CD19+ cell production was restored in the CD34+CD38-T-B- organ cultures by treating with SCF, LIF and IL-6 followed by IL-7 and removing all cytokines for the last 3 days of culture (a six-fold increase). FLOC also produced CD34+CD38-T-B- cells and monocyte-lineage CD33+CD14- cells, both of which increased after cytokine treatment. Re-colonization of secondary FLOC with CD34+CD38-T-B- cells generated in primary FLOC produced additional B-cells, monocytes and CD34+CD38- cells suggesting that the primary cells retained HSC activity. Expansion and differentiation of HSCs depended on the microenvironment of the recipient tissue as well as addition of cytokines in the appropriate order.

Lentivirus-mediated transduction of PKR into CD34(+) hematopoietic stem cells inhibits HIV-1 replication in differentiated T cell progeny

Previous studies from this laboratory evaluated the role of p68 kinase (PKR) in the control of HIV-1 replication via retrovirus-mediated gene transfer. PKR was studied because it is a key component of the interferon (IFN)-associated innate antiviral defense pathway in mammalian cells. In this study, CD34(+) hematopoietic stem cells (HSC) were transduced with an HIV-1-based lentiviral vector encoding the PKR transgene (pHIV-PIB) and cultured under conditions that support in vitro differentiation. With high-titer pseudotyped vector stocks, the histogram suggests 100% transduction of the HSC because the cells were blasticidin resistant. Analysis of transduced cells by hybridization revealed an average proviral vector copy number of 1.8 and 2.1 copies of vector sequence per cell. Increased PKR expression and activity (phosphorylation of eukaryotic initiation factor 2alpha [eIF2alpha]) were demonstrated in PKR-transduced, differentiated HSC. There was minimal reduction in cell viability and no induction of apoptosis after transduction of PKR. HSC transduced with the pHIV-PIB lentiviral vector demonstrated normal differentiation into CD34-derived T cell progeny. Two days after HIV-1 infection, lentivirus-mediated transduction of PKR inhibited HIV-1 replication by 72% in T cell progeny compared with cells transduced with the empty vector control (pHIV-IB). By days 5 and 7 post-HIV-1 infection, the surviving PKR-transduced cells were protected from HIV-1 infection, as evidenced by a decrease in p24 antigen expression of at least two orders of magnitude. Our results demonstrate that PKR can be effectively delivered to HSC by a lentiviral vector and can protect CD34-derived T cell progeny from HIV-1 infection. These results provide support for application of the innate antiviral defense pathway in a gene therapy setting to the treatment of HIV-1 infection.

CD34+CD38- is a good predictive marker of cloning ability and expansion potential of CD34+ cord blood cells

BACKGROUND

Ex vivo expansion of HPCs is an attractive approach to overcoming the current limitations of human cord blood transplantation. It is important not only to define the optimal culture conditions but also to know the number of progenitor cells that can be obtained. CD34+ cells have a great variability in their cloning capacity and in their ability to expand HPCs. This study was carried out to assess whether this variability could be due to intrinsic or extrinsic factors.

STUDY DESIGN AND METHODS

CD34+ cells were analyzed for the expression of CD38, CD133, and CD117 and cultured in serum-free culture medium with four cytokine combinations: SCF plus thrombopoietin plus flt3 ligand (STF), STF plus IL-3, STF plus IL-6, and STF plus IL-6 plus IL-3. After a 1-week culture, the numbers of CD34+ cells and CFUs were determined.

RESULTS

The variability observed both in the cloning ability of CD34+ isolated cells and in their expansion capacity was inversely related to the frequency of the more immature CD34+CD38- cells. When more mature CD34+CD38+ cells were present within CD34+-isolated cells, a higher cloning ability, measured as CFUs, and a higher expansion capacity were observed.

CONCLUSION

Enumeration of CD34+CD38- cells is correlated with the number of committed progenitors and the capacity of generating CD34+ cells, an important parameter if expansion protocols must be used in clinical transplantation.

Selective in vitro expansion and efficient retroviral transduction of human CD34+ CD38- haematopoietic stem cells

Ex vivo expansion of primitive human haematopoietic stem cells (HSC) is clinically relevant for stem cell transplantation and gene therapy. Here, we demonstrate the selective expansion of CD34+CD38- cells from purified CD34+ cells upon stimulation with Flt3-ligand, stem cell factor and thrombopoietin. Over a 100-fold (range 80 to 128-fold) expansion of CD34+CD38- cells was observed with bone marrow and cord blood (CB). The expanded CD34+CD38- cells remained negative for lineage-specific markers and could be induced to differentiate into granulocytes, monocytes, megakaryocytes, erythrocytes, and T and B-lymphocytes in vitro. Lineage differentiation assays with single CD34+CD38- cells showed no loss of multilineage potential of expanded cells after ex vivo culture. We also demonstrated that the increase in frequency of CD34+CD38- cells was not as a result of the downregulation of CD38 expression during the culture. Quantitative analysis showed that the number of 6 week cobblestone area forming cells (CAFCwk6), a measure of proliferating HSC, in cytokine-stimulated CD34+ cells were increased by 20-fold. Expanded CD34+CD38- cells could be transduced efficiently with retroviruses encoding the low affinity nerve growth factor receptor (LNGFR) marker gene (17% to 44%, mean 27%), resulting in long-lasting expression of retroviral-encoded genes in progeny HSC and differentiated progenitors. We conclude that the combination Flt3-ligand (FL), stem cell factor and thrombopoietin (TPO) induced strong ex vivo proliferation of CD34+CD38- cells and that the absolute number of expanded cells with stem cell activity increased substantially in this population.

Both CD34+38+ and CD34+38- cells home specifically to the bone marrow of NOD/LtSZ scid/scid mice but show different kinetics in expansion

Human hemopoietic stem cells (HSC) have been shown to engraft, differentiate, and proliferate in the hemopoietic tissues of sublethally irradiated NOD/LtSZ scid/scid (NOD/SCID) mice. We used this model to study homing, survival, and expansion of human HSC populations from different sources or phenotype. We observed that CD34+ cells homed specifically to bone marrow (BM) and spleen, but by 3 days after injection, survived only in the BM. These BM-homed CD34+ cells proliferated intensively and gave rise to a 12-fold, 5.5-fold, and 4-fold expansion in 3 days for umbilical cord blood, adult mobilized peripheral blood, and adult BM-derived cells, respectively. By injection of purified subpopulations, it was demonstrated that both CD34+38+ and CD34+38- umbilical cord blood HSC homed to the BM and expanded. Importantly, kinetics of expansion were different: CD34+38+ cells started to increase in cell number from day 3 onwards, and by 4 wk after injection, virtually all CD34+ cells had disappeared. In contrast, CD34+38- cells remained quiescent during the first week and started to expand intensively from the third week on. In this paper, we have shown that homing, survival, and expansion of stem cells are three independent phenomena important in the early phase of BM engraftment and that kinetics of engraftment differ between CD34+38+ and CD34+38- cells.

CD133+ cell selection is an alternative to CD34+ cell selection for ex vivo expansion of hematopoietic stem cells

CD133 is a new stem cell antigen that may provide an alternative to CD34 for the selection and expansion of hematopoietic cells for transplantation. This study compared the expansion capacities of CD133(+) and CD34(+) cells isolated from the same cord blood (CB) samples. After 14 days culture in stroma-free, serum-free medium in the presence of stem cell factor (SCF), Flt3-1, megakaryocyte growth and development factor (MGDF), and granulocyte colony-stimulating factor (G-CSF), the CD133(+) and CD34(+) fractions displayed comparable expansion of the myeloid compartment (CFC, LTC-IC, and E-LTC-IC). The expansion of CD133(+) CB cells was up to 1262-fold for total cells, 99-fold for CD34(+) cells, 109-fold for CD34(+) CD133(+) cells, 133-fold for CFU-GM, 14.5-fold for LTC-IC, and 7.5-fold for E-LTC-IC. Moreover, the expanded population was able to generate lymphoid B (CD19(+)), NK (CD56(+)), and T (CD4(+) CD8(+)) cells in liquid or fetal thymic organ cultures, while expression of the homing antigen CXCR4 was similar on expanded and nonexpanded CD133(+) or CD34(+) cells. Thus, the CD133(+) subset could be expanded in the same manner as the CD34(+) subset and conserved its multilineage capacity, which would support the relevance of CD133 for clinical hematopoietic selection.

A phase III study of recombinant human interferon gamma to prevent opportunistic infections in advanced HIV disease

The efficacy and safety of recombinant human interferon gamma (rIFN-gamma) in the reduction of opportunistic disease in patients with advanced HIV-1 infection are assessed. A 12-month double-blind, placebo-controlled, multicenter, Phase III trial of rIFN-gamma in HIV-positive patients with CD4 < 100 x 10(9)/liter on stable antiretroviral therapy. Eighty-four patients were allocated treatment on a 1:1 basis to rIFN-gamma or placebo. Patients received rIFN-gamma 0.05 mg/m(2) or 0.9% saline subcutaneously three times weekly for 48 weeks (optional extension to 18 months). The primary end point was the incidence of opportunist infections (CDC categories B/C). Secondary end points included mortality, immunological, and virological parameters. Patients on placebo had a mean of 3.45 opportunist infections (OIs) in the first 48 weeks. Patients treated with rIFN-gamma had a mean of 1.71 OIs (p = 0.04). However, the model showed overdispersion and the inclusion of a dispersion factor raised the p value to 0.13. rIFN-gamma appeared to have a particular effect on the incidence of Candida, herpes simplex, and cytomegalovirus infections. Three-year survival in the rIFN-gamma arm was 28% compared to 18% in the placebo group (not significant). rIFN-gamma-associated side-effects of headache, fatigue, rigors, influenza-like symptoms, depression, myalgia, and granulocytopenia were reversible. There was no evidence for HIV activation. Although not significant, the trend towards decreased opportunistic infections and increased survival warrants consideration of further trials of rIFN-gamma. The study gives additional information on the safety profile of this cytokine.

Optimization of retroviral gene transfer protocol to maintain the lymphoid potential of progenitor cells

We have attempted to improve retrovirus-mediated gene transfer efficacy into hematopoietic progenitor cells (HPCs) without causing them to lose their lymphoid potential. Highly purified CD34(+) cells on CH-296 fibronectin fragments have been transduced with three different cytokine combinations. Murine CD2 was used as a marker gene. Transgene expression was assayed by FACS analysis shortly after transduction of CD34(+) cells and after long-term culture (LTC) extended by differentiation of various lymphoid lineages: NK cells, B cells, and dendritic cells. Compared with the historical cytokine mix, i.e., SCF (stem cell factor) + IL-3 (interleukin 3) + IL-6, the combination SCF + FL (Flt-3 ligand) + M-GDF (megakaryocyte growth and differentiation factor) + IL-3 significantly improved the total number of viable cells and CD34(+) cells after transduction and the long term-cultured progenitors after 6 weeks. In addition, the combination of SCF + FL + M-GDF + IL-3 maintained more efficiently the lymphoid potential of the progeny of transduced long term-cultured CD34(+) cells, as attested by the significantly higher number of CD56(+), CD19(+), and CD1a(+) cells recovered when FL and M-GDF were added to SCF + IL-3. Thus, even though additional improvements may still be needed in transduction of HPCs, these conditions were adopted for a clinical trial of gene therapy for X-linked severe combined immunodeficiency.

Long-term expansion and maintenance of cord blood haematopoietic stem cells using thrombopoietin, Flt3-ligand, interleukin (IL)-6 and IL-11 in a serum-free and stroma-free culture system

Although cord blood (CB) compares favourably with other haematopoietic stem cell (HSCs) sources, its use in large patients is limited by the low number of cells available. Ex vivo expansion of CB HSCs has been used to overcome this limitation. In this study, we investigated the effect of different cytokine cocktails, including interleukin (IL)-6, IL-11, Flt3-ligand (FL) and thrombopoietin (TPO) combined with serum or serum-free medium on the ex vivo expansion of CD34+ cells from CB. Initial experiments showed that expansion could be slightly improved using serum, but we chose to use serum-free medium in the subsequent investigations to apply good medical practice (GMP) conditions suitable for clinical use. The highest expansion of CD34+ cells was obtained with a cocktail containing FL + TPO + IL-6 + IL-11. The median (range) fold expansions of CD34+ cells at 5 and 10 weeks with serum-free medium were 235.6 (131.3-340) and 5205.6 (4736.6-5674.7) respectively. The absence of IL-11 was associated with a similar fold expansion after 5 weeks (median 215.6, range 149.8-281.5), but after 10 weeks expansion was slightly lower (median 1314.7, range 645-1984.4). Our data support the possibility of maintaining long-term expansion of CB HSCs in a simple stroma- and serum-free system.

In vitro and in vivo evidence for the long-term multilineage (myeloid, B, NK, and T) reconstitution capacity of ex vivo expanded human CD34(+) cord blood cells

The aim of the present report is to describe clinically relevant culture conditions that support the expansion of primitive hematopoietic progenitors/stem cells, with maintenance of their hematopoietic potential as assessed by in vitro assays and the NOD-SCID in vivo repopulating capacity.CD34(+) cord blood (CB) cells were cultured in serum-free medium containing stem cell factor, Flt3 ligand, megakaryocyte growth and development factor, and granulocyte colony-stimulating factor. After 14 days, the primitive functions of expanded and nonexpanded cells were determined in vitro using clonogenic cell (colony-forming cells, long-term culture initiating cell [LTC-IC], and extended [E]-LTC-IC) and lymphopoiesis assays (NK, B, and T) and in vivo by evaluating long-term engraftment of the bone marrow of NOD-SCID mice. The proliferative potential of these cells also was assessed by determining their telomere length and telomerase activity. Levels of expansion were up to 1,613-fold for total cells, 278-fold for colony-forming unit granulocyte-macrophage, 47-fold for LTC-IC, and 21-fold for E-LTC-IC. Lymphoid B-, NK, and T-progenitors could be detected. When the expanded populations were transplanted into NOD-SCID mice, they were able to generate myeloid progenitors and lymphoid cells for 5 months. These primitive progenitors engrafted the NOD-SCID bone marrow, which contained LTC-IC at the same frequency as that of control transplanted mice, with conservation of their clonogenic capacity. Moreover, human CD34(+)CDl9(-) cells sorted from the engrafted marrow were able to generate CD19(+) B-cells, CD56(+)CD3(-) NK cells, and CD4(+)CD8(+)alphabetaTCR(+) T-cells in specific cultures. Our expansion protocol also maintained the telomere length in CD34(+) cells, due to an 8.8-fold increase in telomerase activity over 2 weeks of culture. These experiments provide strong evidence that expanded CD34(+) CB cells retain their ability to support long-term hematopoiesis, as shown by their engraftment in the NOD-SCID model, and to undergo multilineage differentiation along all myeloid and the B-, NK, and T-lymphoid pathways. The expansion protocol described here appears to maintain the hematopoietic potential of CD34(+) CB cells, which suggests its relevance for clinical applications.

FLT3 ligand preserves the uncommitted CD34+CD38- progenitor cells during cytokine prestimulation for retroviral transduction

Before stem cell gene therapy can be considered for clinical applications, problems regarding cytokine prestimulation remain to be solved. In this study, a retroviral vector carrying the genes for the enhanced version of green fluorescent protein (EGFP) and neomycin resistance (neo(r)) was used for transduction of CD34+ cells. The effect of cytokine prestimulation on transduction efficiency and the population of uncommitted CD34+CD38- cells was determined. CD34+ cells harvested from umbilical cord blood were kept in suspension cultures and stimulated with combinations of the cytokines stem cell factor (SCF), FLT3 ligand, interleukin-3 (IL-3), IL-6, and IL-7 prior to transduction. Expression of the two genes was assessed by flow cytometry and determination of neomycin-resistant colonies in a selective colony-forming unit (CFU) assay, respectively. The neomycin resistance gene was expressed in a higher percentage of cells than the EGFP gene, but there seemed to be a positive correlation between expression of the two genes. The effect of cytokine prestimulation was therefore monitored using EGFP as marker for transduction. When SCF was compared to SCF in combination with more potent cytokines, highest transduction efficiency was found with SCF and IL-3 and IL-6 (5.05% +/- 0.80 versus 2.66% +/- 0.53 with SCF alone, p = 0.04). However, prestimulation with SCF in combination with IL-3 and IL-6 also reduced the percentage of CD34+ cells (p = 0.02). Then, prestimulation with SCF and FLT3 ligand was compared. Significant difference in transduction efficiency was not found. Interestingly, FLT3 ligand seemed to preserve the population of CD34+CD38- cells compared to SCF (16.56% +/- 2.02 versus 9.39% +/- 2.35, p = 0.03). In conclusion, prestimulation with potent cytokine combinations increased the transduction efficiency, but reduced the fraction of CD34+ cells. Importantly, the use of FLT3 ligand seemed to preserve the population of uncommitted cells.

Efficiency of transgenic T cell generation from gene-marked cultured human CD34+ cord blood cells is determined by their maturity and the cytokines present in the culture medium

Success of gene therapy for diseases affecting the T cell lineage depends on the thymic repopulation by genetically engineered hematopoietic progenitor cells (HPC). Although it has been shown that retrovirally transduced HPC can repopulate the thymus, little information is available on the effect of the culture protocol. Moreover, for expansion of the number of HPC, cytokine supplemented culture is needed. Here, we transduced purified human umbilical cord blood (CB) CD34+ cells in cultures supplemented with various combinations of the cytokines thrombopoietin (TPO), stem cell factor (SCF), flt3/flk-2 ligand (FL), interleukin-3 (IL-3) and IL-6, and investigated thymus-repopulating ability of gene-marked HPC in vitro. Irrespective of the cytokine cocktail used, transduced CD34+CD38- CB cells, expressing the marker green fluorescent protein (GFP) encoded by the MFG-GFP retrovirus, have both superior proliferative and thymus-repopulating potential compared with transduced CD34+CD38+ CB cells. Effectively transduced GFP+CD34+CD38- HPC, cultured for 3 or 17 days, more readily generated T cells than GFP- HPC from the same culture. The reverse was true in the case of CD34+CD38+ HPC cultures. Finally, our results indicate that the number of GFP+ T cell progenitors actually increased during culture of CD34+CD38- HPC, in a magnitude that is determined by the cytokine cocktail used during culture.