Methylguanine Methyltransferase-Based In Vivo Selection Results in Only Transient Improvement in Long-Term Marking after Autologous Transplantation of Transduced Hematopoietic Stem Cells in Rhesus Macaques.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 3272-3272
Author(s):  
Andre Larochelle ◽  
Uimook Choi ◽  
Nora Naumann ◽  
Josh R. Clevenger ◽  
Harry L. Malech ◽  
...  
Keyword(s):  
Gene Therapy ◽  
Steady State ◽  
Ex Vivo ◽  
Rhesus Macaques ◽  
Autologous Transplantation ◽  
Survival Advantage ◽  
Hematopoietic Stem ◽  
Cd34 Cells ◽  
Selective Survival

Abstract In vivo selective survival advantage of transduced cells contributed to clinically beneficial levels of genetic correction of lymphocytes following X-SCID gene therapy. For most blood disorders there will be no constitutive selective advantage of the gene-corrected cells. Alternatively, a selectable gene incorporated into the vector may provide selective survival advantage. The P140K mutant of human O6-methylguanine-DNA methyltransferase (MGMT*) is a candidate mammalian selectable gene for hematopoietic stem cell (HSC) gene therapy. AMD3100-mobilized CD34+ cells from 5 rhesus macaques were transduced daily from day 2 to 4 of culture using oncoretroviral (n=2 animals) or lentiviral (n=3 animals) vectors encoding the gp91phox-IRES-MGMT* cassette or the GFP-MGMT* fusion protein, respectively. Transduced CD34+ cells were selected after (in vivo, n=4) or before (ex vivo, n=1) autologous transplantation in rhesus macaques using the BG (120mg/m2)/TMZ 400 mg/m2 combination for in vivo selection and the BG (5uM)/BCNU (7.5uM) combination for ex vivo selection. Marking of peripheral blood (PB) cells was evaluated by FACS and/or real-time PCR. Bulk CD34+ cells were marked at 27–58% after transduction with oncoretroviral or lentiviral vectors. Four animals were transplanted with transduced non-selected CD34+ cells. Small fractions of cultured cells not transplanted were exposed to BG/BCNU resulting in an increase of marking to 88–97% in each case, confirming the in vitro survival advantage. Cells from animals #1 and #2 were transduced with oncoretroviral vectors and steady-state marking of 3.5% was obtained in PB. Animal #1 received BG/TMZ infusions at 3 and 6 months post-transplant. Marking declined to 3.3% and 1.1% after BG/TMZ treatment 1 and 2, respectively. Animal #2 received one cycle of BG/TMZ at 4 months post-transplant. Full hematopoietic recovery was not achieved and the animal died of infectious complications one month after treatment. Marking of 2% was detected in the PB at the time of death. Cells from animals #3 and #4 were transduced with lentiviral vectors. Animal #3 received 4 monthly infusions of BG/TMZ starting 5 months after transplantation. Marking increased from 0.1% at steady-state to 1.8% in PB after the first cycle but rapidly declined to 0.2%. Despite significant myelosuppression, additional cycles of BG/TMZ resulted in no significant improvement in marking. Animal #4 received 4 monthly infusions of BG/TMZ starting 3 months after transplantation. Marking increased from 3.3% at steady-state to 29.2% after the first cycle but rapidly declined to 6.2%. Each additional cycle of BG/TMZ resulted in a transient increase in marking with a peak increase gradually declining with each cycle. Animal #5 was transplanted with CD34+ cells transduced with lentiviral vector expressing GFP-MGMT* and exposed to BG/BCNU ex vivo before transplantation. At the time of reinfusion, 55% of the cells were vector positive. Stable hematopoietic recovery required one month, compared to an average recovery of 2 weeks in animals transplanted with transduced cells without ex vivo selection. Steady state marking in PB of only 0.7% was detected. These data combined with the theoretic concern that the use of cytotoxic drugs could increase the risk of leukemogenesis in the setting of drug-resistance gene therapy, raise concerns for the clinical applicability of this approach.

A novel lentiviral vector targets gene transfer into human hematopoietic stem cells in marrow from patients with bone marrow failure syndrome and in vivo in humanized mice

Blood ◽  
2012 ◽  
Vol 119 (5) ◽  
pp. 1139-1150 ◽  
Author(s):  
Cecilia Frecha ◽  
Caroline Costa ◽  
Didier Nègre ◽  
Fouzia Amirache ◽  
Didier Trono ◽  
...  
Keyword(s):  
Gene Therapy ◽  
Cord Blood ◽  
Mononuclear Cells ◽  
Lentiviral Vector ◽  
Ex Vivo ◽  
Bone Marrow Failure ◽  
Humanized Mice ◽  
Hematopoietic Stem ◽  
Cd34 Cells

AbstractIn vivo lentiviral vector (LV)–mediated gene delivery would represent a great step forward in the field of gene therapy. Therefore, we have engineered a novel LV displaying SCF and a mutant cat endogenous retroviral glycoprotein, RDTR. These RDTR/SCF-LVs outperformed RDTR-LVs for transduction of human CD34+ cells (hCD34+). For in vivo gene therapy, these novel RDTR/SCF-displaying LVs can distinguish between the target hCD34+ cells of interest and nontarget cells. Indeed, they selectively targeted transduction to 30%-40% of the hCD34+ cells in cord blood mononuclear cells and in the unfractionated BM of healthy and Fanconi anemia donors, resulting in the correction of CD34+ cells in the patients. Moreover, RDTR/SCF-LVs targeted transduction to CD34+ cells with 95-fold selectivity compared with T cells in total cord blood. Remarkably, in vivo injection of the RDTR/SCF-LVs into the BM cavity of humanized mice resulted in the highly selective transduction of candidate hCD34+Lin− HSCs. In conclusion, this new LV will facilitate HSC-based gene therapy by directly targeting these primitive cells in BM aspirates or total cord blood. Most importantly, in the future, RDTR/SCF-LVs might completely obviate ex vivo handling and simplify gene therapy for many hematopoietic defects because of their applicability to direct in vivo inoculation.

scholarly journals Efficient Nanoparticle-Mediated Delivery of Gene Editing Reagents into Human Hematopoietic Stem and Progenitor Cells

Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 2933-2933
Author(s):  
Rkia El Kharrag ◽  
Kurt Berckmueller ◽  
Margaret Cui ◽  
Ravishankar Madhu ◽  
Anai M Perez ◽  
...  
Keyword(s):  
Gene Therapy ◽  
Quality Control ◽  
Progenitor Cells ◽  
Gene Editing ◽  
Ex Vivo ◽  
Hematopoietic Stem ◽  
Cd34 Cells ◽  
Stem And Progenitor Cells

Abstract Autologous hematopoietic stem cell (HSC) gene therapy has the potential to cure millions of patients suffering from hematological diseases and disorders. Recent HSCs gene therapy trials using CRISPR/Cas9 nucleases to treat sickle cell disease (SCD) have shown promising results paving the way for gene editing approaches for other diseases. However, current applications depend on expensive and rare GMP facilities for the manipulation of HSCs ex vivo. Consequently, this promising treatment option remains inaccessible to many patients especially in low- and middle-income settings. HSC-targeted in vivo delivery of gene therapy reagents could overcome this bottleneck and thereby enhance the portability and availability of gene therapy. Various kinds of nanoparticles (lipid, gold, polymer, etc.) are currently used to develop targeted ex vivo as well as in vivo gene therapy approaches. We have previously shown that poly (β-amino ester) (PBAE)-based nanoparticle (NP) formulations can be used to efficiently deliver mRNA into human T cells and umbilical cord blood-derived CD34 + hematopoietic stem and progenitor cells (HSPCs) (Moffet et al. 2017, Nature Communications). Here, we optimized our NP formulation to deliver mRNA into GCSF-mobilized adult human CD34 + HSPCs, a more clinically relevant and frequently used cell source for ex vivo and the primary target for in vivo gene therapy. Furthermore, we specifically focused on the evaluation of NP-mediated delivery of CRISPR/Cas9 gene editing reagents. The efficiency of our NP-mediated delivery of gene editing reagents was comprehensively tested in comparison to electroporation, the current experimental, pre-clinical as well as clinical standard for gene editing. Most important for the clinical translation of this technology, we defined quality control parameters for NPs, identified standards that can predict the editing efficiency, and established protocols to lyophilize and store formulated NPs for enhanced portability and future in vivo applications. Nanoformulations were loaded with Cas9 ribonucleoprotein (RNP) complexes to knock out CD33, an established strategy in our lab to protect HSCs from anti-CD33 targeted acute myeloid leukemia (AML) immunotherapy (Humbert et al. 2019, Leukemia). RNP-loaded NPs were evaluated for size and charge to correlate physiochemical properties with the outcome as well as establish quality control standards. NPs passing the QC were incubated with human GCSF-mobilized CD34 + hematopoietic stem and progenitor cells (HSPCs). In parallel, RNPs were delivered into CD34 + cells using our established EP protocol. NP- and EP-edited CD34 + cells were evaluated phenotypically by flow cytometry and functionally in colony-forming cell (CFC) assays as well as in NSG xenograft model. The optimal characteristics for RNP-loaded NPs were determined at 150-250 nm and 25-35 mV. Physiochemical assessment of RNP-loaded NP formations provided an upfront quality control of RNP components reliably detecting degraded components. Most importantly, NP charge directly correlated with the editing efficiency (Figure A). NPs achieved more than 85% CD33 knockout using 3-fold lower dose of CRISPR nucleases compared to EP. No impact on the erythromyeloid differentiation potential of gene-edited cells in CFC assays was observed. Finally, NP-modified CD34 + cells showed efficient and sustained gene editing in vivo with improved long-term multilineage engraftment potential in the peripheral blood (PB) and bone marrow stem cell compartment of NSG mice in comparison to EP-edited cells (Figure B). Here we show that PBAE-NPs enable efficient CRISPR/Cas9 gene editing of human GCSF-mobilized CD34 + cells without compromising the viability and long-term multilineage engraftment of human HSPCs in vivo. Most importantly, we defined physiochemical properties of PBAE-NPs that enable us to not only determine the integrity of our gene-editing agents but also predict the efficiency of editing in HSPCs. The requirement of 3-fold less reagents compared to EP, the ability to lyophilize quality-controlled and ready to administer gene therapy reagents, and the opportunity to engineer the surface of PBAE-NPs with HSC-targeting molecules (e.g. antibodies) could make this also a highly attractive and portable editing platform for in vivo HSC gene therapy. Figure 1 Figure 1. Disclosures Kiem: VOR Biopharma: Consultancy; Homology Medicines: Consultancy; Ensoma Inc.: Consultancy, Current holder of individual stocks in a privately-held company. Radtke: Ensoma Inc.: Consultancy; 47 Inc.: Consultancy.

scholarly journals Eliminating SCID row: new approaches to SCID

Hematology ◽  
2014 ◽  
Vol 2014 (1) ◽  
pp. 475-480 ◽  
Author(s):  
Donald B. Kohn
Keyword(s):  
Gene Therapy ◽  
Stem Cell ◽  
Ex Vivo ◽  
Autologous Transplantation ◽  
Unrelated Donor ◽  
Primary Immune Deficiency ◽  
Gene Repair ◽  
Gene Correction ◽  
Hematopoietic Stem ◽  
New Approaches

Abstract Treatments for patients with SCID by hematopoietic stem cell transplantation (HSCT) have changed this otherwise lethal primary immune deficiency disorder into one with an increasingly good prognosis. SCID has been the paradigm disorder supporting many key advances in the field of HSCT, with first-in-human successes with matched sibling, haploidentical, and matched unrelated donor allogeneic transplantations. Nevertheless, the optimal approaches for HSCT are still being defined, including determining the optimal stem cell sources, the use and types of pretransplantation conditioning, and applications for SCID subtypes associated with radiosensitivity, for patients with active viral infections and for neonates. Alternatively, autologous transplantation after ex vivo gene correction (gene therapy) has been applied successfully to the treatment of adenosine deaminase–deficient SCID and X-linked SCID by vector-mediated gene addition. Gene therapy holds the prospect of avoiding risks of GVHD and would allow each patient to be their own donor. New approaches to gene therapy by gene correction in autologous HSCs using site-specific endonuclease-mediated homology-driven gene repair are under development. With newborn screening becoming more widely adopted to detect SCID patients before they develop complications, the prognosis for SCID is expected to improve further. This chapter reviews recent advances and ongoing controversies in allogeneic and autologous HSCT for SCID.

scholarly journals The global clonal complexity of the murine blood system declines throughout life and after serial transplantation

Blood ◽  
2019 ◽  
Vol 133 (18) ◽  
pp. 1927-1942 ◽  
Author(s):  
Miguel Ganuza ◽  
Trent Hall ◽  
David Finkelstein ◽  
Yong-Dong Wang ◽  
Ashley Chabot ◽  
...  
Keyword(s):  
Steady State ◽  
Ex Vivo ◽  
Human Populations ◽  
Systematic Analysis ◽  
Hematopoietic Stem ◽  
Deletion Mutations ◽  
Whole Exome ◽  
Labeling System ◽  
Serial Transplantation

Abstract Although many recent studies describe the emergence and prevalence of “clonal hematopoiesis of indeterminate potential” in aged human populations, a systematic analysis of the numbers of clones supporting steady-state hematopoiesis throughout mammalian life is lacking. Previous efforts relied on transplantation of “barcoded” hematopoietic stem cells (HSCs) to track the contribution of HSC clones to reconstituted blood. However, ex vivo manipulation and transplantation alter HSC function and thus may not reflect the biology of steady-state hematopoiesis. Using a noninvasive in vivo color-labeling system, we report the first comprehensive analysis of the changing global clonal complexity of steady-state hematopoiesis during the natural murine lifespan. We observed that the number of clones (ie, clonal complexity) supporting the major blood and bone marrow hematopoietic compartments decline with age by ∼30% and ∼60%, respectively. Aging dramatically reduced HSC in vivo–repopulating activity and lymphoid potential while increasing functional heterogeneity. Continuous challenge of the hematopoietic system by serial transplantation provoked the clonal collapse of both young and aged hematopoietic systems. Whole-exome sequencing of serially transplanted aged and young hematopoietic clones confirmed oligoclonal hematopoiesis and revealed mutations in at least 27 genes, including nonsense, missense, and deletion mutations in Bcl11b, Hist1h2ac, Npy2r, Notch3, Ptprr, and Top2b.

AMD3100-Mobilized CD34+ Cells Are Phenotypically Different and Better Targets for Retroviral Transduction Than G-CSF-Mobilized CD34+ Cells in Rhesus Macaques.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 2686-2686
Author(s):  
Andre Larochelle ◽  
Allen Krouse ◽  
Donald Orlic ◽  
Robert E. Donahue ◽  
Cynthia E. Dunbar ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Steady State ◽  
Genetic Manipulation ◽  
Rhesus Macaques ◽  
Post Transplantation ◽  
Alternative Source ◽  
Cd34 Cells

Abstract AMD3100 (AMD) has recently been shown to rapidly mobilize primitive hematopoietic cells in mice and humans, but little is known about the properties of cells mobilized with this agent. We initiated a study to determine retroviral (RV) in vivo gene marking efficiency in AMD-mobilized CD34+ cells in rhesus macaques. CD34+ cells collected 3 hours after administration of AMD to 2 animals were transduced using RV vectors containing the NeoR gene. Animals were irradiated and cells reinfused immediately after transduction. By molecular analysis, the levels of PB MNC and granulocyte NeoR gene marking at steady-state (up to 12 months post-transplantation) was 1–2% in animal RC909 and 30–40% in RQ2851. In two additional rhesus macaques, CD34+ cells were collected from steady-state BM and from the PB after mobilization with AMD or G-CSF (G). The two PB populations from each animal were transduced with one of two distinguishable NeoR vectors and simultaneously reinfused into irradiated animals. In animal RQ3590, 2% in vivo gene marking at steady-state (up to 4 months post-transplantation) was derived from AMD-mobilized cells compared to 0.05% from the G-mobilized fraction. Animal RQ3636 showed 10% in vivo marking from the AMD-mobilized fraction and no detectable marking from the G-mobilized cells. We also compared phenotypic and functional characteristics of CD34+ cells from BM, AMD-PB and G-PB. An average of 31% of the AMD-mobilized cells were in the Go phase of the cell cycle, compared to 79% of G-mobilized cells (p=0.02), and 45% for the BM fraction (p=0.24). In contrast, 64% AMD-mobilized cells were in G1 compared to 17% of G-mobilized cells (p=0.03) and 44% for the BM fraction (p=0.15). Flow cytometry showed CXCR4 expression on 59% AMD-mobilized cells, in comparison to 11% G-mobilized cells (p=0.02) and 22% BM cells (p=0.07). Similar results were obtained when comparing VLA-4 expression. The increased expression of CXCR4 on AMD-mobilized CD34+ cells correlated with their increased ability to migrate towards SDF-1α in vitro (45%) compared to G-mobilized cells (8%, p=0.01) and BM cells (17%, p=0.08). Our data indicate efficient long-term in vivo gene marking in the rhesus macaque model, validating the ability of AMD to induce mobilization of true long-term repopulating HSCs. AMD-mobilized PB HSCs represent an alternative source of HSCs amenable to genetic manipulation with integrating RV vectors, with potential applications in gene therapy approaches for patients with sickle cell anemia; documented complications have precluded mobilization using G or G/SCF in these patients. Also, cell cycle status and surface phenotype of AMD-mobilized CD34+ cells are more comparable to steady-state BM cells than G-mobilized PB HSCs. AMD-mobilized CD34+ cells are more actively cycling than G-mobilized CD34+ cells, correlating with the increased efficiency of replication-dependent retrovirus-mediated gene transduction. The increased expression of the adhesion receptors CXCR4 and VLA-4 on primitive AMD-mobilized cells compared to G-mobilized cells suggests fundamental differences in the mechanisms of AMD-mediated and cytokine-mediated stem cell mobilization.

Ex Vivo Expansion of Retrovirally-Transduced Primate CD34+ Cells Results in Preferential Engraftment and Persistence of Clones with MDS1/EVI1 Insertion Sites.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 203-203
Author(s):  
Theo Gomes ◽  
Stephanie Sellers ◽  
Robert E. Donahue ◽  
Rima Adler ◽  
Andre La Rochelle ◽  
...  
Keyword(s):  
Gene Therapy ◽  
Insertional Mutagenesis ◽  
Ex Vivo ◽  
Safety Issue ◽  
Retroviral Vectors ◽  
Ex Vivo Expansion ◽  
Target Cells ◽  
Hematopoietic Stem ◽  
Cd34 Cells ◽  
Clinical Gene Therapy

Abstract There is increasing evidence that insertional activation of proto-oncogenes by retroviral vectors is a significant safety issue that must be addressed before clinical gene therapy, particularly targeting hematopoietic stem and progenitor cells, can be further developed. The risk of insertional mutagenesis for replication-incompetent retroviral vectors has been assumed to be low until the occurence of T cell leukemias in children treated with HSC-directed gene therapy for X-SCID, and recent evidence that retroviral integration is more common in the promoter region of transcriptionally-active genes. The occurence of “common integration sites” in a particular gene also suggests a non-random insertion pattern, and/or immortalization or other change in the behavior of a clone harboring an insertion in these particular genes. We have previously reported a highly non-random occurence of 14 unique vector integrations in the first two introns of the MDS1/EVI1 proto-oncogene out of a total of 702 identified from myeloid cells of 9 rhesus macaques at least 6 months post-transplantion of retrovirally-transduced CD34+ cells.(Calmels et al, 2005). This same gene locus was found frequently activated by insertions in murine bone marrow cells immortalized in long-term in vitro culture after transduction with retroviral vectors.(Du et al Blood, 2005) To begin to investigate the factors contributing to this worrisome finding, particularly given the very recent report of a marked over-representation of MDS1/EVI1 insertions in a human clinical gene therapy trial for chronic granulomatous disease, we asked whether continued ex vivo expansion of transduced CD34+ cells prior to transplantation would further select for clones with insertions in MDS1/EVI1 or other proto-oncogenes. Rhesus CD34+ cells were transduced with the G1Na standard retroviral vector, identical to that used in the prior studies, using our standard 96 hour transduction protocol in the presence of Retronectin and SCF, FLT3L and thrombopoietin. At the end of transduction, all cells were continued in culture for an additional 7 days under the same culture conditions, and then reinfused into the donor animal following 1200 rads TBI. At 1 month post-transplant there were no CIS and no MDS1/EVI1 insertions identified. However, at 6 months post-transplantation 5 out of 27 (19%) of the unique insertions identified in granulocytes were within the first two introns of MDS1/EVI1, very significantly higher than the 2% of MDS1/EVI1 insertions (14 of 702) identified in animals that were transplanted with cells not subjected to additional ex vivo expansion.(p<.0001) One MDS1/EVI1 clone constituted 14% of overall sequences identified, and the 5 clones constituted 37% of total sequences identified. This strongly suggests that the over-representation of this locus in engrafting cells is due to a potent immortalizing signal provided by activation of the MDS1/EVI1 gene products by the stonger retroviral promoter/enhancer, and that the need for extended ex vivo culture of target cells may select for insertion events activating this locus. It also suggests that strategies involving prolonged ex vivo expansion or selection of transduced cells could increase the risk of gene therapy utilizing integrating vectors targeting primitive hematopoietic cells.

Clonal Analyses of Retroviral Vector Integrations in ADA-SCID Patients Treated with Stem Cell Gene Therapy.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 3249-3249
Author(s):  
Barbara Cassani ◽  
Grazia Andolfi ◽  
Massimiliano Mirolo ◽  
Luca Biasco ◽  
Alessandra Recchia ◽  
...  
Keyword(s):  
Gene Therapy ◽  
T Cells ◽  
T Cell ◽  
Gene Transfer ◽  
Human Genome ◽  
Ex Vivo ◽  
Cd34 Cells

Abstract Gene transfer into hematopoietic stem/progenitor cells (HSC) by gammaretroviral vectors is an effective treatment for patients affected by severe combined immunodeficiency (SCID) due to adenosine deaminase (ADA)-deficiency. Recent studied have indicated that gammaretroviral vectors integrate in a non-random fashion in their host genome, but there is still limited information on the distribution of retroviral insertion sites (RIS) in human long-term reconstituting HSC following therapeutic gene transfer. We performed a genome-wide analysis of RIS in transduced bone marrow-derived CD34+ cells before transplantation (in vitro) and in hematopoietic cell subsets (ex vivo) from five ADA-SCID patients treated with gene therapy combined to low-dose busulfan. Vector-genome junctions were cloned by inverse or linker-mediated PCR, sequenced, mapped onto the human genome, and compared to a library of randomly cloned human genome fragments or to the expected distribution for the NCBI annotation. Both in vitro (n=212) and ex vivo (n=496) RIS showed a non-random distribution, with strong preference for a 5-kb window around transcription start sites (23.6% and 28.8%, respectively) and for gene-dense regions. Integrations occurring inside the transcribed portion of a RefSeq genes were more represented in vitro than ex vivo (50.9 vs 41.3%), while RIS <30kb upstream from the start site were more frequent in the ex vivo sample (25.6% vs 19.4%). Among recurrently hit loci (n=50), LMO2 was the most represented, with one integration cloned from pre-infusion CD34+ cells and five from post-gene therapy samples (2 in granulocytes, 3 in T cells). Clone-specific Q-PCR showed no in vivo expansion of LMO2-carrying clones while LMO2 gene overexpression at the bulk level was excluded by RT-PCR. Gene expression profiling revealed a preference for integration into genes transcriptionally active in CD34+ cells at the time of transduction as well as genes expressed in T cells. Functional clustering analysis of genes hit by retroviral vectors in pre- and post-transplant cells showed no in vivo skewing towards genes controlling self-renewal or survival of HSC (i.e. cell cycle, transcription, signal transduction). Clonal analysis of long-term repopulating cells (>=6 months) revealed a high number of distinct RIS (range 42–121) in the T-cell compartment, in agreement with the complexity of the T-cell repertoire, while fewer RIS were retrieved from granulocytes. The presence of shared integrants among multiple lineages confirmed that the gene transfer protocol was adequate to allow stable engraftment of multipotent HSC. Taken together, our data show that transplantation of ADA-transduced HSC does not result in skewing or expansion of malignant clones in vivo, despite the occurrence of insertions near potentially oncogenic genomic sites. These results, combined to the relatively long-term follow-up of patients, indicate that retroviral-mediated gene transfer for ADA-SCID has a favorable safety profile.

Development of Megakaryocyte-Specific Lentiviral Vectors for Gene Therapy of Platelet Disorders.

Blood ◽  
2007 ◽  
Vol 110 (11) ◽  
pp. 5143-5143
Author(s):  
Liesbeth De Waele ◽  
Kathleen Freson ◽  
Chantal Thys ◽  
Christel Van Geet ◽  
Désiré Collen ◽  
...  
Keyword(s):  
Gene Therapy ◽  
Transgene Expression ◽  
Ex Vivo ◽  
Phosphoglycerate Kinase ◽  
Lentiviral Vectors ◽  
Wild Type ◽  
Hematopoietic Stem ◽  
Platelet Disorders

Abstract The prevalence of congenital platelet disorders has not been established but for some life-threatening bleeding disorders the current therapies are not adequate, justifying the development of alternative strategies as gene therapy. In the case of platelet dysfunction and thrombocytopenia as described for GATA1 deficiency, potentially lethal internal bleedings can occur. The objective of the study is to develop improved lentiviral vectors for megakaryocyte(MK)-specific long term gene expression by ex vivo transduction of hematopoietic stem cells (HSC) to ultimately use for congenital thrombopathies as GATA1 deficiency. Self-inactivating lentiviral vectors were constructed expressing GFP driven by the murine (m) or human (h) GPIIb promoter. These promoters contain multiple Ets and GATA binding sites directing MK-specificity. To evaluate the cell lineage-specificity and transgene expression potential of the vectors, murine Sca1+ and human CD34+ HSC were transduced in vitro with Lenti-hGPIIb-GFP and Lenti-mGPIIb-GFP vectors. After transduction the HSC were induced to differentiate in vitro along the MK and non-MK lineages. The mGPIIb and hGPIIb promoters drove GFP expression at overall higher levels (20% in murine cells and 25% in human cells) than the ubiquitous CMV (cytomegalovirus) or PGK (phosphoglycerate kinase) promoters, and this exclusively in the MK lineage. Interestingly, in both human and murine HSC the hGPIIb promoter with an extra RUNX and GATA binding site, was more potent in the MK lineage compared to the mGPIIb promoter. Since FLI1 and GATA1 are the main transcription factors regulating GPIIb expression, we tested the Lenti-hGPIIb-GFP construct in GATA1 deficient HSC and obtained comparable transduction efficiencies as for wild-type HSC. To assess the MK-specificity of the lentiviral vectors in vivo, we transplanted irradiated wild-type C57Bl/6 mice with Sca1+ HSC transduced with the Lenti-hGPIIb-GFP constructs. Six months after transplantation we could detect 6% GFP positive platelets without a GFP signal in other cell lineages. Conclusion: In vitro and in vivo MK-specific transgene expression driven by the hGPIIb and mGPIIb promoters could be obtained after ex vivo genetic engineering of HSC by improved lentiviral vectors. Studies are ongoing to study whether this approach can induce phenotypic correction of GATA1 deficient mice by transplantation of ex vivo Lenti-hGPIIb-GATA1 transduced HSC.

Ex Vivo Expansion and Long-Term Hematopoietic Reconstitution Ability of Sorted CD34+CD59+ Cells from Patients with Paroxysmal Nocturnal Hemoglobinuria.

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 2324-2324
Author(s):  
Juan Xiao ◽  
Bing Han ◽  
Wanling Sun ◽  
Yuping Zhong ◽  
Yongji Wu
Keyword(s):  
Bone Marrow ◽  
Ex Vivo ◽  
Peripheral Blood Cell ◽  
Intravascular Hemolysis ◽  
Blood Cell Count ◽  
Normal Cells ◽  
Hematopoietic Stem ◽  
Cd34 Cells

Abstract Paroxysmal nocturnal hemoglobinuria (PNH) is a clonal hematopoietic stem cell disorder characterized by intravascular hemolysis, venous thrombosis, and bone marrow (BM) failure. Until now, allogeneic hematopoietic stem cell transplantation is still the only way to cure PNH. Eculizumab, although very promising, is not the eradication of the disease because of raising the possibility of severe intravascular hemolysis if therapy is interrupted. Here we enriched the residual bone marrow normal progenitor cells (marked by CD34+CD59+) from PNH patients, tried to find an effective way of expanding the progenitors cells used for autologous bone marrow transplantation (ABMT). Objective To expand CD34+CD59+ cells isolated from patients with PNH and observe the long-term hemaotopoietic reconstruction ability of the expanded cells both ex vivo and in vivo. Methods CD34+CD59+ cells from 13 patients with PNH and CD34+ cells from 11 normal controls were separated from the bone marrow monouclear cells first by immunomagnetic microbead and then by flow cytometry autoclone sorting. The selected cells were then cultivated under different conditions for two weeks to find out the optimal expansion factors. The long-term hematopoietic supporting ability of expanded CD34+CD59+ cells was evaluated by long-term culture in semi-solid medium in vitro and long-term engraftment in irradiated severe combined immunodeficiency(SCID) mice in vivo. Results The best combination of hematopoietic growth factors for ex vivo expansion was SCF+IL-3+IL-6+FL+Tpo+Epo, and the most suitable time for harvest was on day 7. Although the CD34+CD59+ PNH cells had impaired ex vivo increase compared with normal CD34+ cells (the biggest expansion was 23.49±3.52 fold in CD34+CD59+ PNH cells and 38.82±4.32 fold in CD34+ normal cells, P&lt;0.01 ), they remained strong colony-forming capacity even after expansion ( no difference was noticed in CFCs or LTC-IC of PNH CD34+CD59+ cells before and after expansion, P&gt;0.05). According to the above data, 11/13(84.3%) patients with PNH can get enough CD34+CD59+cells for ABMT after expansion. The survival rate and human CD45 expression in different organs was similar between the irradiated SCID mice transplanted with expanded CD34+CD59+ PNH cells and those with normal CD34+ cells (P&gt;0.05). The peripheral blood cell count recovered on day 90 in mice transplanted with PNH cells, which was compatible with those transplanted with normal cells (P&gt;0.05). On secondary transplantation, the peripheral blood cell count returned to almost normal on day 30 in mice transplanted with either PNH cells or normal cells. Lower CD45 percentage was found in secondary transplantation compared with primary transplantation but no difference between mice transplanted with different cells. Conclusion Isolated CD34+CD59+ cells from patients with PNH can be effectively expanded ex vivo and can support lasting hematopoiesis both ex vivo and in vivo. These data provide a new potential way of managing PNH with ABMT.

Small Molecule Combination Enhances CD34+/CD38- Cell Proliferation Via Inhibition of Differentiation

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 658-658
Author(s):  
Lan Wang ◽  
Xin Guan ◽  
Huihui Wang ◽  
Bin Shen ◽  
Yu Zhang ◽  
...  
Keyword(s):  
Cell Proliferation ◽  
Small Molecules ◽  
Cell Expansion ◽  
Target Genes ◽  
Ex Vivo ◽  
Hematopoietic Stem ◽  
Qpcr Analysis ◽  
Cd34 Cells ◽  
Cells Cultured

Abstract Hematopoietic stem cells (HSCs) have become increasingly attractive for the therapy of various hematological system disorders. The aim of this study is to identify approaches that promote the expansion of HSCs. We present here the identification of a combination of small molecules and cytokines that is effective in retaining high stemness of hematopoietic stem/progenitor cells while promoting cell proliferation by inhibiting differentiation. Firstly, five small-molecule candidates were screened for their individual effects on ex vivo expansion of human peripheral blood CD34+ cells in the presence of selected cytokines. The best compounds at their optimal concentrations were further analyzed in combination, to achieve maximum capacity for stimulating the CD34+CD38- cell expansion ex vivo. The extent of cell expansion and the immunophenotype of expanded cells were assessed through flow cytometry. Additional cell and molecular assays were performed to confirm that the expanded CD34± cells are functionally normal in vitro. Subsequently, the expanded cells were transplanted into sublethally irradiated NOD/SCID mice for the assessment ofhuman cell viability and engraftment potential in vivo. Furthermore, the expression of several genes in the cell proliferation and differentiation pathways was analyzed through qPCR during the process of CD34±cell expansion. Following multiple rounds of screening, an optimal formula (named as "SVC cocktail") was obtained, which consisted of four cytokines (stem cell factor, flt-3 ligand, thrombopoietin and interleukin-6) and three small molecules (Stem Regenin 1, valproic acid and CAY10433). CD34+ cells cultured with SVC cocktail had a purity of 76.2%±7.5% and reached expansion folds of 27.9±4.3 for CD34+/CD38- HSCs on day 7. In contrast, CD34+ cells cultured with the cytokines alone displayed a purity of 27.4%±6.3% and expansion folds of 15.5±2.2 for CD34+/CD38- cells. The groups with small molecules only (plus DMSO, the vehicle), or with basal medium only, showed no surviving cells on day 4. Furthermore, cell cycle analysis indicated that the SVC cocktail-induced CD34+/CD38- cells stayed in a more quiescent state (G0/G1: 75.2%±3.6%; S: 9.2%±2.4%). On the other hand, the cells cultured without the three small molecules had active DNA synthesis (G0/G1: 56.0%±2.0%; S: 31.8%±3.2%), implicating a trend of enhanced cell differentiation in the cytokine alone group. RT-qPCR analysis further demonstrated that the expression of HSC stemness markers CD90, CD133, CD117, ALDH1, Bmi1, HoxB4, GATA-2, Runx1, and CXCR4 were elevated in the SVC cocktail-induced CD34+ cells, but dramatically reduced or barely detectable in the cytokine alone group. In addition, CFU assays for the SVC cocktail group vs the cytokine alone group demonstrated BFU-E of 54.0±4.6 vs 11.7±1.5, CFU-GM of 71.0±2.7 vs 8.3±2.5, CFU-GEMM of 40.7±3.8 vs 5.0±2.0 and CFU-Mk of 6.7±1.5 vs 0.7±0.6, respectively. For the in vivo engraftment in mouse bone marrow, human CD45 rate in the SVC cocktail group was much higher than in the cytokine alone group (21.1%±2.7% vs 0.5%±0.1%); similar group differences were also found in the CD34+ and CD34+CD38- rate (7.7%±1.4% vs 1.6%±1.2% and 6.8%±2.2% vs 1.6%±0.1% respectively), all at 8 weeks post transplantation. Moreover, qPCR analysis of Notch and Wnt signaling pathways for cultured cells on day 7 showed that the expression of Notch target genes (related to high activation of HSC property) was enhanced in the SVC cocktail group compare to the cytokine group (HES5: 9.2±2.3 vs 3.6±1.4 in arbitrary units; HEY1: 6.3±1.9 vs 2.6±1.2; HES1: 3.2±1.3 vs 1.3±0.4; Notch1: 1.4±0.3 vs 1.2±0.3), whereas the expression of Wnt target genes (related to activation of HSC differentiation) was greater in the cytokine alone group than in the SVC cocktail group (CCND1: 10.1±4.3 vs 1.2±0.8; LEF1: 4.3±0.6 vs 2.9±0.2; PPAR D: 3.4±0.3 vs 1.5±0.1; FZD2: 1.8±0.2 vs 1.0±0.1). Taken together, our results show that the new SVC cocktail is able to retain the characteristics of HSCs remarkably well, by enhancing their expansion while inhibiting their differentiation. Mechanistically, it appears that the three small molecules can effectively inhibit the cytokines' pro-differentiation effects on CD34+CD38- cells without affecting the cytokines' ability to stimulate cell proliferation. Disclosures Wang: Biopharmagen Corp.: Employment. Ren:Biopharmagen Corp: Employment. Jiang:Biopharmagen Corp: Consultancy.

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