Ex vivo
 expansion and characterisation of CD34+
 cells derived from chronic myeloid leukaemia bone marrow and peripheral blood, and from normal bone marrowand mobilised peripheral blood

Abstract Abstract 4816 Hematopoietic stem cell (HSC) transplantation has become the standard of care for patients with hematologic cancers, anemia, and a variety of other malignant and non-malignant disorders, with greater than 50,000 such procedures being performed globally each year, according to the Worldwide Network for Blood and Marrow Transplantation. Although mobilized peripheral blood (MPB) has become a preferred source of HSCs for transplants, bone marrow (BM) and umbilical cord blood (UCB) are also frequently utilized. Regardless of source, several groups have reported that grafts containing lower total nucleated cell (TNC) and CD34+ cell doses contribute to delayed engraftment and higher graft failure rate. Therefore, methods to increase the total cell number while maintaining the progenitor phenotype, especially the CD34+ progenitor cells, from individual grafts would have a significant clinical impact. Ex vivo expansion of HSCs prior to transplantation is one approach that offers tremendous promise for increasing cell doses and improving clinical outcomes. In many ex vivo culture systems, HSCs are cultured as a suspension cells and cultured in the presence of various media additives that act to enhance cell proliferation while reducing differentiation. An often-overlooked factor influencing fate decisions is the interaction of HSCs with a substrate. In the natural bone marrow microenvironment, HSCs maintain close contact with a complex network of stromal cells and extracellular matrix, likely indicating that cell-cell and cell-matrix interactions play an important role in maintaining their stem cell phenotype. With the goal of mimicking the bone marrow stem cell niche, Arteriocyte, Inc. has developed a 3-D NANEX nanofiber based cell culture substrate. The functionalized NANEX substrate is designed to provide topographical and substrate-immobilized biochemical cues that act in synergy with media additives to enhance HSC proliferation while maintain the progenitors stem cell phenotype. Here, we present our recent work with the NANEX platform towards comparing and achieving a high yield ex vivo expansion of CD34+ cells from MPB, BM, and UCB. Additionally, through the use of flow cytometry and CFU assays, we quantify and characterize NANEX-expanded cells from each source. Furthermore, we compared NANEX to a variety of commercially available products and demonstrate that NANEX significantly improves expansion and reduces phenotype loss during ex vivo culture. Our data indicates that NANEX technology provides a robust ex vivo expansion of HSCs and, with further GMP and clinical development, offers great potential for clinical applications. Disclosures: No relevant conflicts of interest to declare.

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Ex vivo expansion of megakaryocyte progenitor cells from normal bone marrow and peripheral blood and from patients with haematological malignancies

British Journal of Haematology ◽

10.1046/j.0007-1048.2002.03354.x ◽

2002 ◽

Vol 116 (4) ◽

pp. 912-919 ◽

Cited By ~ 12

Author(s):

Allison Blair ◽

Caroline L. Baker ◽

Derwood H. Pamphilon ◽

Philip A. Judson

Keyword(s):

Bone Marrow ◽

Progenitor Cells ◽

Peripheral Blood ◽

Ex Vivo ◽

Ex Vivo Expansion ◽

Normal Bone Marrow ◽

Haematological Malignancies ◽

Normal Bone

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Early-acting cytokine-driven ex vivo expansion of mobilized peripheral blood CD34+ cells generates post-mitotic offspring with preserved engraftment ability in non-obese diabetic/severe combined immunodeficient mice

British Journal of Haematology ◽

10.1046/j.1365-2141.2001.02974.x ◽

2001 ◽

Vol 114 (4) ◽

pp. 920-930 ◽

Cited By ~ 10

Author(s):

C. Herrera ◽

J. Sánchez ◽

A. Torres ◽

C. Bellido ◽

A. Rueda ◽

...

Keyword(s):

Peripheral Blood ◽

Ex Vivo ◽

Ex Vivo Expansion ◽

Immunodeficient Mice ◽

Peripheral Blood Cd34 ◽

Cd34 Cells ◽

Mobilized Peripheral Blood

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Characterization of ‘Early’ vs ‘Late’ Endothelial Progenitor Cells (EPCs) Which Are Derived from Human Umbilical Cord Blood (HCB) during Ex Vivo Expansion.

Blood ◽

10.1182/blood.v106.11.1706.1706 ◽

2005 ◽

Vol 106 (11) ◽

pp. 1706-1706

Author(s):

Eun-Sun Yoo ◽

Jee-Young Ahn ◽

Yun-Kyung Bae ◽

Seung-Eun Lee ◽

Sang min Lee ◽

...

Keyword(s):

Bone Marrow ◽

Peripheral Blood ◽

Ex Vivo ◽

Tube Formation ◽

Ex Vivo Expansion ◽

Human Umbilical Cord ◽

Vascular Injuries ◽

Rt Pcr ◽

Different Types

Abstract EPCs have been isolated from adult peripheral blood and bone marrow. Recently, several groups reported that two types (‘early’ & ‘late’) of EPC could be isolated from peripheral blood and bone marrow when pertinent cocktails of cytokines were used. Interestingly, early and late EPCs are different in terms of expression of surface markers, the abilities of tube formation in vitro and the capabilities of re-vascularization on hind limb ischemia models in mice. We found EPC formation during ex vivo expansion of HCB and one EPC could be found from 314 CD34+ cells from HCB based on limiting dilutional assay (ref. Stem Cells; 2003, Yoo et al). However, little is known about the characteristics of ‘early’ and ‘late’ EPCs that are derived from HCB. In this study, our aims are to isolate the ‘early’ and ‘late’ EPCs from HCB during ex-vivo HCB expansion period and to characterize the biologic properties between ‘early’ and ‘late’ EPCs. 1 x 108 mononuclear cells were plated on a 100mm culture dish coated with 50ug/ml of human fibronectin (Calbiochem) and cultured in EGM-2 BulletKit system (Clonetics). Endothelial cells were assessed by colony counts, flow cytometry, proliferation assay, RT-PCR and in vitro tube formation in Matrigel plate. Migration of EPCs were also measured by in vitro transmigration assay in the presence of VEGF and SDF-1. In results, early spindle-shaped cells (‘early’ EPCs) which were grown at first week of culture were positive for CD31, CD14 and CXCR-4. Cobblestone shaped cells (‘late’ EPC) were in peak growth at second and third weeks of culture and were also positive using above antibodies except CD14. Early EPCs had not expressed mRNA of KDR, vWF and VE-Cadherin by RT-PCR. However, late EPCs expressed high level of mRNA of those endothelial marker genes. Both early and late EPCs expressed mRNA of eNOS. Late EPC produced more nitric oxide and formed more capillary tubes than those of early spindle-shaped cells. Early EPCs were readily migrated by VEGF and SDF-1 compared with those of late EPCs. In conclusions, we have found two different types of EPCs with different biologic properties during HCB ex vivo expansion. These findings may have potential clinical applications for “cell therapy” on vascular injuries (ie, hindlimb ischemia and myocardial infacrtion). Murine models for vascular injuries are being established to test the efficacy of different types of EPCs from HCB in our Lab.

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Human Brain Endothelial Cells (HUBEC) Can Expand Both Human Bone Marrow and Cord Blood SCID-Repopulating Cells (SRC) through Cell Contact Rather Than Soluble Factors.

Blood ◽

10.1182/blood.v106.11.36.36 ◽

2005 ◽

Vol 106 (11) ◽

pp. 36-36

Author(s):

Naoko Takebe ◽

Xiangfei Cheng ◽

Ann M. Farese ◽

Emily Welty ◽

Barry Meisenberg ◽

...

Keyword(s):

Bone Marrow ◽

Endothelial Cells ◽

Human Brain ◽

Ex Vivo ◽

Fold Increase ◽

Ex Vivo Expansion ◽

Scid Mice ◽

Cell Contact ◽

Brain Endothelial Cells ◽

Cd34 Cells

Abstract Human brain endothelial cells (HUBEC), a U.S. Navy proprietary cell line, was reported previously by Chute et al as a promising co-culture ex vivo expansion system for both adult bone marrow (ABM) and cord blood (CB) hematopoietic stem cells (HSC).a,b,c We report here our results of using HUBEC in ex vivo expansion and in vivo engraftment assay using NOD-SCID mice. CD34+ enriched fresh ABM was obtained using the method as described previously.a,b However, we used frozen CB and the same cytokines for both ABM and CB expansion whereas Chute et al used fresh CB and different cytokines. Ex vivo expansion studies for both ABM and CB were performed for 7 days in the HUBEC coated plates with previously reported cell density and cytokine cocktail containing GM-CSF, IL-3, IL-6, SCF, and flt-3 (GM36SF) in IMDM 10% FBS media.a HSC injections and BM harvesting of NOD-SCID mice as well as flow cytometric analysis were performed using the methods of Chute et al.a NOD-SCID mice were transplanted with limiting doses of either fresh ABM CD34+ cells or freshly thawed CB CD34+. The progeny of the identical doses of ABM CD34+ or the progeny of the identical doses of CB CD34+ cells was then transplanted. Culture with GM36SF alone resulted in a 15.5-fold and 70-fold increase in total cells, a 3.4-fold and 32-fold increase in CD34+ cells, and a 4.8-fold and 4.1-fold increase in CD34+/CD38- cells for ABM and CB, respectively. In contrast, HUBEC co-culture with GM36SF yielded a 25-fold and 48-fold increase in total cells, a 8.9-fold and 13-fold increase in CD34+ cells, and 114-fold and 106-fold increase in CD34+/CD38- cells for ABM and CB, respectively. HUBEC co-culture without GM36SF supported a 1.0-fold and 1.0-fold increase in total cells, a 0.06-fold and 0.1-fold increase in CD34+ cells, and 0.25-fold and 0.2-fold increase in CD34+/CD38- cells for ABM and CB. HUBEC co-culture with GM36SF and transwell (non-contact culture) resulted in a 20-fold and 48-fold increase in total cells, a 6-fold and 8-fold increase in CD34+ cells, and a 32-fold and 38-fold increase in CD34+/CD38- cells for ABM and CB. Overall, the transwell expansion of CD34+/CD38- population in both ABM and CB was reduced to 30% of that achieved in the contact culture. ABM CD34+ cells (5 x 105) engrafted 60% and the progeny of 5 x 105 cultured in the HUBEC monolayer with GM36SF engrafted in 90% of transplanted mice. CB CD34+ cells (1 x 104) engrafted 27% and the progeny 1 x 104 CB CD34+ cells cultured in the HUBEC monolayer with GM36SF engrafted 64% of NOD-SCID mice. SRC frequencies calculated as a 3.12-fold and 2.7-fold increase in CD34+ enriched ABM and CB, respectively, which was less than reported previously.a,b In summary, HUBEC supports and expands SRC mainly through cell-to-cell contact between HSC and endothelial cells, with HUBEC-secreted factors playing a minor role.

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Ex Vivo Expansion of Human Mobilized Peripheral Blood Stem Cells Using Epigenetic Modifiers

Blood ◽

10.1182/blood.v118.21.1920.1920 ◽

2011 ◽

Vol 118 (21) ◽

pp. 1920-1920

Author(s):

Santosh Saraf ◽

Hiroto Araki ◽

Benjamin Petro ◽

Kazumi G Yoshinaga ◽

Simona Taioli ◽

...

Keyword(s):

Peripheral Blood ◽

Ex Vivo ◽

Ex Vivo Expansion ◽

Self Renewal ◽

Transcript Levels ◽

Epigenetic Modifiers ◽

Cd34 Cells ◽

Mobilized Peripheral Blood

Abstract Abstract 1920 Currently, a significant percentage of hematopoietic stem cell (HSC) transplantations are being performed using growth factor mobilized peripheral blood (MPB) grafts. Unfortunately, about 5 to 40% of patients are unable to benefit from HSC transplantation due to failure to mobilize and harvest an adequate graft (> 2 × 106 CD34+ cells/kg). Epigenetic modifications are thought to be important in determining the fate of HSC including self renewal and differentiation. We have previously demonstrated that sequential addition of chromatin modifying agents (CMA), 5-aza-2'-deoxyctidine (5azaD) and trichostatin A (TSA), is capable of expanding transplantable HSC 7-fold from human cord blood (CB), likely by preventing the silencing of genes which promote HSC self renewal divisions (Araki et al. Blood 2007). Using the same protocol we have also previously shown that 5azaD/TSA can expand CD34+CD90+ cells containing in vivo repopulating capacity from human bone marrow (BM) 2.5-fold (Milhem et al. Blood 2004). The objectives of our current studies were to assess whether CMA can also expand HSCs present in MPB. In order to test this hypothesis, CD34+ cells were isolated from MPB products from three healthy donors and were expanded ex vivo using 5azaD/TSA for 9 days as described previously (Araki et al. Blood 2007). Following culture, expansion of primitive CD34+CD90+ cells, colony forming unit mixed lineages (CFU-mix), and long term (5 weeks) cobblestone area forming cells (CAFC) were assessed. A 3.74 ± 0.77 fold expansion of CD34+CD90+ cells was observed in 5azaD/TSA expanded MPB cells while only a 0.93 ± 0.23 fold expansion was observed in control cultures (p = 0.025). The 5azaD/TSA expanded MPB cells had a 10.1-fold increase in the number of CFU-mix in comparison to no expansion in the control cultures (p = 0.0055). A 2.26-fold expansion of CAFC numbers was observed in 5azaD/TSA expanded MPB cells in comparison to 0.19-fold expansion in control cultures. Taken together, our data indicate that 5azaD/TSA can expand MPB CD34+CD90+ cells 3.74-fold which also possess the functional capacity to generate primitive CFU-mix and long term CAFCs. This expansion of primitive MPB CD34+CD90+ cells appears to be at an intermediate level (3.74 fold) in comparison to BM and CB which had 2.5-fold and 10.5-fold expansion, respectively. We have previously demonstrated that CD34+CD90+ expanded CB cells are exclusively responsible for reconstituting blood cells following transplantation (Araki et al. Exp Hematol 2006). Currently, the frequency of in vivo repopulating units for CMA expanded MPB is being determined in contrast to expanded BM and CB cells. However, it remains to be investigated what determines the limit for ex vivo expansion of HSC by epigenetic modifiers based on their ontogeny. Towards this goal we analyzed transcription levels of several genes implicated for HSC self renewal/expansion including HoxB4, GATA 2, and Ezh2, which were compared between MPB cells prior to and following expansion in 5azaD/TSA or control cultures. Significantly higher transcript levels were detected for HoxB4 (p = 0.003), GATA 2 (p = 0.0002), and Ezh2 (p = 0.0001) by real time quantitative RT PCR in the 5azaD/TSA expanded MPB graft in comparison to control cultures. Interestingly the transcript levels of HoxB4 and GATA 2 but not Ezh2 were significantly lower in expanded cells in contrast to unmanipulated primary MPB cells. This is in sharp contrast to our earlier results from CB in which 5azaD/TSA expanded cells displayed much higher transcript levels of HoxB4 and GATA 2 compared to primary unmanipulated CB cells. Previously we have demonstrated that environmental conditions can influence the degree of expansion of transplantable HSC from CB (Araki et al. Exp Hematol 2009). Using the same protocol we expanded MPB cells in the presence or absence of CMA using either optimal (SCF, TPO, FLT3L) or suboptimal cytokine cocktails (SCF, TPO, FLT3L with IL-3 and IL-6). Interestingly, unlike CB cells no significant difference in expansion between the two cytokine groups with or without CMA was observed (4.5 versus 4.3-fold expansion of CD34+CD90+ cells, respectively). Corresponding to this, transcript levels of HoxB4 and Ezh2 did not vary between MPB cells expanded with 5azaD/TSA in the two different cytokine environments. Our studies have the potential to be used to expand HSC from poor mobilizers in order to optimize MPB grafts for transplantation. Disclosures: No relevant conflicts of interest to declare.

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