scholarly journals CALR frameshift mutations in MPN patient-derived iPS cells accelerate maturation of megakaryocytes

2021 ◽  
Author(s):  
Kathrin Olschok ◽  
Lijuan Han ◽  
Marcelo A. S. de Toledo ◽  
Janik Boehnke ◽  
Martin Grasshoff ◽  
...  
Keyword(s):  
Myeloproliferative Neoplasms ◽  
Disease Model ◽  
Membrane System ◽  
Ips Cells ◽  
Driver Mutations ◽  
Independent Manner ◽  
Ips Cell ◽  
Calr Mutations ◽  
Induced Pluripotent ◽  
Key Aspects

Calreticulin (CALR) mutations are driver mutations in myeloproliferative neoplasms (MPNs), leading to activation of the thrombopoietin receptor, and causing abnormal megakaryopoiesis. Here, we generated patient-derived CALRins5- or CALRdel52-positive induced pluripotent stem (iPS) cells to establish a MPN disease model for molecular and mechanistic studies. We demonstrated myeloperoxidase deficiency in CD15+ granulocytic cells derived from homozygous CALR-mutant iPS cells, rescued by repairing the mutation using CRISPR/Cas9. iPS cell-derived megakaryocytes showed characteristics of primary megakaryocytes such as formation of demarcation membrane system and cytoplasmic pro-platelets protrusions. Importantly, CALR mutations led to enhanced megakaryopoiesis and accelerated megakaryocytic development in a thrombopoietin-independent manner. Mechanistically, our study identified differentially regulated pathways in mutated vs. unmutated megakaryocytes, such as hypoxia signaling, which represents a potential target for therapeutic intervention. Altogether, we demonstrate key aspects of mutated CALR-driven pathogenesis, dependent on its zygosity and found known and novel therapeutic targets, making our model a valuable tool for clinical drug screening in MPNs.

scholarly journals ProspectiveIn VitroModels of Channelopathies and Cardiomyopathies

2012 ◽  
Vol 2012 ◽  
pp. 1-10 ◽  
Author(s):  
Nanako Kawaguchi ◽  
Emiko Hayama ◽  
Yoshiyuki Furutani ◽  
Toshio Nakanishi
Keyword(s):  
Heart Disease ◽  
Regenerative Medicine ◽  
Expression Profiles ◽  
Disease Model ◽  
Ips Cells ◽  
Micro Rna ◽  
Rna Expression ◽  
Ips Cell ◽  
Induced Pluripotent

Anin vitroheart disease model is a promising model used for identifying the genes responsible for the disease, evaluating the effects of drugs, and regenerative medicine. We were interested in disease models using a patient-induced pluripotent stem (iPS) cell-derived cardiomyocytes because of their similarity to a patient’s tissues. However, as these studies have just begun, we would like to review the literature in this and other related fields and discuss the path for future models of molecular biology that can help to diagnose and cure diseases, and its involvement in regenerative medicine. The heterogeneity of iPS cells and/or differentiated cardiomyocytes has been recognized as a problem. Anin vitroheart disease model should be evaluated using molecular biological analyses, such as mRNA and micro-RNA expression profiles and proteomic analysis.

Analysis of Viral Integration Sites in Human Induced Pluripotent Stem Cells.

Blood ◽  
2009 ◽  
Vol 114 (22) ◽  
pp. 1485-1485
Author(s):  
Thomas Winkler ◽  
Amy R Cantelina ◽  
Jean-Yves Metais ◽  
Xiuli Xu ◽  
Anh-Dao Nguyen ◽  
...  
Keyword(s):  
Transcription Factors ◽  
Gene Transfer ◽  
Cell Lines ◽  
Chromosomal Location ◽  
Somatic Cells ◽  
Ips Cells ◽  
Ips Cell ◽  
Integration Sites ◽  
Equity Ownership ◽  
Induced Pluripotent

Abstract Abstract 1485 Poster Board I-508 The recently discovered approach for the direct reprogramming of somatic cells into induced pluripotent stem (IPS) cells by expression of defined transcription factors may provide new approaches for regenerative medicine, gene therapy and drug screening. Successful reprogramming currently requires at least temporary expression of one to four different transcription factors (among Oct3/4, Sox2, Klf4, c-Myc, Nanog and Lin28) in the targeted cells. Non-viral based reprogramming technologies have been reported, but expression of the reprogramming factors after γ-retroviral or lentiviral gene transfer remains the most efficient and commonly used approach. Since the reprogramming frequency is consistently low in these studies, it has been speculated that gene activation or disruption via proviral integration sites (IS) may play a role in obtaining the pluripotent phenotype. Here we present for the first time an extensive analysis of the lentiviral integration profile in human IPS-cells. We analysed the IS of 8 IPS cell lines derived from either human fetal fibroblasts (IMR90) or newborn foreskin fibroblasts (FS) after lentiviral gene transfer of Oct4, Sox2, Nanog, and Lin28, using linear amplification-mediated PCR (LAM-PCR). With 5 to15 IS per individual IPS clone we identified a total of 78 independent IS. Finally we assigned 75 IS to a unique chromosomal location. In addition to LAM-PCR, we confirmed the total number of IS via Southern blot. Interestingly, in 6 of 8 IPS clones some of these IS were found in pairs, integrated into the same chromosomal location within 4 base pairs of each other. This integration pattern has not been detected in our previous analysis of 702 IS in rhesus macaques transplanted with CD34+ cells transduced with retroviral vectors. Of the 75 valid IS 53 (70.7%) could be mapped to a gene-coding region, 52 located in introns and 1 in an exon, annotated in a human reference sequence in the UCSC Genome Browser RefSeq Genes track. The different IPS-clones had no integration site in common. To investigate the impact of integration on the regulation of vector targeted genes we analyzed the mRNA expression profiles using available microarray data from these clones. Out of 46 evaluable genes only two (WDR66 and MYST2 in clone IMR90-2, p<0.0001) were significantly over-expressed. The expression of two genes in clone FS-1 (ACVR2A p=0.01, RAF1 p=0.02) and one in FS-2 (KIAA0528, p=0.03) was decreased compared to the expression data of all other clones combined. In summary our data suggest that efficient reprogramming of human somatic cells is not dependent on insertional activation or deactivation of specific genes or gene classes. Furthermore, identification of the insertion profile of the IPS cell clones IMR90-1 and -4 as well as FS-1 will be useful to other researchers using these cell lines distributed by the Wisconsin International Stem Cell (WISC) bank. Disclosures: Antosiewicz-Bourget: Cellular Dynamics International: Consultancy, Equity Ownership. Thomson: Cellular Dynamics International: Equity Ownership, Membership on an entity's Board of Directors or advisory committees. Dunbar: ASH: Honoraria.

Targeted Gene Correction of Glanzmann Thrombasthenia Induced Pluripotent Stem Cells Restores Surface Expression and Fibrinogen Binding of Integrin αIIbβ3,

Blood ◽  
2011 ◽  
Vol 118 (21) ◽  
pp. 4173-4173
Author(s):  
Spencer Sullivan ◽  
Jason A. Mills ◽  
Li Zhai ◽  
Prasuna Paluru ◽  
Guohua Zhao ◽  
...  
Keyword(s):  
Stem Cells ◽  
Gene Therapy ◽  
Cell Lines ◽  
Surface Expression ◽  
Ips Cells ◽  
Ips Cell ◽  
Glanzmann Thrombasthenia ◽  
Integrin Αiibβ3 ◽  
Fibrinogen Binding ◽  
Induced Pluripotent

Abstract Abstract 4173 Glanzmann Thrombasthenia (GT) is a rare, autosomal recessive disorder resulting from an absence of functional platelet integrin αIIbβ3, leading to impaired platelet aggregation and clinically presenting with severe bleeding. It is a model of an inherited platelet disorder that might benefit from corrective gene therapy. Treatment options for GT are limited and largely supportive. They include anti-fibrinolytics, activated factor VII, platelet transfusions, and bone marrow transplantation. Recent gene therapy research in a canine model for GT demonstrated that lentiviral transduction of mobilized hematopoietic stem cells could restore 6% αIIbβ3 receptors in thrombasthenic canine platelets relative to wild type (WT) canine platelets. As an alternative gene therapy strategy, we generated induced pluripotent stem (iPS) cell lines from the peripheral blood of two patients with GT and examined whether a megakaryocyte-specific promoter driving αIIb cDNA expression within the AAVS1 safe harbor locus could ameliorate the GT phenotype in iPS cell-derived megakaryocytes. Patient 1 is a compound heterozygote for αIIb with the following two missense mutations: exon 2 c.331T>C (p.L100P) and exon 5 c.607G>A (p.S192N). Patient 2 is homozygous for a c.818G>A (p.G273D) mutation adjacent to the first calcium-binding domain of αIIb, leading to impaired intracellular transport of αIIbβ3. Both patients express <5% αIIbβ3 on the surface of their platelets. Peripheral blood mononuclear cells from both GT patients and WT controls were efficiently reprogrammed to pluripotency using a doxycycline-inducible polycistronic lentivirus containing OCT4, KLF4, SOX2, and CMYC. Transgene constructs using a murine GPIbα promoter driving either a green fluorescent protein (GFP) reporter or αIIb cDNA were inserted into a gene-targeting vector specific for the first intron of AAVS1, a locus amenable to gene targeting and resistant to transgene silencing in human iPS cells. The GPIbα-driven GFP transgene was efficiently targeted into AAVS1 in WT iPS cells using zinc finger nuclease-mediated homologous recombination, as was the αIIb construct into GT iPS cell lines. PCR and Southern blot analyses confirmed single, non-random, transgene integrations. The iPS cells were differentiated into megakaryocytes using a feeder-free/serum-free adherent monolayer protocol and analyzed by flow cytometry. GFP, along with endogenous CD41 (αIIb), was initially expressed in primitive WT hematopoietic progenitor cells. GFP expression was lost in erythrocytes and myeloid cells, but maintained in CD41+/CD42+ megakaryocytes, demonstrating that this transgenic construct mirrors endogenous CD41 expression. The GT phenotype was confirmed in megakaryocytes derived from patient iPS cells, showing loss of αIIbβ3 expression. When compared to WT iPS cell-derived megakaryocytes, gene-corrected GT iPS cell-derived megakaryocytes showed >50% and >70% αIIbβ3 surface expression for patients 1 and 2, respectively. Both patients' iPS cell-derived megakaryocytes also demonstrated fibrinogen binding upon thrombin activation. This is the first report of the generation and genetic correction of iPS cell lines from patients with a disease affecting platelet function. These findings suggest that this GPIbα-promoter construct targeted to the AAVS1 locus drives megakaryocyte-specific expression at a therapeutically significant level, which offers the possibility of correcting severe inherited platelet disorders beginning with iPS cells derived from these affected individuals. Disclosures: Lambert: Cangene: Honoraria.

scholarly journals Extracellular Matrix-Dependent Generation of Integration- and Xeno-Free iPS Cells Using a Modified mRNA Transfection Method

2016 ◽  
Vol 2016 ◽  
pp. 1-11 ◽  
Author(s):  
Kang-In Lee ◽  
Seo-Young Lee ◽  
Dong-Youn Hwang
Keyword(s):  
Extracellular Matrix ◽  
Cell Therapy ◽  
Culture System ◽  
Ips Cells ◽  
Great Promise ◽  
Ips Cell ◽  
Transfection Method ◽  
Reprogramming Efficiency ◽  
Mrna Transfection ◽  
Induced Pluripotent

Human induced pluripotent stem cells (iPS cells) hold great promise in the field of regenerative medicine, especially immune-compatible cell therapy. The most important safety-related issues that must be resolved before the clinical use of iPS cells include the generation of “footprint-free” and “xeno-free” iPS cells. In this study, we sought to examine whether an extracellular matrix- (ECM-) based xeno-free culture system that we recently established could be used together with a microRNA-enhanced mRNA reprogramming method for the generation of clinically safe iPS cells. The notable features of this method are the use of a xeno-free/feeder-free culture system for the generation and expansion of iPS cells rather than the conventional labor-intensive culture systems using human feeder cells or human feeder-conditioned medium and the enhancement of mRNA-mediated reprogramming via the delivery of microRNAs. Strikingly, we observed the early appearance of iPS cell colonies (~11 days), substantial reprogramming efficiency (~0.2–0.3%), and a high percentage of ESC-like colonies among the total colonies (~87.5%), indicating enhanced kinetics and reprogramming efficiency. Therefore, the combined method established in this study provides a valuable platform for the generation and expansion of clinically safe (i.e., integration- and xeno-free) iPS cells, facilitating immune-matched cell therapy in the near future.

Human induced pluripotent stem cells are capable of B-cell lymphopoiesis

Blood ◽  
2011 ◽  
Vol 117 (15) ◽  
pp. 4008-4011 ◽  
Author(s):  
Lee Carpenter ◽  
Ram Malladi ◽  
Cheng-Tao Yang ◽  
Anna French ◽  
Katherine J. Pilkington ◽  
...  
Keyword(s):  
Stem Cells ◽  
B Cell ◽  
Embryonic Stem ◽  
Ips Cells ◽  
Ips Cell ◽  
Lymphoid Lineage ◽  
Human Ips Cells ◽  
Induced Pluripotent ◽  
First Time ◽  
Unique Potential

Abstract Induced pluripotent stem (iPS) cells offer a unique potential for understanding the molecular basis of disease and development. Here we have generated several human iPS cell lines, and we describe their pluripotent phenotype and ability to differentiate into erythroid cells, monocytes, and endothelial cells. More significantly, however, when these iPS cells were differentiated under conditions that promote lympho-hematopoiesis from human embryonic stem cells, we observed the formation of pre-B cells. These cells were CD45+CD19+CD10+ and were positive for transcripts Pax5, IL7αR, λ-like, and VpreB receptor. Although they were negative for surface IgM and CD5 expression, iPS-derived CD45+CD19+ cells also exhibited multiple genomic D-JH rearrangements, which supports a pre–B-cell identity. We therefore have been able to demonstrate, for the first time, that human iPS cells are able to undergo hematopoiesis that contributes to the B-cell lymphoid lineage.

scholarly journals Characterization of Hematopoietic Differentiation Profiles of MPN Patient-Derived Inducible Pluripotent Stem Cells Harboring Homozygous Vs Heterozygous Calreticulin Mutations

Blood ◽  
2018 ◽  
Vol 132 (Supplement 1) ◽  
pp. 3065-3065
Author(s):  
Lijuan Han ◽  
Marcelo A. Szymanski Toledo ◽  
Alexandre Theocharides ◽  
Angela Maurer ◽  
Tim H. Brümmendorf ◽  
...  
Keyword(s):  
Ips Cells ◽  
Patient Specific ◽  
Hematopoietic Differentiation ◽  
In Vitro Differentiation ◽  
Wild Type ◽  
Ips Cell ◽  
Cell Clones ◽  
Calr Mutations ◽  
The Impact

Abstract Introduction: Somatic calreticulin (CALR) mutations were discovered in patients with essential thrombocythemia (ET) and primary myelofibrosis (PMF) and have been shown to be mutually exclusive with Janus kinase 2 (JAK2) and thrombopoietin receptor (MPL) mutations. Recent studies demonstrated that the binding of CALR mutant proteins to MPL induces constitutive activation of the JAK/STAT pathway, thus causing cellular transformation and abnormal megakaryopoiesis. Additionally, it has been reported that patients carrying homozygously mutated CALR ins5 exhibit myeloperoxidase (MPO) deficiency as a result of the absence of CALR chaperone function. However, the impact of CALR mutant homozygosity vs. heterozygosity in CALR del52 mutations as well as on hematopoietic differentiation has not yet been studied. Furthermore, clonal heterogeneity of hematopoietic stem/progenitor cell (HSPC) populations in a patient, together with technical limitations isolating single clones, are major challenges, when determining the impact of CALR mutant zygosity on clonal composition and diversity in MPN. To overcome these limitations, we generated patient-specific iPS cells carrying homozygous or heterozygous CALR mutations or their wild-type counterparts to study their roles in hematopoietic differentiation. Methods: iPS cells were generated by reprogramming peripheral blood-derived mononuclear cells from three patients carrying CALR del52, ins5, or del31 mutations using a CytoTune iPS 2.0 Sendai Reprogramming Kit. Individual colonies were picked and screened for CALR genotypes by PCR. Pluripotency of iPS cells was confirmed by immunofluorescences, and the clones were screened for additional mutations using panel-based next generation sequencing (NGS). Subsequently, CALR iPS cells were subjected to embryonic body formation, mesoderm commitment, and hematopoietic differentiation using our standard in vitro differentiation protocol. CD34+ HSPCs were MACS-sorted and characterized by flow cytometry, cytospins and RNA expression analysis on days 10, 15, and 20 during differentiation. Hematopoietic progenitors, erythrocytes, granulocytes, and megakaryocytes were identified by defined lineage markers. MPO expression was assessed by flow cytometry and cytochemical staining. Results: We established patient-specific iPS cells carrying CALR del52, ins5 or del31 mutation after written informed consent (Table 1). Pluripotency markers OCT4, Tra-1-60 and Tra-1-81 expression were confirmed in all iPS cell clones. In accordance with findings in peripheral blood cells, we detected MPO deficiency in homozygous iPS cell-derived CD15+ cells from CALRins5- and, in addition, also from CALRdel52-mutated patients (pMFI=0.0106 and pMFI=0.0187, resp.). Intriguingly, in vitro hematopoietic differentiation assays revealed additional abnormalities, such as decreased CD66b+ granulocytes derived from homozygous CALR del52 or ins5 iPS cells vs. heterozygous iPS cells on day 10 (pdel52=0.0303 and pins5=0.0253, resp.) and a trend towards increased KIThigh+CD45+ cells. Megakaryopoiesis, defined by CD41+CD42b+ cells, was increased in CALRins5 homozygous vs. heterozygous clones (p=0.0031). However, this bias was not observed in all clones, indicating clone-specific megakaryocytic differentiation potential. No phenotypic differences during hematopoietic differentiation were observed in iPS cell-derived progenitors carrying heterozygous CALRdel31 mutation and its isogenic unmutated CALR controls. Furthermore, our NGS data revealed patient-specific sets of co-occurring mutations in iPS cell clones, which may have contributed to the observed patient-specific phenotypes. As an example, the IDH2 R140Q mutation, reported to block cell differentiation, was found in approximately half of the CALRdel52 iPS clones, and these clones failed to differentiate into the hematopoietic lineage in vitro. Conclusions: We successfully generated patient-specific CALR mutant iPS cells. Upon in vitro differentiation, we detected MPO deficiency and aberrant granulocytic differentiation in CALR homozygous but not heterozygous or wild-type clones. Thus, it is now possible at the single stem cell level to further analyze the molecular mechanisms of CALR-mutant induced MPO deficiency and altered hematopoietic differentiation, in order to better understand disease biology in ET and PMF. Disclosures Brümmendorf: Merck: Consultancy; Novartis: Consultancy, Research Funding; Pfizer: Consultancy, Research Funding; Janssen: Consultancy; Takeda: Consultancy.

181 Establishment of Induced Pluripotent Stem Cells from Fishing Cat and Clouded Leopard Using Integration-Free Method for Wildlife Conservation

2018 ◽  
Vol 30 (1) ◽  
pp. 230 ◽  
Author(s):  
W. Sukparangsi ◽  
R. Bootsri ◽  
W. Sikeao ◽  
S. Karoon ◽  
A. Thongphakdee
Keyword(s):  
Stem Cells ◽  
Pluripotent Stem Cells ◽  
Dermal Fibroblast ◽  
Ips Cells ◽  
Ips Cell ◽  
Clouded Leopard ◽  
Thermo Fisher Scientific ◽  
Reprogramming Factors ◽  
Induced Pluripotent ◽  
Fisher Scientific

Fishing cat (Prionailurus viverrinus) and clouded leopard (Neofelis nebulosa) are wild felids, currently in vulnerable status according to the International Union for Conservation of Nature red list (2017). Several measures in assisted reproductive technology (e.g. AI, embryo transfer) have been used by the Zoological Park Organization of Thailand (ZPO) to increase their offspring in captivity. Recently, the generation of induced pluripotent stem cell (iPS cells) becomes popular and provides alternative way to preserve good genetics in the form of cell with diverse capacities. This great potential of iPS cells is unlimited self-renewal and pluripotency, similar to embryonic stem cells (ESC). Under the right cell culture conditions, pluripotent stem cells can differentiate into all cell types of the body. Here, we aimed to find the optimal condition to generate integration-free iPS cells from fishing cat and clouded leopard. At first, to obtain somatic cells for cellular reprogramming, adult dermal fibroblast cell lines from both species were established from belly skin tissues. Subsequently, several nucleofection programs of AmaxaTM 4D-nucleofectorTM (Lonza, Basel, Switzerland) were examined to introduce integration-free DNA vectors carrying reprogramming factors into the felid fibroblasts. The transfected cells were cultured under numerous conditions: (1) matrix/defined surface including irradiated mouse embryonic fibroblast, gelatin, vitronectin, and Geltrex® (Thermo Fisher Scientific, Waltham, MA, USA); (2) ESC/iPS cell medium including Essential 8TM (Thermo Fisher Scientific) DMEM containing KnockOutTM Serum Replacement (KOSR; Thermo Fisher Scientific) and/or fetal bovine serum (FBS); and (3) supplement including basic fibroblast growth factor (bFGF), leukemia inhibitory factor (LIF), l-ascorbic acid, nicotinamide, ALK5 inhibitor (A83-01) and RevitaCellTM (Thermo Fisher Scientific). We found that optimal nucleofection programs for human dermal fibroblast including FF-135 and EN-150 were able to transfer episomal vectors and excisable piggyBAC transposon carrying reprogramming factors into fishing cat and clouded leopard fibroblasts, respectively. The iPS-like colonies appeared around 26 to 30 days post-nucleofection. The culture of transfected cells on either Geltrex® or Vitronectin-coated surface supports the formation of iPS-like colonies with different derivation efficiency (0.01 and 0.005%, respectively). In addition, all colonies were formed under medium containing FBS, together with both bFGF and LIF supplements. Taken together, we have developed a platform to generate iPS cells from tissue collection to the establishment of iPS cell culture. This will further enable us to apply the technique to obtain iPS cells from other endangered and vulnerable felid species.

scholarly journals Cell Reprogramming, IPS Limitations, and Overcoming Strategies in Dental Bioengineering

2012 ◽  
Vol 2012 ◽  
pp. 1-8 ◽  
Author(s):  
Gaskon Ibarretxe ◽  
Antonia Alvarez ◽  
Maria-Luz Cañavate ◽  
Enrique Hilario ◽  
Maitane Aurrekoetxea ◽  
...  
Keyword(s):  
Pluripotent Stem Cells ◽  
Ips Cells ◽  
Cell Reprogramming ◽  
Animal Cells ◽  
Ips Cell ◽  
Current State ◽  
Organ Systems ◽  
Induced Pluripotent ◽  
Long Term Behavior

The procurement of induced pluripotent stem cells, or IPS cells, from adult differentiated animal cells has the potential to revolutionize future medicine, where reprogrammed IPS cells may be used to repair disease-affected tissues on demand. The potential of IPS cell technology is tremendous, but it will be essential to improve the methodologies for IPS cell generation and to precisely evaluate each clone and subclone of IPS cells for their safety and efficacy. Additionally, the current state of knowledge on IPS cells advises that research on their regenerative properties is carried out in appropriate tissue and organ systems that permit a safe assessment of the long-term behavior of these reprogrammed cells. In the present paper, we discuss the mechanisms of cell reprogramming, current technical limitations of IPS cells for their use in human tissue engineering, and possibilities to overcome them in the particular case of dental regeneration.

Reprogramming of Leukemic and Pre-Leukemic Cells from Primary Human De Novo Acute Myeloid Leukemia Samples into Induced Pluripotent Stem (iPS) Cells

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 1862-1862
Author(s):  
David Spencer ◽  
Daniel R. George ◽  
Jeffery M. Klco ◽  
Timothy J. Ley
Keyword(s):  
Bone Marrow ◽  
Cell Lines ◽  
Myeloid Leukemia ◽  
De Novo ◽  
Ips Cells ◽  
Ips Cell ◽  
A Cell ◽  
Primary Bone ◽  
Induced Pluripotent ◽  
Primary Bone Marrow

Abstract Somatic reprogramming captures the mutations present in individual cells and can yield induced pluripotent stem (iPS) cells that can be used to study these mutations in their native genetic context. iPS cells have been made using a variety of primary tissues and established cell lines, but to date there have been few examples of somatic reprogramming using primary cancer samples. Some studies have reported iPS cell generation using samples from patients with myeloproliferative neoplasms (Ye Z Blood 2009, Hosoi M Exp. Hematol. 2014), and another study successfully reprogrammed primary bone marrow cells from patients with myelodysplastic syndromes (MDS) (Kotini AG Nat. Biotech. 2015). However, it is not yet clear whether fully transformed human myeloid leukemia cells can be reprogrammed to an undifferentiated state. Here we describe the results of reprogramming experiments and subsequent genetic characterization of iPS clones produced from primary bone marrow and peripheral blood samples from adult human de novo AML patients. Our reprogramming approach involved in vitro culture of primary cells on Hs27 stroma with hematopoietic cytokines for 3-7 days, followed by transfer of 250,000 cells to stroma-free conditions for transduction with nonintegrating Sendai viruses expressing cMyc, OCT3/4, KLF4, and SOX2. Cells were then returned to AML culture conditions with stroma for 2-4 days before plating on mouse embryonic fibroblasts (MEF) in human embryonic stem (ES) cell media for 2-6 weeks. Individual clusters of cells with undifferentiated iPS cell colony morphology were then picked and expanded on either MEFs or feeder-free conditions. We performed 21 transductions using 8 peripheral blood and 13 bone marrow samples from 16 AML patients (i.e., multiple samples were attempted for some AMLs), which yielded 65 iPS clones from 9 of the 16 AML patients (56%) that were successfully expanded for genomic analysis. The remaining AMLs either produced no colonies (N=5), or clones that failed to expand after transferring from the original plate (N=2). Initial analysis of representative iPS clones (N=4) via flow cytometry demonstrated expression of the pluripotency markers SSEA-4 and TRA-1-60. Additional experiments to assess the pluripotency of these iPS lines are currently underway, including analysis of all clones via flow cytometry, RNA-sequencing, and teratoma formation assays. To determine the relationship between each iPS clone and the original AML samples used for reprogramming, we performed targeted sequencing for all somatic mutations identified from either whole-genome or exome sequencing. Analysis of each iPS clone for multiple patient-specific AML mutations (range 12-683) demonstrated that the reprogrammed cells were derived from 1 of 3 distinct cell types, depending on the sample. The most common type (N=1, 1, 3, 10, and 12 clones from 5 AMLs) possessed virtually no AML mutations (Figure 1A), suggesting that reprogramming occurred in a cell population that was unrelated to the tumor. Another 24 clones from 2 AML samples (N=1 and N=23) contained a subset of the AML-associated mutations (Figure 1B), but lacked common AML mutations that are generally cooperating 'hits', such as NPM1, and FLT3; for these samples, reprogramming probably occurred in a cell that was ancestral to the AML founding clone (i.e., a pre-leukemic cell). The final group of 14 clones from 2 AMLs (N=7 for both samples) contained the majority of AML-associated mutations in those samples, including canonical mutations in IDH1 and IDH2, and mutations in DNMT3A and RUNX1 (Figure 1C), implying that reprogramming occurred in the most prevalent AML subclone in the sample. Remarkably, for AML samples that yielded >1 iPS clone (N=6), all the iPS clones had the same set of mutations, suggesting that some of the cells in the sample were more "fit" for reprogramming than others. In conclusion, we have generated iPS cell lines from 9 primary AML samples, several of which contain canonical AML mutations. In this study, the majority of the reprogramming events took place in rare cells from clones that were not the most abundant cells in the sample. However, in one case, all iPS clones were derived from the most prevalent AML subclone in the sample. Future study of these iPS cell lines will provide insights into epigenetic dysregulation in cancer, and of the functional consequences of the mutational combinations that were "captured" via reprogramming. Disclosures No relevant conflicts of interest to declare.

Induced human pluripotent stem cells: promises and open questions

2009 ◽  
Vol 390 (9) ◽  
Author(s):  
Alexandra Rolletschek ◽  
Anna M. Wobus
Keyword(s):  
Pluripotent Stem Cells ◽  
Viral Vectors ◽  
Insertional Mutagenesis ◽  
Ips Cells ◽  
Patient Specific ◽  
Ips Cell ◽  
Open Questions ◽  
Induced Pluripotent ◽  
Selective Differentiation

Abstract Adult cells have been reprogrammed into induced pluripotent stem (iPS) cells by introducing pluripotency-associated transcription factors. Here, we discuss recent advances and challenges of in vitro reprogramming and future prospects of iPS cells for their use in diagnosis and cell therapy. The generation of patient-specific iPS cells for clinical application requires alternative strategies, because genome-integrating viral vectors may cause insertional mutagenesis. Moreover, when suitable iPS cell lines will be available, efficient and selective differentiation protocols are needed to generate transplantable grafts. Finally, we point to the requirement of a regulatory framework necessary for the commercial use of iPS cells.

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