Zsuzsa Erdei

Applying a “Double-Feature” Promoter to Identify Cardiomyocytes Differentiated from Human Embryonic Stem Cells Following Transposon-Based Gene Delivery†‡

Human embryonic stem (HuES) cells represent a new potential tool for cell‐therapy and gene‐therapy applications. However, these approaches require the development of efficient, stable gene delivery, and proper progenitor cell and tissue separation methods. In HuES cell lines, we have generated stable, enhanced green fluorescent protein (EGFP)‐expressing clones using a transposon‐based (Sleeping Beauty) system. This method yielded high percentage of transgene integration and expression. Similarly to a lentiviral expression system, both the undifferentiated state and the differentiation pattern of the HuES cells were preserved. By using the CAG promoter, in contrast to several other constitutive promoter sequences (such as CMV, elongation factor 1α, or phosphoglycerate kinase), an exceptionally high EGFP expression was observed in differentiated cardiomyocytes. This phenomenon was independent of the transgene sequence, methods of gene delivery, copy number, and the integration sites. This “double‐feature” promoter behavior, that is providing a selectable marker for transgene expressing undifferentiated stem cells, and also specifically labeling differentiated cardiomyocytes, was assessed by transcriptional profiling. We found a positive correlation between CAG promoter‐driven EGFP transcription and expression of cardiomyocyte‐specific genes. Our experiments indicate an efficient applicability of transposon‐based gene delivery into HuES cells and provide a novel approach to identify differentiated tissues by exploiting a nontypical behavior of a constitutively active promoter, thereby avoiding invasive drug selection methods. Stem Cells 2009;27:1077–1087

Reliable transgene-independent method for determining Sleeping Beauty transposon copy numbers.

BackgroundThe transposon-based gene delivery technique is emerging as a method of choice for gene therapy. The Sleeping Beauty (SB) system has become one of the most favored methods, because of its efficiency and its random integration profile. Copy-number determination of the delivered transgene is a crucial task, but a universal method for measuring this is lacking. In this paper, we show that a real-time quantitative PCR-based, transgene-independent (qPCR-TI) method is able to determine SB transposon copy numbers regardless of the genetic cargo.ResultsWe designed a specific PCR assay to amplify the left inverted repeat-direct repeat region of SB, and used it together with the single-copy control gene RPPH1 and a reference genomic DNA of known copy number. The qPCR-TI method allowed rapid and accurate determination of SB transposon copy numbers in various cell types, including human embryonic stem cells. We also found that this sensitive, rapid, highly reproducible and non-radioactive method is just as accurate and reliable as the widely used blotting techniques or the transposon display method. Because the assay is specific for the inverted repeat region of the transposon, it could be used in any system where the SB transposon is the genetic vehicle.ConclusionsWe have developed a transgene-independent method to determine copy numbers of transgenes delivered by the SB transposon system. The technique is based on a quantitative real-time PCR detection method, offering a sensitive, non-radioactive, rapid and accurate approach, which has a potential to be used for gene therapy.

Calcium signaling in pluripotent stem cells

Pluripotent stem cells represent a new source of biological material allowing the exploration of signaling phenomena during normal cell development and differentiation. Still, the calcium signaling pathways and intracellular calcium responses to various ligands or stress conditions have not been sufficiently explored as yet in embryonic or induced pluripotent stem cells and in their differentiated offspring. This is partly due to the special culturing conditions of these cell types, the rapid morphological and functional changes in heterogeneous cell populations during early differentiation, and methodological problems in cellular calcium measurements. In this paper, we review the currently available data in the literature on calcium signaling in pluripotent stem cells and discuss the potential shortcomings of these studies. Various assay methods are surveyed for obtaining reliable data both in undifferentiated embryonic stem cells and in specific, stem cell-derived human tissues. In this paper, we present the modulation of calcium signaling in human embryonic stem cells (hESC) and in their derivates; mesenchymal stem cell like (MSCl) cells and cardiac tissues using the fluorescent calcium indicator Fluo-4 and confocal microscopy. LPA, trypsin and angiotensin II were effective in inducing calcium signals both in HUES9 and MSCl cells. Histamine and thrombin induced calcium signal exclusively in the MSCl cells, while ATP was effective only in HUES9 cells. There was no calcium signal evoked by GABA, even at relatively high concentrations. In stem cell-derived cardiomyocytes a rapid increase in the beating rate and an increase of the calcium signal peaks could be observed after the addition of adrenaline, while verapamil led to a strong decrease in cellular calcium and stopped spontaneous contractions in a relaxed state.

Evaluation of ABCG2 expression in human embryonic stem cells: Crossing the same river twice?

A recent publication in Stem Cells states that human embryonicstem (ES) cells do not express ABCG2 and ‘‘…absence ofABCG2 isa novelfeatureof humanpluripotentstem cells,whichdistinguishes them from many other stem cells including mouseES cells’’ [1]. This is in sharp contrast to our observations [2]and the report of several other investigators who detectedABCG2 mRNA in various human ES cells [3–6]. The presenceof multidrug resistance ABC (MDR-ABC) transporters may sig-nificantly contribute to stem cell defense mechanisms; thus, thisis an important question that should be addressed properly.Our interest in ABC transporters dates back to the discov-ery of their role in cancer drug resistance over two decadesago. Since then, we have had ample opportunity to experiencehow insufficient methodology and a simplifying approachmay obscure the assessment of the impact of MDR-ABCtransporters on cancer patient survival. Measuring the func-tional expression of ABC transporters proved challengingbecause of the heterogeneity of tumors, the varying levels ofexpression, and the unreliability of the assay systems usedthroughout the trials. As a result, most reports were consid-ered controversial, and the true contribution of MDR-ABCtransporters to therapy failure could only be established onceassay conditions were standardized [7]. The key teaching ofthese extensive studies have immediate relevance to exploringtransporter expression in stem cells. First, MDR-ABC trans-porters are active extrusion pumps that may significantly mod-ify cellular homeostasis or endobiotic and xenobiotic resist-ance even at low levels. Therefore, the assays measuring theirimpact should be sensitive, quantitative, and should preferablytarget the function of the MDR-ABC transporters. Second,samples are often heterogeneous for MDR-ABC expression,as these proteins are rapidly regulated by numerous mecha-nisms, both at the transcriptional and processing levels. How-ever, this initial heterogeneity may be relevant in circumstan-ces of stress, survival, or proliferation. Third, in many cases,the cell type, the mechanism of cell transformation, or differ-entiation does not determine the expression or function ofMDR-ABC transporters. Rather, ABC transporters are modu-lated by numerous environmental conditions [7, 8].In the case of the paper by Zeng et al. [1], the appre-ciation of these features is not possible as there are manyexperimental flaws that are reminiscent of the limitationsthat our field had to overcome to evaluate the MDR ofcancer. First, the reverse transcription polymerase chainreaction (RT-PCR) results are not quantitated, and there isno effort to perform quantitative PCR studies for thedetection of the relevant messages. Second, the Hoechstdye efflux studies lack the essential negative control. Third,instead of using a highly specific ABCG2 inhibitor, theauthors make their case on the basis of the effect of vera-pamil, which is a weak and nonspecific inhibitor ofABCG2. Fourth, the immunostaining studies are not con-vincing, the antibody used requires cell permeabilization,and the membrane localization of ABCG2 is not examined.Fifth, detection of subpopulations is contradictory and isnot evaluated in the context of co-expression of stem cellmarkers. Therefore, this study does not allow conclusionsto be drawn regarding the presence or up- and downregu-lation of ABCG2 in human ES cells.In contrast, we emphasize again that with appropriateexperimental tools, the functional although heterogeneousexpression of membrane ABCG2 is detectable in undifferenti-ated human stem cells. Detailed documentation is not possi-ble here, but the key features of ABCG2 expression in fourdifferent ES cell lines are depicted in Figure 1 and in thesupporting information video. Here we used properly quanti-tated real-time PCR measurements, flow cytometry, and con-focal microscopy with costaining of relevant surface markers.Furthermore, we compare ES cells grown on MEF or Matri-gel, and we also evaluate the expression pattern of a mesen-chymal-like cell line (Figure 1C (F2)). We also document amicroscopic measurement of Hoechst dye uptake in undiffer-entiated stem cells, which is modulated by a specific ABCG2inhibitor. All these measurements suggest that ABCG2 ispresent at relatively high levels in the undifferentiatedhuman ES cells, highlighting its role in the protection of thisvaluable sanctuary against the damage by toxins, drugs, orhypoxia [8, 9].

Characterization of calcium signals in human embryonic stem cells and in their differentiated offspring by a stably integrated calcium indicator protein

Intracellular calcium signaling pathways play a major role in cellular responses such as proliferation, differentiation and apoptosis. Human embryonic stem cells (hESC) provide new possibilities to explore the development and differentiation of various cell types of the human body. Intracellular calcium responses to various ligands and the calcium signaling pathways, however, have not been thoroughly studied in embryonic stem cells and in their differentiated progenies. In our previous work we demonstrated that the use of the fluorescent calcium indicator Fluo-4 with confocal microscopy allows sensitive and reliable measurements of calcium modulation in human embryonic stem cells and stem-cell derived cardiomyocytes. Here we developed a human embryonic stem cell line stably expressing a genetically encoded Ca(2+) indicator (GCaMP2) using a transposon-based gene delivery system. We found that the differentiation properties were fully preserved in the GCaMP2-expressing hESC lines and Ca imaging could be performed without the need of toxic dye-loading of the cells. In undifferentiated hES cells the calcium signals induced by various ligands, ATP, LPA, trypsin or angiotensin II were comparable to those in Fluo-4 loaded cells. In accordance with previous findings, no calcium signal was evoked by thrombin, histamine or GABA. Cardiomyocyte colonies differentiated from hES-GCaMP2 cells could be recognized by spontaneous contractions and Ca(2+) oscillations. GCaMP2-expressing neural cells were identified based on their morphological and immuno-staining properties and Ca signals were characterized on those cells. Characteristics of both the spontaneous and ligand-induced Ca(2+) signals, as well as their pharmacological modification could be successfully examined in these model cells by fluorescence imaging.

Expression pattern of the human ABC transporters in pluripotent embryonic stem cells and in their derivatives

ATP‐binding cassette (ABC) transporters have key roles in various physiological functions as well as providing chemical defense and stress tolerance in human tissues. In this study, we have examined the expression pattern of all ABC proteins in pluripotent human embryonic stem cells (hESCs) and in their differentiated progenies. We paid special attention to the cellular expression and localization of multidrug transporter ABC proteins.

Human pluripotent stem cells in pharmacological and toxicological screening: new perspectives for personalized medicine

Human stem cells provide an important novel tool for generating in vitro pharmacological and toxicological test systems. In the development of new targeted therapies, as well as in critical safety issues, including hepato-, neuro- and cardio-toxicity, animal-based tests are mostly unsatisfactory, whereas the use of in vitro model systems is limited by the unavailability of relevant human tissues. Human embryonic stem cell lines may fill this gap and offer an advantage over primary cultures as well as tissue-derived (adult) stem cells. Human embryonic stem cells represent an unlimited source for the production of differentiated somatic progenies and allow various stable genetic manipulations. As a new opening in personalized medicine test systems, the generation of induced pluripotent stem cell lines and their derivatives can provide patient- and disease-specific cellular assays for drug development and safety assessments. This article reviews promising human stem cell applications in pharmacological and toxicological screenings, focusing on the implications for personalized medicine.

The importance of drug transporters in human pluripotent stem cells and in early tissue differentiation

Introduction: Drug transporters are large transmembrane proteins which catalyse the movement of a wide variety of chemicals, including drugs as well as xeno- and endobiotics through cellular membranes. The major groups of these proteins include the ATP-binding cassette transporters which in eukaryotes work as ATP-fuelled drug ‘exporters’ and the Solute Carrier transporters, with various transport directions and mechanisms. Areas covered: In this review, we discuss the key ATP-binding cassette and Solute Carrier drug transporters which have been reported to contribute to the function and/or protection of undifferentiated human stem cells and during tissue differentiation. We review the various techniques for studying transporter expression and function in stem cells, and the role of drug transporters in foetal and placental tissues is also discussed. We especially focus on the regulation of transporter expression by factors modulating cell differentiation properties and on the function of the transporters in adjustment to environmental challenges. Expert opinion: The relatively new and as yet unexplored territory of transporters in stem cell biology may rapidly expand and bring important new information regarding the metabolic and epigenetic regulation of ‘stemness’ and the early differentiation properties. Drug transporters are clearly important protective and regulatory components in stem cells and differentiation.

Generation of multidrug resistant human tissues by overexpression of the ABCG2 multidrug transporter in embryonic stem cells

The ABCG2 multidrug transporter provides resistance against various endo- and xenobiotics, and protects the stem cells against toxins and stress conditions. We have shown earlier that a GFP-tagged version of ABCG2 is fully functional and may be used to follow the expression, localization and function of this transporter in living cells. In the present work we have overexpressed GFP-ABCG2, driven by a constitutive (CAG) promoter, in HUES9 human embryonic stem cells. Stem cell clones were generated to express the wild-type and a substrate-mutant (R482G) GFP-ABCG2 variant, by using the Sleeping Beauty transposon system. We found that the stable overexpression of these transgenes did not change the pluripotency and growth properties of the stem cells, nor their differentiation capacity to hepatocytes or cardiomyocytes. ABCG2 overexpression provided increased toxin resistance in the stem cells, and protected the derived cardiomyocytes against doxorubicin toxicity. These studies document the potential of a stable ABCG2 expression for engineering toxin-resistant human pluripotent stem cells and selected stem cell derived tissues.

Correction: Reliable transgene-independent method for determining sleeping beauty transposon copy numbers

Authors’ contributions OK established the HEK clones, OK and VK optimized the real-time PCR and performed copy number measurements, AS, ZE and AA established the HUES9 clones, GV helped in FACS measurements, LM measured copy numbers in HeLa clones, ZsI and ZI gave technical help and advices with the SB transposon work, BS provided financial support and discussed the data and TIO designed the overall strategy, analyzed the data and wrote the paper. All authors read and approved the final manuscript.