Development of the Sixth ISSCR Annual Meeting Program

The ISSCR annual meeting series is a cornerstone of the society. Developed by the Annual Meeting Program Committee, each meeting covers a broad spectrum of high-end stem cell research, drawing on the local environment and taking on its own individual feel and emphasis

Single cell analyses of ES cells reveal alternative pluripotent cell states and molecular mechanisms that control self-renewal

Analyses of gene expression in single mouse embryonic stem cells (mESCs) cultured in serum and LIF revealed the presence of two distinct cell subpopulations with individual gene expression signatures. Comparisons with published data revealed that cells in the first subpopulation are phenotypically similar to cells isolated from the inner cell mass (ICM). In contrast, cells in the second subpopulation appear to be more mature. Pluripotency Gene Regulatory Network (PGRN) reconstruction based on single-cell data and published data suggested antagonistic roles for Oct4 and Nanog in the maintenance of pluripotency states. Integrated analyses of published genomic binding (ChIP) data strongly supported this observation. Certain target genes alternatively regulated by OCT4 and NANOG, such as Sall4 and Zscan10, feed back into the top hierarchical regulator Oct4. Analyses of such incoherent feedforward loops with feedback (iFFL-FB) suggest a dynamic model for the maintenance of mESC pluripotency and self-renewal

Proteome biology of stem cells

AbstractThe notion that integration of cutting-edge technologies in stem cell research would be enhanced by proteomic analyses has emanated from rapid advances in proteome technology. These advances have increased the probability that basic properties of stem cells will be elucidated more effectively, leading to acceleration toward novel stem cell therapies. We have therefore sought to establish a world-wide alliance of proteomics and stem cell researchers, which has resulted in the foundation of an initiative supported by the Human Proteome Organisation (HUPO) and the International Society for Stem Cell Research (ISSCR) called the Proteome Biology of Stem Cells Initiative. Here we report on the rationale and goals of this initiative

Molecular Study of Interactions between Hematopoietic Stem Cells and Stromal Cells

Multipotent hematopoietic stem cells (HSCs) are progenitors of all types of hematopoietic cells, and the efficient isolation and propagation of HSCs will significantly enhance our ability to manage many human disorders with bone marrow transplantation, stem cell transplantation and gene therapy. We employed "Signal Sequence Trap (SST)" method with yeast invertase to clone proteins on the surface of or secreted by stromal cells that enhance or inhibit the propagation of HSC’s in culture. AFT024, a mouse fetal liver stromal cell line that maintains stem cell activity in long-term culture, was subjected to SST analysis. We identified more than 60 signal sequences or transmembrane domain containing genes expressed by AFT024 cells. We compared their expression levels between AFT024 cells and BFC012 cells, a mouse fetal liver stromal cell line that was developed in the same way as for AFT024 cells but could not support HSC in long-term culture. Pleiotrophin, T16, Sca-1, deltalike and cytokine receptor like-1(CLF-1) are expressed significantly higher in AFT024 cells than in BFC012 cells. We recently employed Affymatrix genechip technology to study the interaction of HSCs and their microenvironment. In genechip experiments, Sca-1, deltalike, pleiotrophin and CLF-1 are among the most differentially expressed genes between AFT024 and BFC012 cells, while T16 was not represented on the chip. In addition, osteopontin, pigment epithelium-derived factor, proliferins, activin subunit, CXC chemokines GRO1 and LIX are more abundant in AFT024 cells than in BFC012 cells. Genechip technology was also applied to bone marrow stromal cell lines, including MS5, S17 and OP9 cells. Two murine multipotent hematopoietic cell lines, FDCP.mix and EML cells, were also analyzed. Data from these experiments are presented.Singapore-MIT Alliance (SMA

A differential network analysis approach for lineage specifier prediction in stem cell subpopulations

10.1038/npjsba.2015.12npj Systems Biology and Applications11501

Some hematopoietic stem cells are more equal than others

Hematopoietic stem cells (HSCs) save lives in routine clinical practice every day, as they are the key element in transplantation-based therapies for hematologic malignancies. The success of clinical stem cell transplantation critically relies on the ability of stem cells to reconstitute the hematopoietic system for many decades after the administration of the powerful chemotherapy and/or irradiation that is required to eradicate malignant cells, but also irreversibly ablates patients’ own blood forming capacity. Surprisingly, despite enormous efforts and continuous progress in the field, our understanding of the basic biology of HSCs is still rather incomplete. Several recent studies substantially refine our understanding of the cells at the very top of the hematopoietic hierarchy, and suggest that we may need to revise the criteria we typically use to identify and define HSCs

Mapping Dynamic Histone Acetylation Patterns to Gene Expression in Nanog-depleted Murine Embryonic Stem Cells

Embryonic stem cells (ESC) have the potential to self-renew indefinitely and to differentiate into any of the three germ layers. The molecular mechanisms for self-renewal, maintenance of pluripotency and lineage specification are poorly understood, but recent results point to a key role for epigenetic mechanisms. In this study, we focus on quantifying the impact of histone 3 acetylation (H3K9,14ac) on gene expression in murine embryonic stem cells. We analyze genome-wide histone acetylation patterns and gene expression profiles measured over the first five days of cell differentiation triggered by silencing Nanog, a key transcription factor in ESC regulation. We explore the temporal and spatial dynamics of histone acetylation data and its correlation with gene expression using supervised and unsupervised statistical models. On a genome-wide scale, changes in acetylation are significantly correlated to changes in mRNA expression and, surprisingly, this coherence increases over time. We quantify the predictive power of histone acetylation for gene expression changes in a balanced cross-validation procedure. In an in-depth study we focus on genes central to the regulatory network of Mouse ESC, including those identified in a recent genome-wide RNAi screen and in the PluriNet, a computationally derived stem cell signature. We find that compared to the rest of the genome, ESC-specific genes show significantly more acetylation signal and a much stronger decrease in acetylation over time, which is often not reflected in an concordant expression change. These results shed light on the complexity of the relationship between histone acetylation and gene expression and are a step forward to dissect the multilayer regulatory mechanisms that determine stem cell fate.Comment: accepted at PLoS Computational Biolog

An Esrrb and nanog cell fate regulatory module controlled by feed forward loop interactions

Cell fate decisions during development are governed by multi-factorial regulatory mechanisms including chromatin remodeling, DNA methylation, binding of transcription factors to specific loci, RNA transcription and protein synthesis. However, the mechanisms by which such regulatory 'dimensions' coordinate cell fate decisions are currently poorly understood. Here we quantified the multi-dimensional molecular changes that occur in mouse embryonic stem cells (mESCs) upon depletion of Estrogen related receptor beta (Esrrb), a key pluripotency regulator. Comparative analyses of expression changes subsequent to depletion of Esrrb or Nanog, indicated that a system of interlocked feed-forward loops involving both factors, plays a central part in regulating the timing of mESC fate decisions. Taken together, our meta-analyses support a hierarchical model in which pluripotency is maintained by an Oct4-Sox2 regulatory module, while the timing of differentiation is regulated by a Nanog-Esrrb module

Design and validation of an open-source modular Microplate Photoirradiation System for high-throughput photobiology experiments

Research in photobiology is currently limited by a lack of devices capable of delivering precise and tunable irradiation to cells in a high-throughput format. This limits researchers to using expensive commercially available or custom-built light sources which make it difficult to replicate, standardize, optimize, and scale experiments. Here we present an open-source Microplate Photoirradiation System (MPS) developed to enable high-throughput light experiments in standard 96 and 24-well microplates for a variety of applications in photobiology research. This open-source system features 96 independently controlled LEDs (4 LEDs per well in 24-well), Wi-Fi connected control and programmable graphical user interface (GUI) for control and programming, automated calibration GUI, and modular control and LED boards for maximum flexibility. A web-based GUI generates light program files containing irradiation parameters for groups of LEDs. These parameters are then uploaded wirelessly, stored and used on the MPS to run photoirradiation experiments inside any incubator. A rapid and semi-quantitative porphyrin metabolism assay was also developed to validate the system in wild-type fibroblasts. Protoporphyrin IX (PpIX) fluorescence accumulation was induced by incubation with 5-aminolevulinic acid (ALA), a photosensitization method leveraged clinically to destroy malignant cell types in a process termed photodynamic therapy (PDT), and cells were irradiated with 405nm light with varying irradiance, duration and pulsation parameters. Immediately after light treatment with the MPS, subsequent photobleaching was measured in live, adherent cells in both 96-well and a 24-well microplates using a microplate reader. Results demonstrate the utility and reliability of the Microplate Photoirradiation System to irradiate cells with precise irradiance and timing parameters in order to measure PpIx photobleaching kinetics in live adherent cells and perform comparable experiments with both 24 and 96 well microplate formats. The high-throughput capability of the MPS enabled measurement of enough irradiance conditions in a single microplate to fit PpIX fluorescence to a bioexponential decay model of photobleaching, as well as reveal a dependency of photobleaching on duty-cycle-but not frequency-in a pulsed irradiance regimen.We thank the Graduate School of Biological Sciences and the Black Family Stem Cell Institute at Icahn School of Medicine for providing financial support for the project. Chris Merck is affiliated with his own LLC (Merck Engineering LLC). Merck Engineering LLC did not contribute funding to the development of the MPS or its biological validation and has no pecuniary interest in this study. Chris Merck worked as a volunteer collaborator not representing any company or institution. Merck Engineering LLC did not have any additional role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript. The specific role of this author is articulated in the 'author contributions' section