Henrik Sperber

Derivation of naïve human embryonic stem cells

Significance We report on generation of nontransgenic, naïve human pluripotent cells that represent the developmentally earliest state described for human established cells. Existing human ES cell lines in the later primed state can be toggled in reverse to naïve by exposure to histone deacetylase inhibitors prior to naïve culture. A new line was established directly from an eight-cell embryo under naïve culture conditions. We describe the naïve state in humans and show that naïve human ES cells have expanded endoderm developmental capacity. The naïve pluripotent state has been shown in mice to lead to broad and more robust developmental potential relative to primed mouse epiblast cells. The human naïve ES cell state has eluded derivation without the use of transgenes, and forced expression of OCT4, KLF4, and KLF2 allows maintenance of human cells in a naïve state [Hanna J, et al. (2010) Proc Natl Acad Sci USA 107(20):9222–9227]. We describe two routes to generate nontransgenic naïve human ES cells (hESCs). The first is by reverse toggling of preexisting primed hESC lines by preculture in the histone deacetylase inhibitors butyrate and suberoylanilide hydroxamic acid, followed by culture in MEK/ERK and GSK3 inhibitors (2i) with FGF2. The second route is by direct derivation from a human embryo in 2i with FGF2. We show that human naïve cells meet mouse criteria for the naïve state by growth characteristics, antibody labeling profile, gene expression, X-inactivation profile, mitochondrial morphology, microRNA profile and development in the context of teratomas. hESCs can exist in a naïve state without the need for transgenes. Direct derivation is an elusive, but attainable, process, leading to cells at the earliest stage of in vitro pluripotency described for humans. Reverse toggling of primed cells to naïve is efficient and reproducible.

Hypoxia Inducible Factors have distinct and stage-specific roles during reprogramming of human cells to pluripotency

Pluripotent stem cells have distinct metabolic requirements, and reprogramming cells to pluripotency requires a shift from oxidative to glycolytic metabolism. Here, we show that this shift occurs early during reprogramming of human cells and requires hypoxia-inducible factors (HIFs) in a stage-specific manner. HIF1α and HIF2α are both necessary to initiate this metabolic switch and for the acquisition of pluripotency, and the stabilization of either protein during early phases of reprogramming is sufficient to induce the switch to glycolytic metabolism. In contrast, stabilization of HIF2α during later stages represses reprogramming, partly because of the upregulation of TNF-related apoptosis-inducing ligand (TRAIL). TRAIL inhibits induced pluripotent stem cell (iPSC) generation by repressing apoptotic caspase 3 activity specifically in cells undergoing reprogramming but not human embryonic stem cells (hESCs), and inhibiting TRAIL activity enhances human iPSC generation. These results shed light on the mechanisms underlying the metabolic shifts associated with the acquisition of a pluripotent identity during reprogramming.

Let-7 family of microRNA is required for maturation and adult-like metabolism in stem cell-derived cardiomyocytes.

Significance The adult human heart is incapable of significant regeneration after injury. Human embryonic stem cells (hESCs) have the capacity to generate an unlimited number of cardiomyocytes (CMs). However, hESC-derived CMs (hESC-CMs) are at a fetal state with respect to their functional and physiological characteristics, diminishing their utility for modeling adult-related heart disease and therapeutic screening. Thus, the potential for hESC-CMs may improve immensely in cardiac-related therapeutic applications if factors that drive their maturation are uncovered. In this study, we show that members of let-7 miRNA family control CM metabolism, cell size, and force contractility, making them one of the best factors identified to date in promoting maturity of stem cell derivatives. In metazoans, transition from fetal to adult heart is accompanied by a switch in energy metabolism-glycolysis to fatty acid oxidation. The molecular factors regulating this metabolic switch remain largely unexplored. We first demonstrate that the molecular signatures in 1-year (y) matured human embryonic stem cell-derived cardiomyocytes (hESC-CMs) are similar to those seen in in vivo-derived mature cardiac tissues, thus making them an excellent model to study human cardiac maturation. We further show that let-7 is the most highly up-regulated microRNA (miRNA) family during in vitro human cardiac maturation. Gain- and loss-of-function analyses of let-7g in hESC-CMs demonstrate it is both required and sufficient for maturation, but not for early differentiation of CMs. Overexpression of let-7 family members in hESC-CMs enhances cell size, sarcomere length, force of contraction, and respiratory capacity. Interestingly, large-scale expression data, target analysis, and metabolic flux assays suggest this let-7–driven CM maturation could be a result of down-regulation of the phosphoinositide 3 kinase (PI3K)/AKT protein kinase/insulin pathway and an up-regulation of fatty acid metabolism. These results indicate let-7 is an important mediator in augmenting metabolic energetics in maturing CMs. Promoting maturation of hESC-CMs with let-7 overexpression will be highly significant for basic and applied research.

MicroRNA Regulation and Role in Stem Cell Maintenance, Cardiac Differentiation and Hypertrophy

There are currently 1527 known microRNAs (miRNAs) in human, each of which may regulate hundreds or thousands of target genes. miRNA expression levels vary between cell types; for example, miR- 302 and miR-290 families are highly enriched in embryonic stem cells, while miR-1 is a muscle specific miRNA. miRNA biosynthesis and function are highly regulated and this regulation may be cell type specific. The processing enzymes and factors that recognize features in sequence and secondary structure of the miRNA play key roles in regulating the production of mature miRNA. Mature miRNA enriched in stem cells control stem cell self-renewal as well as their differentiation. Though specific miRNAs have been shown to control differentiation towards various lineages such as neural or skin cells, some of the most well characterized miRNAs have been found in promoting the formation of cardiac cells. In addition, miRNAs also play a critical role in cardiomyocyte hypertrophy, especially in a pathological context. Such miRNAs are predicted to be therapeutic targets for treating cardiovascular diseases. In this review we will discuss how miRNAs act to maintain the stem cell state and also explore the current knowledge of the mechanisms that regulate miRNAs. Furthermore, we will discuss the emerging roles of miRNAs using cardiomyocyte differentiation and maturation as a paradigm. Emphasis will also be given on some of the less ventured areas such as the role of miRNAs in the physiological maturation of cardiomyocytes. These potentially beneficial miRNAs are likely to improve cardiac function in both in vivo and in vitro settings and thus provide additional strategy to treat heart diseases and more importantly serve as a good model for understanding cardiomyocyte maturation in vitro.

Molecular mechanism of sphingosine-1-phosphate action in Duchenne muscular dystrophy.

Duchenne muscular dystrophy (DMD) is a lethal muscle-wasting disease. Studies in Drosophila showed that genetic increase of the levels of the bioactive sphingolipid sphingosine-1-phosphate (S1P) or delivery of 2-acetyl-5-tetrahydroxybutyl imidazole (THI), an S1P lyase inhibitor, suppresses dystrophic muscle degeneration. In the dystrophic mouse (mdx), upregulation of S1P by THI increases regeneration and muscle force. S1P can act as a ligand for S1P receptors and as a histone deacetylase (HDAC) inhibitor. Because Drosophila has no identified S1P receptors and DMD correlates with increased HDAC2 levels, we tested whether S1P action in muscle involves HDAC inhibition. Here we show that beneficial effects of THI treatment in mdx mice correlate with significantly increased nuclear S1P, decreased HDAC activity and increased acetylation of specific histone residues. Importantly, the HDAC2 target microRNA genes miR-29 and miR-1 are significantly upregulated, correlating with the downregulation of the miR-29 target Col1a1 in the diaphragm of THI-treated mdx mice. Further gene expression analysis revealed a significant THI-dependent decrease in inflammatory genes and increase in metabolic genes. Accordingly, S1P levels and functional mitochondrial activity are increased after THI treatment of differentiating C2C12 cells. S1P increases the capacity of the muscle cell to use fatty acids as an energy source, suggesting that THI treatment could be beneficial for the maintenance of energy metabolism in mdx muscles.

MiRNA sensitivity to Drosha levels correlates with pre-miRNA secondary structure

microRNAs (miRNAs) are crucial for cellular development and homeostasis. In order to better understand regulation of miRNA biosynthesis, we studied cleavage of primary miRNAs by Drosha. While Drosha knockdown triggers an expected decrease of many mature miRNAs in human embryonic stem cells (hESC), a subset of miRNAs are not reduced. Statistical analysis of miRNA secondary structure and fold change of expression in response to Drosha knockdown showed that absence of mismatches in the central region of the hairpin, 5 and 9-12 nt from the Drosha cutting site conferred decreased sensitivity to Drosha knockdown. This suggests that, when limiting, Drosha processes miRNAs without mismatches more efficiently than mismatched miRNAs. This is important because Drosha expression changes over cellular development and the fold change of expression for miRNAs with mismatches in the central region correlates with Drosha levels. To examine the biochemical relationship directly, we overexpressed structural variants of miRNA-145, miRNA-137, miRNA-9, and miRNA-200b in HeLa cells with and without Drosha knockdown; for these miRNAs, elimination of mismatches in the central region increased, and addition of mismatches decreased their expression in an in vitro assay and in cells with low Drosha expression. Change in Drosha expression can be a biologically relevant mechanism by which eukaryotic cells control miRNA profiles. This phenomenon may explain the impact of point mutations outside the seed region of certain miRNAs.