Maintenance of feeder free anchorage independent cultures of ES and iPS cells by retinol/vitamin A.

Pluripotent embryonic stem (ES) cells derived from mammalian blastocyst and the adult fibroblast derived induced pluripotent stem (iPS cells) exhibit complete potential to form cells representing all the primary germ layers such as mesoderm, endoderm and ectoderm. These cells are usually co-cultured with mouse embryonic fibroblast feeders to prevent spontaneous differentiation. Feeder free cultures can provide substantial advantage to improve the efficiency and consistency of the culture conditions. In these studies, we demonstrate that a small dietary compound retinol, the alcohol form of vitamin A has capacity to regulate the pluripotency of pluripotent stem cells and maintain highly enriched population of pluripotent ES and iPS cells in feeder free suspension cultures. Retinol maintains long-term cultures of undifferentiated cells via elevated expression of stem cell specific transcription factors Nanog and Oct4. The studies provide evidence that retinol regulates the self-renewal of pluripotent stem cells via the over expression of insulin like growth factor II (IGFII) that engages PI3 kinase signaling pathway via IGF1 receptor tyrosine kinase. The ES cells retain capacity to generate high degree germline competent chimeric animals after microinjection into blastocysts. The studies offer a convenient system for long term maintenance of pluripotent stem cells via the activation of intracellular machinery for self-renewal by a physiologically relevant compound for large-scale production of high quality pluripotent stem cells.

Multiple ovarian transplants to rescue a transgenic line of mice.

Transgenic mice are useful tools for studying gene function and regulation but can be difficult to successfully breed. To 'rescue' transgenic lines that are difficult to propagate, researchers use a variety of techniques. One method is ovarian transplant, in which researchers remove ovaries from a donor transgenic mouse, cryopreserve the ovarian tissue, transplant this tissue into histocompatible female mice and breed these recipient females. Though it is a useful technique, cryopreservation can potentially damage ovarian tissue, which could reduce fertility. In this article, the authors describe how they carried out ovarian transplants without cryopreservation to rescue a line of transgenic C57BL/6 mice. Other researchers who have experience with mouse reproductive surgery should be able to use this technique to rescue infertile transgenic lines of mice.

Suppression of ES cell differentiation by retinol (vitamin A) via the overexpression of Nanog.

Embryonic stem cells (ESCs) derived from the inner cell mass of blastocysts maintain their pluripotency through a complex interplay of different signaling pathways and transcription factors including Leukemia Inhibitory Factor (LIF), homeo-domain protein Nanog and POU-domain-containing transcription factor Oct3/4. LIF can maintain the self-renewal of mouse ESCs by activating the Jak/Stat3 pathway; however, it is dispensable for human ESCs. Nanog, a homeo-domain transcription factor alone is sufficient for sustaining the self-renewal of ESCs. Overexpression of Nanog by heterologous promoters can maintain self-renewal of human and mouse ESCs in the absence of LIF/Stat3 pathway. The mechanisms that control the expression of Nanog, however, remain poorly understood. In this report we demonstrate that retinol, the alcohol form of Vitamin A, can suppress the differentiation of ESCs by up-regulating the expression of Nanog. Retinol is mainly associated with differentiation through its active metabolite retinoic acid during early development of the embryo. The activation of Nanog by retinol is not mediated via retinoic acid signaling and appears to be independent of previously described LIF/Stat3, bone morphogenic proteins, Wnt/beta-catenin, and Oct3/4-Sox2 pathways. These studies therefore, reveal a previously unknown function of retinol and offer a model system to define alternate regulatory pathways that control the self-renewal of ESCs as well as to identify upstream "master" regulatory factors that are responsible for maintaining the integrity of stem cells.