Reprogramming after Chromosome Transfer into Mouse Blastomeres

It is well known that oocytes can reprogram differentiated cells, allowing animal cloning by nuclear transfer. We have recently shown that fertilized zygotes retain reprogramming activities [1], suggesting that such activities might also persist in cleavage-stage embryos. Here, we used chromosome transplantation techniques to investigate whether the blastomeres of two-cell-stage mouse embryos can reprogram more differentiated cells. When chromosomes from one of the two blastomeres were replaced with the chromosomes of an embryonic or CD4+ T lymphocyte donor cell, we observed nuclear reprogramming and efficient contribution of the manipulated cell to the developing blastocyst. Embryos produced by this method could be used to derive stem cell lines and also developed to term, generating mosaic ‘‘cloned’’ animals. These results demonstrate that blastomeres retain reprogramming activities and support the notion that discarded human preimplantation embryos may be useful recipients for the production of genetically tailored human embryonic stem cell lines.Stem Cell and Regenerative Biolog

Developmental Bias in Cleavage-Stage Mouse Blastomeres

BACKGROUND: The cleavage-stage mouse embryo is composed of superficially equivalent blastomeres that will generate both the embryonic inner cell mass (ICM) and the supportive trophectoderm (TE). However, it remains unsettled whether the contribution of each blastomere to these two lineages can be accounted for by chance. Addressing the question of blastomere cell fate may be of practical importance, because preimplantation genetic diagnosis requires removal of blastomeres from the early human embryo. To determine whether blastomere allocation to the two earliest lineages is random, we developed and utilized a recombination-mediated, noninvasive combinatorial fluorescent labeling method for embryonic lineage tracing. RESULTS: When we induced recombination at cleavage stages, we observed a statistically significant bias in the contribution of the resulting labeled clones to the trophectoderm or the inner cell mass in a subset of embryos. Surprisingly, we did not find a correlation between localization of clones in the embryonic and abembryonic hemispheres of the late blastocyst and their allocation to the TE and ICM, suggesting that TE-ICM bias arises separately from embryonic-abembryonic bias. Rainbow lineage tracing also allowed us to demonstrate that the bias observed in the blastocyst persists into postimplantation stages and therefore has relevance for subsequent development. CONCLUSIONS: The Rainbow transgenic mice that we describe here have allowed us to detect lineage-dependent bias in early development. They should also enable assessment of the developmental equivalence of mammalian progenitor cells in a variety of tissues.Molecular and Cellular Biolog

Conversion of Mouse and Human Fibroblasts into Functional Spinal Motor Neurons

The mammalian nervous system is composed of a multitude of distinct neuronal subtypes, each with its own phenotype and differential sensitivity to degenerative disease. Although specific neuronal types can be isolated from rodent embryos or engineered from stem cells for translational studies, transcription factor mediated reprogramming might provide a more direct route to their generation. Here we report that the forced expression of select transcription factors is sufficient to convert mouse and human fibroblasts into induced motor neurons (iMNs). iMNs displayed a morphology, gene expression signature, electrophysiology, synaptic functionality, in vivo engraftment capacity and sensitivity to degenerative stimuli, similar to embryo-derived motor neurons. We show that the converting fibroblasts do not transit through a proliferative neural progenitor state, and thus form bona fide motor neurons via a route distinct from embryonic development. Our findings demonstrate that fibroblasts can be converted directly into a specific differentiated and functional neural subtype, the spinal motor neuron.Stem Cell and Regenerative Biolog

Reprogramming within Hours Following Nuclear Transfer into Mouse but not Human Zygotes

Fertilized mouse zygotes can reprogram somatic cells to a pluripotent state. Human zygotes might therefore be useful for producing patient-derived pluripotent stem cells. However, logistical, legal and social considerations have limited the availability of human eggs for research. Here we show that a significant number of normal fertilized eggs (zygotes) can be obtained for reprogramming studies. Using these zygotes, we found that when the zygotic genome was replaced with that of a somatic cell, development progressed normally throughout the cleavage stages, but then arrested before the morula stage. This arrest was associated with a failure to activate transcription in the transferred somatic genome. In contrast to human zygotes, mouse zygotes reprogrammed the somatic cell genome to a pluripotent state within hours after transfer. Our results suggest that there may be a previously unappreciated barrier to successful human nuclear transfer, and that future studies could focus on the requirements for genome activation.Stem Cell and Regenerative Biolog

Notch Inhibition Allows Oncogene-Independent Generation of iPS Cells

The reprogramming of somatic cells to pluripotency using defined transcription factors holds great promise for biomedicine. However, human reprogramming remains inefficient and relies either on the use of the potentially dangerous oncogenes ​KLF4 and ​CMYC or the genetic inhibition of the tumor suppressor gene ​p53. We hypothesized that inhibition of signal transduction pathways that promote differentiation of the target somatic cells during development might relieve the requirement for non-core pluripotency factors during induced pluripotent stem cell (iPSC) reprogramming. Here, we show that inhibition of Notch greatly improves the efficiency of iPSC generation from mouse and human keratinocytes by suppressing ​p21 in a ​p53-independent manner and thereby enriching for undifferentiated cells capable of long-term self-renewal. Pharmacological inhibition of Notch enabled routine production of human iPSCs without ​KLF4 and ​CMYC while leaving ​p53 activity intact. Thus, restricting the development of somatic cells by altering intercellular communication enables the production of safer human iPSCs.Molecular and Cellular BiologyStem Cell and Regenerative Biolog

Somatic coding mutations in human induced pluripotent stem cells

Defined transcription factors can induce epigenetic reprogramming of adult mammalian cells into induced pluripotent stem cells. Although DNA factors are integrated during some reprogramming methods, it is unknown whether the genome remains unchanged at the single nucleotide level. Here we show that 22 human induced pluripotent stem (hiPS) cell lines reprogrammed using five different methods each contained an average of five protein-coding point mutations in the regions sampled (an estimated six protein coding point mutations per exome). The majority of these mutations were non-synonymous, nonsense, or splice variants, and were enriched in genes mutated or having causative effects in cancers. At least half of these reprogramming-associated mutations pre-existed in fibroblast progenitors at low frequencies, while the rest were newly occurring during or after reprogramming. Thus, hiPS cells acquire genetic modifications in addition to epigenetic modifications. Extensive genetic screening should become a standard procedure to ensure hiPS safety before clinical use

Cloning, stem cells and epigenetic reprogramming after nuclear transfer

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Biology, 2003.Includes bibliographical references (leaves 128-146).The process by which a single totipotent cell becomes a complex organism is a unidirectional program, with each mitotic division generating new cells that gradually differentiate towards more specified fates and specialized functions. Nuclear transfer (NT) experiments have demonstrated the epigenetic nature of development and showed, that although differentiated cells have a very limited developmental potential, the nuclei of these cells retain the potency to direct embryogenesis after reintroduction into the unfertilized oocyte. Herein, we have used the mouse as a model system for understanding both the nature of epigenetic reprogramming that occurs after NT as well as the ramifications it has for the development of cloned animals. Specifically, we investigated how epigenetic states are reprogrammed after NT and demonstrated that the inactive X chromosome is reactivated in NT embryos, resulting in normal X inactivation in female clones. Additionally, investigations into the factors that influence the survival of cloned animals, indicate that there are considerable genetic influences on the cloning process. These genetic factors modify the survival of mice cloned from ES cells by influencing the developmental potential of the donor ES cells rather then the reprogramming process itself. This realization has subsequently led to the development of novel methods for the expedited production of complex mutant mice, which are also described. Finally, we have created cloned embryos by NT from both cortical and mature olfactory sensory neurons to address question of nuclear equivalence in the brain and to investigate whether generation of synaptic diversity or odorant receptor choice, are mediated by genetic as well as epigenetic events.by Kevin C. Eggan.Ph.D

Progress toward the clinical application of patient-specific pluripotent stem cells

Induced pluripotent stem (iPS) cells are generated by epigenetic reprogramming of somatic cells through the exogenous expression of transcription factors. These cells, just like embryonic stem cells, are likely to have a major impact on regenerative medicine, because they self-renew and retain the potential to be differentiated into all cell types of the human body. In this Review, we describe the current state of iPS cell technology, including approaches by which they are generated and what is known about their biology, and discuss the potential applications of these cells for disease modeling, drug discovery, and, eventually, cell replacement therapy.Stem Cell and Regenerative Biolog

Erosion of Dosage Compensation Impacts Human iPSC Disease Modeling

Although distinct human induced pluripotent stem cell (hiPSC) lines can display considerable epigenetic variation, it has been unclear whether such variability impacts their utility for disease modeling. Here, we show that although low-passage female hiPSCs retain the inactive X chromosome of the somatic cell they are derived from, over time in culture they undergo an “erosion” of X chromosome inactivation (XCI). This erosion of XCI is characterized by loss of XIST expression and foci of H3-K27-trimethylation, as well as transcriptional derepression of genes on the inactive X that cannot be reversed by either differentiation or further reprogramming. We specifically demonstrate that erosion of XCI has a significant impact on the use of female hiPSCs for modeling Lesch-Nyhan syndrome. However, our finding that most genes subject to XCI are derepressed by this erosion of XCI suggests that it should be a significant consideration when selecting hiPSC lines for modeling any disease.Stem Cell and Regenerative Biolog

Impracticality of Egg Donor Recruitment in the Absence of Compensation

Unfertilized oocytes of many mammalian species can reprogram somatic cells to a pluripotent state. Human oocytes might therefore be useful for producing patient-derived pluripotent stem cells. Because they would carry the patient's genotype, these stem cells may be useful for the production of autologous transplants. Such cells could also be used to determine whether the epigenetic (Lister et al., 2011) and genetic (Gore et al., 2011) changes detected in induced pluripotent stem cells (iPSCs) are universally found in reprogrammed cell lines or instead are unique to iPSCs.Stem Cell and Regenerative Biolog