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This year (2016) will mark the 10th anniversary of the discovery of induced pluripotent stem cells (iPSCs). The finding that the transient expression of four transcription factors can radically remodel the epigenome, transcriptome and metabolome of differentiated cells and reprogram them into pluripotent stem cells has been a major and groundbreaking technological innovation. In this review, we discuss the major applications of this technology that we have grouped in nine categories: a model to study cell fate control; a model to study pluripotency; a model to study human development; a model to study human tissue and organ physiology; a model to study genetic diseases in a dish; a tool for cell rejuvenation; a source of cells for drug screening; a source of cells for regenerative medicine; a tool for the production of human organs in animals.

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To investigate the molecular mechanisms regulating c-myc RNA stability during late amphibian oogenesis, a heterologous system was used in which synthetic Xenopus laevis c-myc transcripts, progressively deleted from their 3' end, were injected into the cytoplasm of two different host axolotl (Ambystoma mexicanum) cells: stage VI oocytes and progesterone-matured oocytes (unfertilized eggs; UFE). This in vivo strategy allowed the behavior of the exogenous c-myc transcripts to be followed and different regions involved in the stability of each intermediate deleted molecule to be identified. Interestingly, these specific regions differ in the two cellular contexts. In oocytes, two stabilizing regions are located in the 3' untranslated region (UTR) and two in the coding sequence (exons II and III) of the RNA. In UFE, the stabilizing regions correspond to the first part of the 3' UTR and to the first part of exon II. However, in UFE, the majority of synthetic transcripts are degraded. This degradation is a consequence of nuclear factors delivered after germinal vesicle breakdown and specifically acting on targeted regions of the RNA. To test the direct implication of these nuclear factors in c-myc RNA degradation, an in vitro system was set up using axolotl germinal vesicle extracts that mimic the in vivo results and confirm the existence of specific destabilizing factors. In vitro analysis revealed that two populations of nuclear molecules are implicated: one of 4.4-5S (50-65 kDa) and the second of 5.4-6S (90-110 kDa). These degrading nuclear factors act preferentially on the coding region of the c-myc RNA and appear to be conserved between axolotl and Xenopus. Thus, this experimental approach has allowed the identification of specific stabilizing sequences in c-myc RNA and the temporal identification of the different factors (cytoplasmic and/or nuclear) involved in post-transcriptional regulation of this RNA during oogenesis.

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It is becoming increasingly clear that transcription control is carried out at several interconnecting levels. Besides nucleosomal organization and interaction between transcription factors and gene promoters and other regulatory elements, long-range organization of chromatin in loops or domains seems to play a role in transcriptional regulation. A similar organization is likely to be crucial in the control of the timing and selection of origins of DNA replication. This review considers the implications of domain organization of eukaryotic genome in developmental control of transcription and replication.

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Acquisition of the competence to replicate requires the assembly of the MCM2-7 (minichromosome maintenance) protein complex onto pre-replicative chromatin, a step of the licensing reaction. This step is thought to occur through binding of a heterohexameric MCM complex containing the six related MCM subunits. Here we show that assembly of the MCM complex onto pre-replicative chromatin occurs through sequential stabilization of specific MCM subunits. Inhibition of licensing with 6-dimethylaminopurine results in chromatin containing specifically bound MCM4 and MCM6. A similar result was obtained by interference of the assembly reaction with an MCM3 antibody. The presence of chromatin-bound MCM intermediates was confirmed by reconstitution experiments in vitro with purified proteins and by the observation of an ordered association of MCM subunits with chromatin. These results indicate that the assembly of the MCM complex onto pre-replicative chromatin is regulated at the level of distinct subunits, suggesting an additional regulatory step in the formation of pre-replication complexes.

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During Xenopus laevis early development, the genome is replicated in less than 15 min every 30 min. We show that during this period, DNA replication proceeds in an atypical manner. Chromosomes become surrounded by a nuclear membrane lamina forming micronuclei or karyomeres. This genomic organization permits that prereplication centers gather on condensed chromosomes during anaphase and that DNA replication initiates autonomously in karyomeres at early telophase before nuclear reconstruction and mitosis completion. The formation of karyomeres is not dependent on DNA replication but requires mitotic spindle formation and the normal segregation of chromosomes. Thus, during early development, chromosomes behave as structurally and functionally independent units. The formation of a nuclear envelope around each chromosome provides an in vivo validation of its role in regulating initiation of DNA replication, enabling the rate of replication to accelerate and S phase to overlap M phase without illegitimate reinitiation. The abrupt disappearance of this atypical organization within one cell cycle after thirteen divisions defines a novel developmental transition at the blastula stage, which may affect both the replication and the transcription programs of development.

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We report here unusual features of c-Myc specific to early embryonic development in Xenopus laevis, a period characterized by generalized transcriptional quiescence and rapid biphasic cell cycles. Two c-Myc protein forms, p61 and p64, are present in large amounts in the oocyte as well as during early development. In contrast, only p64 c-Myc is present in Xenopus somatic cells. p61 c-Myc is the direct translation product from both endogenous c-myc mRNAs and c-myc recombinant DNA. It is converted to the p64 c-Myc form after introduction into an egg extract, in the presence of phosphatase inhibitors. p61 and p64 belong to two distinct complexes localized in the cytoplasm of the oocyte. A 15S complex contains p64 c-Myc, and a 17.4S complex contains p61 c-Myc. Fertilization triggers the selective and total entry of only p64 c-Myc into the nucleus. This translocation occurs in a nonprogressive manner and is completed during the first cell cycles. This phenomenon results in an exceptionally high level of c-Myc in the nucleus, which returns to a somatic cell-like level only at the end of the blastulation period. During early development, when the entire embryonic genome is transcriptionally inactive, c-Myc does not exhibit a DNA binding activity with Max. Moreover, embryonic nuclei not only prevent the formation of c-Myc/Max complexes but also dissociate such preformed complexes. These peculiar aspects of c-Myc behavior suggest a function that could be linked to the rapid DNA replication cycles occurring during the early cell cycles rather than a function involving transcriptional activity.

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C-Myc is a nuclear phosphoprotein whose normal cellular function has not yet been clearly defined. Studies with this protein have always been constrained by the difficulty of obtaining full-length c-Myc in an active form, whatever the expression system used. We report here experimental conditions optimized to increase the solubility and the purification of c-Myc in a baculovirus expression system. Such conditions allow the production of both soluble and active full-length c-Myc. Interestingly, soluble c-Myc is found associated with a 500-kDa high-molecular-mass complex comparable to that found in human and Xenopus laevis embryos, and which may be required for its function in vivo.

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The consequences of denervation on the expression of c-myc protein have been analyzed on the regenerating forelimb of young froglets of Xenopus laevis. The level of c-myc expression, low in control limbs and enhanced in the regenerate, is transiently increased after a three-hour total denervation. For this protein, the level of expression is not a function of the quantity of nerve in the regenerate. Four days after denervation, c-myc signal is back to its base level observed in the regenerate. A different pattern of expression is obtained for an S phase marker (PCNA protein) taken as a control in the same experimental conditions. The data presented here show that the nervous system normally exerts a negative control on the expression of c-myc and PCNA proteins in the limb regenerate of Xenopus.

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In eukaryotic cells, nucleus-cytoplasm exchanges play an important role in genomic regulation. We have analyzed the localization of four nuclear antigens in different growth conditions: two replicative proteins, DNA polymerase alpha and proliferating cell nuclear antigen (PCNA), and two oncogenic regulatory proteins, c-Myc and c-Fos. A kinetic study of subcellular localization of these proteins has been done. In cultures in which cells were sparse, these proteins were detected in the nucleus. When proliferation was stopped by the high density of culture cells or by serum starvation, these proteins left the nucleus for the cytoplasm with different kinetics. DNA polymerase alpha is the first protein to leave the nucleus, with the PCNA protein, c-Fos, and c-Myc leaving the nucleus later. In contrast, during serum stimulation c-Fos and c-Myc relocalize into the nucleus before the replicative proteins. We also noticed that in sparse cell cultures, 10% of the cells exhibit a perinuclear staining for the DNA polymerase alpha, PCNA, and c-Myc proteins but not for c-Fos. This peculiar staining was also observed as an initial step to nuclear localization after serum stimulation and in vivo in Xenopus embryos when the G1 phase is reintroduced in the embryonic cell cycle at the mid-blastula stage. We suggest that such staining could reflect specific structures involved in the initiation of the S phase.

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