Reprogramming with defined factors: from induced pluripotency to induced transdifferentiation.

Ever since work on pluripotency induction was originally published, reporting the reprogramming of somatic cells to induced pluripotent stem cells (iPS cells) by the ectopic expression of the four transcription factors Oct4, Sox2, Klf4 and c-Myc, high expectations regarding their potential use for regenerative medicine have emerged. Very recently, the direct conversion of fibroblasts into functional neurons with no prior pluripotent stage has been described. Interconversion between adult cells from ontogenically different lineages by an induced transdifferentiation process based on the overexpression of a cocktail of transcription factors, while avoiding transition through an embryonic stem cell-like state, provides a new impetus in the field of regenerative medicine. Here, we review the induced reprogramming of somatic cells with defined factors and analyze their potential clinical use. Beginning with induced pluripotency, we summarize the initial objections including their extremely low efficiency and the risk of tumor generation. We also review recent reports describing iPS cells' capacity to generate viable offspring through tetraploid complementation, the most restrictive pluripotency criterion. Finally, we explore the available evidence for 'induced transdifferentiated cells' as a novel tool for adult cell fate modification.

Loss of p53 induces tumorigenesis in p21-deficient mesenchymal stem cells.

There is growing evidence about the role of mesenchymal stem cells (MSCs) as cancer stem cells in many sarcomas. Nevertheless, little is still known about the cellular and molecular mechanisms underlying MSCs transformation. We aimed at investigating the role of p53 and p21, two important regulators of the cell cycle progression and apoptosis normally involved in protection against tumorigenesis. Mesenchymal stem cells from wild-type, p21(-/-)p53(+/+), and p21(-/-)p53(+/-) mice were cultured in vitro and analyzed for the appearance of tumoral transformation properties after low, medium, and high number of passages both in vitro and in vivo. Wild-type or p21(-/-)p53(+/+) MSCs did not show any sign of tumoral transformation. Indeed, after short-term in vitro culture, wild-type MSCs became senescent, and p21(-/-)p53(+/+) MSCs showed an elevated spontaneous apoptosis rate. Conversely, MSCs carrying a mutation in one allele of the p53 gene (p21(-/-)p53(+/-) MSCs) completely lost p53 expression after in vitro long-term culture. Loss of p53 was accompanied by a significant increase in the growth rate, gain of karyotypic instability, loss of p16 expression, and lack of senescence response. Finally, these cells were able to form fibrosarcomas partially differentiated into different mesenchymal lineages when injected in immunodeficient mice both after subcutaneous and intrafemoral injection. These findings show that MSCs are very sensitive to mutations in genes involved in cell cycle control and that these deficiencies can be at the origin of some mesodermic tumors.

AUF1 and Hu proteins in the developing rat brain: implication in the proliferation and differentiation of neural progenitors.

Posttranscriptional events such as RNA stabilization are important for cell differentiation, but little is known about the impact of AU-rich binding proteins (AUBPs) on the fate of neural cells. Expression of destabilizing AUBPs such as AUF1 and neuronal-specific stabilizing proteins such as HuB, HuC and HuD was therefore analyzed in the developing central nervous system. Real-time RT-PCR indicated a specific developmental pattern in the postnatal cerebellum, with a progressive down-regulation of AUF1 from P1, whereas HuB was strongly up-regulated at about P7. These changes were accompanied by a progressive increase in AUF1p45 and the disappearance of one HuB isoform from P15, suggesting particular roles for these AUBPs in the developing cerebellum. AUF1 was detected in the three main cerebellar layers, whereas Hu proteins were found only in postmitotic neurons. A role for Hu proteins in the early stages of neuronal differentiation is further supported by arrest of cell proliferation following induction of HuB or HuD expression in a neural stem cell line. The decrease in nestin expression suggest that HuD, but not HuB, favors the transition of neural progenitors into early neuroblasts, but other factors are most probably required for their full differentiation into neurons, insofar as GAP-43 was not detected in HuD-transfected cells. These data suggest critical roles for HuB at the very earliest stages of neuronal differentiation, such as cell cycle exit, and HuD might also be involved in the transition of neural progenitors into early neuroblasts. Taken together, the present results strengthen the importance of AUBPs in brain ontogenesis.

Conserved asparagine residue 54 of alpha-sarcin plays a role in protein stability and enzyme activity.

Asparagine 54 of alpha-sarcin is a conserved residue within the proteins of the ribotoxin family of microbial ribonucleases. It is located in loop 2 of the protein, which lacks repetitive secondary structure elements but exhibits a well-defined conformation. Five mutant variants at this residue have been produced and characterized. The spectroscopic characterization of these proteins indicates that the overall conformation is not changed upon mutation. Activity and denaturation assays show that Asn-54 largely contributes to protein stability, and its presence is a requirement for the highly specific inhibitory activity of these ribotoxins on ribosomes.

Leucine 145 of the ribotoxin alpha-sarcin plays a key role for determining the specificity of the ribosome-inactivating activity of the protein.

Secreted fungal RNases, represented by RNase T1, constitute a family of structurally related proteins that includes ribotoxins such as alpha-sarcin. The active site residues of RNase T1 are conserved in all fungal RNases, except for Phe 100 that is not present in the ribotoxins, in which Leu 145 occupies the equivalent position. The mutant Leu145Phe of alpha-sarcin has been recombinantly produced and characterized by spectroscopic methods (circular dichroism, fluorescence spectroscopy, and NMR). These analyses have revealed that the mutant protein retained the overall conformation of the wild-type alpha-sarcin. According to the analyses performed, Leu 145 was shown to be essential to preserve the electrostatic environment of the active site that is required to maintain the anomalous low pKa value reported for the catalytic His 137 of alpha-sarcin. Enzymatic characterization of the mutant protein has revealed that Leu 145 is crucial for the specific activity of alpha-sarcin on ribosomes.

Deletion of the NH2-terminal beta-hairpin of the ribotoxin alpha-sarcin produces a nontoxic but active ribonuclease.

Ribotoxins are a family of highly specific fungal ribonucleases that inactivate the ribosomes by hydrolysis of a single phosphodiester bond of the 28 S rRNA. alpha-Sarcin, the best characterized member of this family, is a potent cytotoxin that promotes apoptosis of human tumor cells after internalization via endocytosis. This latter ability is related to its interaction with phospholipid bilayers. These proteins share a common structural core with nontoxic ribonucleases of the RNase T1 family. However, significant structural differences between these two groups of proteins are related to the presence of a long amino-terminal beta-hairpin in ribotoxins and to the different length of their unstructured loops. The amino-terminal deletion mutant Delta(7-22) of alpha-sarcin has been produced in Escherichia coli and purified to homogeneity. It retains the same conformation as the wild-type protein as ascertained by complete spectroscopic characterization based on circular dichroism, fluorescence, and NMR techniques. This mutant exhibits ribonuclease activity against naked rRNA and synthetic substrates but lacks the specific ability of the wild-type protein to degrade rRNA in intact ribosomes. The results indicate that alpha-sarcin interacts with the ribosome at two regions, i.e. the well known sarcin-ricin loop of the rRNA and a different region recognized by the beta-hairpin of the protein. In addition, this latter protein portion is involved in interaction with cell membranes. The mutant displays decreased interaction with lipid vesicles and shows behavior compatible with the absence of one vesicle-interacting region. In agreement with this conclusion, the deletion mutant exhibits a very low cytotoxicity on human rhabdomyosarcoma cells.