Induced pluripotent stem cells reprogramming: Epigenetics and applications in the regenerative medicine.

Induced pluripotent stem cells (iPSCs) are somatic cells reprogrammed into an embryonic-like pluripotent state by the expression of specific transcription factors. iPSC technology is expected to revolutionize regenerative medicine in the near future. Despite the fact that these cells have the capacity to self-renew, they present low efficiency of reprogramming. Recent studies have demonstrated that the previous somatic epigenetic signature is a limiting factor in iPSC performance. Indeed, the process of effective reprogramming involves a complete remodeling of the existing somatic epigenetic memory, followed by the establishment of a "new epigenetic signature" that complies with the new type of cell to be differentiated. Therefore, further investigations of epigenetic modifications associated with iPSC reprogramming are required in an attempt to improve their self-renew capacity and potency, as well as their application in regenerative medicine, with a new strategy to reduce the damage in degenerative diseases. Our review aimed to summarize the most recent findings on epigenetics and iPSC, focusing on DNA methylation, histone modifications and microRNAs, highlighting their potential in translating cell therapy into clinics.

Induced pluripotent stem cells reprogramming: Epigenetics and applications in the regenerative medicine / Células-tronco de pluripotência induzida: papel da epigenética na reprogramação e sua aplicabilidade clínica

Summary Induced pluripotent stem cells (iPSCs) are somatic cells reprogrammed into an embryonic-like pluripotent state by the expression of specific transcription factors. iPSC technology is expected to revolutionize regenerative medicine in the near future. Despite the fact that these cells have the capacity to self-renew, they present low efficiency of reprogramming. Recent studies have demonstrated that the previous somatic epigenetic signature is a limiting factor in iPSC performance. Indeed, the process of effective reprogramming involves a complete remodeling of the existing somatic epigenetic memory, followed by the establishment of a "new epigenetic signature" that complies with the new type of cell to be differentiated. Therefore, further investigations of epigenetic modifications associated with iPSC reprogramming are required in an attempt to improve their self-renew capacity and potency, as well as their application in regenerative medicine, with a new strategy to reduce the damage in degenerative diseases. Our review aimed to summarize the most recent findings on epigenetics and iPSC, focusing on DNA methylation, histone modifications and microRNAs, highlighting their potential in translating cell therapy into clinics.

Resumo As células-tronco de pluripotência induzida (CTPI) ou do inglês induced pluripotent stem cells (iPSCs) são células somáticas reprogramadas para o estado embrionário por meio da expressão de fatores ectópicos de transcrição específicos, tornando-as um alvo promissor para a medicina regenerativa. Apesar das CTPI compartilharem características embrionárias, como pluripotência e capacidade de autorrenovação, elas possuem uma baixa eficiência de reprogramação, sendo a memória epigenética uma das principais barreiras nesse processo. A epigenética é caracterizada por alterações reversíveis e herdáveis no genoma funcional que não alteram a sequência de nucleotídeos do DNA. Dentre as diferentes modificações epigenéticas, destacam-se metilação de DNA, alterações em histonas e microRNA. Atualmente, sabe-se que o processo de reprogramação efetivo das CTPI envolve um completo remodelamento da memória epigenética somática existente, seguido pelo estabelecimento de uma "assinatura epigenética" que esteja de acordo com o novo tipo de célula a ser diferenciada. Modificações epigenéticas personalizadas são capazes de melhorar o rendimento e a efetividade das CTPI geradas, abrindo uma nova perspectiva para a terapia celular. Nesta revisão reunimos as principais informações sobre os fatores epigenéticos que afetam a reprogramação das CTPI, bem como seus benefícios na aplicação da terapia celular.

The involvement of Nek2 and Notch in the proliferation of rat adrenal cortex triggered by POMC-derived peptides.

The adrenal gland is a dynamic organ that undergoes constant cell turnover. This allows for rapid organ remodeling in response to the physiological demands of the HPA axis, which is controlled by proopiomelanocortin (POMC)-derived peptides, such as adrenocorticotropic hormone (ACTH) and N-Terminal peptides (N-POMC). In the rat adrenal cortex, POMC-derived peptides trigger a mitogenic effect, and this process increases cyclins D and E, while inhibiting p27Kip1. The goal of the present study was to further explore the mitogenic effect of ACTH and synthetic N-POMC1-28 peptides by investigating the differences in the expression of key genes involved in the cell cycle of the rat adrenal cortex, following inhibition of the HPA axis. Moreover, we evaluated the differences between the inner and outer fractions of the adrenal cortex (ZF-fraction and ZG-fraction) in terms of their response patterns to different stimuli. In the current study, the inhibition of the HPA axis repressed the expression of Ccnb2, Camk2a, and Nek2 genes throughout the adrenal cortex, while treatments with POMC-derived peptides stimulated Nek2, gene and protein expression, and Notch2 gene expression. Furthermore, Notch1 protein expression was restricted to the subcapsular region of the cortex, an area of the adrenal cortex that is well-known for proliferation. We also showed that different regions of the adrenal cortex respond to HPA-axis inhibition and to induction with POMC-derived peptides at different times. These results suggest that cells in the ZG and ZF fractions could be at different phases of the cell cycle. Our results contribute to the understanding of the mechanisms involved in cell cycle regulation in adrenocortical cells triggered by N-POMC peptides and ACTH, and highlight the involvement of genes such as Nek2 and Notch.