Nanotechnology and multipotent adult progenitor cells in Reparative Medicine: therapeutic perspectives.

The biology of stem cells is one of the most dynamic and promising fields of the biological sciences, since it is the basis for the development of organisms. Its biological complexity demands efforts from several lines of research aimed mainly at its therapeutic use. Nanotechnology has been emerging as a new field of study, which shows great potential in the treatment of various diseases. This new area of health has been called "Nanomedicine" or "Bionanotechnology", which can be applied in Medicine by transport and drug delivery systems, robotic tools to be used in diagnostic and surgical processes, nanobiomaterials, gene therapies, nanobiomedical devices, among others. Because stem cells and Nanotechnology are two areas of extremely promising science, a new field of study, called "stem cell Nanotechnology", has gradually emerged. In this, Nanotechnology is used to help the stem cells apply their therapeutic potential in the treatment, cure, and repair of the damaged tissues, in an effective and safe way. In this way, stem cell Nanotechnology has generated great interest, since it may result in significant contributions to Regenerative Medicine and tissue engineering. The present work aims to present the state-of-the-art regarding its therapeutic use in Human Medicine.

Nanotechnology and multipotent adult progenitor cells in Reparative Medicine: therapeutic perspectives / Nanotecnologia e as células progenitoras adultas multipotentes na Medicina Reparativa: perspectivas terapêuticas

ABSTRACT The biology of stem cells is one of the most dynamic and promising fields of the biological sciences, since it is the basis for the development of organisms. Its biological complexity demands efforts from several lines of research aimed mainly at its therapeutic use. Nanotechnology has been emerging as a new field of study, which shows great potential in the treatment of various diseases. This new area of health has been called "Nanomedicine" or "Bionanotechnology", which can be applied in Medicine by transport and drug delivery systems, robotic tools to be used in diagnostic and surgical processes, nanobiomaterials, gene therapies, nanobiomedical devices, among others. Because stem cells and Nanotechnology are two areas of extremely promising science, a new field of study, called "stem cell Nanotechnology", has gradually emerged. In this, Nanotechnology is used to help the stem cells apply their therapeutic potential in the treatment, cure, and repair of the damaged tissues, in an effective and safe way. In this way, stem cell Nanotechnology has generated great interest, since it may result in significant contributions to Regenerative Medicine and tissue engineering. The present work aims to present the state-of-the-art regarding its therapeutic use in Human Medicine.

RESUMO A biologia das células-tronco é um dos campos mais dinâmicos e promissores das ciências biológicas, pois é a base do desenvolvimento dos organismos. Sua complexidade biológica demanda esforços de diversas linhas de pesquisa, visando principalmente à sua utilização terapêutica. A Nanotecnologia surge como um novo campo de estudo, o qual demonstra grande potencial no que tange ao tratamento de diversas doenças. Esta nova área da saúde vem sendo denominada "Nanomedicina" ou "Bionanotecnologia", a qual pode ser aplicada na Medicina por meio da utilização de sistemas de transporte e liberação de fármacos, ferramentas robóticas a serem utilizadas em processos de diagnóstico e cirurgia, nanobiomateriais, terapias gênicas, dispositivos nanobiomédicos, entre outros. Em razão das células-tronco e a Nanotecnologia serem duas áreas da ciência extremante promissoras, um novo campo de estudo, denominado "Nanotecnologia das células-tronco", surge gradativamente. Neste, a Nanotecnologia é utilizada de forma a auxiliar as células-tronco a exercerem seu potencial terapêutico no tratamento, na cura e na reparação dos tecidos lesionados, de forma eficaz e segura. A Nanotecnologia das células-tronco tem gerado grande interesse, podendo resultar em contribuições significativas na Medicina Regenerativa e na engenharia de tecidos. O presente trabalho teve por objetivo apresentar o estado da arte visando à sua utilização terapêutica na Medicina Humana.

A new mouse model for marfan syndrome presents phenotypic variability associated with the genetic background and overall levels of Fbn1 expression.

Marfan syndrome is an autosomal dominant disease of connective tissue caused by mutations in the fibrillin-1 encoding gene FBN1. Patients present cardiovascular, ocular and skeletal manifestations, and although being fully penetrant, MFS is characterized by a wide clinical variability both within and between families. Here we describe a new mouse model of MFS that recapitulates the clinical heterogeneity of the syndrome in humans. Heterozygotes for the mutant Fbn1 allele mgΔloxPneo, carrying the same internal deletion of exons 19-24 as the mgΔ mouse model, present defective microfibrillar deposition, emphysema, deterioration of aortic wall and kyphosis. However, the onset of a clinical phenotypes is earlier in the 129/Sv than in C57BL/6 background, indicating the existence of genetic modifiers of MFS between these two mouse strains. In addition, we characterized a wide clinical variability within the 129/Sv congenic heterozygotes, suggesting involvement of epigenetic factors in disease severity. Finally, we show a strong negative correlation between overall levels of Fbn1 expression and the severity of the phenotypes, corroborating the suggested protective role of normal fibrillin-1 in MFS pathogenesis, and supporting the development of therapies based on increasing Fbn1 expression.

Presumptive germ cells derived from mouse pluripotent somatic cell hybrids.

The fusion of embryonic stem (ES) cells with differentiated somatic cells is an approach that reverses a somatic cell nucleus to a state of pluripotency. The resulting ES-somatic cell hybrids (ES-SCH) retain most of the properties of ES cells: differentiate into multiple cell types and have the ability to produce embryoid bodies (EB) and chimeras. However, it is still unknown whether ES-SCH will be able to complete the differentiation into germ cells (GC) in vitro similar to ES cells. Here, we show that near diploid ES-SCH, obtained by the fusion of mouse ES and spleen cells, were able to differentiate in vitro into presumptive GC. Differentiation of ES-SCH was induced through EB formation and by the addition of retinoic acid. Presumptive GC obtained reacted positively with anti-EMA, Vasa, Fragilis and Dazl antibodies and expressed GC-specific genes, such as Vasa, Stella, Dazl, Piwil 2, Tex14, Bmp8b, Tdrd1 and Rnf17. Fluorescent in situ hybridization analysis indicates chromosome reduction in the GC-like cells. Expression of meiotic and postmeiotic GC-specific genes such as Haprin, Acrosin, Scyp1, Scyp3 and Stra-8 were also detected. Transmission electron microscopy confirmed ES-SCH differentiation into presumptive GC. The presence of several autosomes and the X chromosome originated from the "somatic" partner did not prevent ES-SCH differentiation towards presumptive GC. Overall our study suggests an interesting in vitro model, which allows the study GC differentiation in reprogrammed somatic cells.

Characterization of equine adipose tissue-derived progenitor cells before and after cryopreservation.

In horses, stem cell therapies are a promising tool to the treatment of many injuries, which are common consequences of athletic endeavor, resulting in high morbidity and often compromising the performance. In spite of many advantages, the isolation of stem cells similar to human, from equine adipose tissue, occurred only recently. The aim of this study was to isolate equine adipose tissue-derived progenitor cells (eAT-PC), to characterize their proliferative potential, and to study their differentiation capacity before and after cryopreservation. The cells, isolated from horse adipose tissue, presented similar fibroblast-like cell morphology in vitro. Their proliferation rate was evaluated during 63 days (23 passages) before and after cryopreservation. After the induction of osteogenic differentiation, von Kossa staining and positive immunostaining studies revealed the formation of calcified extracellular matrix confirming the osteogenic potential of these cells. Adipogenic differentiation was induced using two protocols: routine and other one developed by us, while our protocol requires a shorter time (Oil Red O staining revealed significant accumulation of lipid droplets after 7 days). Chondrogenic differentiation was observed after 21 days of induced pellet culture, as evidenced by histological (toluidine blue) and immunohistochemistry studies. Our data demonstrate that eAT-PC can be easily isolated and successfully expanded in vitro while presenting significant proliferating rate. These cells can be maintained undifferentiated in vitro and can efficiently undergo differentiation at least into mesodermal derivates. These eAT-PC properties were preserved even after cryopreservation. Our findings classify eAT-PC as a promising type of progenitor cells that can be applied in different cell therapies in equines.

Differentiation of mouse embryonic stem cells and their hybrids during embryoid body formation

We studied the karyotypes of three hybrid clones of mouse embryonic stem cells and murine splenocytes (two having near diploid and one having near tetraploid chromosome numbers) and the characteristics of their differentiation during the formation of embryoid bodies. The X chromosome originating from embryonic stem cells may be lost in hybrids with a near diploid chromosome number and reprogramming of the "somatic" X may occur. The morphological data we obtained using light and electron microscopy revealed a correlation between the karyotype constitution of hybrid cells and their differentiation during the formation of embryoid bodies. At the beginning of development, the embryoid bodies derived from hybrid cells already showed an advanced degree of differentiation. The production of significant quantities of cartilage was typical for hybrid cells with near tetraploid chromosome numbers. The hybrid cells showed restricted pluripotent capacity and were already committed when they started to differentiate into embryoid bodies