Resident angiogenic mesenchymal stem cells from multiorgan donor thoracic aortas

Stem cells are one of the most fascinating areas of biology today, and since the discover of an adult population, i.e., adult Stem Cells (aSCs), they have generated much interest especially for their application potential as a source for cell based regenerative medicine and tissue engineering. aSCs have been found in different tissues including bone marrow, skin, intestine, central nervous system, where they reside in a special microenviroment termed “niche” which regulate the homeostasis and repair of adult tissues. The arterial wall of the blood vessels is much more plastic than ever before believed. Several animal studies have demonstrated the presence of cells with stem cell characteristics within the adult vessels. Recently, it has been also hypothesized the presence of a “vasculogenic zone” in human adult arteries in which a complete hierarchy of resident stem cells and progenitors could be niched during lifetime. Accordingly, it can be speculated that in that location resident mesenchymal stem cells (MSCs) with the ability to differentiate in smooth muscle cells, surrounding pericytes and fibroblasts are present. The present research was aimed at identifying in situ and isolating MSCs from thoracic aortas of young and healthy heart-beating multiorgan donors. Immunohistochemistry performed on fresh and frozen human thoracic aortas demonstrated the presence of the vasculogenic zone between the media and the adventitial layers in which a well preserved plexus of CD34 positive cells was found. These cells expressed intensely HLA-I antigens both before and after cryopreservation and after 4 days of organ cultures remained viable. Following these preliminary results, we succeeded to isolate mesenchymal cells from multi-organ thoracic aortas using a mechanical and enzymatic combined procedure. Cells had phenotypic characteristics of MSC i.e., CD44+, CD90+, CD105+, CD166+, CD34low, CD45- and revealed a transcript expression of stem cell markers, e.g., OCT4, c-kit, BCRP-1, IL6 and BMI-1. As previously documented using bone marrow derived MSCs, resident vascular wall MSCs were able to differentiate in vitro into endothelial cells in the presence of low-serum supplemented with VEGF-A (50 ng/ml) for 7 days. Under the condition described above, cultured cells showed an increased expression of KDR and eNOS, down-regulation of the CD133 transcript, vWF expression as documented by flow cytometry, immunofluorescence, qPCR and TEM. Moreover, matrigel assay revealed that VEGF induced cells were able to form capillary-like structures within 6 hours of seeding. In summary, these findings indicate that thoracic aortas from heart-beating, multi-organ donors are highly suitable for obtaining MSCs with the ability to differentiate in vitro into endothelial cells. Even though their differentiating potential remains to be fully established, it is believed that their angiogenic ability could be a useful property for allogenic use. These cells can be expanded rapidly, providing numbers which are adequate for therapeutic neovascularization; furthermore they can be cryostored in appropriate cell banking facilities for later use.

Vascular wall stem cells. Selection and conditioning of progenitors useful for cell therapy. A pathological case study

The arterial wall contains MSCs with mesengenic and angiogenic abilities. These multipotent precursors have been isolated from variously-sized human adult segments, belying the notion that vessel wall is a relatively quiescent tissue. Recently, our group identified in normal human arteries a vasculogenic niche and subsequently isolated and characterized resident MSCs (VW-MSCs) with angiogenic ability and multilineage potential. To prove that VW-MSCs are involved in normal and pathological vascular remodeling, we used a long-term organ culture system; this method was of critical importance to follow spontaneous 3-D vascular remodeling without any influence of blood cells. Next we tried to identify and localize in situ the VW-MSCs and to understand their role in the vascular remodeling in failed arterial homografts. Subsequently, we isolated this cell population and tested in vitro their multilineage differentiation potential through immunohistochemical, immunofluorescence, RT-PCR and ultrastructural analysis. From 25-30cm2 of each vascular wall homograft sample, we isolated a cell population with MSCs properties; these cells expressed MSC lineage molecules (CD90, CD44, CD105, CD29, CD73), stemness (Notch-1, Oct-4, Sca-1, Stro-1) and pericyte markers (NG2) whilst were negative for hematopoietic and endothelial markers (CD34, CD133, CD45, KDR, CD146, CD31 and vWF). MSCs derived from failed homografts (H-MSCs) exhibited adipogenic, osteogenic and chondrogenic potential but scarce propensity to angiogenic and leiomyogenic differentiation. The present study demonstrates that failed homografts contain MSCs with morphological, phenotypic and functional MSCs properties; H-MSCs are long-lived in culture, highly proliferating and endowed with prompt ability to differentiate into adipocytes, osteocytes and chondrocytes; compared with VW-MSCs from normal arteries, H-MSCs show a failure in angiogenic and leiomyogenic differentiation. A switch in MSCs plasticity could be the basis of pathological remodeling and contribute to aneurysmal failure of arterial homografts. The study of VW-MSCs in a pathological setting indicate that additional mechanisms are involved in vascular diseases; their knowledge will be useful for opening new therapeutic options in cardiovascular diseases.

Adipose-derived stem cells and tissue revascularization: enhancing islet survival and performance for diabetes care.

Pancreatic islet transplantation represents a fascinating procedure that, at the moment, can be considered as alternative to standard insulin treatment or pancreas transplantation only for selected categories of patients with type 1 diabetes mellitus. Among the factors responsible for leading to poor islet engraftment, hypoxia plays an important role. Mesenchymal stem cells (MSCs) were recently used in animal models of islet transplantation not only to reduce allograft rejection, but also to promote revascularization. Currently adipose tissue represents a novel and good source of MSCs. Moreover, the capability of adipose-derived stem cells (ASCs) to improve islet graft revascularization was recently reported after hybrid transplantation in mice. Within this context, we have previously shown that hyaluronan esters of butyric and retinoic acids can significantly enhance the rescuing potential of human MSCs. Here we evaluated whether ex vivo preconditioning of human ASCs (hASCs) with a mixture of hyaluronic (HA), butyric (BU), and retinoic (RA) acids may result in optimization of graft revascularization after islet/stem cell intrahepatic cotransplantation in syngeneic diabetic rats. We demonstrated that hASCs exposed to the mixture of molecules are able to increase the secretion of vascular endothelial growth factor (VEGF), as well as the transcription of angiogenic genes, including VEGF, KDR (kinase insert domain receptor), and hepatocyte growth factor (HGF). Rats transplanted with islets cocultured with preconditioned hASCs exhibited a better glycemic control than rats transplanted with an equal volume of islets and control hASCs. Cotransplantation with preconditioned hASCs was also associated with enhanced islet revascularization in vivo, as highlighted by graft morphological analysis. The observed increase in islet graft revascularization and function suggests that our method of stem cell preconditioning may represent a novel strategy to remarkably improve the efficacy of islets-hMSCs cotransplantation.