Excess hydrogen peroxide inhibits head and foot regeneration in hydra by affecting DNA repair and expression of essential genes.

Reactive oxygen species (ROS) are necessary for various cellular processes. However, excess ROS cause damage to many biological molecules and therefore must be tightly regulated in time and space. Hydrogen peroxide (H2 O2 ) is the most commonly used ROS as second messenger in the cell. It is a relatively long-lived freely diffusible signaling molecule during early events of injury. In the Cnidarian hydra, injury-induced ROS production is essential for regeneration to proceed. In the present study, we have examined influence of varying exposure to H2 O2 on head and foot regeneration in the middlepieces of trisected hydra. We find that longer (4 hours) exposure to 1 mM H2 O2 inhibits both head and foot regeneration while shorter exposure (2 hours) does not. Longer exposure to H2 O2 resulted in extensive damage to DNA that could not be repaired, probably due to suboptimal induction of APE1, an enzyme necessary for base excision repair (BER). Concomitantly, genes involved in activation of Wnt pathway, necessary for head regeneration, were significantly downregulated. This appeared to be due to failure of both stabilization and transient nuclear localization of ß-catenin. Similarly, genes involved in foot regeneration were also downregulated on longer exposure to H2 O2 . Thus, exposure to excess ROS inhibits regenerative processes in hydra through reduced expression of genes involved in regeneration and diminished DNA repair.

Human bone marrow-derived mesenchymal cells differentiate and mature into endocrine pancreatic lineage in vivo.

BACKGROUND AIMS: The scarcity of human islets for transplantation remains a major limitation of cell replacement therapy for diabetes. Bone marrow-derived progenitor cells are of interest because they can be isolated, expanded and offered for such therapy under autologous/allogeneic settings. METHODS: We characterized and compared human bone marrow-derived mesenchymal cells (hBMC) obtained from (second trimester), young (1-24 years) and adult (34-81 years) donors. We propose a novel protocol that involves assessment of paracrine factors from regenerating pancreas in differentiation and maturation of hBMC into endocrine pancreatic lineage in vivo. RESULTS: We observed that donor age was inversely related to growth potential of hBMC. Following in vitro expansion and exposure to specific growth factors involved in pancreatic development, hBMC migrated and formed islet-like cell aggregates (ICA). ICA show increased abundance of pancreatic transcription factors (Ngn3, Brn4, Nkx6.1, Pax6 and Isl1). Although efficient differentiation was not achieved in vitro, we observed significant maturation and secretion of human c-peptide (insulin) upon transplantation into pancreactomized and Streptozotocin (STZ)-induced diabetic mice. Transplanted ICA responded to glucose and maintained normoglycemia in diabetic mice. CONCLUSIONS: Our data demonstrate that hBMC have tremendous in vitro expansion potential and can be differentiated into multiple lineages, including the endocrine pancreatic lineage. Paracrine factors secreted from regenerating pancreas help in efficient differentiation and maturation of hBMC, possibly via recruiting chromatin modulators, to generate glucose-responsive insulin-secreting cells.

Mesenchymal stem cells derived from bone marrow of diabetic patients portrait unique markers influenced by the diabetic microenvironment.

Cellular microenvironment is known to play a critical role in the maintenance of human bone marrow-derived mesenchymal stem cells (BM-MSCs). It was uncertain whether BM-MSCs obtained from a 'diabetic milieu' (dBM-MSCs) offer the same regenerative potential as those obtained from healthy (non-diabetic) individuals (hBM-MSCs). To investigate the effect of diabetic microenvironment on human BM-MSCs, we isolated and characterized these cells from diabetic patients (dBM-MSCs). We found that dBM-MSCs expressed mesenchymal markers such as vimentin, smooth muscle actin, nestin, fibronectin, CD29, CD44, CD73, CD90, and CD105. These cells also exhibited multilineage differentiation potential, as evident from the generation of adipocytes, osteocytes, and chondrocytes when exposed to lineage specific differentiation media. Although the cells were similar to hBM-MSCs, 6% (3/54) of dBM-MSCs expressed proinsulin/C-peptide. Emanating from the diabetic microenvironmental milieu, we analyzed whether in vitro reprogramming could afford the maturation of the islet-like clusters (ICAs) derived from dBM-MSCs. Upon mimicking the diabetic hyperglycemic niche and the supplementation of fetal pancreatic extract, to differentiate dBM-MSCs into pancreatic lineage in vitro, we observed rapid differentiation and maturation of dBM-MSCs into islet-like cell aggregates. Thus, our study demonstrated that diabetic hyperglycemic microenvironmental milieu plays a major role in inducing the differentiation of human BM-MSCs in vivo and in vitro.

Human umbilical cord blood serum promotes growth, proliferation, as well as differentiation of human bone marrow-derived progenitor cells.

Fetal calf serum (FCS) is conventionally used for animal cell cultures due to its inherent growth-promoting activities. However animal welfare issues and stringent requirements for human transplantation studies demand a suitable alternative for FCS. With this view, we studied the effect of FCS, human AB serum (ABS), and human umbilical cord blood serum (UCBS) on murine islets of Langerhans and human bone marrow-derived mesenchymal-like cells (hBMCs). We found that there was no difference in morphology and functionality of mouse islets cultured in any of these three different serum supplements as indicated by insulin immunostaining. A comparative analysis of hBMCs maintained in each of these three different serum supplements demonstrated that UCBS supplemented media better supported proliferation of hBMCs. Moreover, a modification of adipogenic differentiation protocol using UCBS indicates that it can be used as a supplement to support differentiation of hBMCs into adipocytes. Our results demonstrate that UCBS not only is suitable for maintenance of murine pancreatic islets, but also supports attachment, propagation, and differentiation of hBMCs in vitro. We conclude that UCBS can serve as a better serum supplement for growth, maintenance, and differentiation of hBMCs, making it a more suitable supplement in cell systems that have therapeutic potential in human transplantation programs.