Cryopreserved H2 O2 -preconditioned human adipose-derived stem cells exhibit fast post-thaw recovery and enhanced bioactivity against oxidative stress.

Abstract

Human adipose-derived stem cells (ASCs), despite being one of the most attractive cell populations for tissue engineering and regenerative medicine, currently have certain limitations that reduce their therapeutic efficacy. One of the most serious problems is the poor engraftment of cryopreserved ASCs at injured tissue, attributed to the diminished biological activity of ASCs immediately post-thaw and their poor survival under harsh conditions of oxidative stress. Seeking to address these issues, we have developed a hormetic strategy to preadapt human ASCs to oxidative stress based on a new hydrogen peroxide preconditioning procedure, resulting in cells we call HC016. These cells rapidly recover their biological activity and functionality after cryopreservation while maintaining their mesenchymal stem cell status. Compared with non-preconditioned ASCs, HC016 cells showed (a) faster in vitro adhesion capacity and cell cycle progression immediately post-thaw, (b) enhanced cell survival under oxidative stress in a serum-free environment, and (c) heightened chemotaxis towards damage signals of oxidized glial cells. In addition, compared with ASC-conditioned medium, HC016-conditioned medium showed a greater cytoprotective and pro-recovery effect on oxidized fibroblasts under serum-free conditions. Consistent with these results, in HC016 cells exposed to oxidative stress, we observed markedly higher expression of insulin-like growth factor-1 (a key factor in cell survival and migration) and of 6-phosphofructo-2-kinase/fructose-2,6-biphosphatase 4 and pyruvate dehydrogenase kinase isozyme 1 (essential enzymes to upregulate glycolysis and downregulate oxidative phosphorylation) along with lower basal mitochondrial activity. Taking into account all the aforementioned advantages, HC016 cells might be considered an important breakthrough in ASC-based cell therapies.