The endothelial cell secretome as a novel treatment to prime adipose-derived stem cells for improved wound healing in diabetes.

BACKGROUND: Chronic wounds are a common surgical problem exacerbated by diabetes and ischemia. Although adipose-derived stem cells (ASCs) have shown promise as a wound healing therapy, their function and proliferation are hindered in diabetes. This study examines the ability of the human umbilical vein endothelial cell (HUVEC) secretome to reverse the deleterious effects of high glucose concentrations on ASCs through priming, thereby enhancing their ability to participate in angiogenesis and wound healing.
METHODS: Institutional review board-approved human ASCs were cultured in M199 medium with or without glucose (30 mmol/L). HUVEC were grown in 30 mmol/L glucose-containing M199 medium; the resulting conditioned medium (HUVEC-CM) was collected every 3 days and used to prime ASCs. An aliquot of HUVEC-CM was heated (85°C for 30 minutes) to produce thermal denaturation of protein. Viability, proliferation, and endothelial differentiation were measured by MTT assays, growth curves, and quantitative polymerase chain reaction, respectively. A Matrigel assay was used to assess the ability of primed ASCs to participate in capillary-like tube formation. An Institutional Animal Care and Use Committee-approved in vivo murine model of diabetic and ischemic hindlimbs was used to evaluate the angiogenic potential of primed stem cells. Human ASCs were cultured with either control M199 or HUVEC-CM. Mice were randomized to a control group, an unprimed ASC group, or a HUVEC-primed ASC group. Cellular therapies were injected into the ischemic muscle. Thirty days later, slides were made. Microvessels were counted by three blinded observers.
RESULTS: MTT assays revealed that HUVEC-priming induced a 1.5 times increase in cell viability over diabetic controls. This promoting effect was lost with heated HUVEC-CM (P < .001), indicating that the active molecules are of protein origin. After 9 days, ASCs cultured in 30 mmol/L glucose solution showed a 14% reduction in growth from nondiabetic controls (P = .013) and exhibited atrophic morphology. Conversely, diabetic HUVEC-primed stem cells demonstrated a nearly four-fold increase in proliferation (P < .05) and took on a fusiform, endothelial-like phenotype. Polymerase chain reaction demonstrated enhanced expression of CD31 messenger RNA by 4.7-fold after 14 days in the HUVEC-primed group, and endothelial nitric oxide synthase messenger RNA messenger RNA was increased 20.1-fold from controls. Unlike unprimed controls, HUVEC-primed ASCs readily formed capillary-like tube networks on Matrigel. Diabetic mice that were injected with HUVEC-primed ASCs demonstrated greater vessel density than both controls (2.1-fold) and unprimed stem cell treatments (P < .001).
CONCLUSIONS: HUVECs secrete protein factors that significantly increase proliferation and endothelial differentiation of ASCs under diabetic conditions. Injection of ischemic hindlimbs in diabetic mice with HUVEC-primed ASCs leads to enhanced angiogenesis.