It is well established that bone maintenance and healing is compromised in alcoholics. Adult bone marrow-derived stromal cells (BMSCs) and adipose tissue-derived stromal cells (ASCs) likely contribute to bone homeostasis and formation. Direct and indirect alcohol exposure inhibits osteoprogenitor cell function through a variety of proposed mechanisms. The goal of this study was to characterize the effects of chronic alcohol ingestion on the native number and in vitro growth characteristics and multipotentiality of adult BMSCs and ASCs in a rat model. Adult male Sprague-Dawley rats received a liquid diet containing 36% ethanol or an isocaloric substitution of dextramaltose (control). After 4, 8, or 12 weeks of the diet, ASCs were harvested from epididymal adipose tissue and BMSCs from femoral and tibial bone marrow. Cell doublings (CDs) per day and doubling times (DTs) were determined for primary cells (P0) and cell passages 1 through 6 (P1-P6). Fibroblastic (CFU-F), adipogenic (CFU-Ad), and osteogenic (CFU-Ob) colony-forming unit (CFU) frequencies were assessed for P0, P3, and P6. The CDs and DTs were lower and higher, respectively, for ASCs and BMSCs harvested from ethanol versus control rats at all time points. The CFU-F, CFU-Ad, and CFU-Ob were significantly higher in ASCs harvested from control versus ethanol rats for P0, P3, and P6 at all times. Both CFU-Ad and CFU-Ob were significantly higher in P0 BMSCs harvested from control versus ethanol rats after 12 weeks of the diet. The CFU-Ob for P3 BMSCs from control rats was significantly higher than those from ethanol rats after 8 and 12 weeks on the diet. All three CFU frequencies in ASCs from ethanol rats tended to decrease with increasing diet duration. The ASC cell and colony morphology was different between control and ethanol cohorts in culture. These results emphasize the significant detrimental effects of chronic alcohol ingestion on the in vitro expansion and multipotentiality of adult mesenchymal stromal cells (MSCs). Maintenance of the effects through multiple cell passages in vitro suggests cells may be permanently compromised.
Published by Elsevier Inc.