Ependymal cells (EC) in the spinal cord central canal (CC) are believed to be responsible for the postnatal neurogenesis following pathological or stimulatory conditions. In this study, we have analyzed the proliferation of the CC ependymal progenitors in adult rats processed to compression SCI or enhanced physical activity. To label dividing cells, a single daily injection of Bromo-deoxyuridine (BrdU) was administered over a 14-day-survival period. Systematic quantification of BrdU-positive ependymal progenitors was performed by using stereological principles of systematic, random sampling, and optical Dissector software. The number of proliferating BrdU-labeled EC increased gradually with the time of survival after both paradigms, spinal cord injury, or increased physical activity. In the spinal cord injury group, we have found 4.9-fold (4 days), 7.1-fold (7 days), 4.9-fold (10 days), and 5.6-fold (14 days) increase of proliferating EC in the rostro-caudal regions, 4 mm away from the epicenter. In the second group subjected to enhanced physical activity by running wheel, we have observed 2.1-2.6 fold increase of dividing EC in the thoracic spinal cord segments at 4 and 7 days, but no significant progression at 10-14 days. Nestin was rapidly induced in the ependymal cells of the CC by 2-4 days and expression decreased by 7-14 days post-injury. Double immunohistochemistry showed that dividing cells adjacent to CC expressed astrocytic (GFAP, S100beta) or nestin markers at 14 days. These data demonstrate that SCI or enhanced physical activity in adult rats induces an endogenous ependymal cell response leading to increased proliferation and differentiation primarily into macroglia or cells with nestin phenotype.
Mesenchymal stem cells (MSCs) have generated a great deal of promise as a potential source of cells for cell-based therapies. Various labeling techniques have been developed to trace MSC survival, migration, and behavior in vitro or in vivo. In the present study, we labeled MSCs derived from rat bone marrow (rMSCs) with florescent membrane dyes PKH67 and DiI, and with nuclear labeling using 5 μM BrdU and 10 μM BrdU. The cells were then cultured for 6 d or passaged (1-3 passages). The viability of rMSCs, efficacy of fluorescent expression, and transfer of the dyes were assessed. Intense fluorescence in rMSCs was found immediately after membrane labeling (99.3 ± 1.6% PKH67+ and 98.4 ± 1.7% DiI+) or after 2 d when tracing of nuclei was applied (91.2 ± 4.6% 10 μM BrdU+ and 77.6 ± 4.6% 5 μM BrdU+), which remained high for 6 d. Viability of labeled cells was 91 ± 3.8% PKH67+, 90 ± 1.5% DiI+, 91 ± 0.8% 5 μM BrdU+, and 76.9 ± 0.9% 10 μM BrdU+. The number of labeled rMSCs gradually decreased during the passages, with almost no BrdU+ nuclei left at final passage 3. Direct cocultures of labeled rMSCs (PKH67+ or DiI+) with unlabeled rMSCs revealed almost no dye transfer from donor to unlabeled recipient cells. Our results confirm that labeling of rMSCs with PKH67 or DiI represents a non-toxic, highly stable, and efficient method suitable for steady tracing of cells, while BrdU tracing is more appropriate for temporary labeling due to decreasing signal over time.
Living organisms are extremely complex functional systems. At present, there are many in vivo models of spinal cord injury (SCI) that allow the modeling of any type of central nervous system (CNS) injury, however, with some disadvantages. The production of injury models can be a highly invasive and time-consuming process and requires high technical requirements, and costly financial issues should also be taken into account. Of course, a large number of animals have been used to obtain the relevant data of statistical significance. All of these aspects can be reduced by carrying out experiments in in vitro conditions. The primary advantage of in vitro method is that it simplifies the system under study. There are two major groups of in vitro model in use: cell culture and organotypic slice (OTS) culture. OTS is an intermediate system of the screening of in vitro cell culture and animal models and represents the in vitro system preserving the basic tissue architecture that able to closely mimic the cellular and physiological characteristics in vivo. In vitro models are the preferred methods for the study of acute or subacute pathophysiology after a trauma stimulus, enabling precise control on the extracellular environment, easy and repeatable access to the cells.
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