Goat umbilical cord cells are permissive to small ruminant lentivirus infection in vitro

Abstract Small ruminant lentiviruses isolated from peripheral blood leukocytes and target organs can be propagated in vitro in fibroblasts derived from goat synovial membrane cells. These cells are obtained from tissues collected from embryos or fetuses and are necessary for the establishment of the fibroblast primary culture. A new alternative type of host cells, derived from goat umbilical cord, was isolated and characterized phenotypically with its main purpose being to obtain cell monolayers that could be used for the diagnosis and isolation of small ruminant lentiviruses in cell culture. To accomplish this goal, cells were isolated from umbilical cords; characterized phenotypically by flow cytometry analysis; differentiate into osteogenic, chondrogenic and adipogenic lineage; and submitted to viral challenge. The proliferation of goat umbilical cord cells was fast and cell monolayers formed after 15 days. These cells exhibited morphology, immunophenotype, growth characteristics, and lineage differentiation potential similar to mesenchymal stem cells of other origins. The goat umbilical cord derived cells stained positive for vimentin and CD90, but negative for cytokeratin, CD34 and CD105 markers. Syncytia and cell lysis were observed in cell monolayers infected by CAEV-Cork and MVV-K1514, showing that the cells are permissive to small ruminant lentivirus infection in vitro. These data demonstrate the proliferative competence of cells derived from goat umbilical cords and provide a sound basis for future research to standardize this cell lineage.

Infection of MSCs by adenovirus expression system expressing NRF2 as a cytoprotective factor

Poor viability of Mesenchymal Stem Cells [MSCs] following transplantation is one of the major challenges in their therapeutic application. Manipulation of MSCs by the genetic engineering method is one of the strategies used to protect the cells against cytotoxic microenvironment. However, maintaining multi differentiation capacity of MSCs following manipulation is important. We investigated if the manipulation of MSCs with NRF2 affects the multi differentiation capacity. MSCs were isolated from bone marrow. NRF2 was isolated and TOPO cloned into the pENTR vector. The recombinant vector was transferred into pAD/CMV/V5-DEST vector by gateway technology. Recombinant adenovirus was produced in AD293 cells, followed by being infected into MSCs. Expression of NRF2 was verified by RT-PCR. The NRF2 engineered MSCs were exposed to stress conditions followed by the evaluation of the cells viability and apoptosis. Finally, NRF2 expressing MSCs differentiation into osteoblast and adipocyte lineages was studied. NRF2 was successfully expressed in MSCs. NRF2- MSCs differentiation into osteoblast and adipocyte lineages indicating overexpression of NRF2 does not affect the differentiation property of MSCs. Expression of NRF2, a well known cytoprotective factor, by using adenovirus expression system does not intervene in the differentiation capacity of MSCs. NRF2-MSCs might be applicable for stem cell-based cell therapy in future