Clinical chemistry of human FcRn transgenic mice.

Mice genetically engineered to express human FcRn are valuable models for the evaluation of therapeutic antibodies in the context of human FcRn in vivo. However, only limited clinical chemistry information on these mouse strains is available. Thus, we have compared 30 clinical chemical parameters of C57BL/6J wild-type mice, murine FcRn-knockout mice, and two human FcRn transgenic mouse strains expressing human FcRn in the absence of murine FcRn. Since FcRn-mediated recycling prevents albumin and IgG from intracellular degradation, significant differences for both proteins were observed in the murine FcRn-knockout mice. Mice lacking FcRn show lower IgG and albumin levels compared to wild-type mice. The most prominent differences in clinical chemical parameters can be explained by secondary effects of the altered albumin levels of murine FcRn-knockout mice on liver metabolism, as similar tendencies have been observed in analbuminemic Nagase rats and hypoalbuminemic human patients, showing an overall increased liver metabolism. Both human FcRn transgenic strains show clinical chemical parameters similar to those found for wild-type mice, with the exception of endogenous IgG levels, which are greatly reduced in these mice.

Mesenchymal stromal cell characteristics vary depending on their origin.

Mesenchymal stromal cells (MSCs) are rare progenitor cells that can be isolated from various tissues. They exhibit multilineage differentiation potential, support regenerative processes, and interact with various immune cells. Therefore, MSCs represent a promising tool for regenerative medicine. However, source-dependent and donor-dependent differences of MSC properties, including implications on their clinical application are still largely unknown. We evaluated MSCs derived from perinatal tissues umbilical cord (UC) and amniotic membrane (AM) in comparison to adult MSCs from bone marrow (BM), which were used as gold standard. We found genetic background-independent differences between MSCs from UC and AM. While AM- and UC-MSCs were closer to each other than to BM-MSCs, they also exhibited differences between each other. AM-MSCs from different donors but not UC-MSCs displayed high interdonor variability. In addition, we show that although all MSCs expressed similar surface markers, MSC populations from UC and AM showed differential profiles of gene expression and paracrine factor secretion to BM-derived MSCs. Notably, pathway analysis of gene expression data revealed intriguing differences between MSCs suggesting that MSCs from UC and AM possess in general a higher potential of immunomodulatory capacity, whereas BM-MSCs showed a higher potential of supporting regenerative processes as exemplified by neuronal differentiation and development. These differences between perinatal and BM-derived MSCs may be relevant for clinical applications.