Scientists study the functions of microglia by transcriptomics. This method provides dynamic information about genes that are active in the cell in both health and disease states. To do so, they isolate single cells from tissue followed by an enrichment of selected cell types with fluorescence-activated cell sorting (FACS).
The FACS method is not without its problems though: "We were able to show that the sorted microglia exhibited ex vivo activation signatures," says Dr. Felix Mulenge, a postdoc at the Institute of Experimental Infection Research at TWINCORE and first author of the study , now published in the Journal of Neuroinflammation . "This is because the cells encounter hydrodynamic stress or traumatic injury during sorting which alters the microglial transcriptome.
So we never see the cells in a truly quiescent state." A long-standing concern is whether such "spurious" signatures are unique to microglia, or whether they are also prevalent in peripheral immune cells. The researchers detected artificial signatures in publicly available data of cells from the CNS as well as other cell types .
They started to wonder whether findings reported in those studies fully reflect the in vivo status of the analyzed cells. "In this era of 'big data,' such ex vivo transcriptional alterations constitute a major technical challenge for many studies," says Mulenge. To avoid this, Mulenge adopted an alternative method called ribosomal tagging, or RiboTag in short.
Instead of sorting th.