Oligodendrocyte progenitor cells become regionally diverse and heterogeneous with age

Oligodendrocyte progenitor cells (OPCs), which differentiate into myelinating oligodendrocytes during central nervous system (CNS) development, are the main proliferative cells in the adult brain. OPCs are conventionally considered a homogeneous population, particularly with respect to their electrophysiological properties, but this has been debated. We show, by using single-cell electrophysiological recordings, that OPCs start out as a homogeneous population, but become functionally heterogeneous, varying both within and between brain regions and with age. These electrophysiological changes in OPCs correlate with the differentiation potential of OPCs; thus, they may underlie the differentiational differences in OPCs between regions and likewise differentiation failure with age.We acknowledge the support of the Wellcome - MRC Cambridge Stem Cell Institute core facility managers, in particular for this work Dr Maike Paramor and Miss Victoria Murray with RNA sequencing, and all staff members of the University Biomedical Services (UBS). This project has received funding from: the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement No 771411; R.T.K, K.A.E); the Wellcome Trust, a Research Career Development Fellowship (R.T.K. and K.A.E. 091543/Z/10/Z) and a Studentship (102160/Z/13/Z; Y.K); The Paul G Allen Frontiers Group, Allen Distinguished Investigator Award (12076, R.T.K., D.K.V.); The Medical Research Council, a studentship (S.O.S.); The Gates Foundation, a Gates Scholarship (S.S.), The Biotechnology and Biological Sciences Research Council, a studentship (S.A.); Homerton College Cambridge, a Junior Research Fellowship (D.K.V); The UK MS Society, a Cambridge Myelin Repair Centre grant (50; R.T.K, O.D.F.); The Fonds de recherche du Québec-Santé, a scholarship (Y.K.); The Cambridge Commonwealth European & International Trust, a scholarship (Y.K.); and the Lister Institute, a Research Prize (R.T.K., K.A.E, SOS)

Early maturation and distinct tau pathology in induced pluripotent stem cell-derived neurons from patients with MAPT mutations.

Tauopathies, such as Alzheimer's disease, some cases of frontotemporal dementia, corticobasal degeneration and progressive supranuclear palsy, are characterized by aggregates of the microtubule-associated protein tau, which are linked to neuronal death and disease development and can be caused by mutations in the MAPT gene. Six tau isoforms are present in the adult human brain and they differ by the presence of 3(3R) or 4(4R) C-terminal repeats. Only the shortest 3R isoform is present in foetal brain. MAPT mutations found in human disease affect tau binding to microtubules or the 3R:4R isoform ratio by altering exon 10 splicing. We have differentiated neurons from induced pluripotent stem cells derived from fibroblasts of controls and patients with N279K and P301L MAPT mutations. Induced pluripotent stem cell-derived neurons recapitulate developmental tau expression, showing the adult brain tau isoforms after several months in culture. Both N279K and P301L neurons exhibit earlier electrophysiological maturation and altered mitochondrial transport compared to controls. Specifically, the N279K neurons show abnormally premature developmental 4R tau expression, including changes in the 3R:4R isoform ratio and AT100-hyperphosphorylated tau aggregates, while P301L neurons are characterized by contorted processes with varicosity-like structures, some containing both alpha-synuclein and 4R tau. The previously unreported faster maturation of MAPT mutant human neurons, the developmental expression of 4R tau and the morphological alterations may contribute to disease development.This work was supported by CurePSP, The Cambridge Newton Trust, The William Scholl Foundation and the NIHR Cambridge Biomedical Research Centre (BRC). The contribution of the NC3Rs CRACK IT- Alzheimer’s Research UK is also acknowledged. S.A. holds a BBSRC studentship. A.G.-R. holds a Michael Foster Studentship. O.P. acknowledges BBSRC support. L.V. is supported by the ERC starting grant relieve-IMDs. S.O. and T.L. acknowledge support by the Irish Institute of Clinical Neuroscience. R.T.K. is supported by the Welcome Trust grant 091543/Z/10/Z and D.G. and M.dC.V.-H. are supported by Wellcome Trust grant #098051.This is the final version. It was first published by OUP at http://dx.doi.org/10.1093/brain/awv22

Gene Editing in Rat Embryonic Stem Cells to Produce In Vitro Models and In Vivo Reporters

Rat embryonic stem cells (ESCs) offer the potential for sophisticated genome engineering in this valuable biomedical model species. However, germline transmission has been rare following conventional homologous recombination and clonal selection. Here, we used the CRISPR/Cas9 system to target genomic mutations and insertions. We first evaluated utility for directed mutagenesis and recovered clones with biallelic deletions in Lef1. Mutant cells exhibited reduced sensitivity to glycogen synthase kinase 3 inhibition during self-renewal. We then generated a non-disruptive knockin of dsRed at the Sox10 locus. Two clones produced germline chimeras. Comparative expression of dsRed and SOX10 validated the fidelity of the reporter. To illustrate utility, live imaging of dsRed in neonatal brain slices was employed to visualize oligodendrocyte lineage cells for patch-clamp recording. Overall, these results show that CRISPR/Cas9 gene editing technology in germline-competent rat ESCs is enabling for in vitro studies and for generating genetically modified rats

Surpassing light-induced cell damage in vitro with novel cell culture media

AbstractLight is extensively used to study cells in real time (live cell imaging), separate cells using fluorescence activated cell sorting (FACS) and control cellular functions with light sensitive proteins (Optogenetics). However, photo-sensitive molecules inside cells and in standard cell culture media generate toxic by-products that interfere with cellular functions and cell viability when exposed to light. Here we show that primary cells from the rat central nervous system respond differently to photo-toxicity, in that astrocytes and microglia undergo morphological changes, while in developing neurons and oligodendrocyte progenitor cells (OPCs) it induces cellular death. To prevent photo-toxicity and to allow for long-term photo-stimulation without causing cellular damage, we formulated new photo-inert media called MEMO and NEUMO, and an antioxidant rich and serum free supplement called SOS. These new media reduced the detrimental effects caused by light and allowed cells to endure up to twenty times more light exposure without adverse effects, thus bypassing the optical constraints previously limiting experiments.</jats:p