Identifying the optimal developmental age of human pluripotent stem cell-derived midbrain dopaminergic progenitors for transplantation in a rodent model of Parkinson's disease.

Donor cell age can have a significant impact on transplantation outcomes. Despite the rapid advancement of human pluripotent stem cell (hPSC)-derived dopaminergic (DA) progenitors to the clinic for transplantation into Parkinson's Disease (PD), surprisingly limited data exists regarding the influence of cellular age on neural graft survival, composition, and integration. Here we examined the impact of transplanting ventral midbrain (VM) progenitors at varying days of differentiation (from day 13-30) into a rodent PD model, comparing two hPSC lines (an embryonic and an induced pluripotent cell line, hESC and hiPSC, respectively). Both hPSC lines expressed GFP under the promoter PITX3 enabling specific tracking of graft-derived DA neurons. Post-mortem analysis at 6 months revealed larger grafts from Day19 (D19), D22 and D25 progenitors, yet contained a higher proportion of non-DA and poorly specified (FOXA2-) cells. While D13 and D30 progenitors yielded smaller grafts. D13-derived grafts had the highest DA neuron proportion and proportionally more GIRK2+ DA neurons, the subpopulation critical for motor function. These younger progenitor grafts maintained their capacity to innervate developmentally relevant DA targets, with increased innervation capacity per DA neuron, collectively resulting in restoration of motor deficits with equal or greater proficiency than older donor cells. While donor age effects were reproducible for a given hPSC line and trends were similar between the two hPSC lines, grafts of D13 hiPSC-derived progenitors showed a 6-fold greater density of DA neurons compared to D13 hESC-derived grafts, highlighting between-line variability. These findings show that hPSC-derived VM donor age has a direct impact on graft survival, composition and maturation, and that careful assessment, on a line-to-line basis is required prior to translation.

Three-dimensional imaging of human stem cells using soft X-ray tomography.

Three-dimensional imaging of human stem cells using transmission soft X-ray tomography (SXT) is presented for the first time. Major organelle types--nuclei, nucleoli, mitochondria, lysosomes and vesicles--were discriminated at approximately 50 nm spatial resolution without the use of contrast agents, on the basis of measured linear X-ray absorption coefficients and comparison of the size and shape of structures to transmission electron microscopy (TEM) images. In addition, SXT was used to visualize the distribution of a cell surface protein using gold-labelled antibody staining. We present the strengths of SXT, which include excellent spatial resolution (intermediate between that of TEM and light microscopy), the lack of the requirement for fixative or contrast agent that might perturb cellular morphology or produce imaging artefacts, and the ability to produce three-dimensional images of cells without microtome sectioning. Possible applications to studying the differentiation of human stem cells are discussed.