Physiological normoxia and absence of EGF is required for the long-term propagation of anterior neural precursors from human pluripotent cells

Widespread use of human pluripotent stem cells (hPSCs) to study neuronal physiology and function is hindered by the ongoing need for specialist expertise in converting hPSCs to neural precursor cells (NPCs). Here, we describe a new methodology to generate cryo-preservable hPSC-derived NPCs that retain an anterior identity and are propagatable long-term prior to terminal differentiation, thus abrogating regular de novo neuralization. Key to achieving passagable NPCs without loss of identity is the combination of both absence of EGF and propagation in physiological levels (3%) of O2. NPCs generated in this way display a stable long-term anterior forebrain identity and importantly retain developmental competence to patterning signals. Moreover, compared to NPCs maintained at ambient O2 (21%), they exhibit enhanced uniformity and speed of functional maturation, yielding both deep and upper layer cortical excitatory neurons. These neurons display multiple attributes including the capability to form functional synapses and undergo activity-dependent gene regulation. The platform described achieves long-term maintenance of anterior neural precursors that can give rise to forebrain neurones in abundance, enabling standardised functional studies of neural stem cell maintenance, lineage choice and neuronal functional maturation for neurodevelopmental research and disease-modelling

Cellular energy metabolism, trans-plasma and trans-mitochondrial membrane potentials, and pH gradients in mouse neuroblastoma

A method for quantitative evaluation of transmembrane electrical potential and pH gradients across a subcellular compartment in an intact cell is presented. This approach has been applied in studies of mouse neuroblastoma C-1300 clone NB41A3, in which the transmembrane electrical potential and pH gradients and the mitochondrial volume percent have been determined. Membrane potentials and pH gradients were measured by two different methods. Equilibrium distributions of [(3)H]triphenylmethyl phosphonium and [(14)C]-thiocyanate ions gave calculated apparent membrane potentials of -77.0 and -29.6 mV, respectively, at 20-25°C; a value of -60.8 mV was obtained from microelectrode measurements. Equilibrium distributions of weak acids ([(14)C]trimethylacetic acid and 5,5-di[(14)C]methyl-2,4-oxazolidine-dione) and of weak bases ([(14)C]dimethylamine and [(14)C]trimethylamine) gave calculated upper and lower limits of the pH gradient (Δ pH = pH(e) - pH(i)) of -0.14 and -0.21 pH unit, respectively. The microelectrode measurements showed that the intracellular pH is within 0.1 of a pH unit or less of the extracellular pH over the extracellular pH range of 7.35-6.85. The mitochondrial volume percent calculated on the basis of the measured cytochrome c content is 5.6 ± 1.2% and compares well with estimates of 5.4 ± 1.1% obtained from 25 electron micrographs. Measurements of the cellular energetic parameters gave values within the range found in other cells and perfused organs. Comparison of the results of the microelectrode and equilibrium measurements permits estimates of the electrical potential and pH gradients across the mitochondrial membrane (mitochondria-to-cytoplasm gradients) to be made and suggests that the trans-mitochondrial membrane protonmotive force in the intact cell cannot be greater than -143 mV