The protracted maturation of human ESC-derived interneurons

www.landesbioscience.com Cell Cycle 3129 In the cerebral cortex, GABAergic interneurons play critical roles in regulating the output of individual excitatory pyramidal neurons as well as synchronizing the outputs of pyramidal neuron ensembles. In both mice and humans, many cortical interneurons originate in a subcortical embryonic structure, the medial ganglionic eminence (MGE), and fall into 1 of 2 non-overlapping categories defined by their expression of either parvalbumin (PV) or somatostatin (SST). Deficits in either of these subpopulations have been implicated in a variety of neuropsychiatric disorders, including schizophrenia, autism and epilepsy. Thus, the derivation of these neurons from human stem cells is an invaluable advance to the study of the molecular mechanisms underlying the pathogenesis of cortical interneuron-related disorders in humans. Furthermore, cortical interneurons have the remarkable ability to survive, migrate and integrate into neonatal or adult CNS post-transplantation, making them attractive candidates for usage in cell-based therapies for neuropsychiatric disorders. Recently there has been a flourish of progress in generating cortical interneurons from both mouse and human embryonic stem cells (ESC)s. Much of this progress can be attributed to the use of BAC transgenic or homologous recombination approaches to insert the fluorescent reporter GFP under control of Nkx2.1 or Lhx6, transcription factors expressed in MGE progenitors or post-mitotic interneurons, respectively. Following the pioneering work of Sasai, Maroof et al. used an Lhx6-GFP mouse ESC line to demonstrate that mouse embryonic stem cells (mESCs) can be differentiated into both PV+ and SST+ cortical interneurons. Importantly, 30 d after transplantation into neonatal neocortex, these cells were found to display the typical fast-spiking or burst-spiking responses to depolarizing current expected for PV and SSTexpressing interneurons, respectively. Similar results inducing MGE fates were achieved using a FoxG1::Venus ESC line. However, at this point no study of stemcell derived interneurons has demonstrated their capacity to show native-like axonal targeting properties, such as a tendency to target the cell body and proximal dendrites of pyramidal neurons for PV+ interneurons, or the tendency to target more distal dendrites for SST+ interneurons. While studies differentiating human stem cells into putative cortical interneurons have yet to demonstrate either subgroup-selective axon targeting or spiking properties, major progress has recently been made using a human ES line in which GFP has been knocked into the Nkx2.1 locus. Since the initial study of this line used a relatively low-efficiency, retinoic-acid based protocol to generate SST+, interneuron-like cells identified after culture with mouse cortical cells, 3 recent papers have used this line in demonstrations of cortical interneuron differentiation. While a detailed comparison of these studies is well beyond the scope of this piece, a summary of their collective progress and shortcomings is warranted. Key aspects of progress include: (1) the efficient generation of Nkx2.1-Foxg1 pallidal telencephalon; (2) the generation of cells that express cortical interneuron markers within extensions of the initial culture; (3) migration from MGE to cortex on mouse slices; (4) PV and SST differentiation, as well as input and output synaptogenesis in co-cultures with dissociated cells from mouse cortex or on cortical astrocytes. Of note, interneuron maturation appeared to occur far more rapidly for human MGE-like progenitors when cultured on the dissociated cortex of mouse embryos (4 weeks) vs. cortical astrocytes (20–30 weeks). That said, a direct and carefully controlled comparison would be needed to confirm this seemingly important difference; (5) tangential migration following transplant into neonatal neocortex, with survival up to 7 mo, and evidence that the transplanted neurons receive excitatory inputs. Finally, an additional study used a protocol similar to those implemented above to generate Nkx2.1+ cells that, following transplantation into adult mouse hippocampus, altered hippocampal electrophysiology and function. However, while promising, in this study transplantation included cholinergic and GABAergic neurons, and interneuronselective differentiation of the GABAergic neurons was not demonstrated. Collectively, these studies lay a solid foundation for using human stem cells in the study of ventral forebrain progenitor fate determination, as well as the initial fate determination of GABAergic interneurons, their intrinsic mechanisms of tangential migration, migration guidance, and their input/ouptut synaptogenesis. Each of the above areas has associations to neurodevelopmental disorders involving specific genes and proteins. Despite these advances, major shortcomings to realizing the full potential of human stem cellderived cortical interneurons remain. Key among these is the protracted maturation