Julius A. Steinbeck

A rosette-type, self-renewing human ES cell-derived neural stem cell with potential for in vitro instruction and synaptic integration

An intriguing question in human embryonic stem cell (hESC) biology is whether these pluripotent cells can give rise to stably expandable somatic stem cells, which are still amenable to extrinsic fate instruction. Here, we present a pure population of long-term self-renewing rosette-type hESC-derived neural stem cells (lt-hESNSCs), which exhibit extensive self-renewal, clonogenicity, and stable neurogenesis. Although lt-hESNSCs show a restricted expression of regional transcription factors, they retain responsiveness to instructive cues promoting the induction of distinct subpopulations, such as ventral midbrain and spinal cord fates. Using lt-hESNSCs as a donor source for neural transplantation, we provide direct evidence that hESC-derived neurons can establish synaptic connectivity with the mammalian nervous system. Combining long-term stability, maintenance of rosette-properties and phenotypic plasticity, lt-hESNSCs may serve as useful tool to study mechanisms of human NSC self-renewal, lineage segregation, and functional in vivo integration.

Store-operated calcium entry modulates neuronal network activity in a model of chronic epilepsy.

Store-operated Ca(2+) entry (SOCE) over the plasma membrane is activated by depletion of intracellular Ca(2+) stores and has only recently been shown to play a role in CNS processes like synaptic plasticity. However, the direct effect of SOCE on the excitability of neuronal networks in vitro and in vivo has never been determined. We confirmed the presence of SOCE and the expression of the calcium sensors STIM1 and STIM2, which convey information about the calcium load of the stores to channel proteins at the plasma membrane, in neurons and astrocytes. Inhibition of SOCE by pharmacological agents 2-APB and ML-9 reduced the steady-state neuronal Ca(2+) concentration, reduced network activity, and increased synchrony of primary neuronal cultures grown on multi-electrode arrays, which prompted us to elucidate the relative expression of STIM proteins in conditions of pathologic excitability. Both proteins were increased in brains of chronic epileptic rodents and strongly expressed in hippocampal specimens from medial temporal lobe epilepsy patients. Pharmacologic inhibition of SOCE in chronic epileptic hippocampal slices suppressed interictal spikes and rhythmized epileptic burst activity. Our results indicate that SOCE modulates the activity of neuronal networks in vitro and in vivo and delineates SOCE as a potential drug target.

Human embryonic stem cell-derived neurons establish region-specific, long-range projections in the adult brain

While the availability of pluripotent stem cells has opened new prospects for generating neural donor cells for nervous system repair, their capability to integrate with adult brain tissue in a structurally relevant way is still largely unresolved. We addressed the potential of human embryonic stem cell-derived long-term self-renewing neuroepithelial stem cells (lt-NES cells) to establish axonal projections after transplantation into the adult rodent brain. Transgenic and species-specific markers were used to trace the innervation pattern established by transplants in the hippocampus and motor cortex. In vitro, lt-NES cells formed a complex axonal network within several weeks after the initiation of differentiation and expressed a composition of surface receptors known to be instrumental in axonal growth and pathfinding. In vivo, these donor cells adopted projection patterns closely mimicking endogenous projections in two different regions of the adult rodent brain. Hippocampal grafts placed in the dentate gyrus projected to both the ipsilateral and contralateral pyramidal cell layers, while axons of donor neurons placed in the motor cortex extended via the external and internal capsule into the cervical spinal cord and via the corpus callosum into the contralateral cortex. Interestingly, acquisition of these region-specific projection profiles was not correlated with the adoption of a regional phenotype. Upon reaching their destination, human axons established ultrastructural correlates of synaptic connections with host neurons. Together, these data indicate that neurons derived from human pluripotent stem cells are endowed with a remarkable potential to establish orthotopic long-range projections in the adult mammalian brain.

Genome Editing in Neuroepithelial Stem Cells to Generate Human Neurons with High Adenosine‐Releasing Capacity

As a powerful regulator of cellular homeostasis and metabolism, adenosine is involved in diverse neurological processes including pain, cognition, and memory. Altered adenosine homeostasis has also been associated with several diseases such as depression, schizophrenia, or epilepsy. Based on its protective properties, adenosine has been considered as a potential therapeutic agent for various brain disorders. Since systemic application of adenosine is hampered by serious side effects such as vasodilatation and cardiac suppression, recent studies aim at improving local delivery by depots, pumps, or cell‐based applications. Here, we report on the characterization of adenosine‐releasing human embryonic stem cell‐derived neuroepithelial stem cells (long‐term self‐renewing neuroepithelial stem [lt‐NES] cells) generated by zinc finger nuclease (ZFN)‐mediated knockout of the adenosine kinase (ADK) gene. ADK‐deficient lt‐NES cells and their differentiated neuronal and astroglial progeny exhibit substantially elevated release of adenosine compared to control cells. Importantly, extensive adenosine release could be triggered by excitation of differentiated neuronal cultures, suggesting a potential activity‐dependent regulation of adenosine supply. Thus, ZFN‐modified neural stem cells might serve as a useful vehicle for the activity‐dependent local therapeutic delivery of adenosine into the central nervous system. Stem Cells Translational Medicine 2018;7:477–486