Developmental and Functional Nature of Human iPSC Derived Motoneurons

One of the major functional properties of the mature motoneuron is its ability to generate and conduct signals from the central nervous system (CNS) to the peripheral muscle cell in order to induce and control muscle contraction [1]. The molecular composition of the neuromuscular junction (NMj) is crucial for its function and maintenance whereas dysregulation of endplate physiology is considered to be involved in denervation of the muscle cells and subsequent motoneuron degeneration [2, 3]. At early developmental stages of the neuron-to-muscle synaptogenesis, a large number of spinal motoneurons die, presumably because they fail to form adequate connections with the target muscle. In fact, if the limb bud (the precursor of limb muscles) is removed before the formation of neuromuscular connections all the corresponding motoneurons eventually degenerate [4]. In vitro, various cell systems are utilized to search for developmental and functional characteristics of the motoneuron system. Both, primary cultures and stem cellderived motoneurons are used for various questions. Pluripotent embryonic stem cells [5] from mouse and human origin [6] had been shown to be able to generate motoneurons in vitro. Since the first discovery and invention of the induced pluripotent stem cell (iPSC) technology by Takahashi and Yamanaka [7], it is now possible to analyze and study cell development and differentiation on the basis of a gene defect in patient specific settings [8, 9]. For comparison all these studies are crucially dependent upon the analysis of human cell differentiation, morphology and protein expression under