Familial dysautonomia (FD) is a devastating developmental and progressive peripheral neuropathy caused by a mutation in the gene inhibitor of kappa B kinase complex-associated protein (IKBKAP). To identify the cellular and molecular mechanisms that cause FD, we generated mice in which Ikbkap expression is ablated in the peripheral nervous system and identify the steps in peripheral nervous system development that are Ikbkap-dependent. We show that Ikbkap is not required for trunk neural crest migration or pathfinding, nor for the formation of dorsal root or sympathetic ganglia, or the adrenal medulla. Instead, Ikbkap is essential for the second wave of neurogenesis during which the majority of tropomyosin-related kinase A (TrkA + ) nociceptors and thermoreceptors arise. In its absence, approximately half the normal complement of TrkA + neurons are lost, which we show is partly due to p53-mediated premature differentiation and death of mitotically-active progenitors that express the paired-box gene Pax3 and give rise to the majority of TrkA + neurons. By the end of sensory development, the number of TrkC neurons is significantly increased, which may result from an increase in Runx3 + cells. Furthermore, our data demonstrate that TrkA + (but not TrkC + ) sensory and sympathetic neurons undergo exacerbated Caspase 3-mediated programmed cell death in the absence of Ikbkap and that this death is not due to a reduction in nerve growth factor synthesis. In summary, these data suggest that FD does not result from a failure in trunk neural crest migration, but rather from a critical function for Ikbkap in TrkA progenitors and TrkA + neurons.H ereditary sensory and autonomic neuropathies (HSANs) are a group of five phenotypically diverse but overlapping disorders of the peripheral nervous system (PNS) that result from mutations in 12 distinct genes (1). HSAN type 3, or familial dysautonomia (FD) (also called Riley-Day syndrome), results from an intronic mutation (IVS20 + 6T > C; 99.5% of patients) in a gene called inhibitor of kappa B kinase complex-associated protein or IKBKAP, causing mis-splicing and subsequent tissuespecific reductions in IKAP protein (2, 3). FD is marked by tachycardia, blood pressure lability, autonomic vomiting "crises," decreased pain and temperature sensation, and commonly death during early adulthood (4). The function of IKAP in the nervous system is unclear, nor is it understood why deletions in this broadly expressed gene primarily devastate the PNS. The earliest pathology study, performed on a 2-y-old child with FD, showed that ∼90% of cells in the dorsal root and sympathetic ganglia (SG) were missing (5). To identify IKAP's function in the developing PNS, we first need to establish the steps in which it is essential.The vertebrate PNS derives primarily from the neural crest, a multipotent, heterogeneous cell population that delaminates from the neural tube and migrates throughout the embryo (6). Those neural crest cells that stop laterally to the neural tube give rise to the chain of sensory...
