A number of developmental and adult brain disorders are associated with midbrain dopamine neurons (mDNs), including Parkinson's disease (PD), schizophrenia, autism, dyskinesias, and drug addiction. Thus, the fundamental mechanisms that regulate the development and function of these cells are of great import. In prior studies, we and others have investigated basic regulatory processes, such as regulation of the expression of key enzymes in the dopamine biosynthetic pathway in the context of dopamine neuron development, function, and survival. However, it is clear from these studies that there is a high level of complexity governing all of these processes. For instance, at least 2 transcription factors, Nurr1 and Pitx3, function synergistically to govern expression of late developmental mDN markers in simplified ES cell-based culture models. More recently, in preliminary data and a published manuscript, my lab has found evidence of an added layer of complexity involving post-transcriptional regulation by microRNAs (miRNAs) in the context of mDN development and function. miRNAs are evolutionarily conserved, 18-25 nucleotide non-protein coding transcripts that play an important function in post-transcriptional regulation of gene expression during development. Specifically, we identified microRNA, miR-133b that is enriched in mDNs and functions within a regulatory feedback circuit with Pitx3. Here we propose to more broadly define the level of complexity of gene expression regulation by miRNA in mDNs, and to determine the function of these forms of regulation in vivo. Ultimately, such forms of regulation are likely to play a role in mDN-associated diseases, and furthermore manipulations of these mechanisms offer potential avenues for therapies. We wish to test two hypotheses: 1. miRNAs function in the regulation of mDNs, both within feedback circuits with mDN transcription factors and by the direct regulation of key mDN targets. 2. Such regulatory networks play functionally important roles in mDNs in vivo.
A number of developmental and adult brain disorders are associated with midbrain dopaminergic neurons (mDNs), including Parkinson's disease (PD), schizophrenia, autism, dyskinesias, and drug addiction. Thus, the fundamental mechanisms that regulate the development and function of these cells are of great import. Here we propose to unravel the complex molecular regulatory signals that determine the development and function of midbrain dopamine neurons. We focus on the role of microRNAs, which are short RNA molecules that regulate the expression of key dopaminergic neuron genes. We initially use simplified model systems, including embryonic stem cell derived dopamine neurons and primary neuron cultures, which allow for a detailed molecular analysis. Ultimately, we extend these studies to confirming the role of regulatory molecular circuits in the intact behaving rodent.
|Rhinn, Herve; Fujita, Ryousuke; Qiang, Liang et al. (2013) Integrative genomics identifies APOE ?4 effectors in Alzheimer's disease. Nature 500:45-50|
|MacLeod, David A; Rhinn, Herve; Kuwahara, Tomoki et al. (2013) RAB7L1 interacts with LRRK2 to modify intraneuronal protein sorting and Parkinson's disease risk. Neuron 77:425-39|
|Inoue, Keiichi; Rispoli, Joanne; Yang, Lichuan et al. (2013) Coordinate regulation of mature dopaminergic axon morphology by macroautophagy and the PTEN signaling pathway. PLoS Genet 9:e1003845|
|Doege, Claudia A; Inoue, Keiichi; Yamashita, Toru et al. (2012) Early-stage epigenetic modification during somatic cell reprogramming by Parp1 and Tet2. Nature 488:652-5|
|Inoue, Keiichi; Rispoli, Joanne; Kaphzan, Hanoch et al. (2012) Macroautophagy deficiency mediates age-dependent neurodegeneration through a phospho-tau pathway. Mol Neurodegener 7:48|
|Rhinn, Herve; Qiang, Liang; Yamashita, Toru et al. (2012) Alternative ?-synuclein transcript usage as a convergent mechanism in Parkinson's disease pathology. Nat Commun 3:1084|
|Qiang, Liang; Fujita, Ryousuke; Yamashita, Toru et al. (2011) Directed conversion of Alzheimer's disease patient skin fibroblasts into functional neurons. Cell 146:359-71|
|Abeliovich, Asa; Doege, Claudia A (2009) Reprogramming therapeutics: iPS cell prospects for neurodegenerative disease. Neuron 61:337-9|
|Hammond, Rachel; Blaess, Sandra; Abeliovich, Asa (2009) Sonic hedgehog is a chemoattractant for midbrain dopaminergic axons. PLoS One 4:e7007|
|Kim, Jongpil; Inoue, Keiichi; Ishii, Jennifer et al. (2007) A MicroRNA feedback circuit in midbrain dopamine neurons. Science 317:1220-4|