Lorraine Iacovitti, PhD

Contact Dr. Iacovitti

900 Walnut St.
Suite 462
Philadelphia, PA 19107

215-955-8118
215-955-2992 fax

Can we Develop Dopamine Neurons from Stem Cells for the Therapeutic Treatment of Parkinson's Disease?

Research in my laboratory is aimed at understanding how neurons differentiate into dopamine neurons during development of the brain and how that information may be useful for the treatment of neurodegenerative diseases such as Parkinson's. A major goal of our studies has been defining the key fate determinant genes and lineage stages in the development of human dopamine neurons. Our hope is that an understanding of those mechanisms that first direct expression of neurotransmitter genes during differentiation will provide a molecular blueprint that can be used to intentionally target the differentiation of cells, such as human embryonic stem or precursor cells, toward that phenotype. Using an approach that combines cell culture and genetic engineering, our aim is to induce dopaminergic traits in human stem/progenitor cells and devise ways to amplify and purify prospective human dopamine neurons for study after transplantation into rat and monkey models of Parkinson's disease.

In our laboratory, we use a multidisciplinary approach, employing tissue culture (primary and cell lines), molecular (qPCR, microarray, gene cloning, transfection, transduction), anatomical (immunocytochemistry, confocal) biochemical (HPLC), surgical (stereotaxic brain surgery, arterial occlusion), imaging (PET, spect) and behavioral (sensory and motor skills tests).

The overall goal of our studies is take what we have learned about the differentiation of dopamine neurons from human stem cells and translate that into a cell replacement treatment for Parkinson's disease.

Publications

Most recent Peer-reviewed Publications

1. Evolutionary conservation of an atypical glucocorticoid-responsive element in the human tyrosine hydroxylase gene
2. BMP and TGF-Β pathway mediators are critical upstream regulators of Wnt signaling during midbrain dopamine differentiation in human pluripotent stem cells
3. Tracking Transplanted Bone Marrow Stem Cells and Their Effects in the Rat MCAO Stroke Model
4. Gremlin is a novel VTA derived neuroprotective factor for dopamine neurons
5. Changes in host blood factors and brain glia accompanying the functional recovery after systemic administration of bone marrow stem cells in ischemic stroke rats
6. Cell-autonomous alteration of dopaminergic transmission by wild type and mutant (ΔE) TorsinA in transgenic mice
7. VTA neurons show a potentially protective transcriptional response to MPTP
8. Dopaminergic neurons derived from human induced pluripotent stem cells survive and integrate into 6-OHDA-lesioned rats
9. Heterotopically transplanted CVO neural stem cells generate neurons and migrate with SVZ cells in the adult mouse brain
10. Genetic ablation of caveolin-1 increases neural stem cell proliferation in the subventricular zone (SVZ) of the adult mouse brain
11. Functional heterogeneity at dopamine release sites
12. Human amniotic fluid stem cells do not differentiate into dopamine neurons in vitro or after transplantation in vivo
13. Circumventricular organs: A novel site of neural stem cells in the adult brain
14. The role of Lmx1a in the differentiation of human embryonic stem cells into midbrain dopamine neurons in culture and after transplantation into a Parkinson's disease model
15. Expression of the LRRK2 gene in the midbrain dopaminergic neurons of the substantia nigra
16. Transcription and epigenetic profile of the promoter, first exon and first intron of the human tyrosine hydroxylase gene
17. A protocol for the differentiation of human embryonic stem cells into dopaminergic neurons using only chemically defined human additives: Studies in vitro and in vivo
18. Adult human bone marrow stromal spheres express neuronal traits in vitro and in a rat model of Parkinson's disease
19. Tyrosine hydroxylase gene regulation in human neuronal progenitor cells does not depend on Nurr1 as in the murine and rat systems
20. Purified mouse dopamine neurons thrive and function after transplantation into brain but require novel glial factors for survival in culture.

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