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conferenceseries

.com

Volume 7, Issue 4 (Suppl)

J Clin Exp Pathol, an open access journal

ISSN: 2161-0681

Euro Pathology 2017

August 02-03, 2017

13

th

EUROPEAN PATHOLOGY CONGRESS

August 02-03, 2017 Milan, Italy

Recapitulating malformations of cortical development via induced pluripotent stem cell technology

Anita Huttner

Yale University School of Medicine, USA

Background:

Progress in our understanding of somatic cell reprogramming, particularly the isolation and characterization of human

induced pluripotent stem cells (iPSCs) opened new avenues for modeling human disease. iPSCs allow the generation of large numbers

of genetically modifiable cells specific to the underlying human genetic background, and form an unparalleled opportunity to gain

new insight into disease pathophysiology. This will further lay the foundation for the development of patient specific pharmacological

assays and/or stem cell based therapies. We focused on Walker Warburg Syndrome (WWS), a rare and severe form of lissencephaly

paired with congenital muscular dystrophy. Most children die before the age of three years. Several genes have been implicated in

the etiology of this syndrome, however, to this date the pathogenesis is poorly understood. In addition, none of the animal models

appears to faithfully reflect the human condition. Patient derived IPSCs, however, allow the targeted differentiation of cells into tissue

specific phenotypes of brain and muscle, and thus, provide an assay for the recapitulation of disease specific pathophysiology.

Design:

iPSCs lines were derived from skin biopsy specimens of patients withWWS and normal age matched controls. The generation

of iPSCs followed established protocols using nucleofection (Amaxa system) of episomal plasmids expressing OCT3/4, SHp53, SOX2,

KLF4, LIN28, and MYC. The cells were grown in culture and differentiated into all lineages of the human brain. Furthermore, since

one of the hallmark features of lissencephaly is altered neuronal activity, this system forms a unique opportunity to monitor electrical

activity of iPSC derived neurons.

Result:

Directed differentiation of iPSCs into neuronal precursors was demonstrated

in vitro

with antibodies for CNS phenotypes,

like GFAP, TUJ1, Tbr1/2. Furthermore, neuronal activity was monitored with ultrasensitive fluorescent protein calcium sensors

(GCaMP6) and showed altered neuronal activity in neurons derived from patients versus normal controls.

Conclusion:

This model allows the phenotypic recapitulation of complex neurogenetic traits, and provides insights into the

pathophysiology of human forms of malformations of cortical development. The combination of technologies offers a unique

opportunity to model human neurological disease and hold promise for the development of new treatment strategies.

Biography

Anita Huttner started her career as MD at University of Erlangen-Nurnberg, Germany in 1998. She worked as Clinical Fellow at Yale Medical School-Yale-New

Haven Hospital & Harvard Medical School-Brigham and Women's Hospital and Children's Hospital. She has completed her Pre-/Post-doctoral fellow at National

Institutes of Health. Currently, she is working as an Associate Professor of Pathology at Yale University School of Medicine.

anita.huttner@yale.edu

Anita Huttner, J Clin Exp Pathol 2017, 7:4(Suppl)

DOI: 10.4172/2161-0681-C1-037