Quantitative Live Imaging of Human Embryonic Stem Cell Derived Neural Rosettes Reveals Structure-Function Dynamics Coupled to Cortical Development.

Neural stem cells (NSCs) are progenitor cells for brain development, where cellular spatial composition (cytoarchitecture) and dynamics are hypothesized to be linked to critical NSC capabilities. However, understanding cytoarchitectural dynamics of this process has been limited by the difficulty to...

Full description

Bibliographic Details
Main Authors: Omer Ziv, Assaf Zaritsky, Yakey Yaffe, Naresh Mutukula, Reuven Edri, Yechiel Elkabetz
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2015-10-01
Series:PLoS Computational Biology
Online Access:http://europepmc.org/articles/PMC4608579?pdf=render
id doaj-1b967ed9b7104e1192077a76419c176b
record_format Article
spelling doaj-1b967ed9b7104e1192077a76419c176b2020-11-25T01:52:56ZengPublic Library of Science (PLoS)PLoS Computational Biology1553-734X1553-73582015-10-011110e100445310.1371/journal.pcbi.1004453Quantitative Live Imaging of Human Embryonic Stem Cell Derived Neural Rosettes Reveals Structure-Function Dynamics Coupled to Cortical Development.Omer ZivAssaf ZaritskyYakey YaffeNaresh MutukulaReuven EdriYechiel ElkabetzNeural stem cells (NSCs) are progenitor cells for brain development, where cellular spatial composition (cytoarchitecture) and dynamics are hypothesized to be linked to critical NSC capabilities. However, understanding cytoarchitectural dynamics of this process has been limited by the difficulty to quantitatively image brain development in vivo. Here, we study NSC dynamics within Neural Rosettes--highly organized multicellular structures derived from human pluripotent stem cells. Neural rosettes contain NSCs with strong epithelial polarity and are expected to perform apical-basal interkinetic nuclear migration (INM)--a hallmark of cortical radial glial cell development. We developed a quantitative live imaging framework to characterize INM dynamics within rosettes. We first show that the tendency of cells to follow the INM orientation--a phenomenon we referred to as radial organization, is associated with rosette size, presumably via mechanical constraints of the confining structure. Second, early forming rosettes, which are abundant with founder NSCs and correspond to the early proliferative developing cortex, show fast motions and enhanced radial organization. In contrast, later derived rosettes, which are characterized by reduced NSC capacity and elevated numbers of differentiated neurons, and thus correspond to neurogenesis mode in the developing cortex, exhibit slower motions and decreased radial organization. Third, later derived rosettes are characterized by temporal instability in INM measures, in agreement with progressive loss in rosette integrity at later developmental stages. Finally, molecular perturbations of INM by inhibition of actin or non-muscle myosin-II (NMII) reduced INM measures. Our framework enables quantification of cytoarchitecture NSC dynamics and may have implications in functional molecular studies, drug screening, and iPS cell-based platforms for disease modeling.http://europepmc.org/articles/PMC4608579?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Omer Ziv
Assaf Zaritsky
Yakey Yaffe
Naresh Mutukula
Reuven Edri
Yechiel Elkabetz
spellingShingle Omer Ziv
Assaf Zaritsky
Yakey Yaffe
Naresh Mutukula
Reuven Edri
Yechiel Elkabetz
Quantitative Live Imaging of Human Embryonic Stem Cell Derived Neural Rosettes Reveals Structure-Function Dynamics Coupled to Cortical Development.
PLoS Computational Biology
author_facet Omer Ziv
Assaf Zaritsky
Yakey Yaffe
Naresh Mutukula
Reuven Edri
Yechiel Elkabetz
author_sort Omer Ziv
title Quantitative Live Imaging of Human Embryonic Stem Cell Derived Neural Rosettes Reveals Structure-Function Dynamics Coupled to Cortical Development.
title_short Quantitative Live Imaging of Human Embryonic Stem Cell Derived Neural Rosettes Reveals Structure-Function Dynamics Coupled to Cortical Development.
title_full Quantitative Live Imaging of Human Embryonic Stem Cell Derived Neural Rosettes Reveals Structure-Function Dynamics Coupled to Cortical Development.
title_fullStr Quantitative Live Imaging of Human Embryonic Stem Cell Derived Neural Rosettes Reveals Structure-Function Dynamics Coupled to Cortical Development.
title_full_unstemmed Quantitative Live Imaging of Human Embryonic Stem Cell Derived Neural Rosettes Reveals Structure-Function Dynamics Coupled to Cortical Development.
title_sort quantitative live imaging of human embryonic stem cell derived neural rosettes reveals structure-function dynamics coupled to cortical development.
publisher Public Library of Science (PLoS)
series PLoS Computational Biology
issn 1553-734X
1553-7358
publishDate 2015-10-01
description Neural stem cells (NSCs) are progenitor cells for brain development, where cellular spatial composition (cytoarchitecture) and dynamics are hypothesized to be linked to critical NSC capabilities. However, understanding cytoarchitectural dynamics of this process has been limited by the difficulty to quantitatively image brain development in vivo. Here, we study NSC dynamics within Neural Rosettes--highly organized multicellular structures derived from human pluripotent stem cells. Neural rosettes contain NSCs with strong epithelial polarity and are expected to perform apical-basal interkinetic nuclear migration (INM)--a hallmark of cortical radial glial cell development. We developed a quantitative live imaging framework to characterize INM dynamics within rosettes. We first show that the tendency of cells to follow the INM orientation--a phenomenon we referred to as radial organization, is associated with rosette size, presumably via mechanical constraints of the confining structure. Second, early forming rosettes, which are abundant with founder NSCs and correspond to the early proliferative developing cortex, show fast motions and enhanced radial organization. In contrast, later derived rosettes, which are characterized by reduced NSC capacity and elevated numbers of differentiated neurons, and thus correspond to neurogenesis mode in the developing cortex, exhibit slower motions and decreased radial organization. Third, later derived rosettes are characterized by temporal instability in INM measures, in agreement with progressive loss in rosette integrity at later developmental stages. Finally, molecular perturbations of INM by inhibition of actin or non-muscle myosin-II (NMII) reduced INM measures. Our framework enables quantification of cytoarchitecture NSC dynamics and may have implications in functional molecular studies, drug screening, and iPS cell-based platforms for disease modeling.
url http://europepmc.org/articles/PMC4608579?pdf=render
work_keys_str_mv AT omerziv quantitativeliveimagingofhumanembryonicstemcellderivedneuralrosettesrevealsstructurefunctiondynamicscoupledtocorticaldevelopment
AT assafzaritsky quantitativeliveimagingofhumanembryonicstemcellderivedneuralrosettesrevealsstructurefunctiondynamicscoupledtocorticaldevelopment
AT yakeyyaffe quantitativeliveimagingofhumanembryonicstemcellderivedneuralrosettesrevealsstructurefunctiondynamicscoupledtocorticaldevelopment
AT nareshmutukula quantitativeliveimagingofhumanembryonicstemcellderivedneuralrosettesrevealsstructurefunctiondynamicscoupledtocorticaldevelopment
AT reuvenedri quantitativeliveimagingofhumanembryonicstemcellderivedneuralrosettesrevealsstructurefunctiondynamicscoupledtocorticaldevelopment
AT yechielelkabetz quantitativeliveimagingofhumanembryonicstemcellderivedneuralrosettesrevealsstructurefunctiondynamicscoupledtocorticaldevelopment
_version_ 1724991869474045952