The regeneration of pattern following injury and the maintenance of form during normal cellular turnover requires the participation of adult stem cells. In order to understand and ultimately learn to control these processes for biomedical applications, it is necessary to identify the molecular mechanisms by which stem cells communicate with their neighbors. Such communication is needed for stem cells to know where, when, and how to differentiate. Because fundamental cellular control mechanisms are widely conserved, and because we believe fundamental progress can be made in systems that are amenable to the molecular investigation of a recognizable adult stem population, we propose study stem cell interactions in vivo by capitalizing on a powerful model system: the planarian Schmidtea mediterranea. These complex flatworms are able to replace any part of their body using a recognizable adult stem cell population: the neoblasts. This is an ideal system in which to investigate the molecular signals sent to and from neoblasts. In contrast and complement to the field's focus on biochemical factors, our lab studies roles of endogenous ion flows, and pH and voltage gradients in controlling cell proliferation, migration, and differentiation. We will test the hypothesis that a large component of the local and long-range signals controlling stem cell behavior within their environment is bioelectrical, consisting of the physiological results of specific ion channel and pump activity. We will characterize the involvement of several channels, pumps, and gap junctions in controlling stem cell positional information and their contribution during regeneration. We propose two main aims: 1) molecular validation (using RNAi) of several candidate channel and pump proteins involved in neoblast-mediated events, followed by their expression analysis and a detailed characterization of their roles in regeneration and remodeling; and 2) characterization of the bioelectrical properties of stem cells as they progress through the different phases of differentiation and development of functional techniques to control neoblast movement, proliferation, and differentiation in vivo. The expertise which our group has developed with this field in embryonic development and regeneration in several vertebrate and invertebrate systems will allow rapid and important progress to uncover novel aspects of stem cell regulation, and will result in the high-reward outcome of an entirely new set of controls of stem cell signaling, which ultimately will be used to drive biomedical applications aiming to induce regeneration in adult cells of the patient. This work is an ideal fit for the Cancer, Aging, and Biomedical Imaging and Bioengineering Institutes because we propose to use novel imaging and biophysical manipulation techniques to enable medical applications in which adult stem cells can be induced to properly replace aging, damaged, or cancerous tissue. Our work will lead to the understanding of how adult stem cells allow some animals to perfectly repair any part of their body. This information will be used to develop methods whereby regeneration of tissues, organs, and appendages may be induced in human patients following injury, aging, or tumor growth. ? ? ?

Agency
National Institute of Health (NIH)
Institute
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Type
Exploratory/Developmental Grants (R21)
Project #
7R21HD055850-03
Application #
7870045
Study Section
Development - 1 Study Section (DEV1)
Program Officer
Tasca, Richard J
Project Start
2007-05-07
Project End
2009-10-31
Budget Start
2008-11-01
Budget End
2009-10-31
Support Year
3
Fiscal Year
2008
Total Cost
$196,498
Indirect Cost
Name
Tufts University
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
073134835
City
Medford
State
MA
Country
United States
Zip Code
02155
Beane, Wendy Scott; Morokuma, Junji; Lemire, Joan M et al. (2013) Bioelectric signaling regulates head and organ size during planarian regeneration. Development 140:313-22
Adams, Dany S; Levin, Michael (2012) General principles for measuring resting membrane potential and ion concentration using fluorescent bioelectricity reporters. Cold Spring Harb Protoc 2012:385-97
Beane, Wendy S; Tseng, Ai-Sun; Morokuma, Junji et al. (2012) Inhibition of planar cell polarity extends neural growth during regeneration, homeostasis, and development. Stem Cells Dev 21:2085-94
Chernet, Brook T; Adams, Dany S; Levin, Michael (2012) Photoconversion for tracking the dynamics of cell movement in Xenopus laevis embryos. Cold Spring Harb Protoc 2012:683-90
Beane, Wendy S; Morokuma, Junji; Adams, Dany S et al. (2011) A chemical genetics approach reveals H,K-ATPase-mediated membrane voltage is required for planarian head regeneration. Chem Biol 18:77-89
Oviedo, Nestor J; Morokuma, Junji; Walentek, Peter et al. (2010) Long-range neural and gap junction protein-mediated cues control polarity during planarian regeneration. Dev Biol 339:188-99
Levin, Michael (2009) Bioelectric mechanisms in regeneration: Unique aspects and future perspectives. Semin Cell Dev Biol 20:543-56
Sundelacruz, Sarah; Levin, Michael; Kaplan, David L (2009) Role of membrane potential in the regulation of cell proliferation and differentiation. Stem Cell Rev 5:231-46
Zhang, Ying; Levin, Michael (2009) Particle tracking model of electrophoretic morphogen movement reveals stochastic dynamics of embryonic gradient. Dev Dyn 238:1923-35
Oviedo, Nestor J; Pearson, Bret J; Levin, Michael et al. (2008) Planarian PTEN homologs regulate stem cells and regeneration through TOR signaling. Dis Model Mech 1:131-43;discussion 141

Showing the most recent 10 out of 12 publications