Abstract

Synapses are most fundamental to the function of a nervous system. C. elegans is an excellent genetic model system for finding genes and elucidating pathways because of its sequenced genome and the abundance of molecular biology tools and mutants. Due to the simplicity of its nervous system, many breakthroughs have been made in C. elegans for understanding molecular mechanisms in the patterning of the nervous system and synapse development. The current bottlenecks, however, are in the manual and non-quantitative techniques such as visual screens, often limiting both the throughput of the experiments and the phenotypes one can examine. Our long-term objective is to develop technologies to understand how genes, age, and the environment together define and continue to remodel the nervous system of an organism. Microtechnologies are ideal for studies of C. elegans neuroscience because of the relevant length scales and the possibility for automation;similarly quantitative imaging techniques are key to deciphering molecular mechanisms. The objective of this R01 project is to engineer micro devices for large-scale live imaging and quantitative imaging technologies in order to study synapse development in an in vivo system. Genes and pathways emerging from this study could potentially become targets of therapeutics in neurological disorders. We hypothesize that quantitative microscopy-based approaches can indeed enable identification of novel genes and pathways that conventional approaches cannot. The first component of this project is to develop on-chip rapid and high-content in vivo imaging techniques, and in parallel to develop algorithms and quantitative measures for the analysis of such high-content data. The second component of the project is to perform screens and studies using these novel technologies. The approach is innovative because the technology developed here dramatically increases the capabilities of existing imaging and screening tools by several orders of magnitude in speed and much more sensitive and accurate than conventional manual approaches. The proposed research is significant because it fills the urgent need in high-throughput and high-content screens as well as identifying novel genes and pathways. In addition, besides the contribution to the specific neurobiology, the technologies are widely applicable to areas such as developmental cell biology, and to other small organisms such as fly larvae and zebrafish embryos.

Public Health Relevance

Synapse development is an important and active area of research linking genes and environments to the formation and maintenance of synapses in the nervous system. It has direct implications in many human diseases such as neurodegeneration and mental illnesses.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM088333-02
Application #
8249809
Study Section
Neurotechnology Study Section (NT)
Program Officer
Deatherage, James F
Project Start
2011-04-01
Project End
2015-03-31
Budget Start
2012-04-01
Budget End
2013-03-31
Support Year
2
Fiscal Year
2012
Total Cost
$274,245
Indirect Cost
$86,245

  Institution

Name
Georgia Institute of Technology
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
097394084
City
Atlanta
State
GA
Country
United States
Zip Code
30332

  Publications

Chew, Yee Lian; Tanizawa, Yoshinori; Cho, Yongmin et al. (2018) An Afferent Neuropeptide System Transmits Mechanosensory Signals Triggering Sensitization and Arousal in C. elegans. Neuron 99:1233-1246.e6
de Carlos Cáceres, Ivan; Porto, Daniel A; Gallotta, Ivan et al. (2018) Automated screening of C. elegans neurodegeneration mutants enabled by microfluidics and image analysis algorithms. Integr Biol (Camb) 10:539-548
Rouse, T; Aubry, G; Cho, Y et al. (2018) A programmable platform for sub-second multichemical dynamic stimulation and neuronal functional imaging in C. elegans. Lab Chip 18:505-513
Aubry, G; Lu, H (2017) Droplet array for screening acute behaviour response to chemicals in Caenorhabditis elegans. Lab Chip 17:4303-4311
Cho, Yongmin; Porto, Daniel A; Hwang, Hyundoo et al. (2017) Automated and controlled mechanical stimulation and functional imaging in vivo in C. elegans. Lab Chip 17:2609-2618
Diana, Giovanni; Patel, Dhaval S; Entchev, Eugeni V et al. (2017) Genetic control of encoding strategy in a food-sensing neural circuit. Elife 6:
Patel, Dhaval S; Diana, Giovanni; Entchev, Eugeni V et al. (2017) Quantification of Information Encoded by Gene Expression Levels During Lifespan Modulation Under Broad-range Dietary Restriction in C. elegans. J Vis Exp :
Goyal, Yogesh; Levario, Thomas J; Mattingly, Henry H et al. (2017) Parallel imaging of Drosophila embryos for quantitative analysis of genetic perturbations of the Ras pathway. Dis Model Mech 10:923-929
Jackson-Holmes, E L; McDevitt, T C; Lu, H (2017) A microfluidic trap array for longitudinal monitoring and multi-modal phenotypic analysis of individual stem cell aggregates. Lab Chip 17:3634-3642
Zhuo, Weipeng; Lu, Hang; McGrath, Patrick T (2017) Microfluidic platform with spatiotemporally controlled micro-environment for studying long-term C. elegans developmental arrests. Lab Chip 17:1826-1833

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