Author
Listed:
- Syuan-Ming Guo
(MIT)
- Remi Veneziano
(MIT)
- Simon Gordonov
(MIT)
- Li Li
(Broad Institute of MIT and Harvard
Broad Institute of MIT and Harvard)
- Eric Danielson
(MIT)
- Karen Perez de Arce
(Broad Institute of MIT and Harvard
Broad Institute of MIT and Harvard)
- Demian Park
(MIT)
- Anthony B. Kulesa
(MIT
Broad Institute of MIT and Harvard)
- Eike-Christian Wamhoff
(MIT)
- Paul C. Blainey
(MIT
Broad Institute of MIT and Harvard)
- Edward S. Boyden
(MIT
MIT
MIT)
- Jeffrey R. Cottrell
(Broad Institute of MIT and Harvard
Broad Institute of MIT and Harvard)
- Mark Bathe
(MIT
Broad Institute of MIT and Harvard)
Abstract
Synapses contain hundreds of distinct proteins whose heterogeneous expression levels are determinants of synaptic plasticity and signal transmission relevant to a range of diseases. Here, we use diffusible nucleic acid imaging probes to profile neuronal synapses using multiplexed confocal and super-resolution microscopy. Confocal imaging is performed using high-affinity locked nucleic acid imaging probes that stably yet reversibly bind to oligonucleotides conjugated to antibodies and peptides. Super-resolution PAINT imaging of the same targets is performed using low-affinity DNA imaging probes to resolve nanometer-scale synaptic protein organization across nine distinct protein targets. Our approach enables the quantitative analysis of thousands of synapses in neuronal culture to identify putative synaptic sub-types and co-localization patterns from one dozen proteins. Application to characterize synaptic reorganization following neuronal activity blockade reveals coordinated upregulation of the post-synaptic proteins PSD-95, SHANK3 and Homer-1b/c, as well as increased correlation between synaptic markers in the active and synaptic vesicle zones.
Suggested Citation
Syuan-Ming Guo & Remi Veneziano & Simon Gordonov & Li Li & Eric Danielson & Karen Perez de Arce & Demian Park & Anthony B. Kulesa & Eike-Christian Wamhoff & Paul C. Blainey & Edward S. Boyden & Jeffre, 2019.
"Multiplexed and high-throughput neuronal fluorescence imaging with diffusible probes,"
Nature Communications, Nature, vol. 10(1), pages 1-14, December.
Handle:
RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-12372-6
DOI: 10.1038/s41467-019-12372-6
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