Sequencing the Connectome

Anthony M. Zador; Joshua Dubnau; Hassana K. Oyibo; Huiqing Zhan; Gang Cao; Ian D. Peikon

doi:10.1371/journal.pbio.1001411

Sequencing the Connectome

Anthony M. Zador
, Joshua Dubnau
, Hassana K. Oyibo
, Huiqing Zhan
, Gang Cao
, Ian D. Peikon

Anesthesiology

Stony Brook University

Cold Spring Harbor Laboratory
Watson School for Biological Sciences

Research output: Contribution to journal › Article › peer-review

88 Scopus citations

Abstract

Connectivity determines the function of neural circuits. Historically, circuit mapping has usually been viewed as a problem of microscopy, but no current method can achieve high-throughput mapping of entire circuits with single neuron precision. Here we describe a novel approach to determining connectivity. We propose BOINC ("barcoding of individual neuronal connections"), a method for converting the problem of connectivity into a form that can be read out by high-throughput DNA sequencing. The appeal of using sequencing is that its scale-sequencing billions of nucleotides per day is now routine-is a natural match to the complexity of neural circuits. An inexpensive high-throughput technique for establishing circuit connectivity at single neuron resolution could transform neuroscience research.

Original language	English
Article number	e1001411
Journal	PLOS Biology
Volume	10
Issue number	10
DOIs	https://doi.org/10.1371/journal.pbio.1001411
State	Published - Oct 2012

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10.1371/journal.pbio.1001411

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title = "Sequencing the Connectome",

abstract = "Connectivity determines the function of neural circuits. Historically, circuit mapping has usually been viewed as a problem of microscopy, but no current method can achieve high-throughput mapping of entire circuits with single neuron precision. Here we describe a novel approach to determining connectivity. We propose BOINC ({"}barcoding of individual neuronal connections{"}), a method for converting the problem of connectivity into a form that can be read out by high-throughput DNA sequencing. The appeal of using sequencing is that its scale-sequencing billions of nucleotides per day is now routine-is a natural match to the complexity of neural circuits. An inexpensive high-throughput technique for establishing circuit connectivity at single neuron resolution could transform neuroscience research.",

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AU - Cao, Gang

AU - Peikon, Ian D.

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AB - Connectivity determines the function of neural circuits. Historically, circuit mapping has usually been viewed as a problem of microscopy, but no current method can achieve high-throughput mapping of entire circuits with single neuron precision. Here we describe a novel approach to determining connectivity. We propose BOINC ("barcoding of individual neuronal connections"), a method for converting the problem of connectivity into a form that can be read out by high-throughput DNA sequencing. The appeal of using sequencing is that its scale-sequencing billions of nucleotides per day is now routine-is a natural match to the complexity of neural circuits. An inexpensive high-throughput technique for establishing circuit connectivity at single neuron resolution could transform neuroscience research.

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Sequencing the Connectome

Abstract

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