# Precision editing of neural circuits using engineered electrical synapses

> **NIH NIH DP1** · DUKE UNIVERSITY · 2024 · $1,127,000

## Abstract

Title: Precision editing of neural circuits using engineered electrical synapses
Pioneering approaches including optogenetics and designer receptors exclusively activated by
designer drugs (DREADDs) enable the direct modulation of the activity of individual genetically
defined cell types. Nevertheless, it remains a fundamental challenge to selectively regulate the
hallmark feature of neural circuits: the interface between two specific brain cells. To address this
challenge, we have created a new approach, Long-term integration of circuits using Connexins
(LinCx), that employs a novel pair of engineered connexin hemichannels to directly modulate
genetically defined neural circuits. When each member of the hemichannel pair is expressed in
two different cell(s)/cell-types that compose a circuit, they engage in heterotypic docking
(docking with each other) and an electrical synapse is constituted between the two cells. These
pair of hemichannels is engineered 1) to prevent them from engaging in homotypic docking
(forming electrical synapses with themselves), and 2) to disrupt them from docking with other
connexin hemichannels endogenously expressed in the mammalian brain. Finally, 3) the
hemichannel pair exhibits rectification. Together, these three properties confer LinCx with
unprecedented spatial-, temporal-, and context precision, enabling the precise editing of neural
circuits.
We propose to deploy LinCx across model organisms. We will determine the impact of LinCx
neuromodulation on neural circuit physiology and emotional behavior. We will also test whether
LinCx modulation is sufficient to restore normal behavior in animal models of psychiatric
disorders. Successful completion of these high-risk experiments will yield a new method for
long-term circuit editing to regulate emotional states in preclinical models. In the future, LinCx
can be integrated with emerging viral tools that enable systemic delivery of genetically encoded
proteins to specific brain cell-types. Thus, LinCx also has an attainable path to human
translation for ameliorating devastating psychiatric disorders.

## Key facts

- **NIH application ID:** 10880335
- **Project number:** 5DP1MH132709-03
- **Recipient organization:** DUKE UNIVERSITY
- **Principal Investigator:** Kafui Dzirasa
- **Activity code:** DP1 (R01, R21, SBIR, etc.)
- **Funding institute:** NIH
- **Fiscal year:** 2024
- **Award amount:** $1,127,000
- **Award type:** 5
- **Project period:** 2022-09-08 → 2027-05-31

## Primary source

NIH RePORTER: https://reporter.nih.gov/project-details/10880335

## Citation

> US National Institutes of Health, RePORTER application 10880335, Precision editing of neural circuits using engineered electrical synapses (5DP1MH132709-03). Retrieved via AI Analytics 2026-05-23 from https://api.ai-analytics.org/grant/nih/10880335. Licensed CC0.

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