Next-generation GRAB sensors for monitoring dopaminergic activity in vivo

Sun, Fangmiao; Zhou, Jingheng; Dai, Bing; Qian, Tong; Zeng, Jianzhi; Li, Xuelin; Zhuo, Yizhou; Zhang, Yajun; Wang, Yipan; Cheng, Qian; Tan, Ke; Feng, Jiguang; Dong, Hui; Lin, Dayu; Cui, Guohong; Li, Yulong

doi:10.1038/s41592-020-00981-9

Cited by 313 publications

(292 citation statements)

References 56 publications

(44 reference statements)

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“…Two families of GPCR-based dopamine (3,4-dihydroxyphenethylamine or DA) sensors, human D 2 dopamine receptor-based GRAB DA [ 25 , 36 ] and human D 1 dopamine receptor-based dLight [ 26 , 37 ] sensors, are engineered (Table 1 ). GRAB DA1m , GRAB DA1h , GRAB DA2m , and GRAB DA2h are the green versions of genetically encoded DA sensors, while rGRAB DA1m and rGRAB DA1h belong to the first red versions of genetically encoded neuromodulatory transmitter sensors [ 25 , 36 ]. dLight sensors also have multiple versions with somewhat different properties [ 26 , 37 ].…”

Section: Introductionmentioning

confidence: 99%

“…dLight sensors also have multiple versions with somewhat different properties [ 26 , 37 ]. The top-performing GRAB DA2m and dLight 1 registered robust dopaminergic signals from populations of cells in the striatum [ 32 , 36 ] and basal amygdala [ 38 ], which receive the heaviest dopaminergic innervations with probably largest dopaminergic signals [ 38 – 40 ]. A recent addition is a D 2 dopamine receptor-based red version of genetically encoded DA sensor, RdLight 1 [ 41 ], further expanding the toolbox for DA sensors.…”

Section: Introductionmentioning

confidence: 99%

“…A recent addition is a D 2 dopamine receptor-based red version of genetically encoded DA sensor, RdLight 1 [ 41 ], further expanding the toolbox for DA sensors. Direct experimental comparison showed that GRAB DA2m produced slightly larger single-cell dopaminergic responses with a better signal-to-noise ratio compared to dLight 1 in the same striatal preparation [ 32 , 36 ]. While the extremely low baseline dLight 1 fluorescence often precludes identification of individual expressing cells, dLight 1 appears to have slightly higher selectivity over NE than GRAB DA2m [ 26 , 36 ].…”

Section: Introductionmentioning

confidence: 99%

“…Direct experimental comparison showed that GRAB DA2m produced slightly larger single-cell dopaminergic responses with a better signal-to-noise ratio compared to dLight 1 in the same striatal preparation [ 32 , 36 ]. While the extremely low baseline dLight 1 fluorescence often precludes identification of individual expressing cells, dLight 1 appears to have slightly higher selectivity over NE than GRAB DA2m [ 26 , 36 ]. It remains unclear whether GRAB DA2m and dLight 1 are capable of detecting modest single-cell dopaminergic signals at other brain areas, such as the prefrontal cortex and hippocampus.…”

Section: Introductionmentioning

confidence: 99%

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Genetically encoded sensors enable micro- and nano-scopic decoding of transmission in healthy and diseased brains

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Neural communication orchestrates a variety of behaviors, yet despite impressive effort, delineating transmission properties of neuromodulatory communication remains a daunting task due to limitations of available monitoring tools. Recently developed genetically encoded neurotransmitter sensors, when combined with superresolution and deconvolution microscopic techniques, enable the first micro- and nano-scopic visualization of neuromodulatory transmission. Here we introduce this image analysis method by presenting its biophysical foundation, practical solutions, biological validation, and broad applicability. The presentation illustrates how the method resolves fundamental synaptic properties of neuromodulatory transmission, and the new data unveil unexpected fine control and precision of rodent and human neuromodulation. The findings raise the prospect of rapid advances in the understanding of neuromodulatory transmission essential for resolving the physiology or pathogenesis of various behaviors and diseases.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Genetically encoded sensors enable micro- and nano-scopic decoding of transmission in healthy and diseased brains

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“…For example, cp-based sensors detecting the activity of the receptors for acetylcholine [ 106 ], norepinephrine [ 107 ], adenosine [ 108 ], and serotonin [ 109 ] were developed, allowing the monitoring of spatiotemporal activity of various neurotransmitter receptors. In addition to green sensors, red dopamine receptor sensors have recently been developed utilizing cp-mApple [ 110 , 111 ], and thereby different neurotransmitter signals can be simultaneously monitored in living neurons and animals.…”

Section: Sensing Strategies Of Fp-based Biosensorsmentioning

confidence: 99%

Genetically Encoded Biosensors Based on Fluorescent Proteins

Kim

Lee

et al. 2021

Sensors

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Genetically encoded biosensors based on fluorescent proteins (FPs) allow for the real-time monitoring of molecular dynamics in space and time, which are crucial for the proper functioning and regulation of complex cellular processes. Depending on the types of molecular events to be monitored, different sensing strategies need to be applied for the best design of FP-based biosensors. Here, we review genetically encoded biosensors based on FPs with various sensing strategies, for example, translocation, fluorescence resonance energy transfer (FRET), reconstitution of split FP, pH sensitivity, maturation speed, and so on. We introduce general principles of each sensing strategy and discuss critical factors to be considered if available, then provide representative examples of these FP-based biosensors. These will help in designing the best sensing strategy for the successful development of new genetically encoded biosensors based on FPs.

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Multimodal Technologies for Closed‐Loop Neural Modulation and Sensing

Li,

Zhang,

Zhao

et al. 2024

Adv Healthcare Materials

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Existing methods for studying neural circuits and treating neurological disorders are typically based on physical and chemical cues to manipulate and record neural activities. These approaches often involve predefined, rigid, and unchangeable signal patterns, which cannot be adjusted in real time according to the patient's condition or neural activities. With the continuous development of neural interfaces, conducting in vivo research on adaptive and modifiable treatments for neurological diseases and neural circuits is now possible. In this review, we summarize current and potential integration of various modalities to achieve precise, closed‐loop modulation and sensing in neural systems. We highlight advanced materials, devices, or systems that generate or detect electrical, magnetic, optical, acoustic, or chemical signals and utilize them to interact with neural cells, tissues, and networks for closed‐loop interrogation. Further, we elaborate on the significance of developing closed‐loop techniques for diagnostics and treatment of neurological disorders such as epilepsy, depression, rehabilitation of spinal cord injury patients, and exploration of brain neural circuit functionality.This article is protected by copyright. All rights reserved

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Next-generation GRAB sensors for monitoring dopaminergic activity in vivo

Cited by 313 publications

References 56 publications

Genetically encoded sensors enable micro- and nano-scopic decoding of transmission in healthy and diseased brains

Genetically encoded sensors enable micro- and nano-scopic decoding of transmission in healthy and diseased brains

Genetically Encoded Biosensors Based on Fluorescent Proteins

Multimodal Technologies for Closed‐Loop Neural Modulation and Sensing

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