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2 Janelia Publications

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    07/08/20 | Bright and high-performance genetically encoded Ca indicator based on mNeonGreen fluorescent protein.
    Zarowny L, Aggarwal A, Rutten VM, Kolb I, GENIE Project , Patel R, Huang H, Chang Y, Phan T, Kanyo R, Ahrens MB, Allison WT, Podgorski K, Campbell RE
    ACS Sensors. 2020 Jul 08:. doi: 10.1021/acssensors.0c00279

    Genetically encodable calcium ion (Ca) indicators (GECIs) based on green fluorescent proteins (GFP) are powerful tools for imaging of cell signaling and neural activity in model organisms. Following almost 2 decades of steady improvements in the GFP-based GCaMP series of GECIs, the performance of the most recent generation (i.e., jGCaMP7) may have reached its practical limit due to the inherent properties of GFP. In an effort to sustain the steady progression toward ever-improved GECIs, we undertook the development of a new GECI based on the bright monomeric GFP, mNeonGreen (mNG). The resulting indicator, mNG-GECO1, is 60% brighter than GCaMP6s in vitro and provides comparable performance as demonstrated by imaging Ca dynamics in cultured cells, primary neurons, and in vivo in larval zebrafish. These results suggest that mNG-GECO1 is a promising next-generation GECI that could inherit the mantle of GCaMP and allow the steady improvement of GECIs to continue for generations to come.

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    02/25/20 | High-throughput cellular-resolution synaptic connectivity mapping in vivo with concurrent two-photon optogenetics and volumetric Ca2+ imaging
    McRaven C, Tanese D, Zhang L, Yang C, Ahrens MB, Emiliani V, Koyama M
    bioRxiv. 2020 Feb 25:. doi: https://doi.org/10.1101/2020.02.21.959650

    The ability to measure synaptic connectivity and properties is essential for understanding neuronal circuits. However, existing methods that allow such measurements at cellular resolution are laborious and technically demanding. Here, we describe a system that allows such measurements in a high-throughput way by combining two-photon optogenetics and volumetric Ca2+ imaging with whole-cell recording. We reveal a circuit motif for generating fast undulatory locomotion in zebrafish.

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