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1. Simultaneous Ca 2+ Imaging and Optogenetic Stimulation of Cortical Astrocytes in Adult Murine Brain Slices

   https://doi.org/10.1002/cpns.110  

   Balachandar, Lakshmini ; Montejo, Karla A. ; Castano, Eleane ; Perez, Melissa ; Moncion, Carolina ; Chambers, Jeremy W. ; Lujan, J. Luis ; Diaz, Jorge Riera ( December 2020 , Current Protocols in Neuroscience)

   Astrocytes are actively involved in a neuroprotective role in the brain, which includes scavenging reactive oxygen species to minimize tissue damage. They also modulate neuroinflammation and reactive gliosis prevalent in several brain disorders like epilepsy, Alzheimer's, and Parkinson's disease. In animal models, targeted manipulation of astrocytic function via modulation of their calcium (Ca²⁺) oscillations by incorporating light‐sensitive cation channels like Channelrhodopsin‐2 (ChR2) offers a promising avenue in influencing the long‐term progression of these disorders. However, using adult animals for Ca²⁺imaging poses major challenges, including accelerated deterioration ofin situslice health and age‐ related changes. Additionally, optogenetic preparations necessitate usage of a red‐shifted Ca²⁺indicator like Rhod‐2 AM to avoid overlapping light issues between ChR2 and the Ca²⁺indicator during simultaneous optogenetic stimulation and imaging. In this article, we provide an experimental setting that uses live adult murine brain slices (2‐5 months) from a knock‐in model expressing Channelrhodopsin‐2 (ChR2(C128S)) in cortical astrocytes, loaded with Rhod‐2 AM to elicit robust Ca²⁺response to light stimulation. We have developed and standardized a protocol for brain extraction, sectioning, Rhod‐2 AM loading, maintenance of slice health, and Ca²⁺imaging during light stimulation. This has been successfully applied to optogenetically control adult cortical astrocytes, which exhibit synchronous patterns of Ca²⁺activity upon light stimulation, drastically different from resting spontaneous activity. © 2020 Wiley Periodicals LLC.

   Basic Protocol 1: Experimental preparation, setup, slice preparation and Rhod‐2 AM staining

   Basic Protocol 2: Image acquisition and analysis

    

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2. Development, Screening, and Validation of Camelid‐Derived Nanobodies for Neuroscience Research

   https://doi.org/10.1002/cpns.107  

   Gavira‐O'Neill, Clara E. ; Dong, Jie‐Xian ; Trimmer, James S. ( November 2020 , Current Protocols in Neuroscience)

   Nanobodies (nAbs) are recombinant antigen‐binding variable domain fragments obtained from heavy‐chain‐only immunoglobulins. Among mammals, these are unique to camelids (camels, llamas, alpacas, etc.). Nanobodies are of great use in biomedical research due to their efficient folding and stability under a variety of conditions, as well as their small size. The latter characteristic is particularly important for nAbs used as immunolabeling reagents, since this can improve penetration of cell and tissue samples compared to conventional antibodies, and also reduce the gap distance between signal and target, thereby improving imaging resolution. In addition, their recombinant nature allows for unambiguous definition and permanent archiving in the form of DNA sequence, enhanced distribution in the form of sequences or plasmids, and easy and inexpensive production using well‐established bacterial expression systems, such as the IPTG induction method described here. This article will review the basic workflow and process for developing, screening, and validating novel nAbs against neuronal target proteins. The protocols described make use of the most common nAb development method, wherein an immune repertoire from an immunized llama is screened via phage display technology. Selected nAbs can then be taken through validation assays for use as immunolabels or as intrabodies in neurons. © 2020 Wiley Periodicals LLC.

   This article was corrected on 26 June 2021. See the end of the full text for details.

   Basic Protocol 1: Total RNA isolation from camelid leukocytes

   Basic Protocol 2: First‐strand cDNA synthesis; V_HH and V_Hrepertoire PCR

   Basic Protocol 3: Preparation of the phage display library

   Basic Protocol 4: Panning of the phage display library

   Basic Protocol 5: Small‐scale nAb expression

   Basic Protocol 6: Sequence analysis of selected nAb clones

   Basic Protocol 7: Nanobody validation as immunolabels

   Basic Protocol 8: Generation of nAb‐pEGFP mammalian expression constructs

   Basic Protocol 9: Nanobody validation as intrabodies

   Support Protocol 1: ELISA for llama serum testing, phage titer, and screening of selected clones

   Support Protocol 2: Amplification of helper phage stock

   Support Protocol 3: nAb expression in amber suppressorE. colibacterial strains

    

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3. Metabolic Analysis at the Nanoscale with Multi‐Isotope Imaging Mass Spectrometry (MIMS)

   https://doi.org/10.1002/cpcb.111  

   Narendra, Derek P. ; Steinhauser, Matthew L. ( July 2020 , Current Protocols in Cell Biology)

   Incorporation of a stable‐isotope metabolic tracer into cells or tissue can be followed at submicron resolution by multi‐isotope imaging mass spectrometry (MIMS), a form of imaging secondary ion microscopy optimized for accurate isotope ratio measurement from microvolumes of sample (as small as ∼30 nm across). In a metabolic MIMS experiment, a cell or animal is metabolically labeled with a tracer containing a stable isotope. Relative accumulation of the heavy isotope in the fixed sample is then measured as an increase over its natural abundance by MIMS. MIMS has been used to measure protein turnover in single organelles, track cellular divisionin vivo, visualize sphingolipid rafts on the plasma membrane, and measure dopamine incorporation into dense‐core vesicles, among other biological applications. In this article, we introduce metabolic analysis using NanoSIMS by focusing on two specific applications: quantifying protein turnover in single organelles of cultured cells and tracking cell replication in mouse tissuesin vivo. These examples illustrate the versatility of metabolic analysis with MIMS. © 2020 Wiley Periodicals LLC.

   Basic Protocol 1: Metabolic labeling for MIMS

   Basic Protocol 2: Embedding of samples for correlative transmission electron microscopy and MIMS with a genetically encoded reporter

   Alternate Protocol: Embedding of samples for correlative light microscopy and MIMS

   Support Protocol: Preparation of silicon wafers as sample supports for MIMS

   Basic Protocol 3: Analysis of MIMS data

    

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4. Magnetic Stimulation of Dissociated Cortical Neurons on a Planar Mulitelectrode Array

   Mukesh, S ; Zeller-Townson, R ; Butera, R ; Bhatti, P ( March 2019 , International IEEE/EMBS Conference on Neural Engineering)

   We perform experiments to study the magnetic stimulus-induced changes in neural activity in dissociated cortical neurons with different stimulation parameters. The goal of performing these studies is to build on the results from our previous work that suggested magnetic stimulation may lead to improved performance of cochlear implants. A magnetic stimulator is assembled using a micro-scale coil. To detect small changes in activity, we use glass substrate MEAs to measure culture-wide synaptically-mediated response to stimulation, rather than the direct activation of individual neurons. Our initial findings show magnetic stimulation is associated with changes in network-wide firing rates, beyond those expected by spontaneous drift in activity. This suggests that the magnetic stimulation parameters we used were able to evoke neural activity. However, we observe substantial differences in the type of change induced in neural activity in different cultures and with different stimulation parameters, some showing increases in activity and others showing decreases in activity. This may be due to differences in the number and type of neurons (inhibitory or excitatory) activated by stimulation in different experiments, which in turn may be affected by differences in stimulator location and alignment, differences in stimulus pulse waveform and amplitudes, or differences in culture density or cell morphology. We also compare the power consumption and heating of this stimulation technique with that of electrical stimulation. Finally, a need to optimize the experimental setup to allow longer experiments is identified, to reach definite conclusions. 

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5. Optogenetic Tools for Manipulating Protein Subcellular Localization and Intracellular Signaling at Organelle Contact Sites

   https://doi.org/10.1002/cpz1.71  

   Benedetti, Lorena ( March 2021 , Current Protocols)

   Intracellular signaling processes are frequently based on direct interactions between proteins and organelles. A fundamental strategy to elucidate the physiological significance of such interactions is to utilize optical dimerization tools. These tools are based on the use of small proteins or domains that interact with each other upon light illumination. Optical dimerizers are particularly suitable for reproducing and interrogating a given protein‐protein interaction and for investigating a protein's intracellular role in a spatially and temporally precise manner. Described in this article are genetic engineering strategies for the generation of modular light‐activatable protein dimerization units and instructions for the preparation of optogenetic applications in mammalian cells. Detailed protocols are provided for the use of light‐tunable switches to regulate protein recruitment to intracellular compartments, induce intracellular organellar membrane tethering, and reconstitute protein function using enhanced Magnets (eMags), a recently engineered optical dimerization system. © 2021 Wiley Periodicals LLC.

   This article was corrected on 25 July 2022. See the end of the full text for details.

   Basic Protocol 1: Genetic engineering strategy for the generation of modular light‐activated protein dimerization units

   Support Protocol 1: Molecular cloning

   Basic Protocol 2: Cell culture and transfection

   Support Protocol 2: Production of dark containers for optogenetic samples

   Basic Protocol 3: Confocal microscopy and light‐dependent activation of the dimerization system

   Alternate Protocol 1: Protein recruitment to intracellular compartments

   Alternate Protocol 2: Induction of organelles’ membrane tethering

   Alternate Protocol 3: Optogenetic reconstitution of protein function

   Basic Protocol 4: Image analysis

   Support Protocol 3: Analysis of apparent on‐ and off‐kinetics

   Support Protocol 4: Analysis of changes in organelle overlap over time

    

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