Neuroscience

Transfecting neurons remains technically challenging due to their sensitivity. Conventional methods, such as Lipofectamine 2000 or Lipofectamine RNAiMAX, often result in significant cytotoxicity, which limits their utility. Although lentiviral transfection offers high efficiency, it is hindered by high costs and complex procedures. This experiment employs a small interfering RNA (siRNA)-specific transfection reagent from the Kermey company. This reagent is a novel nanoparticle-based lipid material designed for the efficient delivery of oligonucleotides, including siRNA, into a wide range of cell types. Its efficacy in achieving high transfection efficiency in neurons, however, has not yet been established. After several days of in vitro neuronal culture, researchers can perform a simple transfection procedure using this reagent to achieve robust transfection efficiency. Notably, the protocol does not require medium replacement 6–8 h post-transfection, streamlining the workflow and minimizing cellular stress.

Three-dimensional (3D) human brain tissue models derived from induced pluripotent stem cells (iPSCs) have transformed the study of neural development and disease in vitro. While cerebral organoids offer high structural complexity, their large size often leads to necrotic core formation, limiting reproducibility and challenging the integration of microglia. Here, we present a detailed, reproducible protocol for generating multi-cell type 3D neurospheres that incorporate neurons, astrocytes, and optionally microglia, all derived from the same iPSCs. While neurons and astrocytes differentiate spontaneously from neural precursor cells, generated by dual SMAD-inhibition (blocking BMP and TGF-b signaling), microglia are generated in parallel and can infiltrate the mature neurosphere tissue after plating neurospheres into 48-well plates. The system supports a range of downstream applications, including functional confocal live imaging of GCaMP6f after adeno-associated virus (AAV) transduction of neurospheres or immunofluorescence staining after fixation. Our approach has been successfully implemented across multiple laboratories, demonstrating its robustness and translational potential for studying neuron–glia interactions and modeling neurodegenerative processes.

Accurate labeling of excitatory postsynaptic sites remains a major challenge for high-resolution imaging due to the dense and sterically restricted environment of the postsynaptic density (PSD). Here, we present a protocol utilizing Sylites, 3 kDa synthetic peptide probes that bind with nanomolar affinity to key postsynaptic markers, PSD-95 and Gephyrin. eSylites (excitatory Sylites) specifically target the PDZ1 and PDZ2 domains of PSD-95, enabling precise and efficient labeling of excitatory postsynaptic density (ePSD). In contrast, iSylites (inhibitory Sylites) bind to the dimerizing E-domain of the Gephyrin C-terminus, allowing selective visualization of inhibitory postsynaptic density (iPSD). Their small size reduces linkage error and enhances accessibility compared to conventional antibodies, enabling clear separation of PSD-95 nanodomains in super-resolution microscopy. The protocol is compatible with co-labeling using standard antibodies and integrates seamlessly into multichannel immunocytochemistry workflows for primary neurons and brain tissue. This method enables robust, reproducible labeling of excitatory synapses with enhanced spatial resolution and can be readily adapted for expansion microscopy or live-cell applications.

Understanding the nanoscale organization and molecular rearrangement of synaptic components is critical for elucidating the mechanisms of synaptic transmission and plasticity. Traditional synaptosome isolation protocols involve multiple centrifugation and resuspension steps, which may cause structural damage or alter the synaptosomal fraction, compromising their suitability for cryo-electron tomography (cryo-ET). Here, we present an ultrafast isolation method optimized for cryo-ET that yields two types of synaptosomal fractions: synaptosomes and synaptoneurosomes. This streamlined protocol preserves intact postsynaptic membranes apposed to presynaptic active zones and produces thin, high-quality samples suitable for in situ structural studies. The entire procedure, from tissue homogenization to vitrification, takes less than 15 min, offering a significant advantage for high-resolution cryo-ET analysis of synaptic architecture.

Over the lifespan of an individual, brain function requires adjustments in response to environmental changes and learning experiences. During early development, neurons overproduce neurite branches, and neuronal pruning removes the unnecessary neurite branches to make a more accurate neural circuit. Drosophila motoneurons prune their intermediate axon bundles rather than the terminal neuromuscular junction (NMJ) by degeneration, which provides a unique advantage for studying axon pruning. The pruning process of motor axon bundles can be directly analyzed by real-time imaging, and this protocol provides a straightforward method for monitoring the developmental process of Drosophila motor neurons using live cell imaging.

Since the discovery that astrocytes are characterized by Ca²⁺-based excitability, investigating the function of these glial cells within the brain requires Ca²⁺ imaging approaches. The technical evolution from chemical fluorescent Ca²⁺ probes with low cellular specificity to genetically encoded indicators (GECIs) has enabled detailed analysis of the spatial and temporal features of intracellular Ca²⁺ signal. Different imaging methodologies allow the extraction of distinct information on calcium signals in astrocytes from brain slices, with resolution ranging from cell populations to single cells up to subcellular domains.

Here, we describe 2-photon laser scanning microscopy (2PLSM) Ca²⁺ imaging in astrocytes from the somatosensory cortex (SSCx) of adult mice in ex vivo acute cortical slices, performed using two genetically encoded Ca²⁺ indicators, i.e., cytosolic GCaMP6f and endoplasmic reticulum-targeted G-CEPIA1er. The main advantage of the 2PLSM technique, compared to single-photon microscopy, is the possibility to go deeper in the tissue while avoiding photodamage, by limiting laser excitation to a single focal plane. The fluorescent signal of the indicator is analyzed offline in different compartments—soma, proximal processes, and microdomains—for GCaMP6f experiments and in the perinuclear, somatic area for G-CEPIA1er. The analysis of Ca²⁺ signal from different compartments, although not providing a value of absolute concentration, allows a critical comparison of the degree of astrocyte activation between different experimental conditions or mouse models. Moreover, the analysis of G-CEPIA1er signal, which reveals metabotropic receptor activation as a dynamic decrease in free Ca²⁺ in the endoplasmic reticulum (ER), can provide information on possible alterations in this critical second messenger pathway in astrocytes, including, for example, steady-state ER Ca²⁺ levels and kinetics of Ca²⁺ release.

Primary oligodendrocyte cultures are a crucial driving force for in vitro research on oligodendrocytes (OLs) and myelin. Various methods are available to obtain oligodendrocyte lineage cells, primarily from neonatal rodent brains or human induced pluripotent stem cells (iPSCs). In this protocol, we describe a step-by-step procedure for detaching and cryopreserving primary rat oligodendrocyte progenitor cells (OPCs), followed by the thawing, proliferation, and differentiation of the cryopreserved OPCs. After freezing in a serum-free cryopreservation medium, the OPCs can be preserved at -80 °C for up to two months without notable changes in viability, proliferation, or differentiation into mature OLs. Cryopreserved OPCs can be differentiated into mature OLs with robust myelin processes and the capacity to wrap around neuron-mimicking structures. Combined with the author’s method for primary OL culture, which allows for bulk production of OPCs, OPC cryopreservation may substantially improve the efficiency of in vitro OL research.

AMPA-type receptors are transported large distances to support synaptic plasticity at distal dendritic locations. Studying the motion of AMPA receptor⁺ vesicles can improve our understanding of the mechanisms that underlie learning and memory. Nevertheless, technical challenges that prevent the visualization of AMPA receptor⁺ vesicles limit our ability to study how these vesicles are trafficked. Existing methods rely on the overexpression of fluorescent protein-tagged AMPA receptors from plasmids, resulting in a saturated signal that obscures vesicles. Photobleaching must be applied to detect individual AMPA receptor⁺ vesicles, which may eliminate important vesicle populations from analysis. Here, we present a protocol to study AMPA receptor⁺ vesicles that addresses these challenges by 1) tagging AMPA receptors expressed from native loci with HaloTag and 2) employing a block-and-chase strategy with Janelia Fluor-conjugated HaloTag ligand to achieve sparse AMPA receptor labeling that obviates the need for photobleaching. After timelapse imaging is performed, AMPA receptor⁺ vesicles can be identified during image analysis, and their motion can be characterized using a single-particle tracking pipeline.

Long-term depression (LTD), a key form of synaptic plasticity, is typically induced through regulated Ca²⁺ entry via NMDA receptors and achieved by prolonged (up to hundreds of seconds) low-frequency presynaptic stimulation or bath application of NMDA receptor agonists. Electrophysiological approach to LTD induction requires specialized equipment, while bath applications limit productivity, as only one neuron per sample may be recorded. Here, we present a simple and effective protocol for pharmacological modeling of LTD in primary cultured neurons. This approach relies on highly localized iontophoretic application of NMDA, which induces LTD in individual cells, enhancing experimental throughput. We have analyzed spatio-temporal patterns of iontophoretic drug delivery and demonstrated how this technique may be combined with electrophysiological and live-cell imaging approaches to investigate LTD-related changes in synaptic strength and Ca²⁺-dependent signaling of neuronal Ca²⁺ sensor proteins.

The growth cone is a highly motile tip structure that guides axonal elongation and directionality in differentiating neurons. Migrating immature neurons also exhibit a growth cone–like structure (GCLS) at the tip of the leading process. However, it remains unknown whether the GCLS in migrating immature neurons shares the morphological and molecular features of axonal growth cones and can thus be considered equivalent to them. Here, we describe a detailed method for time-lapse imaging and optical manipulation of growth cones using a super-resolution laser-scanning microscope. To observe growth cones in elongating axons and migrating neurons, embryonic cortical neurons and neonatal ventricular–subventricular zone (V-SVZ)-derived neurons, respectively, were transfected with plasmids encoding fluorescent protein–conjugated cytoskeletal probes and three-dimensionally cultured in Matrigel, which mimics the in vivo background. At 2–5 days in vitro, the morphology and dynamics of these growth cones and their associated cytoskeletal molecules were assessed by time-lapse super-resolution imaging. The use of photoswitchable cytoskeletal inhibitors, which can be reversibly and precisely controlled by laser illumination at two different wavelengths, revealed the spatiotemporal regulatory machinery and functional significance of growth cones in neuronal migration. Furthermore, machine learning–based methods enabled us to automatically segment growth cone morphology from elongating axons and the leading process. This protocol provides a cutting-edge methodology for studying the growth cone in developmental and regenerative neuroscience, being adaptable for various cell biology and imaging applications.