bims-axbals Biomed News
on Axonal Biology and ALS
Issue of 2024‒08‒18
seventeen papers selected by
TJ Krzystek, ALS Therapy Development Institute
  1. Live Imaging Analysis of Axonal Regeneration in Human iPSC-Derived Motor Neurons Using a Microfluidic System.
  2. Cortical neurodegeneration caused by Psen1 mutations is independent of Aβ.
  3. Visualization and Quantification of Organelle Axonal Transport in Cultured Neurons.
  4. Poly-GR Impairs PRMT1-Mediated Arginine Methylation of Disease-Linked RNA-Binding Proteins by Acting as a Substrate Sink.
  5. 3D Reconstruction of the Mitochondrial Network within the Neuronal Soma from SBF-SEM Volume Data.
  6. A patient-derived amyotrophic lateral sclerosis blood-brain barrier model for focused ultrasound-mediated anti-TDP-43 antibody delivery.
  7. Culturing Primary Cortical Neurons for Live-Imaging.
  8. Neurons Specialize in Presynaptic Autophagy: A Perspective to Ameliorate Neurodegeneration.
  9. A PIKfyve modulator combined with an integrated stress response inhibitor to treat lysosomal storage diseases.
  10. In Vitro and In Vivo Analysis of Neuronal Polarity.
  11. Analysis of Neurite and Spine Formation in Neurons In Vitro.
  12. Endoplasmic reticulum associated degradation preserves neurons viability by maintaining endoplasmic reticulum homeostasis.
  13. EVs move messes, not messages, at the synapse.
  14. Protocol for the generation of cultured cortical brain organoid slices.
  15. Novel CDKL5 targets identified in human iPSC-derived neurons.
  16. Generating and Co-culturing Murine Primary Microglia and Cortical Neurons.
  17. Measuring Retrograde Actin Flow in Neuronal Growth Cones.
  1. Methods Mol Biol. 2024 ;2831 333-350
    Live Imaging Analysis of Axonal Regeneration in Human iPSC-Derived Motor Neurons Using a Microfluidic System.
    Katherine L Marshall, Mohamed H Farah.
      Axonal damage is a common feature of traumatic injury and neurodegenerative disease. The capacity for axons to regenerate and to recover functionality after injury is a phenomenon that is seen readily in the peripheral nervous system, especially in rodent models, but human axonal regeneration is limited and does not lead to full functional recovery. Here we describe a system where dynamics of human axonal outgrowth and regeneration can be evaluated via live imaging of human-induced pluripotent stem cell (hiPSC)-derived neurons cultured in microfluidic systems, in which cell bodies are isolated from their axons. This system could aid in studying axonal outgrowth dynamics and could be useful for testing potential drugs that encourage regeneration and repair of the nervous system.
    Keywords:  Axonal regeneration; Axotomy; Human iPSCs; Live imaging; Microfluidic devices; Motor neurons; Neuronal cytoskeletal markers; Outgrowth
    DOI:  https://doi.org/10.1007/978-1-0716-3969-6_23
  2. Proc Natl Acad Sci U S A. 2024 Aug 20. 121(34): e2409343121
    Cortical neurodegeneration caused by Psen1 mutations is independent of Aβ.
    Kuo Yan, Chen Zhang, Jongkyun Kang, Paola Montenegro, Jie Shen.
      Mutations in the PSEN genes are the major cause of familial Alzheimer's disease, and presenilin (PS) is the catalytic subunit of γ-secretase, which cleaves type I transmembrane proteins, including the amyloid precursor protein (APP) to release Aβ peptides. While PS plays an essential role in the protection of neuronal survival, PSEN mutations also increase the ratio of Aβ42/Aβ40. Thus, it remains unresolved whether PSEN mutations cause AD via a loss of its essential function or increases of Aβ42/Aβ40. Here, we test whether the knockin (KI) allele of Psen1 L435F, the most severe FAD mutation located closest to the active site of γ-secretase, causes age-dependent cortical neurodegeneration independent of Aβ by crossing various Psen mutant mice to the App-null background. We report that removing Aβ completely through APP deficiency has no impact on the age-dependent neurodegeneration in Psen mutant mice, as shown by the absence of effects on the reduced cortical volume and decreases of cortical neurons at the ages of 12 and 18 mo. The L435F KI allele increases Aβ42/Aβ40 in the cerebral cortex while decreasing de novo production and steady-state levels of Aβ42 and Aβ40 in the presence of APP. Furthermore, APP deficiency does not alleviate elevated apoptotic cell death in the cerebral cortex of Psen mutant mice at the ages of 2, 12, and 18 mo, nor does it affect the progressive microgliosis in these mice. Our findings demonstrate that Psen1 mutations cause age-dependent neurodegeneration independent of Aβ, providing further support for a loss-of-function pathogenic mechanism underlying PSEN mutations.
    Keywords:  APP; Alzheimer’s disease; Presenilin; apoptosis; gliosis
    DOI:  https://doi.org/10.1073/pnas.2409343121
  3. Methods Mol Biol. 2024 ;2831 219-234
    Visualization and Quantification of Organelle Axonal Transport in Cultured Neurons.
    Jayne Aiken, Erika L F Holzbaur.
      The specialized function and extreme geometry of neurons necessitates a unique reliance upon long-distance microtubule-based transport. Appropriate trafficking of axonal cargos by motor proteins is essential for establishing circuitry during development and continuing function throughout a lifespan. Visualizing and quantifying cargo movement provides valuable insight into how axonal organelles are replenished, recycled, and degraded during the dynamic dance of outgoing and incoming axonal traffic. Long-distance axonal trafficking is of particular importance as it encompasses a pathway commonly disrupted in developmental and degenerative disease states. Here, we describe neuronal organelles and outline methods for live imaging and quantifying their movement throughout the axon via transient expression of fluorescently labeled organelle markers. This resource provides recommendations for target proteins/domains and appropriate acquisition time scales for visualizing distinct neuronal cargos in cultured neurons derived from human induced pluripotent stem cells (iPSCs) and primary rat neurons.
    Keywords:  Axonal transport; Live imaging; Organelle movement; Primary neuron; Trafficking; Transfection; iPSC-derived neuron
    DOI:  https://doi.org/10.1007/978-1-0716-3969-6_15
  4. Biochemistry. 2024 Aug 15.
    Poly-GR Impairs PRMT1-Mediated Arginine Methylation of Disease-Linked RNA-Binding Proteins by Acting as a Substrate Sink.
    Saskia Hutten, Jia-Xuan Chen, Adrian M Isaacs, Dorothee Dormann.
      Dipeptide repeat proteins (DPRs) are aberrant protein species found in C9orf72-linked amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD), two neurodegenerative diseases characterized by the cytoplasmic mislocalization and aggregation of RNA-binding proteins (RBPs). In particular, arginine (R)-rich DPRs (poly-GR and poly-PR) have been suggested to promiscuously interact with multiple cellular proteins and thereby exert high cytotoxicity. Components of the protein arginine methylation machinery have been identified as modulators of DPR toxicity and/or potential cellular interactors of R-rich DPRs; however, the molecular details and consequences of such an interaction are currently not well understood. Here, we demonstrate that several members of the family of protein arginine methyltransferases (PRMTs) can directly interact with R-rich DPRs in vitro and in the cytosol. In vitro, R-rich DPRs reduce solubility and promote phase separation of PRMT1, the main enzyme responsible for asymmetric arginine-dimethylation (ADMA) in mammalian cells, in a concentration- and length-dependent manner. Moreover, we demonstrate that poly-GR interferes more efficiently than poly-PR with PRMT1-mediated arginine methylation of RBPs such as hnRNPA3. We additionally show by two alternative approaches that poly-GR itself is a substrate for PRMT1-mediated arginine dimethylation. We propose that poly-GR may act as a direct competitor for arginine methylation of cellular PRMT1 targets, such as disease-linked RBPs.
    DOI:  https://doi.org/10.1021/acs.biochem.4c00308
  5. Methods Mol Biol. 2024 ;2831 145-177
    3D Reconstruction of the Mitochondrial Network within the Neuronal Soma from SBF-SEM Volume Data.
    Jane Tweedy, Ross Laws, George Merces, Tracey Davey, Amy K Reeve, Amy E Vincent.
      Neurons contain three compartments, the soma, long axon, and dendrites, which have distinct energetic and biochemical requirements. Mitochondria feature in all compartments and regulate neuronal activity and survival, including energy generation and calcium buffering alongside other roles including proapoptotic signaling and steroid synthesis. Their dynamicity allows them to undergo constant fusion and fission events in response to the changing energy and biochemical requirements. These events, termed mitochondrial dynamics, impact their morphology and a variety of three-dimensional (3D) morphologies exist within the neuronal mitochondrial network. Distortions in the morphological profile alongside mitochondrial dysfunction may begin in the neuronal soma in ageing and common neurodegenerative disorders. However, 3D morphology cannot be comprehensively examined in flat, two-dimensional (2D) images. This highlights a need to segment mitochondria within volume data to provide a representative snapshot of the processes underpinning mitochondrial dynamics and mitophagy within healthy and diseased neurons. The advent of automated high-resolution volumetric imaging methods such as Serial Block Face Scanning Electron Microscopy (SBF-SEM) as well as the range of image software packages allow this to be performed.We describe and evaluate a method for randomly sampling mitochondria and manually segmenting their whole morphologies within randomly generated regions of interest of the neuronal soma from SBF-SEM image stacks. These 3D reconstructions can then be used to generate quantitative data about mitochondrial and cellular morphologies. We further describe the use of a macro that automatically dissects the soma and localizes 3D mitochondria into the subregions created.
    Keywords:  3D reconstruction; Ageing; Mitochondria; Morphology; Neurodegeneration; SBF-SEM; Three-dimensional; Two-dimensional; mtDNA
    DOI:  https://doi.org/10.1007/978-1-0716-3969-6_11
  6. Fluids Barriers CNS. 2024 Aug 13. 21(1): 65
    A patient-derived amyotrophic lateral sclerosis blood-brain barrier model for focused ultrasound-mediated anti-TDP-43 antibody delivery.
    Joanna M Wasielewska, Juliana C S Chaves, Mauricio Castro Cabral-da-Silva, Martina Pecoraro, Stephani J Viljoen, Tam Hong Nguyen, Vincenzo La Bella, Lotta E Oikari, Lezanne Ooi, Anthony R White.
      BACKGROUND: Amyotrophic lateral sclerosis (ALS) is a rapidly progressing neurodegenerative disorder with minimally effective treatment options. An important hurdle in ALS drug development is the non-invasive therapeutic access to the motor cortex currently limited by the presence of the blood-brain barrier (BBB). Focused ultrasound and microbubble (FUS+ MB) treatment is an emerging technology that was successfully used in ALS patients to temporarily open the cortical BBB. However, FUS+ MB-mediated drug delivery across ALS patients' BBB has not yet been reported. Similarly, the effects of FUS+ MB on human ALS BBB cells remain unexplored.METHODS: Here we established the first FUS+ MB-compatible, fully-human ALS patient-cell-derived BBB model based on induced brain endothelial-like cells (iBECs) to study anti-TDP-43 antibody delivery and FUS+ MB bioeffects in vitro.
    RESULTS: Generated ALS iBECs recapitulated disease-specific hallmarks of BBB pathology, including reduced BBB integrity and permeability, and TDP-43 proteinopathy. The results also identified differences between sporadic ALS and familial (C9orf72 expansion carrying) ALS iBECs reflecting patient heterogeneity associated with disease subgroups. Studies in these models revealed successful ALS iBEC monolayer opening in vitro with no adverse cellular effects of FUS+ MB as reflected by lactate dehydrogenase (LDH) release viability assay and the lack of visible monolayer damage or morphology change in FUS+ MB treated cells. This was accompanied by the molecular bioeffects of FUS+ MB in ALS iBECs including changes in expression of tight and adherens junction markers, and drug transporter and inflammatory mediators, with sporadic and C9orf72 ALS iBECs generating transient specific responses. Additionally, we demonstrated an effective increase in the delivery of anti-TDP-43 antibody with FUS+ MB in C9orf72 (2.7-fold) and sporadic (1.9-fold) ALS iBECs providing the first proof-of-concept evidence that FUS+ MB can be used to enhance the permeability of large molecule therapeutics across the BBB in a human ALS in vitro model.
    CONCLUSIONS: Together, this study describes the first characterisation of cellular and molecular responses of ALS iBECs to FUS+ MB and provides a fully-human platform for FUS+ MB-mediated drug delivery screening on an ALS BBB in vitro model.
    Keywords:  Amyotrophic lateral sclerosis; Antibody; Blood-brain barrier; Drug delivery; Focused ultrasound; In vitro model; TDP-43
    DOI:  https://doi.org/10.1186/s12987-024-00565-1
  7. Methods Mol Biol. 2024 ;2831 1-9
    Culturing Primary Cortical Neurons for Live-Imaging.
    Kyle R Northington, Emily Anne Bates.
      Primary neuronal cultures allow for in vitro analysis of early developmental processes such as axon pathfinding and growth dynamics. When coupled with methods to visualize and measure microtubule dynamics, this methodology enables an inside look at how the cytoskeleton changes in response to extracellular signaling cues. Here, we describe the culturing conditions and tools required to extract primary cortical neurons from postnatal mouse brains and visualize cytoskeletal components.
    Keywords:  Cytoskeleton; Live-imaging; Microtubules; Neuron culture; Primary cortical neuron
    DOI:  https://doi.org/10.1007/978-1-0716-3969-6_1
  8. Mol Neurobiol. 2024 Aug 14.
    Neurons Specialize in Presynaptic Autophagy: A Perspective to Ameliorate Neurodegeneration.
    Abhishek Kumar Mishra, Manish Kumar Tripathi, Dipak Kumar, Satya Prakash Gupta.
      The efficient and prolonged neurotransmission is reliant on the coordinated action of numerous synaptic proteins in the presynaptic compartment that remodels synaptic vesicles for neurotransmitter packaging and facilitates their exocytosis. Once a cycle of neurotransmission is completed, membranes and associated proteins are endocytosed into the cytoplasm for recycling or degradation. Both exocytosis and endocytosis are closely regulated in a timely and spatially constrained manner. Recent research demonstrated the impact of dysfunctional synaptic vesicle retrieval in causing retrograde degeneration of midbrain neurons and has highlighted the importance of such endocytic proteins, including auxilin, synaptojanin1 (SJ1), and endophilin A (EndoA) in neurodegenerative diseases. Additionally, the role of other associated proteins, including leucine-rich repeat kinase 2 (LRRK2), adaptor proteins, and retromer proteins, is being investigated for their roles in regulating synaptic vesicle recycling. Research suggests that the degradation of defective vesicles via presynaptic autophagy, followed by their recycling, not only revitalizes them in the active zone but also contributes to strengthening synaptic plasticity. The presynaptic autophagy rejuvenating terminals and maintaining neuroplasticity is unique in autophagosome formation. It involves several synaptic proteins to support autophagosome construction in tiny compartments and their retrograde trafficking toward the cell bodies. Despite having a comprehensive understanding of ATG proteins in autophagy, we still lack a framework to explain how autophagy is triggered and potentiated in compact presynaptic compartments. Here, we reviewed synaptic proteins' involvement in forming presynaptic autophagosomes and in retrograde trafficking of terminal cargos. The review also discusses the status of endocytic proteins and endocytosis-regulating proteins in neurodegenerative diseases and strategies to combat neurodegeneration.
    Keywords:  Autophagy; Endocytic proteins; Neurodegenerative diseases; Presynaptic autophagy; Synaptic dysfunction; Synaptic proteins
    DOI:  https://doi.org/10.1007/s12035-024-04399-8
  9. Proc Natl Acad Sci U S A. 2024 Aug 20. 121(34): e2320257121
    A PIKfyve modulator combined with an integrated stress response inhibitor to treat lysosomal storage diseases.
    William C Hou, Lynée A Massey, Derek Rhoades, Yin Wu, Wen Ren, Chiara Frank, Herman S Overkleeft, Jeffrey W Kelly.
      Lysosomal degradation pathways coordinate the clearance of superfluous and damaged cellular components. Compromised lysosomal degradation is a hallmark of many degenerative diseases, including lysosomal storage diseases (LSDs), which are caused by loss-of-function mutations within both alleles of a lysosomal hydrolase, leading to lysosomal substrate accumulation. Gaucher's disease, characterized by <15% of normal glucocerebrosidase function, is the most common LSD and is a prominent risk factor for developing Parkinson's disease. Here, we show that either of two structurally distinct small molecules that modulate PIKfyve activity, identified in a high-throughput cellular lipid droplet clearance screen, can improve glucocerebrosidase function in Gaucher patient-derived fibroblasts through an MiT/TFE transcription factor that promotes lysosomal gene translation. An integrated stress response (ISR) antagonist used in combination with a PIKfyve modulator further improves cellular glucocerebrosidase activity, likely because ISR signaling appears to also be slightly activated by treatment by either small molecule at the higher doses employed. This strategy of combining a PIKfyve modulator with an ISR inhibitor improves mutant lysosomal hydrolase function in cellular models of additional LSD.
    Keywords:  Gaucher’s disease; PIKfyve; Parkinson’s disease; integrated stress response; lysosomal storage disease
    DOI:  https://doi.org/10.1073/pnas.2320257121
  10. Methods Mol Biol. 2024 ;2831 113-132
    In Vitro and In Vivo Analysis of Neuronal Polarity.
    Mini Jose.
      Neuronal development is characterized by the unidirectional flow of signal from the axon to the dendrites via synapses. Neuronal polarization is a critical step during development that allows the specification of the different neuronal processes as a single axon and multiple dendrites both structurally and functionally, allowing the unidirectional flow of information. Along with extrinsic and intrinsic signaling, a whole network of molecular complexes involved in positive and negative feedback loops play a major role in this critical distinction of neuronal processes. As a result, neuronal morphology is drastically altered during establishment of polarity. In this chapter, we discuss how we can analyze the morphological alterations of neurons in vitro in culture to assess the development and polarity status of the neuron. We also discuss how these studies can be conducted in vivo, where polarity studies pose a greater challenge with promising results for addressing multiple pathological conditions. Our experimental model is limited to rodent hippocampal/cortical neurons in culture and cortical neurons in brain tissues, which are well-characterized model systems for understanding neuronal polarization.
    Keywords:  Antibodies; Axon; Dendrites; Imaging; Immunocytochemistry; Immunohistochemistry; In utero electroporation; Microscopy; Neuronal development and polarity; Primary rodent hippocampal/cortical neuronal cultures; Rodent brain slices
    DOI:  https://doi.org/10.1007/978-1-0716-3969-6_9
  11. Methods Mol Biol. 2024 ;2831 21-37
    Analysis of Neurite and Spine Formation in Neurons In Vitro.
    Jenny R Diaz, Martin J Sadowski.
      Primary neuronal cultures are commonly used to study genetic and exogenous factors influencing neuronal development and maturation. During development, neurons undergo robust morphological changes involving expansion of dendritic arbor, formation of dendritic spines, and expression of synaptic proteins. In this chapter, we will cover methodological approaches allowing quantitative assessment of in vitro cultured neurons. Various quantitative characteristics of dendritic arbor can be derived based on immunostaining against anti-microtubule-associated protein 2 followed by dendrite tracing with the SNT plug-in of the FIJI software package. The number and subtypes of dendritic spines can be assessed by double labeling with DiI and Phalloidin iFluor448 followed by laser scanning confocal microscopy analysis. Finally, expression of presynaptic and postsynaptic proteins can be determined by immunohistochemistry and quantification using several available software packages including FIJI and Imaris, which also allows for 3D rendering and statistical displaying of the expression level of synaptic proteins.
    Keywords:  Dendritic arbor; Dendritic spines; FIJI; Fluorescent microscopy; Imaris; Laser scanning confocal microscopy; Neuronal cultures; Synaptic proteins
    DOI:  https://doi.org/10.1007/978-1-0716-3969-6_3
  12. Front Neurosci. 2024 ;18 1437854
    Endoplasmic reticulum associated degradation preserves neurons viability by maintaining endoplasmic reticulum homeostasis.
    Shuangchan Wu, Pingting Liu, Marija Cvetanovic, Wensheng Lin.
      Endoplasmic reticulum-associated degradation (ERAD) is a principal quality-control mechanism responsible for targeting misfolded ER proteins for cytosolic degradation. Evidence suggests that impairment of ERAD contributes to neuron dysfunction and death in neurodegenerative diseases, many of which are characterized by accumulation and aggregation of misfolded proteins. However, the physiological role of ERAD in neurons remains unclear. The Sel1L-Hrd1 complex consisting of the E3 ubiquitin ligase Hrd1 and its adaptor protein Sel1L is the best-characterized ERAD machinery. Herein, we showed that Sel1L deficiency specifically in neurons of adult mice impaired the ERAD activity of the Sel1L-Hrd1 complex and led to disruption of ER homeostasis, ER stress and activation of the unfold protein response (UPR). Adult mice with Sel1L deficiency in neurons exhibited weight loss and severe motor dysfunction, and rapidly succumbed to death. Interestingly, Sel1L deficiency in neurons caused global brain atrophy, particularly cerebellar and hippocampal atrophy, in adult mice. Moreover, we found that cerebellar and hippocampal atrophy in these mice resulted from degeneration of Purkinje neurons and hippocampal neurons, respectively. These findings indicate that ERAD is required for maintaining ER homeostasis and the viability and function of neurons in adults under physiological conditions.
    Keywords:  ER stress; ER-associated degradation; Purkinje neuron; hippocampal neuron; neurodegeneration
    DOI:  https://doi.org/10.3389/fnins.2024.1437854
  13. J Cell Biol. 2024 Sep 02. pii: e202408028. [Epub ahead of print]223(9):
    EVs move messes, not messages, at the synapse.
    Marina N Bostelman, Heather T Broihier.
      Extracellular vesicles are known for intercellular signaling roles but can also serve to simply dispose of unwanted cargoes. In this issue, Bostelman and Broihier discuss new work from Rodal and colleagues (https://doi.org/10.1083/jcb.202405025) that refutes prior work by showing that extracellular vesicles at Drosophila neuromuscular junctions are not required for signaling and instead likely serve a proteostasis role.
    DOI:  https://doi.org/10.1083/jcb.202408028
  14. STAR Protoc. 2024 Aug 09. pii: S2666-1667(24)00377-0. [Epub ahead of print]5(3): 103212
    Protocol for the generation of cultured cortical brain organoid slices.
    Laura Petersilie, Karl W Kafitz, Louis A Neu, Sonja Heiduschka, Stephanie Le, Alessandro Prigione, Christine R Rose.
      Three-dimensional brain organoids from human pluripotent stem cells are a powerful tool for studying human neural networks. Here, we present a protocol for generating cortical brain organoid slices (cBOS) derived from regionalized cortical organoids and grown at the air-liquid interphase. We provide steps for slicing organoids and maintaining them in long-term culture. We then detail approaches for quality control including the evaluation of cell death and cellular identity. Finally, we describe procedures for the expression of a genetically encoded nanosensor for ATP. For complete details on the use and execution of this protocol, please refer to Petersilie et al.1.
    Keywords:  Cell culture; Microscopy; Neuroscience; Organoids
    DOI:  https://doi.org/10.1016/j.xpro.2024.103212
  15. Cell Mol Life Sci. 2024 Aug 13. 81(1): 347
    Novel CDKL5 targets identified in human iPSC-derived neurons.
    Sean Massey, Ching-Seng Ang, Nadia M Davidson, Anita Quigley, Ben Rollo, Alexander R Harris, Robert M I Kapsa, John Christodoulou, Nicole J Van Bergen.
      CDKL5 Deficiency Disorder (CDD) is a debilitating epileptic encephalopathy disorder affecting young children with no effective treatments. CDD is caused by pathogenic variants in Cyclin-Dependent Kinase-Like 5 (CDKL5), a protein kinase that regulates key phosphorylation events in neurons. For therapeutic intervention, it is essential to understand molecular pathways and phosphorylation targets of CDKL5. Using an unbiased phosphoproteomic approach we identified novel targets of CDKL5, including GTF2I, PPP1R35, GATAD2A and ZNF219 in human iPSC-derived neuronal cells. The phosphoserine residue in the target proteins lies in the CDKL5 consensus motif. We validated direct phosphorylation of GTF2I and PPP1R35 by CDKL5 using complementary approaches. GTF2I controls axon guidance, cell cycle and neurodevelopment by regulating expression of neuronal genes. PPP1R35 is critical for centriole elongation and cilia morphology, processes that are impaired in CDD. PPP1R35 interacts with CEP131, a known CDKL5 phospho-target. GATAD2A and ZNF219 belong to the Nucleosome Remodelling Deacetylase (NuRD) complex, which regulates neuronal activity-dependent genes and synaptic connectivity. In-depth knowledge of molecular pathways regulated by CDKL5 will allow a better understanding of druggable disease pathways to fast-track therapeutic development.
    Keywords:  CDKL5 deficiency disorder; GTF2I; Kinase; Neurodevelopmental disorder; PPP1R35; Phosphoproteomics; Phosphorylation
    DOI:  https://doi.org/10.1007/s00018-024-05389-8
  16. J Vis Exp. 2024 Jul 26.
    Generating and Co-culturing Murine Primary Microglia and Cortical Neurons.
    Jian Park, Ruoqi Yu, Yifei Dong.
      Microglia are tissue-resident macrophages of the central nervous system (CNS), performing numerous functions that support neuronal health and CNS homeostasis. They are a major population of immune cells associated with CNS disease activity, adopting reactive phenotypes that potentially contribute to neuronal injury during chronic neurodegenerative diseases such as multiple sclerosis (MS). The distinct mechanisms by which microglia regulate neuronal function and survival during health and disease remain limited due to challenges in resolving the complex in vivo interactions between microglia, neurons, and other CNS environmental factors. Thus, the in vitro approach of co-culturing microglia and neurons remains a valuable tool for studying microglia-neuronal interactions. Here, we present a protocol to generate and co-culture primary microglia and neurons from mice. Specifically, microglia were isolated after 9-10 days in vitro from a mixed glia culture established from brain homogenates derived from neonatal mice between post-natal days 0-2. Neuronal cells were isolated from brain cortices of mouse embryos between embryonic days 16-18. After 4-5 days in vitro, neuronal cells were seeded in 96-well plates, followed by the addition of microglia to form the co-culture. Careful timing is critical for this protocol as both cell types need to reach experimental maturity to establish the co-culture. Overall, this co-culture can be useful for studying microglia-neuron interactions and can provide multiple readouts, including immunofluorescence microscopy, live imaging, as well as RNA and protein assays.
    DOI:  https://doi.org/10.3791/67078
  17. Methods Mol Biol. 2024 ;2831 265-282
    Measuring Retrograde Actin Flow in Neuronal Growth Cones.
    Laura Pulido Cifuentes, Daniel M Suter.
      Actin flow refers to the motion of the F-actin cytoskeleton and has been observed in many different cell types, especially in motile cells including neuronal growth cones. The direction of the actin flow is generally retrograde from the periphery toward the center of the cell. Actin flow can be harnessed for forward movement of the cell through substrate-cytoskeletal coupling; thus, a key function of actin flow is in cell locomotion. In this chapter, we illustrate three different methods of quantifying retrograde F-actin flow in growth cones derived from cultured Aplysia bag cell neurons. These methods include tracking the movement of surface marker beads as well as kymograph analysis of time-lapse sequences acquired by differential interference contrast (DIC) imaging or fluorescent speckle microscopy (FSM). Due to their large size, Aplysia neuronal growth cones are uniquely suited for these methods; however, they can also be applied to any other growth cones with clear F-actin-rich peripheral domains.
    Keywords:  Actin cytoskeleton; Kymograph; Neuronal growth cone; Retrograde F-actin flow; Time-lapse imaging
    DOI:  https://doi.org/10.1007/978-1-0716-3969-6_18
This page is being maintained by Thomas Krichel. It was last updated on 2024‒08‒19 at 12:41.