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1. Neuronal Growth and Formation of Neuron Networks on Directional Surfaces

   https://doi.org/10.3390/biomimetics6020041  

   Yurchenko, Ilya; Farwell, Matthew; Brady, Donovan D.; Staii, Cristian (June 2021, Biomimetics)

   The formation of neuron networks is a process of fundamental importance for understanding the development of the nervous system and for creating biomimetic devices for tissue engineering and neural repair. The basic process that controls the network formation is the growth of an axon from the cell body and its extension towards target neurons. Axonal growth is directed by environmental stimuli that include intercellular interactions, biochemical cues, and the mechanical and geometrical properties of the growth substrate. Despite significant recent progress, the steering of the growing axon remains poorly understood. In this paper, we develop a model of axonal motility, which incorporates substrate-geometry sensing. We combine experimental data with theoretical analysis to measure the parameters that describe axonal growth on micropatterned surfaces: diffusion (cell motility) coefficients, speed and angular distributions, and cell-substrate interactions. Experiments performed on neurons treated with inhibitors for microtubules (Taxol) and actin filaments (Y-27632) indicate that cytoskeletal dynamics play a critical role in the steering mechanism. Our results demonstrate that axons follow geometrical patterns through a contact-guidance mechanism, in which geometrical patterns impart high traction forces to the growth cone. These results have important implications for bioengineering novel substrates to guide neuronal growth and promote nerve repair. 

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2. A new view of axon growth and guidance grounded in the stochastic dynamics of actin networks

   https://doi.org/10.1098/rsob.220359  

   Forghani, Rameen; Chandrasekaran, Aravind; Papoian, Garegin; Giniger, Edward (June 2023, Open Biology)

   The mechanism of axon growth and guidance is a core, unsolved problem in neuroscience and cell biology. For nearly three decades, our view of this process has largely been based on deterministic models of motility derived from studies of neurons cultured in vitro on rigid substrates. Here, we suggest a fundamentally different, inherently probabilistic model of axon growth, one that is grounded in the stochastic dynamics of actin networks. This perspective is motivated and supported by a synthesis of results from live imaging of a specific axon growing in its native tissue in vivo , together with single-molecule computational simulations of actin dynamics. In particular, we show how axon growth arises from a small spatial bias in the intrinsic fluctuations of the axonal actin cytoskeleton, one that produces net translocation of the axonal actin network by differentially modulating local probabilities of network expansion versus compaction. We discuss the relationship between this model and current views of axon growth and guidance mechanism and demonstrate how it offers explanations for various longstanding puzzles in this field. We further point out the implications of the probabilistic nature of actin dynamics for many other processes of cell morphology and motility. 

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3. Spatiotemporal analysis of axonal autophagosome–lysosome dynamics reveals limited fusion events and slow maturation

   https://doi.org/10.1091/mbc.E22-03-0111  

   Cason, Sydney E.; Mogre, Saurabh S.; Holzbaur, Erika L.; Koslover, Elena F. (November 2022, Molecular Biology of the Cell)

   Edelstein-Keshet, Leah (Ed.)

   Macroautophagy is a homeostatic process required to clear cellular waste. Neuronal autophagosomes form constitutively in the distal tip of the axon and are actively transported toward the soma, with cargo degradation initiated en route. Cargo turnover requires autophagosomes to fuse with lysosomes to acquire degradative enzymes; however, directly imaging these fusion events in the axon is impractical. Here we use a quantitative model, parameterized and validated using data from primary hippocampal neurons, to explore the autophagosome maturation process. We demonstrate that retrograde autophagosome motility is independent of fusion and that most autophagosomes fuse with only a few lysosomes during axonal transport. Our results indicate that breakdown of the inner autophagosomal membrane is much slower in neurons than in nonneuronal cell types, highlighting the importance of this late maturation step. Together, rigorous quantitative measurements and mathematical modeling elucidate the dynamics of autophagosome–lysosome interaction and autophagosomal maturation in the axon. 

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4. Axon determination of subtype specific myelin ensheathment and pruning

   Nelson, HN; Treichel, AJ; Eggum, EN; Martell, MR; Kaiser, AJ; Trudel, AG; Gronseth, JR; Maas, ST; Bergen, S; Hines, JH (January 2019, Annual meeting of the Society for Neuroscience)

   In the developing central nervous system, pre-myelinating oligodendrocytes contact and sample candidate nerve axons by extending and retracting process extensions. Some contacts stabilize and mature, leading to the initiation of axon wrapping, myelin sheath formation, and sheath elongation by oligodendrocytes. Although axonal signals influence the overall process of myelination, which precise steps and oligodendrocyte cell behaviors require signaling from axons is incompletely understood. In this study, we investigated whether cell behaviors during the early events of myelination involve input from axons or are mediated by an oligodendrocyte-autonomous myelination program. To address this, we utilized in vivo time-lapse imaging in embryonic and larval zebrafish during the initial hours and days of axon wrapping and myelination. Transgenic reporter lines marked individual axon subtypes or oligodendrocyte membranes. In the larval zebrafish spinal cord, individual axon subtypes supported distinct nascent sheath growth rates and pruning frequencies. Oligodendrocytes ensheathed individual axon subtypes at different rates during a two-day period after initial axon wrapping. When the ratio of oligodendrocytes to target axons was increased by ablating spinal projection axons, local spinal neuron axons supported a constant ensheathment rate despite the increased ratio of oligodendrocytes to target axons. We conclude that properties of individual axon subtypes instruct oligodendrocyte behaviors during initial stages of myelination by differentially controlling nascent sheath growth and stabilization. 

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5. Individual neuronal subtypes control initial myelin sheath growth and stabilization

   https://doi.org/10.1186/s13064-020-00149-3  

   Nelson, Heather N.; Treichel, Anthony J.; Eggum, Erin N.; Martell, Madeline R.; Kaiser, Amanda J.; Trudel, Allie G.; Gronseth, James R.; Maas, Samantha T.; Bergen, Silas; Hines, Jacob H. (December 2020, Neural Development)

   null (Ed.)

   Abstract Background In the developing central nervous system, pre-myelinating oligodendrocytes sample candidate nerve axons by extending and retracting process extensions. Some contacts stabilize, leading to the initiation of axon wrapping, nascent myelin sheath formation, concentric wrapping and sheath elongation, and sheath stabilization or pruning by oligodendrocytes. Although axonal signals influence the overall process of myelination, the precise oligodendrocyte behaviors that require signaling from axons are not completely understood. In this study, we investigated whether oligodendrocyte behaviors during the early events of myelination are mediated by an oligodendrocyte-intrinsic myelination program or are over-ridden by axonal factors. Methods To address this, we utilized in vivo time-lapse imaging in embryonic and larval zebrafish spinal cord during the initial hours and days of axon wrapping and myelination. Transgenic reporter lines marked individual axon subtypes or oligodendrocyte membranes. Results In the larval zebrafish spinal cord, individual axon subtypes supported distinct nascent sheath growth rates and stabilization frequencies. Oligodendrocytes ensheathed individual axon subtypes at different rates during a two-day period after initial axon wrapping. When descending reticulospinal axons were ablated, local spinal axons supported a constant ensheathment rate despite the increased ratio of oligodendrocytes to target axons. Conclusion We conclude that properties of individual axon subtypes instruct oligodendrocyte behaviors during initial stages of myelination by differentially controlling nascent sheath growth and stabilization. 

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