Gunja K. Pathak scite author profile

Translation of mRNA in axons and dendrites enables a rapid supply of proteins to specific sites of localization within the neuron. Distinct mRNA-containing cargoes, including granules and mitochondrial mRNA, are transported within neuronal projections. The distributions of these cargoes appear to change during neuronal development, but details on the dynamics of mRNA transport during these transitions remain to be elucidated. For this study, we have developed imaging and image processing methods to quantify several transport parameters that can define the dynamics of RNA transport and localization. Using these methods, we characterized the transport of mitochondrial and non-mitochondrial mRNA in differentiated axons and dendrites of cultured hippocampal neurons varying in developmental maturity. Our results suggest differences in the transport profiles of mitochondrial and non-mitochondrial mRNA, and differences in transport parameters at different time points, and between axons and dendrites. Furthermore, within the non-mitochondrial mRNA pool, we observed two distinct populations that differed in their fluorescence intensity and velocity. The net axonal velocity of the brighter pool was highest at day 7 (0.002±0.001 µm/s, mean ± SEM), raising the possibility of a presynaptic requirement for mRNA during early stages of synapse formation. In contrast, the net dendritic velocity of the brighter pool increased steadily as neurons matured, with a significant difference between day 12 (0.0013±0.0006 µm/s ) and day 4 (−0.003±0.001 µm/s) suggesting a postsynaptic role for mRNAs in more mature neurons. The dim population showed similar trends, though velocities were two orders of magnitude higher than of the bright particles. This study provides a baseline for further studies on mRNA transport, and has important implications for the regulation of neuronal plasticity during neuronal development and in response to neuronal injury.

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Mouse hippocampal explant culture system to study isolated axons

Pathak

Aranda‐Espinoza

Shah

2014

Journal of Neuroscience Methods

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Variability in Membrane Continuity Between Schwann Cells and Neurons

et al. 2012

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Both Schwann cells (SCs) and neurons dynamically expand and contract their plasma membrane during their extension of projections and movement. However, these cell types have very different motility profiles and physiological function. We developed methods to measure the correlated movement of regions of plasma membrane, based on quantitative analysis of the movement of fluorescently labeled wheat-germ agglutinin (WGA) bound to the extracellular membrane. WGA trajectories were compared between SCs and neurons isolated from neonatal SpragueDawley rats, using both cross-correlation and regression analysis. Schwann cellular membranes exhibited significantly higher correlation (42.37 ± 5.87%, mean ± SEM) compared to neurons (24.51 ± 3.52%). Additionally, Schwann cellular membranes were more mobile (À0.165 ± 0.099 lm/min average velocity) compared to neurons (0.052 ± 0.032 lm/s). Comparison of both cell types upon establishment of contact with another neuron failed to identify any difference with the non-contacting state. Our results are suggestive of a role for forces generated by mobility on the biomechanical continuity of plasma membrane. Such forces are likely to interact with factors, including the cytoskeletal framework and adhesion proteins. This work has implications for interactions of neurons and SCs during development and neuronal regeneration.

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Characterization of fluorescent iron nanoparticles—candidates for multimodal tracking of neuronal transport

Godo¹,

Gaskell²,

Pathak³

et al. 2016

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Increases in Retrograde Injury Signaling Complex-Related Transcripts in Central Axons following Injury

et al. 2016

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Axons in the peripheral nervous system respond to injury by activating retrograde injury signaling (RIS) pathways, which promote local axonal protein synthesis (LPS) and neuronal regeneration. RIS is also initiated following injury of neurons in the central nervous system (CNS). However, regulation of the localization of axonal mRNA required for LPS is not well understood. We used a hippocampal explant system to probe the regulation of axonal levels of RIS-associated transcripts following axonal injury. Axonal levels of importin β1 and RanBP1 were elevated biphasically at 1 and 24 hrs after axotomy. Transcript levels for β-actin, a prototypic axonally synthesized protein, were similarly elevated. Our data suggest differential regulation of axonal transcripts. At 1 hr after injury, deployment of actinomycin revealed that RanBP1, but not importin β1, requires de novo mRNA synthesis. At 24 hrs after injury, use of importazole revealed that the second wave of increased axonal mRNA levels required importin β-mediated nuclear import. We also observed increased importin β1 axonal protein levels at 1 and 6 hrs after injury. RanBP1 levels and vimentin levels fluctuated but were unchanged at 3 and 6 hrs after injury. This study revealed temporally complex regulation of axonal transcript levels, and it has implications for understanding neuronal response to injury in the CNS.

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Gunja K. Pathak

A Comparative Quantitative Assessment of Axonal and Dendritic mRNA Transport in Maturing Hippocampal Neurons

Mouse hippocampal explant culture system to study isolated axons

Variability in Membrane Continuity Between Schwann Cells and Neurons

Characterization of fluorescent iron nanoparticles—candidates for multimodal tracking of neuronal transport

Increases in Retrograde Injury Signaling Complex-Related Transcripts in Central Axons following Injury

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