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2. Synaptic branch stability is mediated by non-enzymatic functions of MEC-17/αTAT1 and ATAT-2

Author

Jean-Sébastien Teoh, Amruta Vasudevan, Wenyue Wang, Samiksha Dhananjay, Gursimran Chandhok, Roger Pocock, Sandhya P. Koushika, and Brent Neumann

Subjects
Medicine, Science
Abstract

Abstract Microtubules are fundamental elements of neuronal structure and function. They are dynamic structures formed from protofilament chains of α- and β-tubulin heterodimers. Acetylation of the lysine 40 (K40) residue of α-tubulin protects microtubules from mechanical stresses by imparting structural elasticity. The enzyme responsible for this acetylation event is MEC-17/αTAT1. Despite its functional importance, however, the consequences of altered MEC-17/αTAT1 levels on neuronal structure and function are incompletely defined. Here we demonstrate that overexpression or loss of MEC-17, or of its functional paralogue ATAT-2, causes a delay in synaptic branch extension, and defective synaptogenesis in the mechanosensory neurons of Caenorhabditis elegans. Strikingly, by adulthood, the synaptic branches in these animals are lost, while the main axon shaft remains mostly intact. We show that MEC-17 and ATAT-2 regulate the stability of the synaptic branches largely independently from their acetyltransferase domains. Genetic analyses reveals novel interactions between both mec-17 and atat-2 with the focal adhesion gene zyx-1/Zyxin, which has previously been implicated in actin remodelling. Together, our results reveal new, acetylation-independent roles for MEC-17 and ATAT-2 in the development and maintenance of neuronal architecture.

Published
2022
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3. Maintaining robust size across environmental conditions through plastic brain growth dynamics

Author

Ansa E. Cobham, Brent Neumann, and Christen K. Mirth

Subjects
whole brain, mushroom bodies, insulin signalling, growth rate, plasticity, robustness, Biology (General), QH301-705.5
Abstract

Organ growth is tightly regulated across environmental conditions to generate an appropriate final size. While the size of some organs is free to vary, others need to maintain constant size to function properly. This poses a unique problem: how is robust final size achieved when environmental conditions alter key processes that regulate organ size throughout the body, such as growth rate and growth duration? While we know that brain growth is ‘spared’ from the effects of the environment from humans to fruit flies, we do not understand how this process alters growth dynamics across brain compartments. Here, we explore how this robustness in brain size is achieved by examining differences in growth patterns between the larval body, the brain and a brain compartment—the mushroom bodies—in Drosophila melanogaster across both thermal and nutritional conditions. We identify key differences in patterns of growth between the whole brain and mushroom bodies that are likely to underlie robustness of final organ shape. Further, we show that these differences produce distinct brain shapes across environments.

Published
2022
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4. Disruption of genes associated with Charcot-Marie-Tooth type 2 lead to common behavioural, cellular and molecular defects in Caenorhabditis elegans.

Author

Ming S Soh, Xinran Cheng, Tarika Vijayaraghavan, Arwen Vernon, Jie Liu, and Brent Neumann

Subjects
Medicine, Science
Abstract

Charcot-Marie-Tooth (CMT) disease is an inherited peripheral motor and sensory neuropathy. The disease is divided into demyelinating (CMT1) and axonal (CMT2) neuropathies, and although we have gained molecular information into the details of CMT1 pathology, much less is known about CMT2. Due to its clinical and genetic heterogeneity, coupled with a lack of animal models, common underlying mechanisms remain elusive. In order to gain an understanding of the normal function of genes associated with CMT2, and to draw direct comparisons between them, we have studied the behavioural, cellular and molecular consequences of mutating nine different genes in the nematode Caenorhabditis elegans (lin-41/TRIM2, dyn-1/DNM2, unc-116/KIF5A, fzo-1/MFN2, osm-9/TRPV4, cua-1/ATP7A, hsp-25/HSPB1, hint-1/HINT1, nep-2/MME). We show that C. elegans defective for these genes display debilitated movement in crawling and swimming assays. Severe morphological defects in cholinergic motors neurons are also evident in two of the mutants (dyn-1 and unc-116). Furthermore, we establish methods for quantifying muscle morphology and use these to demonstrate that loss of muscle structure occurs in the majority of mutants studied. Finally, using electrophysiological recordings of neuromuscular junction (NMJ) activity, we uncover reductions in spontaneous postsynaptic current frequency in lin-41, dyn-1, unc-116 and fzo-1 mutants. By comparing the consequences of mutating numerous CMT2-related genes, this study reveals common deficits in muscle structure and function, as well as NMJ signalling when these genes are disrupted.

Published
2020
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5. Bridging the gap: axonal fusion drives rapid functional recovery of the nervous system

Author

Jean-Sébastien Teoh, Michelle Yu-Ying Wong, Tarika Vijayaraghavan, and Brent Neumann

Subjects
axonal fusion, axon regeneration, nervous system repair, nerve injury, phosphatidylserine, functional repair, axonal transport, Caenorhabditis elegans, Neurology. Diseases of the nervous system, RC346-429
Abstract

Injuries to the central or peripheral nervous system frequently cause long-term disabilities because damaged neurons are unable to efficiently self-repair. This inherent deficiency necessitates the need for new treatment options aimed at restoring lost function to patients. Compared to humans, a number of species possess far greater regenerative capabilities, and can therefore provide important insights into how our own nervous systems can be repaired. In particular, several invertebrate species have been shown to rapidly initiate regeneration post-injury, allowing separated axon segments to re-join. This process, known as axonal fusion, represents a highly efficient repair mechanism as a regrowing axon needs to only bridge the site of damage and fuse with its separated counterpart in order to re-establish its original structure. Our recent findings in the nematode Caenorhabditis elegans have expanded the promise of axonal fusion by demonstrating that it can restore complete function to damaged neurons. Moreover, we revealed the importance of injury-induced changes in the composition of the axonal membrane for mediating axonal fusion, and discovered that the level of axonal fusion can be enhanced by promoting a neuron's intrinsic growth potential. A complete understanding of the molecular mechanisms controlling axonal fusion may permit similar approaches to be applied in a clinical setting.

Published
2018
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6. The Heterochronic Gene lin-14 Controls Axonal Degeneration in C. elegans Neurons

Author

Fiona K. Ritchie, Rhianna Knable, Justin Chaplin, Rhiannon Gursanscky, Maria Gallegos, Brent Neumann, and Massimo A. Hilliard

Subjects
LIN-14, axonal degeneration, axonal embedment, epidermis, hypodermis, C. elegans, heterochronic gene, mechanosensory neurons, motor neurons, Biology (General), QH301-705.5
Abstract

The disproportionate length of an axon makes its structural and functional maintenance a major task for a neuron. The heterochronic gene lin-14 has previously been implicated in regulating the timing of key developmental events in the nematode C. elegans. Here, we report that LIN-14 is critical for maintaining neuronal integrity. Animals lacking lin-14 display axonal degeneration and guidance errors in both sensory and motor neurons. We demonstrate that LIN-14 functions both cell autonomously within the neuron and non-cell autonomously in the surrounding tissue, and we show that interaction between the axon and its surrounding tissue is essential for the preservation of axonal structure. Furthermore, we demonstrate that lin-14 expression is only required during a short period early in development in order to promote axonal maintenance throughout the animal’s life. Our results identify a crucial role for LIN-14 in preventing axonal degeneration and in maintaining correct interaction between an axon and its surrounding tissue.

Published
2017
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7. Loss of MEC-17 Leads to Microtubule Instability and Axonal Degeneration

Author

Brent Neumann and Massimo A. Hilliard

Subjects
Biology (General), QH301-705.5
Abstract

Axonal degeneration arises as a consequence of neuronal injury and is a common hallmark of a number of neurodegenerative diseases. However, the genetic causes and the cellular mechanisms that trigger this process are still largely unknown. Based on forward genetic screening in C. elegans, we have identified the α-tubulin acetyltransferase gene mec-17 as causing spontaneous, adult-onset, and progressive axonal degeneration. Loss of MEC-17 leads to microtubule instability, a reduction in mitochondrial number, and disrupted axonal transport, with altered distribution of both mitochondria and synaptic components. Furthermore, mec-17-mediated axonal degeneration occurs independently from its acetyltransferase domain; is enhanced by mutation of coel-1, a tubulin-associated molecule; and correlates with the animal’s body length. This study therefore identifies a critical role for the conserved microtubule-associated protein MEC-17 in preserving axon integrity and preventing axonal degeneration.

Published
2014
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8. The dynamin GTPase mediates regenerative axonal fusion in Caenorhabditis elegans by regulating fusogen levels

Author

Tarika Vijayaraghavan, Samiksha Dhananjay, Xue Yan Ho, Rosina Giordano-Santini, Massimo Hilliard, and Brent Neumann

Abstract

Axonal fusion is a neuronal repair mechanism that results in the reconnection of severed axon fragments, leading to the restoration of cytoplasmic continuity and neuronal function. While synaptic vesicle recycling has been linked to axonal regeneration, its role in axonal fusion remains unknown. Dynamin proteins are large GTPases that hydrolyze lipid-binding membranes to carry out clathrin-mediated synaptic vesicle recycling. Here, we show that the Caenorhabditis elegans dynamin protein DYN-1 is a key component of the axonal fusion machinery. Animals carrying a temperature-sensitive allele of dyn-1(ky51) displayed wild-type levels of axonal fusion at the permissive temperature (15°C) but presented strongly reduced levels at the restrictive temperature (25°C). Furthermore, the average length of regrowth was significantly diminished in dyn-1(ky51) animals at the restrictive temperature. The expression of wild-type DYN-1 cell-autonomously into dyn-1(ky51) mutant animals rescued both the axonal fusion and regrowth defects. Furthermore, DYN-1 was not required prior to axonal injury, suggesting that it functions specifically after injury to control axonal fusion. Finally, using epistatic analyses and superresolution imaging, we demonstrate that DYN-1 regulates the levels of the fusogen protein EFF-1 post-injury to mediate axonal fusion. Together, these results establish DYN-1 as a novel regulator of axonal fusion.

Published
2023
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9. Charcot–Marie–tooth disease causing mutation (p.R158H) in pyruvate dehydrogenase kinase 3 (PDK3) affects synaptic transmission, ATP production and causes neurodegeneration in a CMTX6 C. elegans model

Author

Gonzalo Perez-Siles, Melina Ellis, Andrew Burgess, Megan H. Brewer, Steve Vucic, Ramesh K Narayanan, Garth A. Nicholson, Marina L. Kennerson, Brent Neumann, and Carolyn Ly

Subjects
AcademicSubjects/SCI01140, Pyruvate dehydrogenase kinase, Mutant, Biology, Neurotransmission, medicine.disease_cause, Synaptic Transmission, Adenosine Triphosphate, In vivo, Charcot-Marie-Tooth Disease, Genetics, medicine, Animals, Humans, Caenorhabditis elegans, Molecular Biology, Genetics (clinical), Mutation, Neurodegeneration, Wild type, Pyruvate Dehydrogenase Acetyl-Transferring Kinase, General Medicine, medicine.disease, Phenotype, Cell biology, General Article
Abstract

Charcot–Marie-Tooth (CMT) is a commonly inherited, non-fatal neurodegenerative disorder that affects sensory and motor neurons in patients. More than 90 genes are known to cause axonal and demyelinating forms of CMT. The p.R158H mutation in the pyruvate dehydrogenase kinase 3 (PDK3) gene is the genetic cause for an X linked form of axonal CMT (CMTX6). In vitro studies using patient fibroblasts and iPSC-derived motor neurons have shown that this mutation causes deficits in energy metabolism and mitochondrial function. Animal models that recapitulate pathogenic in vivo events in patients are crucial for investigating mechanisms of axonal degeneration and developing therapies for CMT. We have developed a C. elegans model of CMTX6 by knocking-in the p.R158H mutation in pdhk-2, the ortholog of PDK3. In addition, we have developed animal models overexpressing the wild type and mutant form of human PDK3 specifically in the GABAergic motor neurons of C. elegans. CMTX6 mutants generated in this study exhibit synaptic transmission deficits, locomotion defects and show signs of progressive neurodegeneration. Furthermore, the CMTX6 in vivo models display energy deficits that recapitulate the phenotype observed in patient fibroblasts and iPSC-derived motor neurons. Our CMTX6 animals represent the first in vivo model for this form of CMT and have provided novel insights into the cellular function and metabolic pathways perturbed by the p.R158H mutation, all the while closely replicating the clinical presentation observed in CMTX6 patients.

Published
2021

10. Novel gene-intergenic fusion involving ubiquitin E3 ligase UBE3C causes distal hereditary motor neuropathy: A new mechanism for motor neuron degeneration

Author

Anthony N. Cutrupi, Ramesh K. Narayanan, Gonzalo Perez-Siles, Bianca R. Grosz, Kaitao Lai, Alexandra Boyling, Melina Ellis, Ruby CY Lin, Brent Neumann, Di Mao, Motonari Uesugi, Garth A. Nicholson, Steve Vucic, Mario A. Saporta, and Marina L. Kennerson

Abstract

Distal hereditary motor neuropathies (dHMNs) are a group of inherited diseases involving the progressive, length-dependent axonal degeneration of the lower motor neurons. There are currently 29 reported causative genes and 4 disease loci implicated in dHMN. Despite the high genetic heterogeneity, mutations in the known genes account for less than 20% of dHMN cases with the mutations identified predominantly being point mutations or indels. We have expanded the spectrum of dHMN mutations with the identification of a 1.35 Mb complex structural variation (SV) causing a form of autosomal dominant dHMN (DHMN1 OMIM %182906). Given the complex nature of SV mutations and the importance of studying pathogenic mechanisms in a neuronal setting, we generated a patient-derived DHMN1 motor neuron model harbouring the 1.35 Mb complex insertion. The DHMN1 complex insertion creates a duplicated copy of the first 10 exons of the ubiquitin-protein E3 ligase gene (UBE3C) and forms a novel gene-intergenic fusion sense transcript by incorporating a terminal pseudo-exon from intergenic sequence within the DHMN1 locus. The UBE3C intergenic fusion (UBE3C-IF) transcript does not undergo nonsense-mediated decay and results in a significant reduction of wild type full length UBE3C (UBE3C-WT) protein levels in DHMN1 iPSC-derived motor neurons. An engineered transgenic C. elegans model expressing the UBE3C-IF transcript in GABA-ergic motor neurons shows neuronal synaptic transmission deficits. Furthermore, the transgenic animals are susceptible to heat stress which may implicate defective protein homeostasis underlying DHMN1 pathogenesis. Identification of the novel UBE3C-IF gene-intergenic fusion transcript in motor neurons highlights a potential new disease mechanism underlying axonal and motor neuron degeneration. These complementary models serve as a powerful paradigm for studying the DHMN1 complex SV and an invaluable tool for defining therapeutic targets for DHMN1.

Published
2022
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12. Novel gene-intergenic fusion involving ubiquitin E3 ligase UBE3C causes distal hereditary motor neuropathy

Author

Anthony N Cutrupi, Ramesh K Narayanan, Gonzalo Perez-Siles, Bianca R Grosz, Kaitao Lai, Alexandra Boyling, Melina Ellis, Ruby C Y Lin, Brent Neumann, Di Mao, Motonari Uesugi, Garth A Nicholson, Steve Vucic, Mario A Saporta, and Marina L Kennerson

Subjects
Neurology (clinical)
Abstract

Distal hereditary motor neuropathies (dHMNs) are a group of inherited diseases involving the progressive, length-dependent axonal degeneration of the lower motor neurons. There are currently 29 reported causative genes and four disease loci implicated in dHMN. Despite the high genetic heterogeneity, mutations in the known genes account for less than 20% of dHMN cases, with the mutations identified predominantly being point mutations or indels. We have expanded the spectrum of dHMN mutations with the identification of a 1.35 Mb complex structural variation (SV) causing a form of autosomal dominant dHMN (DHMN1 OMIM %182906). Given the complex nature of SV mutations and the importance of studying pathogenic mechanisms in a neuronal setting, we generated a patient-derived DHMN1 motor neuron model harbouring the 1.35 Mb complex insertion. The DHMN1 complex insertion creates a duplicated copy of the first 10 exons of the ubiquitin-protein E3 ligase gene (UBE3C) and forms a novel gene–intergenic fusion sense transcript by incorporating a terminal pseudo-exon from intergenic sequence within the DHMN1 locus. The UBE3C intergenic fusion (UBE3C-IF) transcript does not undergo nonsense-mediated decay and results in a significant reduction of wild-type full-length UBE3C (UBE3C-WT) protein levels in DHMN1 iPSC-derived motor neurons. An engineered transgenic Caenorhabditis elegans model expressing the UBE3C-IF transcript in GABA-ergic motor neurons shows neuronal synaptic transmission deficits. Furthermore, the transgenic animals are susceptible to heat stress, which may implicate defective protein homeostasis underlying DHMN1 pathogenesis. Identification of the novel UBE3C-IF gene–intergenic fusion transcript in motor neurons highlights a potential new disease mechanism underlying axonal and motor neuron degeneration. These complementary models serve as a powerful paradigm for studying the DHMN1 complex SV and an invaluable tool for defining therapeutic targets for DHMN1.

Published
2022

14. Novel putative interactors of FZO-1/mitofusin 2 identified using large-scale yeast two-hybrid screening in C. elegans

Author

Samiksha, Dhananjay, Brent, Neumann, and Gursimran, Chandhok

Abstract

Mitochondria are dynamic organelles with a unique ability to transition between opposing fusion and fission states, resulting in changes in their morphology and movement, and allowing them to exist in large interconnected networks. This ability to shift between fusion/fission states allows mitochondria to adapt to changing cellular conditions and maintain their essential functions in meeting cellular bioenergetic demands, regulating intracellular Ca2+, and mediating the cellular stress response (Chandhok et al. 2018). The fusion process allows material to be exchanged between mitochondria, providing a method for damaged mitochondria to regain essential components and thus mitigate stress (Ono et al. 2001). In contrast, fission largely serves as a quality control measure by allowing deteriorated components of damaged mitochondria to be budded off for targeted breakdown via autophagy or mitophagy (Westermann 2012). Thus, dysfunctional mitochondrial dynamics can have detrimental consequences for organelle function and are intricately linked to cellular health (Yapa et al. 2021).

Published
2022
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15. Mutation of the H12-helix of α-tubulin/MEC-12 disrupts the localization of neuronal mitochondria

Author

Jean-Sébastien, Teoh, Samiksha, Dhananjay, and Brent, Neumann

Abstract

The three main components of a neuron (dendrites, soma, and axon) differ in both cellular structure and function (Kueh and Mitchison 2009, Akhmanova and Steinmetz 2015, Brouhard and Rice 2018). Many proteins that are synthesized in the soma are transported in a tightly regulated fashion to reach their required destination in the dendrites or axons. Microtubules form the structural network that allows and regulates this polarized transport of neuronal proteins (Kueh and Mitchison 2009, Akhmanova and Steinmetz 2015). Microtubules assemble from α- and β-tubulin heterodimers to form hollow cylinders that are subjected to post-translational modification and interaction with a variety of microtubule associated proteins (MAPs) (Desai and Mitchison 1997, Wloga and Gaertig 2010). Previous studies have suggested that molecular motor proteins including kinesin and dynein share a highly conserved and overlapping regulatory region at the C-terminus of α-tubulin, the H12-helix (Mizuno, Toba et al. 2004, Kikkawa and Hirokawa 2006, Tischfield, Baris et al. 2010, Redwine, Hernandez-Lopez et al. 2012, Niwa, Takahashi et al. 2013, Hsu, Chen et al. 2014, Uchimura, Fujii et al. 2015). The N-terminus of this highly conserved helix consists of acidic residues (414-417: EEGE) that are important for the interaction between kinesin, dynein, and microtubules (Hsu, Chen et al. 2014). Here, we studied the function of the H12-helix in regulating mitochondrial localization in the posterior lateral microtubule (PLM) neurons of Caenorhabditis elegans.

Published
2022
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16. Disruption of mitochondrial dynamics affects behaviour and lifespan in Caenorhabditis elegans

Author

Brent Neumann, Simon Crawford, Ansa Emmanuel Cobham, Jean-Sébastien Teoh, Ming S. Soh, Christen K. Mirth, Nethmi M. B. Yapa, Joseph J. Byrne, Tarika Vijayaraghavan, and Gursimran Chandhok

Subjects
Dynamins, FZO-1, Longevity, Calcium buffering, Kaplan-Meier Estimate, DRP1, Mitochondrion, Mitochondrial Dynamics, OPA1, GTP Phosphohydrolases, Mitochondrial Proteins, 03 medical and health sciences, Cellular and Molecular Neuroscience, Mitofusin-2, 0302 clinical medicine, Microscopy, Electron, Transmission, Mitofusin 1, Mitofusin 2, Animals, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Inner mitochondrial membrane, Molecular Biology, 030304 developmental biology, Neurons, Pharmacology, 0303 health sciences, biology, Cell Biology, EAT-3, biology.organism_classification, Fusion protein, Mitochondria, Mitochondria, Muscle, DRP-1, Cell biology, mitochondrial fusion, Mutation, Molecular Medicine, Original Article, Mitochondrial fission, Transmission electron microscopy, 030217 neurology & neurosurgery
Abstract

Mitochondria are essential components of eukaryotic cells, carrying out critical physiological processes that include energy production and calcium buffering. Consequently, mitochondrial dysfunction is associated with a range of human diseases. Fundamental to their function is the ability to transition through fission and fusion states, which is regulated by several GTPases. Here, we have developed new methods for the non-subjective quantification of mitochondrial morphology in muscle and neuronal cells of Caenorhabditis elegans. Using these techniques, we uncover surprising tissue-specific differences in mitochondrial morphology when fusion or fission proteins are absent. From ultrastructural analysis, we reveal a novel role for the fusion protein FZO-1/mitofusin 2 in regulating the structure of the inner mitochondrial membrane. Moreover, we have determined the influence of the individual mitochondrial fission (DRP-1/DRP1) and fusion (FZO-1/mitofusin 1,2; EAT-3/OPA1) proteins on animal behaviour and lifespan. We show that loss of these mitochondrial fusion or fission regulators induced age-dependent and progressive deficits in animal movement, as well as in muscle and neuronal function. Our results reveal that disruption of fusion induces more profound defects than lack of fission on animal behaviour and tissue function, and imply that while fusion is required throughout life, fission is more important later in life likely to combat ageing-associated stressors. Furthermore, our data demonstrate that mitochondrial function is not strictly dependent on morphology, with no correlation found between morphological changes and behavioural defects. Surprisingly, we find that disruption of either mitochondrial fission or fusion significantly reduces median lifespan, but maximal lifespan is unchanged, demonstrating that mitochondrial dynamics play an important role in limiting variance in longevity across isogenic populations. Overall, our study provides important new insights into the central role of mitochondrial dynamics in maintaining organismal health. Electronic supplementary material The online version of this article (10.1007/s00018-019-03024-5) contains supplementary material, which is available to authorized users.

Published
2019
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17. Bridging the gap: axonal fusion drives rapid functional recovery of the nervous system

Author

Brent Neumann, Jean-Sébastien Teoh, Michelle Yu-Ying Wong, and Tarika Vijayaraghavan

Subjects
0301 basic medicine, Nervous system, phosphatidylserine, Biology, lcsh:RC346-429, axonal fusion, 03 medical and health sciences, 0302 clinical medicine, Developmental Neuroscience, medicine, Axon, Caenorhabditis elegans, lcsh:Neurology. Diseases of the nervous system, Invited Review, Mechanism (biology), Regeneration (biology), axon regeneration, nervous system repair, nerve injury, functional repair, axonal transport, Nerve injury, 030104 developmental biology, medicine.anatomical_structure, nervous system, Peripheral nervous system, Axoplasmic transport, Neuron, medicine.symptom, Neuroscience, 030217 neurology & neurosurgery
Abstract

Injuries to the central or peripheral nervous system frequently cause long-term disabilities because damaged neurons are unable to efficiently self-repair. This inherent deficiency necessitates the need for new treatment options aimed at restoring lost function to patients. Compared to humans, a number of species possess far greater regenerative capabilities, and can therefore provide important insights into how our own nervous systems can be repaired. In particular, several invertebrate species have been shown to rapidly initiate regeneration post-injury, allowing separated axon segments to re-join. This process, known as axonal fusion, represents a highly efficient repair mechanism as a regrowing axon needs to only bridge the site of damage and fuse with its separated counterpart in order to re-establish its original structure. Our recent findings in the nematode Caenorhabditis elegans have expanded the promise of axonal fusion by demonstrating that it can restore complete function to damaged neurons. Moreover, we revealed the importance of injury-induced changes in the composition of the axonal membrane for mediating axonal fusion, and discovered that the level of axonal fusion can be enhanced by promoting a neuron's intrinsic growth potential. A complete understanding of the molecular mechanisms controlling axonal fusion may permit similar approaches to be applied in a clinical setting.

Published
2018

19. Quantitative Approaches for Studying Cellular Structures and Organelle Morphology in Caenorhabditis elegans

Author

Jean-Sébastien, Teoh, Ming S, Soh, Joseph J, Byrne, and Brent, Neumann

Subjects
Organelles, Microscopy, Confocal, Phenotype, Muscles, Mutation, Synapses, Image Processing, Computer-Assisted, Animals, Caenorhabditis elegans, Mitochondria
Abstract

Defining the cellular mechanisms underlying disease is essential for the development of novel therapeutics. A strategy frequently used to unravel these mechanisms is to introduce mutations in candidate genes and qualitatively describe changes in the morphology of tissues and cellular organelles. However, qualitative descriptions may not capture subtle phenotypic differences, might misrepresent phenotypic variations across individuals in a population, and are frequently assessed subjectively. Here, quantitative approaches are described to study the morphology of tissues and organelles in the nematode Caenorhabditis elegans using laser scanning confocal microscopy combined with commercially available bio-image processing software. A quantitative analysis of phenotypes affecting synapse integrity (size and integrated fluorescence levels), muscle development (muscle cell size and myosin filament length), and mitochondrial morphology (circularity and size) was performed to understand the effects of genetic mutations on these cellular structures. These quantitative approaches are not limited to the applications described here, as they could readily be used to quantitatively assess the morphology of other tissues and organelles in the nematode, as well as in other model organisms.

Published
2019

20. Development and maintenance of synaptic structure is mediated by the alpha-tubulin acetyltransferase MEC-17/αTAT1

Author

Brent Neumann, Wang W, Teoh J, Roger Pocock, and Chandhok G

Subjects
0303 health sciences, Chemistry, Synaptogenesis, 3. Good health, Zyxin, Cell biology, Focal adhesion, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Acetylation, Acetyltransferase, 030217 neurology & neurosurgery, Loss function, Actin, 030304 developmental biology
Abstract

Microtubules are fundamental elements of neuronal structure and function. They are dynamic structures formed from protofilament chains of α- and β-tubulin heterodimers. Acetylation of the lysine 40 (K40) residue of α-tubulin protects microtubules from mechanical stresses by imparting structural elasticity. The enzyme responsible for this acetylation event is MEC-17/αTAT1. However, despite its functional importance, the consequences of MEC-17/αTAT1 misregulation on neuronal structure and function are incompletely defined. Using overexpression and loss of function approaches, we have analysed the effects of MEC-17 misregulation on the development and maintenance of synaptic branches in the mechanosensory neurons of Caenorhabditis elegans . We find that synaptic branch extension is delayed, and that synaptogenesis is defective in these animals. Strikingly, by adulthood the synaptic branches specifically and spontaneously degenerate. This phenotype is dependent on the acetyltransferase domain on MEC-17, revealing that correct levels of K40 acetylation are essential for the maintenance of neuronal structure. Finally, we investigate the genetic pathways in which mec-17 functions, uncovering novel interactions with dual leucine-zipper kinase dlk-1 and the focal adhesion gene zyx-1/Zyxin . These interactions link MEC-17 together with factors involved in neuronal and actin remodelling to protect synaptic branches. Together, our results reveal that appropriate levels of α-tubulin K40 acetylation by MEC-17 are crucial for the development and maintenance of neuronal architecture.

Published
2019
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21. The Apoptotic Engulfment Machinery Regulates Axonal Degeneration in C. elegans Neurons

Author

Alessandra Donato, Massimo A. Hilliard, Ding Xue, Cara Nolan, Annika L.A. Nichols, Rosina Giordano-Santini, David H. Hall, Ellen Meelkop, Casey Linton, Brent Neumann, and Robert K. P. Sullivan

Subjects
0301 basic medicine, Apoptosis, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Apoptotic cell clearance, 03 medical and health sciences, Adapter molecule crk, medicine, Animals, Small GTPase, Axon, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Neurons, fungi, Membrane Proteins, Signal transducing adaptor protein, Axotomy, Proto-Oncogene Proteins c-crk, Phosphoproteins, biology.organism_classification, rac GTP-Binding Proteins, Cell biology, Rac GTP-Binding Proteins, Cytoskeletal Proteins, 030104 developmental biology, medicine.anatomical_structure, Epidermal Cells, Gene Expression Regulation, Nerve Degeneration, ATP-Binding Cassette Transporters, Guanine nucleotide exchange factor, Epidermis, Apoptosis Regulatory Proteins, Carrier Proteins, Signal Transduction
Abstract

SummaryAxonal degeneration is a characteristic feature of neurodegenerative disease and nerve injury. Here, we characterize axonal degeneration in Caenorhabditis elegans neurons following laser-induced axotomy. We show that this process proceeds independently of the WLDS and Nmnat pathway and requires the axonal clearance machinery that includes the conserved transmembrane receptor CED-1/Draper, the adaptor protein CED-6, the guanine nucleotide exchange factor complex Crk/Mbc/dCed-12 (CED-2/CED-5/CED-12), and the small GTPase Rac1 (CED-10). We demonstrate that CED-1 and CED-6 function non-cell autonomously in the surrounding hypodermis, which we show acts as the engulfing tissue for the severed axon. Moreover, we establish a function in this process for CED-7, an ATP-binding cassette (ABC) transporter, and NRF-5, a lipid-binding protein, both associated with release of lipid-vesicles during apoptotic cell clearance. Thus, our results reveal the existence of a WLDS/Nmnat-independent axonal degeneration pathway, conservation of the axonal clearance machinery, and a function for CED-7 and NRF-5 in this process.

Published
2016
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22. Axonal fusion: An alternative and efficient mechanism of nerve repair

Author

Casey Linton, Massimo A. Hilliard, Rosina Giordano-Santini, and Brent Neumann

Subjects
0301 basic medicine, Nervous system, Cell Communication, Biology, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Humans, Axon, Nerve repair, Process (anatomy), Neurons, Mechanism (biology), General Neuroscience, Regeneration (biology), Molecular control, Recovery of Function, Axons, Nerve Regeneration, 030104 developmental biology, medicine.anatomical_structure, nervous system, Nerve cells, Neuroscience, 030217 neurology & neurosurgery
Abstract

Injuries to the nervous system can cause lifelong morbidity due to the disconnect that occurs between nerve cells and their cellular targets. Re-establishing these lost connections is the ultimate goal of endogenous regenerative mechanisms, as well as those induced by exogenous manipulations in a laboratory or clinical setting. Reconnection between severed neuronal fibers occurs spontaneously in some invertebrate species and can be induced in mammalian systems. This process, known as axonal fusion, represents a highly efficient means of repair after injury. Recent progress has greatly enhanced our understanding of the molecular control of axonal fusion, demonstrating that the machinery required for the engulfment of apoptotic cells is repurposed to mediate the reconnection between severed axon fragments, which are subsequently merged by fusogen proteins. Here, we review our current understanding of naturally occurring axonal fusion events, as well as those being ectopically produced with the aim of achieving better clinical outcomes.

Published
2018

23. Disruption of RAB-5 Increases EFF-1 Fusogen Availability at the Cell Surface and Promotes the Regenerative Axonal Fusion Capacity of the Neuron

Author

Casey Linton, Xue Yan Ho, Rosina Giordano-Santini, M. Asrafuzzaman Riyadh, Massimo A. Hilliard, and Brent Neumann

Subjects
Cell, Regulator, Vesicular Transport Proteins, Biology, Endocytosis, Cell Fusion, 03 medical and health sciences, 0302 clinical medicine, parasitic diseases, medicine, Animals, Small GTPase, Axon, Caenorhabditis elegans Proteins, Research Articles, 030304 developmental biology, Neurons, 0303 health sciences, Membrane Glycoproteins, General Neuroscience, Cell Membrane, Membrane Proteins, Axons, Cell biology, Nerve Regeneration, medicine.anatomical_structure, nervous system, Mutation, Neuron, Rab, Extracellular Space, 030217 neurology & neurosurgery, Reinnervation
Abstract

Following a transection injury to the axon, neurons from a number of species have the ability to undergo spontaneous repair via fusion of the two separated axonal fragments. In the nematodeCaenorhabditis elegans, this highly efficient regenerative axonal fusion is mediated by epithelial fusion failure-1 (EFF-1), a fusogenic protein that functions at the membrane to merge the two axonal fragments. Identifying modulators of axonal fusion and EFF-1 is an important step toward a better understanding of this repair process. Here, we present evidence that the small GTPase RAB-5 acts to inhibit axonal fusion, a function achieved via endocytosis of EFF-1 within the injured neuron. Therefore, we find that perturbing RAB-5 activity is sufficient to restore axonal fusion in mutant animals with decreased axonal fusion capacity. This is accompanied by enhanced membranous localization of EFF-1 and the production of extracellular EFF-1-containing vesicles. These findings identify RAB-5 as a novel regulator of axonal fusion inC. eleganshermaphrodites and the first regulator of EFF-1 in neurons.SIGNIFICANCE STATEMENTPeripheral and central nerve injuries cause life-long disabilities due to the fact that repair rarely leads to reinnervation of the target tissue. In the nematodeCaenorhabditis elegans, axonal regeneration can proceed through axonal fusion, whereby a regrowing axon reconnects and fuses with its own separated distal fragment, restoring the original axonal tract. We have characterized axonal fusion and established that the fusogen epithelial fusion failure-1 (EFF-1) is a key element for fusing the two separated axonal fragments back together. Here, we show that the small GTPase RAB-5 is a key cell-intrinsic regulator of the fusogen EFF-1 and can in turn regulate axonal fusion. Our findings expand the possibility for this process to be controlled and exploited to facilitate axonal repair in medical applications.

Published
2018

24. RAB-5 regulates regenerative axonal fusion by controlling EFF-1 endocytosis

Author

Casey Linton, Brent Neumann, Rosina Giordano-Santini, and Massimo A. Hilliard

Subjects
0303 health sciences, Chemistry, Vesicle, Regulator, Endocytosis, Cell biology, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, nervous system, parasitic diseases, medicine, Extracellular, Small GTPase, Neuron, Rab, Axon, 030217 neurology & neurosurgery, 030304 developmental biology
Abstract

Following a transection injury to the axon, neurons from a number of species have the ability to undergo spontaneous repair via fusion of the two separated axonal fragments. In the nematode C. elegans, this highly efficient regenerative axonal fusion is mediated by Epithelial Fusion Failure-1 (EFF-1), a fusogenic protein that functions at the membrane to merge the two axonal fragments. Identifying modulators of axonal fusion and EFF-1 is the next step towards harnessing this process for clinical applications. Here, we present evidence that the small GTPase RAB-5 acts to inhibit axonal fusion, a function achieved via endocytosis of EFF-1 within the injured neuron. Consequently, we find that perturbing RAB-5 activity increases the capacity of the neuron to undergo axonal fusion, through enhanced membranous localization of EFF-1 and the production of extracellular EFF-1-containing vesicles. These findings identify RAB-5 as a novel regulator of axonal fusion and the first regulator of EFF-1 in neurons.

Published
2018
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25. Phosphatidylserine save-me signals drive functional recovery of severed axons in

Author

Zehra C, Abay, Michelle Yu-Ying, Wong, Jean-Sébastien, Teoh, Tarika, Vijayaraghavan, Massimo A, Hilliard, and Brent, Neumann

Subjects
Male, phosphatidylserine, Cell Membrane, axonal regeneration, Axotomy, Phosphatidylserines, Recovery of Function, Biological Sciences, Axons, Nerve Regeneration, axonal fusion, nervous system, PNAS Plus, Animals, Hermaphroditic Organisms, nervous system repair, Caenorhabditis elegans, Mechanoreceptors, Neuroscience
Abstract

Significance Nervous system injury can cause lifelong disability, because repair rarely leads to reconnection with the target tissue. In the nematode Caenorhabditis elegans and in several other species, regeneration can proceed through a mechanism of axonal fusion, whereby regrowing axons reconnect and fuse with their own separated fragments, rapidly and efficiently restoring the original axonal tract. We have found that the process of axonal fusion restores full function to damaged neurons. In addition, we show that injury-induced changes to the axonal membrane that result in exposure of lipid “save-me” signals mediate the level of axonal fusion. Thus, our results establish axonal fusion as a complete regenerative mechanism that can be modulated by changing the level of save-me signals exposed after injury., Functional regeneration after axonal injury requires transected axons to regrow and reestablish connection with their original target tissue. The spontaneous regenerative mechanism known as axonal fusion provides a highly efficient means of achieving targeted reconnection, as a regrowing axon is able to recognize and fuse with its own detached axon segment, thereby rapidly reestablishing the original axonal tract. Here, we use behavioral assays and fluorescent reporters to show that axonal fusion enables full recovery of function after axotomy of Caenorhabditis elegans mechanosensory neurons. Furthermore, we reveal that the phospholipid phosphatidylserine, which becomes exposed on the damaged axon to function as a “save-me” signal, defines the level of axonal fusion. We also show that successful axonal fusion correlates with the regrowth potential and branching of the proximal fragment and with the retraction length and degeneration of the separated segment. Finally, we identify discrete axonal domains that vary in their propensity to regrow through fusion and show that the level of axonal fusion can be genetically modulated. Taken together, our results reveal that axonal fusion restores full function to injured neurons, is dependent on exposure of phospholipid signals, and is achieved through the balance between regenerative potential and level of degeneration.

Published
2017

26. The ETS-5 transcription factor regulates activity states in Caenorhabditis elegans by controlling satiety

Author

Steffen Nørgaard, Agnieszka Podolska, David Pladevall-Morera, Brent Neumann, Roger Pocock, and Vaida Juozaityte

Subjects
2. Zero hunger, 0301 basic medicine, Communication, Multidisciplinary, Mechanism (biology), business.industry, ETS transcription factor family, Neuropeptide, Biology, Serotonergic, biology.organism_classification, Cell biology, 03 medical and health sciences, 030104 developmental biology, Signal transduction, business, Transcription factor, Gene, Caenorhabditis elegans
Abstract

Animal behavior is shaped through interplay among genes, the environment, and previous experience. As in mammals, satiety signals induce quiescence in Caenorhabditis elegans Here we report that the C. elegans transcription factor ETS-5, an ortholog of mammalian FEV/Pet1, controls satiety-induced quiescence. Nutritional status has a major influence on C. elegans behavior. When foraging, food availability controls behavioral state switching between active (roaming) and sedentary (dwelling) states; however, when provided with high-quality food, C. elegans become sated and enter quiescence. We show that ETS-5 acts to promote roaming and inhibit quiescence by setting the internal "satiety quotient" through fat regulation. Acting from the ASG and BAG sensory neurons, we show that ETS-5 functions in a complex network with serotonergic and neuropeptide signaling pathways to control food-regulated behavioral state switching. Taken together, our results identify a neuronal mechanism for controlling intestinal fat stores and organismal behavioral states in C. elegans, and establish a paradigm for the elucidation of obesity-relevant mechanisms.

Published
2017
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27. The ETS-5 transcription factor regulates activity states in

Author

Vaida, Juozaityte, David, Pladevall-Morera, Agnieszka, Podolska, Steffen, Nørgaard, Brent, Neumann, and Roger, Pocock

Subjects
Behavior, Animal, Proto-Oncogene Proteins c-ets, Sensory Receptor Cells, PNAS Plus, Neuropeptides, Animals, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Serotonergic Neurons, Signal Transduction, Transcription Factors
Abstract

Animals constantly monitor their internal energy levels and modify their eating and foraging behavior as required. Our work defines a role for the ETS-5 transcription factor in the control of body fat levels and thereby the activity of animals. We have defined the responses controlled by ETS-5 at the genetic, cellular, and organismal levels and identified how ETS-5 interacts with known pathways that regulate food-regulated behavioral states. These findings provide insight into how fat levels are regulated and how satiety controls organismal activity.

Published
2017

28. Structure, function, and regulation of mitofusin-2 in health and disease

Author

Brent Neumann, Gursimran Chandhok, and Michael Lazarou

Subjects
0301 basic medicine, Cell signaling, obesity, MFN2, Mitochondrion, Biology, Charcot–Marie–Tooth disease, General Biochemistry, Genetics and Molecular Biology, Gene Expression Regulation, Enzymologic, GTP Phosphohydrolases, Mitochondrial Proteins, 03 medical and health sciences, Mitofusin-2, neurodegenerative disease, medicine, MFN1, Humans, Genetics, diabetes, vascular disease, Original Articles, medicine.disease, mitofusin‐1, mitofusin‐2, mitochondrial dynamics, Cell biology, Mitochondria, 030104 developmental biology, mitochondrial fusion, DNAJA3, Optic Atrophy 1, Original Article, General Agricultural and Biological Sciences
Abstract

Mitochondria are highly dynamic organelles that constantly migrate, fuse, and divide to regulate their shape, size, number, and bioenergetic function. Mitofusins (Mfn1/2), optic atrophy 1 (OPA1), and dynamin‐related protein 1 (Drp1), are key regulators of mitochondrial fusion and fission. Mutations in these molecules are associated with severe neurodegenerative and non‐neurological diseases pointing to the importance of functional mitochondrial dynamics in normal cell physiology. In recent years, significant progress has been made in our understanding of mitochondrial dynamics, which has raised interest in defining the physiological roles of key regulators of fusion and fission and led to the identification of additional functions of Mfn2 in mitochondrial metabolism, cell signalling, and apoptosis. In this review, we summarize the current knowledge of the structural and functional properties of Mfn2 as well as its regulation in different tissues, and also discuss the consequences of aberrant Mfn2 expression.

Published
2017

29. A dominant mutation inmec-7/β-tubulinaffects axon development and regeneration inCaenorhabditis elegansneurons

Author

Sean Coakley, Leonie Kirszenblat, Brent Neumann, and Massimo A. Hilliard

Subjects
Neurite, macromolecular substances, Polymorphism, Single Nucleotide, Tubulin, Microtubule, Neurites, medicine, Animals, Nerve Growth Factors, Axon, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Mitosis, Cytoskeleton, Genes, Dominant, Neurons, biology, Articles, Sequence Analysis, DNA, Cell Biology, biology.organism_classification, Tubulin Modulators, Nerve Regeneration, Cell biology, Wnt Proteins, Protein Transport, Phenotype, medicine.anatomical_structure, nervous system, Mutation, Synapses, biology.protein, Neuron, Collapsin response mediator protein family, Mitogen-Activated Protein Kinases, Colchicine
Abstract

Microtubules are the basic elements of the cytoskeleton. This study demonstrates that a specific mutation in mec-7/β-tubulin is necessary for the correct number of neurites a neuron extends in vivo and the neuron’s capacity for axonal regeneration following injury., Microtubules have been known for decades to be basic elements of the cytoskeleton. They form long, dynamic, rope-like structures within the cell that are essential for mitosis, maintenance of cell shape, and intracellular transport. More recently, in vitro studies have implicated microtubules as signaling molecules that, through changes in their stability, have the potential to trigger growth of axons and dendrites in developing neurons. In this study, we show that specific mutations in the Caenorhabditis elegans mec-7/β-tubulin gene cause ectopic axon formation in mechanosensory neurons in vivo. In mec-7 mutants, the ALM mechanosensory neuron forms a long ectopic neurite that extends posteriorly, a phenotype that can be mimicked in wild-type worms with a microtubule-stabilizing drug (paclitaxel), and suppressed by mutations in unc-33/CRMP2 and the kinesin-related gene, vab-8. Our results also reveal that these ectopic neurites contain RAB-3, a marker for presynaptic loci, suggesting that they have axon-like properties. Interestingly, in contrast with the excessive axonal growth observed during development, mec-7 mutants are inhibited in axonal regrowth and remodeling following axonal injury. Together our results suggest that MEC-7/β-tubulin integrity is necessary for the correct number of neurites a neuron generates in vivo and for the capacity of an axon to regenerate.

Published
2013
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32. EFF-1-mediated regenerative axonal fusion requires components of the apoptotic pathway

Author

Casey Linton, Brent Neumann, Ding Xue, Eui Seung Lee, Akihisa Nakagawa, Rosina Giordano-Santini, Massimo A. Hilliard, and Sean Coakley

Subjects
Nervous system, medicine.medical_treatment, Growth Cones, Apoptosis, Receptors, Cell Surface, Phosphatidylserines, Apoptotic cell clearance, Phagocytosis, medicine, Animals, Axon, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Phagocytes, Multidisciplinary, Membrane Glycoproteins, biology, Regeneration (biology), Spectrin, Anatomy, biology.organism_classification, Phosphoproteins, Hedgehog signaling pathway, Axons, Cell biology, Nerve Regeneration, medicine.anatomical_structure, nervous system, Mutation, ATP-Binding Cassette Transporters, Neuron, Axotomy, Apoptosis Regulatory Proteins, Carrier Proteins, Signal Transduction
Abstract

Functional regeneration after nervous system injury requires transected axons to reconnect with their original target tissue. Axonal fusion, a spontaneous regenerative mechanism identified in several species, provides an efficient means of achieving target reconnection as a regrowing axon is able to contact and fuse with its own separated axon fragment, thereby re-establishing the original axonal tract. Here we report a molecular characterization of this process in Caenorhabditis elegans, revealing dynamic changes in the subcellular localization of the EFF-1 fusogen after axotomy, and establishing phosphatidylserine (PS) and the PS receptor (PSR-1) as critical components for axonal fusion. PSR-1 functions cell-autonomously in the regrowing neuron and, instead of acting in its canonical signalling pathway, acts in a parallel phagocytic pathway that includes the transthyretin protein TTR-52, as well as CED-7, NRF-5 and CED-6 (refs 9, 10, 11, 12). We show that TTR-52 binds to PS exposed on the injured axon, and can restore fusion several hours after injury. We propose that PS functions as a 'save-me' signal for the distal fragment, allowing conserved apoptotic cell clearance molecules to function in re-establishing axonal integrity during regeneration of the nervous system.

Published
2013

33. Axonal regeneration proceeds through specific axonal fusion in transected C. elegans neurons

Author

Ken C. Q. Nguyen, David H. Hall, Adela Ben-Yakar, Massimo A. Hilliard, and Brent Neumann

Subjects
Wallerian degeneration, medicine.medical_treatment, Green Fluorescent Proteins, Models, Biological, Article, Animals, Genetically Modified, Cell Fusion, medicine, Animals, Axon, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Neurons, Cell fusion, biology, Regeneration (biology), Membrane Proteins, Axotomy, Anatomy, medicine.disease, biology.organism_classification, Axons, Cell biology, Nerve Regeneration, medicine.anatomical_structure, nervous system, Cytoplasm, Kaede, Developmental Biology
Abstract

Functional neuronal recovery following injury arises when severed axons reconnect with their targets. In Caenorhabditis elegans following laser-induced axotomy, the axon still attached to the cell body is able to regrow and reconnect with its separated distal fragment. Here we show that reconnection of separated axon fragments during regeneration of C. elegans mechanosensory neurons occurs through a mechanism of axonal fusion, which prevents Wallerian degeneration of the distal fragment. Through electron microscopy analysis and imaging with the photoconvertible fluorescent protein Kaede, we show that the fusion process re-establishes membrane continuity and repristinates anterograde and retrograde cytoplasmic diffusion. We also provide evidence that axonal fusion occurs with a remarkable level of accuracy, with the proximal re-growing axon recognizing its own separated distal fragment. Thus, efficient axonal regeneration can occur by selective reconnection and fusion of separated axonal fragments beyond an injury site, with restoration of the damaged neuronal tract. Developmental Dynamics 240:1365–1372, 2011. V C 2011 Wiley-Liss, Inc.

Published
2011

34. Subcellular localization of the Schlafen protein family

Author

Kathleen M. Murphy, Thomas J. Gonda, Brent Neumann, Liang Zhao, Neumann, Brent, Zhao, Liang, Murphy, Kathleen, and Gonda, Thomas J

Subjects
Cytoplasm, Protein family, Cellular differentiation, Biophysics, Cell Cycle Proteins, Biology, Biochemistry, Cell Line, Mice, schlafen, subcellular localization, medicine, Gene family, Animals, Humans, Myeloid Cells, Nuclear protein, Cell Cycle Protein, Molecular Biology, Phylogeny, Genetics, Cell Nucleus, murine, nucleus, Nuclear Proteins, Cell Differentiation, differentiation, Cell Biology, Subcellular localization, Cell biology, Cell nucleus, medicine.anatomical_structure, cytoplasm
Abstract

Although the first members of the Schlafen gene family were first described almost 10 years ago, the precise molecular/biochemical functions of the proteins they encode still remain largely unknown. Roles in cell growth, haematopoietic cell differentiation, and T cell development/maturation have, with some experimental support, been postulated, but none have been conclusively verified. Here, we have determined the subcellular localization of Schlafens 1, 2, 4, 5, 8, and 9, representing all three of the murine subgroups. We show that the proteins from subgroups I and II localize to the cytoplasm, while the longer forms in subgroup III localize exclusively to the nuclear compartment. We also demonstrate upregulation of Schlafen2 upon differentiation of haematopoietic cells and show this endogenous protein localizes to the cytoplasm. Thus, we propose the different subgroups of Schlafen proteins are likely to have functionally distinct roles, reflecting their differing localizations within the cell. Refereed/Peer-reviewed

Published
2008

35. Lack of reproducible growth inhibition by Schlafen1 and Schlafen2 in vitro

Author

Kathleen M. Murphy, Liang Zhao, Brent Neumann, Thomas J. Gonda, John Silke, Zhao, Liang, Neumann, Brent, Murphy, Kathleen, Silke, John, and Gonda, Thomas J

Subjects
Cyclin D, proliferation, Cyclin A, Cyclin B, cyclin D1, Gene Expression, Cell Cycle Proteins, Biology, fibroblast, Mice, schlafen genes, Cyclin D1, Animals, Promoter Regions, Genetic, Molecular Biology, Cells, Cultured, Cell Proliferation, Cell growth, Cell Cycle, Cell Biology, Hematology, Cell cycle, Fibroblasts, Cell biology, biology.protein, Cancer research, Molecular Medicine, Ectopic expression, myeloid, Cyclin A2
Abstract

The Schlafen gene family has been implicated in lymphoid and myeloid maturation and differentiation as well as inflammation. However, little is known about the functions of this gene family except that anti-proliferative activities, particularly for Schlafen1, the prototype member of the family, have been reported. This was shown mainly by ectopic expression of Schlafen1 in murine fibroblasts resulting in growth inhibition and a G1 cell cycle arrest apparently via repression of Cyclin D1 expression. However, we have been unable to reproduce these findings. Schlafen1 and Schlafen2 failed to inhibit cell proliferation, cause G1 cell cycle arrest, or affect Cyclin D1 level in murine fibroblasts. This was regardless of whether overexpression was constitutive, induced or from transient transfections. Moreover, in our hands, Schlafen1 and -2 do not appear to regulate the activity of Cyclin D1 promoter. Importantly, we also showed that Schlafen1 and -2 do not play anti-proliferative roles in more physiologically-relevant myeloid cell lines. We therefore suggest that Schlafen1 and Schlafen2 might not have obligatory anti-proliferative activities, at least in vitro, and that efforts to explore their functions should be directed to other aspects, such as haemopoietic development and immune response. Refereed/Peer-reviewed

Published
2008

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