Neurotrophic effects of progranulin in vivo in reversing motor neuron defects caused by over or under expression of TDP-43 or FUS

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Abstract

Progranulin (PGRN) is a glycoprotein with multiple roles in normal and disease states. Mutations within the GRN gene cause frontotemporal lobar degeneration (FTLD). The affected neurons display distinctive TAR DNA binding protein 43 (TDP-43) inclusions. How partial loss of PGRN causes TDP-43 neuropathology is poorly understood. TDP-43 inclusions are also found in affected neurons of patients with other neurodegenerative diseases including amyotrophic lateral sclerosis (ALS) and Alzheimer's disease. In ALS, TDP-43 inclusions are typically also immunoreactive for fused in sarcoma (FUS). Mutations within TDP-43 or FUS are themselves neuropathogenic in ALS and some cases of FTLD. We used the outgrowth of caudal primary motor neurons (MNs) in zebrafish embryos to investigate the interaction of PGRN with TDP-43 and FUS in vivo. As reported previously, depletion of zebrafish PGRN-A (zfPGRN-A) is associated with truncated primary MNs and impaired motor function. Here we found that depletion of zfPGRN-A results in primary MNs outgrowth stalling at the horizontal myoseptum, a line of demarcation separating the myotome into dorsal and ventral compartments that is where the final destination of primary motor is assigned. Successful axonal outgrowth beyond the horizontal myoseptum depends in part upon formation of acetylcholine receptor clusters and this was found to be disorganized upon depletion of zfPGRN-A. PGRN reversed the effects of zfPGRN-A knockdown, but a related gene, zfPGRN-1, was without effect. Both knockdown of TDP-43 or FUS, as well as expression of humanTDP-43 and FUS mutants results in MN abnormalities that are reversed by co-expression of hPGRN mRNA. Neither TDP-43 nor FUS reversed MN phenotypes caused by the depletion of PGRN. Thus TDP-43 and FUS lie upstream of PGRN in a gene complementation pathway. The ability of PGRN to override TDP-43 and FUS neurotoxicity due to partial loss of function or mutation in the corresponding genes may have therapeutic relevance.

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Most cited references 46

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The use of zebrafish to understand immunity.

Nikolaus S Trede, David M Langenau, David Traver … (2004)

For decades immunologists have relied heavily on the mouse model for their experimental designs. With the realization of the important role innate immunity plays in orchestrating immune responses, invertebrates such as worms and flies have been added to the repertoire. Here, we discuss the advent of the zebrafish as a powerful vertebrate model organism that promises to positively impact immunologic research.

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Progranulin functions as a neurotrophic factor to regulate neurite outgrowth and enhance neuronal survival

Philip van Damme, Annelies Van Hoecke, Diether Lambrechts … (2008)

Recently, mutations in the progranulin (PGRN) gene were found to cause familial and apparently sporadic frontotemporal lobe dementia (FTLD). Moreover, missense changes in PGRN were identified in patients with motor neuron degeneration, a condition that is related to FTLD. Most mutations identified in patients with FTLD until now have been null mutations. However, it remains unknown whether PGRN protein levels are reduced in the central nervous system from such patients. The effects of PGRN on neurons also remain to be established. We report that PGRN levels are reduced in the cerebrospinal fluid from FTLD patients carrying a PGRN mutation. We observe that PGRN and GRN E (one of the proteolytic fragments of PGRN) promote neuronal survival and enhance neurite outgrowth in cultured neurons. These results demonstrate that PGRN/GRN is a neurotrophic factor with activities that may be involved in the development of the nervous system and in neurodegeneration.

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The granulin gene family: from cancer to dementia.

Andrew Bateman, Tom J H Bennett (2009)

The growth factor progranulin (PGRN) regulates cell division, survival, and migration. PGRN is an extracellular glycoprotein bearing multiple copies of the cysteine-rich granulin motif. With PGRN family members in plants and slime mold, it represents one of the most ancient of the extracellular regulatory proteins still extant in modern animals. PRGN has multiple biological roles. It contributes to the regulation of early embryogenesis, to adult tissue repair and inflammation. Elevated PGRN levels often occur in cancers, and PGRN immunotherapy inhibits the growth of hepatic cancer xenografts in mice. Recent studies have demonstrated roles for PGRN in neurobiology. An autosomal dominant mutation in GRN, the gene for PGRN, leads to neuronal atrophy in the frontal and temporal lobes, resulting in the disease frontotemporal lobar dementia. In this review we will discuss current knowledge of the multifaceted biology of PGRN.

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Author and article information

Contributors

Peter F Hitchcock: Role: Editor

Journal

Journal ID (nlm-ta): PLoS One

Journal ID (iso-abbrev): PLoS ONE

Journal ID (publisher-id): plos

Journal ID (pmc): plosone

Title: PLoS ONE

Publisher: Public Library of Science (San Francisco, CA USA )

ISSN (Electronic): 1932-6203

Publication date (Electronic): 30 March 2017

Publication date Collection: 2017

Volume: 12

Issue: 3

Electronic Location Identifier: e0174784

Affiliations

[1 ]Endocrine Research Laboratory, Royal Victoria Hospital, McGill University Health Centre Research Institute, Montreal, Québec, Canada

[2 ]Neurodyn Inc., Charlottetown, Prince Edward Island, Canada

University of Michigan, UNITED STATES

Author notes

Competing Interests: HPJB is a member of the Scientific Advisory board of Neurodyn Inc. HPJB, AB and DGK have shares in Neurodyn Inc. This does not alter our adherence to PLOS ONE policies on data sharing and materials.

Conceptualization: BC AB DGK HPJB.
Data curation: BC AB HPJB.
Formal analysis: BC AB.
Funding acquisition: HB BC.
Investigation: BC.
Methodology: BC AB HPJB.
Project administration: BC.
Resources: HPJB AB.
Supervision: HPJB AB.
Validation: BC HPJB AB.
Visualization: BC.
Writing – original draft: BC AB.
Writing – review & editing: BC AB DGK HPJB.

* E-mail: babykumari.chitramuthu@ 123456mail.mcgill.ca (BPC); hugh.bennett@ 123456mcgill.ca (HPJB)

Article

Publisher ID: PONE-D-16-43963

DOI: 10.1371/journal.pone.0174784

PMC ID: 5373598

PubMed ID: 28358904

SO-VID: 2bc0e46b-c1ee-4918-bac3-2fa83af875fd

License:

This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

History

Date received : 7 November 2016

Date accepted : 15 March 2017

Page count

Figures: 5, Tables: 0, Pages: 21

Funding

Funded by: funder-id http://dx.doi.org/10.13039/501100000038, Natural Sciences and Engineering Research Council of Canada;

Award ID: RGPIN 327185-11

Award Recipient : Hugh P. J. Bennett

Funded by: funder-id http://dx.doi.org/10.13039/501100000038, Natural Sciences and Engineering Research Council of Canada;

Award ID: Ph.D studentship 425959-2012

Award Recipient : Babykumari P. Chitramuthu

The authors acknowledge the financial support of Neurodyn Inc. and the Natural Sciences and Engineering Research Council of Canada Discovery Grant (H.B) and Studentship awards (to BC) FRSQ and NSERC(CGS). The funder provided support in the form of salaries for authors [BC and DGK], but did not have any additional role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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Data Availability All relevant data are within the paper and its Supporting Information files.

Neurotrophic effects of progranulin in vivo in reversing motor neuron defects caused by over or under expression of TDP-43 or FUS

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