Literature DB >> 25461258

Hematogenous macrophage depletion reduces the fibrotic scar and increases axonal growth after spinal cord injury.

Y Zhu1, C Soderblom1, V Krishnan1, J Ashbaugh1, J R Bethea1, J K Lee2.   

Abstract

Spinal cord injury (SCI) leads to formation of a fibrotic scar that is inhibitory to axon regeneration. Recent evidence indicates that the fibrotic scar is formed by perivascular fibroblasts, but the mechanism by which they are recruited to the injury site is unknown. Using bone marrow transplantation in mouse model of spinal cord injury, we show that fibroblasts in the fibrotic scar are associated with hematogenous macrophages rather than microglia, which are limited to the surrounding astroglial scar. Depletion of hematogenous macrophages results in reduced fibroblast density and basal lamina formation that is associated with increased axonal growth in the fibrotic scar. Cytokine gene expression analysis after macrophage depletion indicates that decreased Tnfsf8, Tnfsf13 (tumor necrosis factor superfamily members) and increased BMP1-7 (bone morphogenetic proteins) expression may serve as anti-fibrotic mechanisms. Our study demonstrates that hematogenous macrophages are necessary for fibrotic scar formation and macrophage depletion results in changes in multiple cytokines that make the injury site less fibrotic and more conducive to axonal growth.
Copyright © 2014 Elsevier Inc. All rights reserved.

Entities:  

Keywords:  Axonal growth; Bone morphogenetic protein; Fibroblasts; Fibrotic scar; Hematogenous macrophages; Spinal cord injury; Tumor necrosis factor

Mesh:

Substances:

Year:  2014        PMID: 25461258      PMCID: PMC4323620          DOI: 10.1016/j.nbd.2014.10.024

Source DB:  PubMed          Journal:  Neurobiol Dis        ISSN: 0969-9961            Impact factor:   5.996


  44 in total

1.  Differential detection and distribution of microglial and hematogenous macrophage populations in the injured spinal cord of lys-EGFP-ki transgenic mice.

Authors:  Leah A Mawhinney; Sakina G Thawer; Wei-Yang Lu; Nico van Rooijen; Lynne C Weaver; Arthur Brown; Gregory A Dekaban
Journal:  J Neuropathol Exp Neurol       Date:  2012-03       Impact factor: 3.685

2.  Prevention of both neutrophil and monocyte recruitment promotes recovery after spinal cord injury.

Authors:  Sang Mi Lee; Steven Rosen; Philip Weinstein; Nico van Rooijen; Linda J Noble-Haeusslein
Journal:  J Neurotrauma       Date:  2011-08-08       Impact factor: 5.269

3.  Deficient CX3CR1 signaling promotes recovery after mouse spinal cord injury by limiting the recruitment and activation of Ly6Clo/iNOS+ macrophages.

Authors:  Dustin J Donnelly; Erin E Longbrake; Todd M Shawler; Kristina A Kigerl; Wenmin Lai; C Amy Tovar; Richard M Ransohoff; Phillip G Popovich
Journal:  J Neurosci       Date:  2011-07-06       Impact factor: 6.167

4.  Fate mapping reveals origins and dynamics of monocytes and tissue macrophages under homeostasis.

Authors:  Simon Yona; Ki-Wook Kim; Yochai Wolf; Alexander Mildner; Diana Varol; Michal Breker; Dalit Strauss-Ayali; Sergey Viukov; Martin Guilliams; Alexander Misharin; David A Hume; Harris Perlman; Bernard Malissen; Elazar Zelzer; Steffen Jung
Journal:  Immunity       Date:  2012-12-27       Impact factor: 31.745

5.  Basso Mouse Scale for locomotion detects differences in recovery after spinal cord injury in five common mouse strains.

Authors:  D Michele Basso; Lesley C Fisher; Aileen J Anderson; Lyn B Jakeman; Dana M McTigue; Phillip G Popovich
Journal:  J Neurotrauma       Date:  2006-05       Impact factor: 5.269

6.  Anti-inflammatory M2, but not pro-inflammatory M1 macrophages promote angiogenesis in vivo.

Authors:  Nadine Jetten; Sanne Verbruggen; Marion J Gijbels; Mark J Post; Menno P J De Winther; Marjo M P C Donners
Journal:  Angiogenesis       Date:  2013-09-08       Impact factor: 9.596

7.  Hepatic gene expression profiles associated with fibrosis progression and hepatocarcinogenesis in hepatitis C patients.

Authors:  Run-Xuan Shao; Yujin Hoshida; Motoyuki Otsuka; Naoya Kato; Ryosuke Tateishi; Takuma Teratani; Shuichiro Shiina; Hiroyoshi Taniguchi; Masaru Moriyama; Takao Kawabe; Masao Omata
Journal:  World J Gastroenterol       Date:  2005-04-07       Impact factor: 5.742

8.  High-resolution intravital imaging reveals that blood-derived macrophages but not resident microglia facilitate secondary axonal dieback in traumatic spinal cord injury.

Authors:  Teresa A Evans; Deborah S Barkauskas; Jay T Myers; Elisabeth G Hare; Jing Qiang You; Richard M Ransohoff; Alex Y Huang; Jerry Silver
Journal:  Exp Neurol       Date:  2014-01-24       Impact factor: 5.330

9.  A potential role for bone morphogenetic protein signalling in glial cell fate determination following adult central nervous system injury in vivo.

Authors:  David W Hampton; Richard A Asher; Toru Kondo; John D Steeves; Matt S Ramer; James W Fawcett
Journal:  Eur J Neurosci       Date:  2007-12       Impact factor: 3.386

10.  Chemical clearing and dehydration of GFP expressing mouse brains.

Authors:  Klaus Becker; Nina Jährling; Saiedeh Saghafi; Reto Weiler; Hans-Ulrich Dodt
Journal:  PLoS One       Date:  2012-03-30       Impact factor: 3.240
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  72 in total

1.  Fra-2-expressing macrophages promote lung fibrosis in mice.

Authors:  Alvaro C Ucero; Latifa Bakiri; Ben Roediger; Masakatsu Suzuki; Maria Jimenez; Pratyusha Mandal; Paola Braghetta; Paolo Bonaldo; Luis Paz-Ares; Coral Fustero-Torre; Pilar Ximenez-Embun; Ana Isabel Hernandez; Diego Megias; Erwin F Wagner
Journal:  J Clin Invest       Date:  2019-05-28       Impact factor: 14.808

2.  Fibronectin EDA forms the chronic fibrotic scar after contusive spinal cord injury.

Authors:  John G Cooper; Su Ji Jeong; Tammy L McGuire; Sripadh Sharma; Wenxia Wang; Swati Bhattacharyya; John Varga; John A Kessler
Journal:  Neurobiol Dis       Date:  2018-04-27       Impact factor: 5.996

Review 3.  Cell biology of spinal cord injury and repair.

Authors:  Timothy M O'Shea; Joshua E Burda; Michael V Sofroniew
Journal:  J Clin Invest       Date:  2017-07-24       Impact factor: 14.808

Review 4.  The origin, fate, and contribution of macrophages to spinal cord injury pathology.

Authors:  Lindsay M Milich; Christine B Ryan; Jae K Lee
Journal:  Acta Neuropathol       Date:  2019-03-30       Impact factor: 17.088

5.  Proliferating NG2-Cell-Dependent Angiogenesis and Scar Formation Alter Axon Growth and Functional Recovery After Spinal Cord Injury in Mice.

Authors:  Zoe C Hesp; Rim Y Yoseph; Ryusuke Suzuki; Peter Jukkola; Claire Wilson; Akiko Nishiyama; Dana M McTigue
Journal:  J Neurosci       Date:  2017-12-26       Impact factor: 6.167

6.  Intravenous immune-modifying nanoparticles as a therapy for spinal cord injury in mice.

Authors:  Su Ji Jeong; John G Cooper; Igal Ifergan; Tammy L McGuire; Dan Xu; Zoe Hunter; Sripadh Sharma; Derrick McCarthy; Stephen D Miller; John A Kessler
Journal:  Neurobiol Dis       Date:  2017-08-18       Impact factor: 5.996

Review 7.  The Biology of Regeneration Failure and Success After Spinal Cord Injury.

Authors:  Amanda Phuong Tran; Philippa Mary Warren; Jerry Silver
Journal:  Physiol Rev       Date:  2018-04-01       Impact factor: 37.312

8.  Macrophage Transcriptional Profile Identifies Lipid Catabolic Pathways That Can Be Therapeutically Targeted after Spinal Cord Injury.

Authors:  Y Zhu; K Lyapichev; D H Lee; D Motti; N M Ferraro; Y Zhang; S Yahn; C Soderblom; J Zha; J R Bethea; K L Spiller; V P Lemmon; J K Lee
Journal:  J Neurosci       Date:  2017-01-27       Impact factor: 6.167

9.  The role of the immune system during regeneration of the central nervous system.

Authors:  K Z Sabin; K Echeverri
Journal:  J Immunol Regen Med       Date:  2019-11-05

10.  Reducing age-dependent monocyte-derived macrophage activation contributes to the therapeutic efficacy of NADPH oxidase inhibition in spinal cord injury.

Authors:  Bei Zhang; William M Bailey; Anna Leigh McVicar; Andrew N Stewart; Amy K Veldhorst; John C Gensel
Journal:  Brain Behav Immun       Date:  2018-11-16       Impact factor: 7.217
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