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Written by - Xie Changnan, Wang Yihan responsible for editing - Wang Sizhen, Fang Yiyi
Editor—Summer Leaf
Spinal cord injury (SCI) is a common clinical central nervous system traumatic disease that causes loss of motor and sensory function, even paralysis and even death, with devastating consequences
for the patient's physical, mental and social health.
Spinal cord injury is pathophysiologically divided into primary injury and secondary injury
.
Primary injury destroys the blood-spinal cord barrier (BSCB), causing infiltrating lesions such as various inflammatory cytokines, neutrophils, and macrophages, resulting in secondary injury [1].
。 Subsequently, secondary injury triggers a cascade of reactions, including neuronal and glial cell death, inflammation, and glial fiber scarring, leading to axon regeneration failure [2].
Therefore, maintaining the integrity of BSCB is key
to reducing secondary injuries and facilitating spinal cord injury repair.
Perlecan is an important component of basement membrane and has a protective effect on
vascular integrity.
Spinal cord injury causes degradation and synthesis of basement membrane proteins, resulting in vascular wall structural abnormalities such as tight junctions (TJs), increasing the permeability of BSCB and secondary inflammatory response [3, 4].
。 Compared to collagen Collagen IV and laminin Laminin, Perlecan is the most sensitive basement membrane component to stroke response, shown Perlecan plays an important role in diseases of the central nervous system [5].
In addition, clinical evidence suggests that changes in Perlecan expression are associated with disease progression in patients with human brain arteriovenous malformations and cerebral amyloid angiopathy [6, 7].
However, changes and function of Perlecan after spinal cord injury have not been reported
.
On October 10, 2022, Professor Zhu Lixin of Zhujiang Hospital of Southern Medical University and Professor Guo Jiasong's research group of School of Basic Medicine jointly published a paper entitled in Molecular Neurobiology "Perlecan improves blood spinal cord barrier repair through the integrin β1/ROCK/MLC pathway after spinal cord injury
.
" The study observed that Perlecan is specifically localized to the blood-spinal barrier basement membrane
.
After spinal cord injury, Perlecan undergoes a process
of degradation/remodeling.
Overexpression of Perlecan can reduce BSCB permeability, reduce inflammatory response, and improve motor function and nerve regeneration
in mice after spinal cord injury.
In addition, the authors confirmed that Perlecan inhibits the downstream ROCK/MLC signaling pathway by interacting with integrin β1, reducing the breakdown of TJs-associated proteins , improve the integrity of BSCB after spinal cord injury, and provide new ideas
for the treatment of spinal cord injury.
This study first examined the localization of Perlecan protein expression in various components of the blood-spinal cord barrier structure of the mouse spinal cord (Figure 1A-F).
The results showed that Perlecan was specifically localized to the basement membrane (Laminin and Collagen IV) in the mouse spinal cord while being replaced by endothelial cells (CD31).
), vascular fibroblasts/pericytes (ACTA2), and astrocyte foot processes (GFAP) are surrounded, but not expressed in microglia
.
In addition, the degradation and remodeling of Perlecan can be observed after spinal cord injury (Figure 1G-J).
This suggests that Perlecan protein is associated
with blood-spinal cord barrier function after spinal cord injury.
Fig.
1 Perlecan is localized to the basement membrane and degrades/remodeling processes occur after spinal cord injury
(Source: Changnan Xie, et al.
) , Mol Neurobiol, 2022)
To further clarify the role of Perlecan in spinal cord injury, the authors used the SAM system of CRISPR/Cas9 to overexpress Perlecan and model
spinal cord injury 。 Mouse movement, neuronal survival and axon regeneration were detected by swimming experiments, footprint experiments, immunofluorescence staining, and electron microscopy
experiments.
Results showed that overexpression of Perlecan improved motor function recovery and axon regeneration after spinal cord injury (Figure 2).
It is suggested that Perlecan protein promotes motor and neurological recovery after spinal cord injury
.
Fig.
2 Overexpression of Perlecan promotes motor and neurological recovery in spinal cord injury
(Source: Changnan Xie, et al.
) , Mol Neurobiol, 2022)
Previous studies have shown that the increase in inflammatory cells and factors and the recruitment of immune cells due to spinal cord injury are closely related to the destruction of the blood-spinal cord barrier basement membrane [8].
Therefore, the authors examined the inflammatory response of overexpression of Perlecan after spinal cord injury
.
In order to verify this, the research team found that overexpression of Perlecan reduced macrophage/microglia and leukocyte infiltration after spinal cord injury and promoted the expression of anti-inflammatory factors through immunofluorescence and qPCR experiments (Figure 3).
Fig.
3 Overexpression of Perlecan reduces inflammation after spinal cord injury
(Source: Changnan Xie, et al.
, Mol Neurobiol, 2022).
To investigate whether Perlecan reduces the inflammatory response by affecting the permeability of BSCB, the authors performed Evans blue staining and immunofluorescence and found that Evans blue and fibronectin () after overexpression of Perlecan reduced spinal cord injury Fibronectin) leak (Figures 4A-C).
In addition, western blotting and electron microscopy found that TJs were destroyed after spinal cord injury, while overexpression of Perlecan reduced TJs degradation and improvement TJs structure (Figure 4D-E).
These results suggest that Perlecan improves BSCB permeability
by reducing the disassembly of TJs after spinal cord injury.
Fig.
4 Disassembly of TJs after overexpression of Perlecan reduces spinal cord injury to improve BSCB permeability
(Source: Changnan Xie, et al.
) , Mol Neurobiol, 2022)
Previous studies have shown that stress fiber formation mediated by the ROCK/MLC signaling pathway can result from centripetal tension on the binding of cell-cell/cell-extracellular matrix interactions by contracting actin TJs open and BBB permeability increase[9,10].
To investigate whether Perlecan's improvement in TJs structure and BSCB permeability is via the ROCK/MLC signaling pathway, the authors passed Western blotting and immunofluorescence experiments, observed that overexpression of Perlecan reduced ROCK1 and P-MLC expression (Fig 5)
。 In addition, endothelial cell integrin β1 interacts with the extracellular matrix to stabilize TJs and BBB/BSCB integrity [11,12].
。 The author passes qPCR, western blotting, and in vivo injection of the integrin beta1 inhibitor GRGDSP inhibit integrin beta1 Function, it was found that overexpression of Perlecan promoted integrin β1 expression, and in addition to reverse ZO-1 in spinal cord injury mice in the GRGDSP administration group , P-MLC expression and BSCB permeability (Figure 5).
These results suggest that Perlecan inhibits the ROCK/MLC signaling pathway by interacting with interginβ1, reducing TJs after spinal cord injury Disassembly of improves BSCB permeability
.
Fig.
5 Overexpression Perlecan improves BSCB after TJs disassembly after spinal cord injury is reduced by interginβ1/ROCK/MLC signaling pathway Permeability
(Source: Changnan Xie, et al.
) , Mol Neurobiol, 2022)
Fig.
6 Pattern of Perlecan BSCB repair after spinal cord injury
(Source: Changnan Xie, et al.
) , Mol Neurobiol, 2022)
。 Overexpression Perlecan inhibits the downstream ROCK/MLC signaling pathway by interacting with interginβ1, thereby inhibiting the inflammatory response and promoting blood-spinal cord barrier repair and neurological function recovery
.
The downside of this study is that how Perlecan degrades and remodels after spinal cord injury is not fully understood
.
Previous studies have shown that Perlecan can be cleaved by proteases (MMPs, cathepsins, etc.
) to form various degradation products within hours of ischemic stroke [13].
However, the exact protease and Perlecan degradation products involved in functional recovery after spinal cord injury are unclear and warrant further investigation
.
In addition, previous studies have shown that Perlecan is secreted and maintains the function of BSCB primarily by endothelial cells and astrocytes [3].
And glial scarring and angiogenesis are major biological events within two weeks of spinal cord injury, manifested by extensive astrocyte activation and neovascularization [14].
Therefore, the authors speculate that Perlecan remodeling may be caused by activated astrocytes and neoendothelial cells secreting Perlecan in large quantities.
On the other hand, the mechanism by which Perlecan regulates the ROCK/MLC signaling pathway is unclear
.
It has been reported in the literature that in traumatic brain injury, TIMP1 interacts with intergin β1 to inhibit the FAK/RhoA pathway and promote F-actin Depolymerization and structural stabilization of endothelial cells lead to the restoration of BBB function [15].
The results of this study show that Perlecan inhibits the downstream ROCK/MLC signaling pathway by interacting with intergin β1, thereby inhibiting stress fiber formation and improving the permeability and permeability of BSCB after spinal cord injury TJs integrity
.
However, the interaction of Perlecan with intergin β1 mediates the ROCK/MLC pathway to promote BSCB recovery needs to be further
。
Original link: https://doi.
org/10.
1007/s12035-022-03041-9
Funds: National Natural Science Foundation of China project numbers: 82071386, 81974329, 81672140; Natural Science Foundation of Guangdong Province: 2017A030312009, 2017A030313111; Key R&D Program of Guangdong Laboratory of Regenerative Medicine and Health: 2018GZR110104008; Guangdong Provincial Key Laboratory of Mental Illness Research Grant Project No.
: N201904
Zhu Lixin (left), Guo Jiasong (right).
(Photo courtesy of Zhu Lixin and Guo Jiasong Lab)
Lixin Zhu, Ph.
D.
, professor, doctoral supervisor, department director, director
of orthopedic center.
Director of Orthopedic Center and Director of Spine Surgery of Zhujiang Hospital of Southern Medical University, Chairman of Spine Surgery Branch of Guangdong Medical Association, Standing Director of Guangdong Biomedical Engineering Association, Chairman of Spine Surgery Engineering Professional Committee of Guangdong Biomedical Engineering Association, Vice Chairman of Spine Surgery Professional Committee of Guangdong Medical Association, Head of Non-Fusion Group of Spine Surgery Professional Committee of Guangdong Medical Association Member of the Standing Committee
of the Digital Orthopedics Society of SICOT China.
Engaged in bone tissue engineering and spinal cord injury and repair research, as corresponding author or first author in Biomaterials, ACS Appl Mater Interfaces, Molecular Neurobiology, etc Applied Materials Today and other international mainstream journals have published more than 20 SCI papers
.
He has presided over 2 projects of the National Natural Science Foundation, more than 10 provincial and ministerial funds, won 2 national patents, participated in the editing of 5 monographs, and won the second prize of Guangdong Province Science and Technology Progress Award1 3 second prizes for medical achievements and 4 third prizes
for medical achievements in the army.
Guo Jiasong, Ph.
D.
, postdoctoral fellow, professor, doctoral supervisor, deputy director of the National Key Discipline, deputy director of the Embryo Teaching and Research Office of the School of Basic Medicine of Southern Medical University, double professor of spine surgery of Zhujiang Hospital, deputy director of Guangdong Provincial Key Laboratory of Organization Construction and Testing, provincial-level object of Guangdong Provincial University Thousand and Ten Talents Program, excellent teacher
of the General Logistics Department of the People's Liberation Army 。 He is currently the vice chairman of the Regenerative Medicine Branch of the Chinese Anatomical Society, a member of the Standing Committee of the Neural Regeneration and Repair Professional Committee of the Chinese Research Hospital Association, a standing director of the Guangdong Anatomical Society, a vice chairman of the Cell Branch of the Guangdong Society for Brain Development and Encephalopathy Prevention and Treatment, and an editorial board member
of Neural Regeneration Research and Chinese Journal of Clinical Anatomy.
Mainly engaged in peripheral and central nervous system injury and repair research, in Annals of Neurology, Advanced Healthcare Materials, Molecular Neurobiology, J Neuroinflammation and other international mainstream journals have published more than 50 SCI papers and obtained 8 authorized patents
.
He has presided over 6 projects of the National Natural Science Foundation of China, as well as the sub-projects of the glial cell project of the China Brain Plan, the sub-projects of the National Key Basic Research Program (973 Program), and the high-level talent project of Guangdong Province
.
He is the chief editor of 6 textbooks, associate editor and co-editor of 18 textbooks
.
Ten graduate students have won awards at or above the provincial level (such as national doctoral scholarships, provincial excellent master's degrees and special prizes for domestic conference papers, etc.
).
[1] Schizophrenia—Brain network hub and working memory performance in patients with schizophrenia
[2] Front Cell Neurosci—uses bibliometrics to analyze research trends in astrocytes and stroke
[3] Cereb Cortex-Liu Tao's team revealed the accelerated degeneration pattern of white matter structure in the elderly
[4] Biophys J—Professor Xu Guangkui's research group reveals the network dynamics of nonlinear power-law relaxation in the cell cortex
[5] Science—Analysis of neurogenesis and regeneration in Mexican salamander using single-cellular, multi-omics techniques
[6] J Neuroinflammation Review—Ni Wenfei/Zhou Kailiang team focused on the important role of STING pathway in neuroinflammation and cell death after CNS injury
[7] Sci Adv—Sheng Neng-yin/Mao Bingyu/Ding Yuqiang teamed up to discover a new mechanism of AMPA receptor ubiquitination in the regulation of excitatory synaptic function
[8] Brain—Liu Gang/Hu Qingmao's team revealed the driving role of auxiliary motor areas in the alteration of the whole brain structural network in patients with blepharospasm
[9] FASEB J—Liu Yang's team found that antipsychotic drugs on experimental animals caused vascular abnormalities in hematopoietic organs
[10] Science-Du Yang team and others collaborated to develop non-opioid-free analgesics that target adrenergic receptors
Recommended high-quality scientific research training courses[1] Symposium on Single Cell Sequencing and Spatial Transcriptomics Data Analysis (October 29-30 Tencent Online Conference) Conference/Forum/Seminar Preview[1] Immune Zoom Seminar—Screening of B cells in the immune and nervous system (Professor Xu Heping)
[2] Academic Conference - 2022 Symposium on Neural Circuit Tracing Technology and the Second Round of the Second Round of the 6th National Training Course on Neural Circuit Tracing Technology
[3] Roundtable – Xu Fuqiang/Jia Yichang/Han Lanqing/Cai Lei et al.
discussed gene therapy innovation for neurodegenerative diseases and ophthalmic diseases
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End of this article
