Photobiomodulation promotes repair following spinal cord injury by restoring neuronal mitochondrial bioenergetics via AMPK/PGC-1α/TFAM pathway

Zhu, Zhijie; Wang, Xuankang; Song, Zhiwen; Zuo, Xiaoshuang; Ma, Yinbo; Zhang, Zhihao; Cheng, Ju; Liang, Zhicheng; Li, Kun; Hu, Xueyu; Wang, Zhe

doi:10.3389/fphar.2022.991421

Cited by 11 publications

(9 citation statements)

References 62 publications

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“…Chronic inflammatory response and oxidative stress in skeletal muscle after SCI may be the mechanisms leading to atrophy (9,(67)(68)(69). At present, the known factors and related proteins involved in skeletal muscle atrophy include: tumor necrosis factor-alpha (TNF-α) and its receptor (70)(71)(72), human tumor necrosis factor-related weak apoptosis-inducing factor (TWEAK) and its receptor (56, 67, 73), interleukin-1β (IL-1β) (72,74), interleukin-6 (IL-6) and its receptor (75,76), growth factor (IGF-1) (77, 78), human dystrophin (Fbox-1, also known as Atrogin-1) (79, 80), musclespecific RING finger protein 1 (MuRF1) (79,80), peroxisome proliferator-activated receptor-γ coactivator-1α (PGC-1α) (20,58,81), fibroblast growth factor-inducible receptor 14 (Fn14) (73), reactive oxygen species (ROS) (20,68,82) and others. The discovery of these skeletal dystrophins has provided a deeper understanding of skeletal muscle atrophy at the molecular level and suggest the possibility of intervening via corresponding signaling pathways and factors to delay the atrophy process or promote skeletal muscle regeneration.…”

Section: Cytokines Associated With Skeletal Muscle Atrophy After Scimentioning

confidence: 99%

“…Oxidative stress-mediated skeletal muscle atrophy after spinal cord injury Peroxisome proliferator-activated receptor-γ coactivator (PGC)α PGC-1α is a regulator of mitochondrial bioenergetics and abundantly expressed in skeletal muscle, and plays an essential role in skeletal muscle repair after SCI via transformation of fasttwitch to slow-twitch muscle fibers (77,81,110,111). It can induce mitochondrial biogenesis, and by up-regulating nuclear respiratory factors 1,2 (Nrf1, 2) and mitochondrial transcription factors expressed against oxidative stress in skeletal muscle and spinal cord (81,112) it can increase myoglobin activity and promote energy metabolism in skeletal muscle. After SCI, PGC-1α expression decreases (110), and expression of myosin heavy chain protein also decreases accordingly (31).…”

Section: Interleukin /mentioning

confidence: 99%

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Mechanism of skeletal muscle atrophy after spinal cord injury: A narrative review

Talifu²,

Zhang³

et al. 2023

Front. Nutr.

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Spinal cord injury leads to loss of innervation of skeletal muscle, decreased motor function, and significantly reduced load on skeletal muscle, resulting in atrophy. Factors such as braking, hormone level fluctuation, inflammation, and oxidative stress damage accelerate skeletal muscle atrophy. The atrophy process can result in skeletal muscle cell apoptosis, protein degradation, fat deposition, and other pathophysiological changes. Skeletal muscle atrophy not only hinders the recovery of motor function but is also closely related to many systemic dysfunctions, affecting the prognosis of patients with spinal cord injury. Extensive research on the mechanism of skeletal muscle atrophy and intervention at the molecular level has shown that inflammation and oxidative stress injury are the main mechanisms of skeletal muscle atrophy after spinal cord injury and that multiple pathways are involved. These may become targets of future clinical intervention. However, most of the experimental studies are still at the basic research stage and still have some limitations in clinical application, and most of the clinical treatments are focused on rehabilitation training, so how to develop more efficient interventions in clinical treatment still needs to be further explored. Therefore, this review focuses mainly on the mechanisms of skeletal muscle atrophy after spinal cord injury and summarizes the cytokines and signaling pathways associated with skeletal muscle atrophy in recent studies, hoping to provide new therapeutic ideas for future clinical work.

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Section: Cytokines Associated With Skeletal Muscle Atrophy After Scimentioning

confidence: 99%

Section: Interleukin /mentioning

confidence: 99%

Mechanism of skeletal muscle atrophy after spinal cord injury: A narrative review

Talifu²,

Zhang³

et al. 2023

Front. Nutr.

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“…In addition, PBM could regulate reactive oxygen species (ROS) production and activate a variety of transcription factors thus it has been used to treat SCI, ischemic stroke, traumatic brain injury, Alzheimer's disease and so on 26–29 . However, mitochondrial dysfunction that occurs after SCI limits the therapeutic effect of PBM 30 …”

Section: Introductionmentioning

confidence: 99%

“…[26][27][28][29] However, mitochondrial dysfunction that occurs after SCI limits the therapeutic effect of PBM. 30 To address the problems mentioned above, we first studied embedded laser fiber-mediated PBM combined with platelet-derived mitochondrial transplantation in the treatment of SCI. Our results indicated that combined treatment was better than that of a single treatment in terms of motor function recovery, tissue repair, and inhibition of neuronal apoptosis.…”

Section: Introductionmentioning

confidence: 99%

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Photobiomodulation augments the effects of mitochondrial transplantation in the treatment of spinal cord injury in rats by facilitating mitochondrial transfer to neurons via Connexin 36

Zhu

Wang

et al. 2022

Bioengineering & Transla Med

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Mitochondrial transplantation is a promising treatment for spinal cord injury (SCI), but it has the disadvantage of low efficiency of mitochondrial transfer to targeted cells. Here, we demonstrated that Photobiomodulation (PBM) could promote the transfer process, thus augmenting the therapeutic effect of mitochondrial transplantation. In vivo experiments, motor function recovery, tissue repair, and neuronal apoptosis were evaluated in different treatment groups. Under the premise of mitochondrial transplantation, the expression of Connex36 (Cx36), the trend of mitochondria transferred to neurons, and its downstream effects, such as ATP production and antioxidant capacity, were evaluated after PBM intervention. In in vitro experiments, dorsal root ganglia (DRG) were cotreated with PBM and 18β‐GA (a Cx36 inhibitor). In vivo experiments showed that PBM combined with mitochondrial transplantation could increase ATP production and reduce oxidative stress and neuronal apoptosis levels, thereby promoting tissue repair and motor function recovery. In vitro experiments further verified that Cx36 mediated the transfer of mitochondria into neurons. PBM could facilitate this progress via Cx36 both in vivo and in vitro. The present study reports a potential method of using PBM to facilitate the transfer of mitochondria to neurons for the treatment of SCI.

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Revisiting the Emerging Role of Light-Based Therapies in the Management of Spinal Cord Injuries

Sen,

Parihar,

Patil

et al. 2024

Mol Neurobiol

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Photobiomodulation promotes repair following spinal cord injury by restoring neuronal mitochondrial bioenergetics via AMPK/PGC-1α/TFAM pathway

Cited by 11 publications

References 62 publications

Mechanism of skeletal muscle atrophy after spinal cord injury: A narrative review

Mechanism of skeletal muscle atrophy after spinal cord injury: A narrative review

Photobiomodulation augments the effects of mitochondrial transplantation in the treatment of spinal cord injury in rats by facilitating mitochondrial transfer to neurons via Connexin 36

Revisiting the Emerging Role of Light-Based Therapies in the Management of Spinal Cord Injuries

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