Glial fibrillary acidic protein levels are associated with global histone H4 acetylation after spinal cord injury in rats

doi:10.4103/1673-5374.239443

Neural Regeneration Research ›› 2018, Vol. 13 ›› Issue (11): 1945-1952.doi: 10.4103/1673-5374.239443

Glial fibrillary acidic protein levels are associated with global histone H4 acetylation after spinal cord injury in rats

Mayara Ferraz de Menezes^{1, 2}, Fabrício Nicola³, Ivy Reichert Vital da Silva⁴, Adriana Vizuete³, Viviane Rostirola Elsner⁴, Léder Leal Xavier^{1, 2}, Carlos Alberto Saraiva Gonçalves³, Carlos Alexandre Netto³, Régis Gemerasca Mestriner^{1, 2}

1 Neurorehabilitation and Neural Repair Research Group, Pontifícia Universidade Católica do Rio Grande do Sul, Porto Alegre, RS, Brazil
2 Graduate Program in Cellular and Molecular Biology, Pontifícia Universidade Católica do Rio Grande do Sul, Porto Alegre, RS, Brazil
3 Department of Biochemistry, Basic Science Institute, Universidade Federal do Rio Grande do Sul, Porto Alegre, RS, Brazil
4 Graduate Program in Biosciences and Rehabilitation. Centro Universitário Metodista IPA, Porto Alegre, RS, Brazil

Received:2018-08-02 Online:2018-11-15 Published:2018-11-15
Contact: Viviane Rostirola Elsner, PhD,elsner.viviane@gmail.com.
Supported by:
This research was supported by Brazilian funding agencies CNPq, CAPES and FAPERGS.

Abstract

Abstract:

Emerging evidence has suggested global histone H4 acetylation status plays an important role in neural plasticity. For instance, the imbalance of this epigenetic marker has been hypothesized as a key factor for the development and progression of several neurological diseases. Likewise, astrocytic reactivity - a wellknown process that markedly influences the tissue remodeling after a central nervous system injury - is crucial for tissue remodeling after spinal cord injury (SCI). However, the linkage between the above-mentioned mechanisms after SCI remains poorly understood. We sought to investigate the relation between both glial fibrillary acidic protein (GFAP) and S100 calcium-binding protein B (S100B) (astrocytic reactivity classical markers) and global histone H4 acetylation levels. Sixty-one male Wistar rats (aged ~3 months) were divided into the following groups: sham; 6 hours post-SCI; 24 hours post-SCI; 48 hours post-SCI; 72 hours post-SCI; and 7 days post-SCI. The results suggested that GFAP, but not S100B was associated with global histone H4 acetylation levels. Moreover, global histone H4 acetylation levels exhibited a complex pattern after SCI, encompassing at least three clearly defined phases (first phase: no changes in the 6, 24 and 48 hours post-SCI groups; second phase: increased levels in the 72 hours post-SCI group; and a third phase: return to levels similar to control in the 7 days post-SCI group). Overall, these findings suggest global H4 acetylation levels exhibit distinct patterns of expression during the first week post-SCI, which may be associated with GFAP levels in the perilesional tissue. Current data encourage studies using H4 acetylation as a possible biomarker for tissue remodeling after spinal cord injury.

Key words: histones, spinal cord injury, glial fibrillary acidic protein, S100 calcium-binding protein B, neural plasticity, astrocyte, ELISA-immunoassay, recovery, neural repair, rats

Mayara Ferraz de Menezes, Fabrício Nicola, Ivy Reichert Vital da Silva, Adriana Vizuete, Viviane Rostirola Elsner, Léder Leal Xavier, Carlos Alberto Saraiva Gonçalves, Carlos Alexandre Netto, Régis Gemerasca Mestriner. Glial fibrillary acidic protein levels are associated with global histone H4 acetylation after spinal cord injury in rats[J]. Neural Regeneration Research, 2018, 13(11): 1945-1952.

[1]	Liu-Lin Xiong, Jie Chen, Ruo-Lan Du, Jia Liu, Yan-Jun Chen, Mohammed Al Hawwas, Xin-Fu Zhou, Ting-Hua Wang, Si-Jin Yang, Xue Bai. Brain-derived neurotrophic factor and its related enzymes and receptors play important roles after hypoxic-ischemic brain damage [J]. Neural Regeneration Research, 2021, 16(8): 1453-1459.
[2]	Yu Li, Ping-Ping Shen, Bin Wang. Induced pluripotent stem cell technology for spinal cord injury: a promising alternative therapy [J]. Neural Regeneration Research, 2021, 16(8): 1500-1509.
[3]	Ci Li, Song-Yang Liu, Wei Pi, Pei-Xun Zhang. Cortical plasticity and nerve regeneration after peripheral nerve injury [J]. Neural Regeneration Research, 2021, 16(8): 1518-1523.
[4]	Yong-Bin Gao, Zhi-Gang Liu, Guo-Dong Lin, Yang Guo, Lei Chen, Bo-Tao Huang, Yao-Bin Yin, Chen Yang, Li-Ying Sun, Yan-Bo Rong, Shanlin Chen. Safety and efficacy of a nerve matrix membrane as a collagen nerve wrapping: a randomized, single-blind, multicenter clinical trial [J]. Neural Regeneration Research, 2021, 16(8): 1652-1659.
[5]	Wen-Jing Wang, Yan-Biao Zhong, Jing-Jun Zhao, Meng Ren, Si-Cong Zhang, Ming-Shu Xu, Shu-Tian Xu, Ying-Jie Zhang, Chun-Lei Shan. Transcranial pulse current stimulation improves the locomotor function in a rat model of stroke [J]. Neural Regeneration Research, 2021, 16(7): 1229-1234.
[6]	Faisal F. Alamri, Abdullah Al Shoyaib, Nausheen Syeara, Anisha Paul, Srinidhi Jayaraman, Serob T. Karamyan, Thiruma V. Arumugam, Vardan T. Karamyan. Delayed atomoxetine or fluoxetine treatment coupled with limited voluntary running promotes motor recovery in mice after ischemic stroke [J]. Neural Regeneration Research, 2021, 16(7): 1244-1251.
[7]	Ayaka Sugeno, Wenhui Piao, Miki Yamazaki, Kiyofumi Takahashi, Koji Arikawa, Hiroko Matsunaga, Masahito Hosokawa, Daisuke Tominaga, Yoshio Goshima, Haruko Takeyama, Toshio Ohshima. Cortical transcriptome analysis after spinal cord injury reveals the regenerative mechanism of central nervous system in CRMP2 knock-in mice [J]. Neural Regeneration Research, 2021, 16(7): 1258-1265.
[8]	Dulce Parra-Villamar, Liliana Blancas-Espinoza, Elisa Garcia-Vences, Juan Herrera-García, Adrian Flores-Romero, Alberto Toscano-Zapien, Jonathan Vilchis Villa, Rodríguez Barrera-Roxana, Soria Zavala Karla, Antonio Ibarra, Raúl Silva-García. Neuroprotective effect of immunomodulatory peptides in rats with traumatic spinal cord injury [J]. Neural Regeneration Research, 2021, 16(7): 1273-1280.
[9]	Li-Jian Zhang, Yao Chen, Lu-Xuan Wang, Xiao-Qing Zhuang He-Chun Xia. Identification of potential oxidative stress biomarkers for spinal cord injury in erythrocytes using mass spectrometry [J]. Neural Regeneration Research, 2021, 16(7): 1294-1301.
[10]	Rong Li, Zu-Cheng Huang, Hong-Yan Cui, Zhi-Ping Huang, Jun-Hao Liu, Qing-An Zhu, Yong Hu. Utility of somatosensory and motor-evoked potentials in reflecting gross and fine motor functions after unilateral cervical spinal cord contusion injury [J]. Neural Regeneration Research, 2021, 16(7): 1323-1330.
[11]	Poornima D. E. Weerasinghe-Mudiyanselage, Jeongtae Kim, Yuna Choi, Changjong Moon, Taekyun Shin, Meejung Ahn. Ninjurin-1: a biomarker for reflecting the process of neuroinflammation after spinal cord injury [J]. Neural Regeneration Research, 2021, 16(7): 1331-1335.
[12]	Tianci Chu, Lisa B.E. Shields, Wenxin Zeng, Yi Ping Zhang, Yuanyi Wang, Gregory N. Barnes, Christopher B. Shields, Jun Cai. Dynamic glial response and crosstalk in demyelination-remyelination and neurodegeneration processes [J]. Neural Regeneration Research, 2021, 16(7): 1359-1368.
[13]	Martin A. Schick, Malgorzata Burek, Carola Y. Förster, Michiaki Nagai, Christian Wunder, Winfried Neuhaus. Hydroxyethylstarch revisited for acute brain injury treatment [J]. Neural Regeneration Research, 2021, 16(7): 1372-1376.
[14]	Zhe Cheng, Feng-Wu Li, Christopher R. Stone, Kenneth Elkin, Chang-Ya Peng, Redina Bardhi, Xiao-Kun Geng, Yu-Chuan Ding. Normobaric oxygen therapy attenuates hyperglycolysis in ischemic stroke [J]. Neural Regeneration Research, 2021, 16(6): 1017-1023.
[15]	Qiu-Shi Gao, Ya-Han Zhang, Hang Xue, Zi-Yi Wu, Chang Li, Ping Zhao . Brief inhalation of sevoflurane can reduce glial scar formation after hypoxic-ischemic brain injury in neonatal rats [J]. Neural Regeneration Research, 2021, 16(6): 1052-1061.

Glial fibrillary acidic protein levels are associated with global histone H4 acetylation after spinal cord injury in rats

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments