A comparative analysis of differentially expressed genes in rostral and caudal regions after spinal cord injury in rats

doi:10.4103/1673-5374.336874

Neural Regeneration Research ›› 2022, Vol. 17 ›› Issue (10): 2267-2271.doi: 10.4103/1673-5374.336874

Previous Articles Next Articles

A comparative analysis of differentially expressed genes in rostral and caudal regions after spinal cord injury in rats

Xue-Min Cao, Sheng-Long Li, Yu-Qi Cao, Ye-Hua Lv, Ya-Xian Wang, Bin Yu, Chun Yao

Key Laboratory of Neuroregeneration of Jiangsu and Ministry of Education, NMPA Key Laboratory for Research and Evaluation of Tissue Engineering Technology Products, Co-innovation Center of Neuroregeneration, Nantong University, Nantong, Jiangsu Province, China

Online:2022-10-15 Published:2022-03-16
Contact: Chun Yao, PhD, yaochun@ntu.edu.cn; Bin Yu, PhD, yubin@ntu.edu.cn.
Supported by:
This work was supported by Postgraduate Research & Practice Innovation Program of Jiangsu Province, No. KYCX-2065 (to XMC).

Abstract

Abstract: The initial mechanical damage of a spinal cord injury (SCI) triggers a progressive secondary injury cascade, which is a complicated process integrating multiple systems and cells. It is crucial to explore the molecular and biological process alterations that occur after SCI for therapy development. The differences between the rostral and caudal regions around an SCI lesion have received little attention. Here, we analyzed the differentially expressed genes between rostral and caudal sites after injury to determine the biological processes in these two segments after SCI. We identified a set of differentially expressed genes, including Col3a1, Col1a1, Dcn, Fn1, Kcnk3, and Nrg1, between rostral and caudal regions at different time points following SCI. Functional enrichment analysis indicated that these genes were involved in response to mechanical stimulus, blood vessel development, and brain development. We then chose Col3a1, Col1a1, Dcn, Fn1, Kcnk3, and Nrg1 for quantitative real-time PCR and Fn1 for immunostaining validation. Our results indicate alterations in different biological events enriched in the rostral and caudal lesion areas, providing new insights into the pathology of SCI.

Key words: biological process, caudal, differentially expressed genes, Gene Ontology, hemisection, immunostaining, Rattus norvegicus, RNA-sequencing, rostral, spinal cord injury

Xue-Min Cao, Sheng-Long Li, Yu-Qi Cao, Ye-Hua Lv, Ya-Xian Wang, Bin Yu, Chun Yao. A comparative analysis of differentially expressed genes in rostral and caudal regions after spinal cord injury in rats[J]. Neural Regeneration Research, 2022, 17(10): 2267-2271.

[1]	Wei Liu, Jie Yu, Yi-Fan Wang, Qian-Qian Shan, Ya-Xian Wang. [J]. Neural Regeneration Research, 2022, 17(on line): 1387-1392.
[2]	Wei Liu, Jin-Cheng Tao, Sheng-Ze Zhu, Chao-Lun Dai, Ya-Xian Wang, Bin Yu, Chun Yao, Yu-Yu Sun. Expression and regulatory network of long noncoding RNA in rats after spinal cord hemisection injury [J]. Neural Regeneration Research, 2022, 17(on line): 1-5.
[3]	Zhan-Yang Qian, Ren-Yi Kong, Sheng Zhang, Bin-Yu Wang, Jie Chang, Jiang Cao, Chao-Qin Wu, Zi-Yan Huang, Ao Duan, Hai-Jun Li, Lei Yang, Xiao-Jian Cao. Ruxolitinib attenuates secondary injury after traumatic spinal cord injury [J]. Neural Regeneration Research, 2022, 17(9): 2029-2035.
[4]	Ya Zheng, Dan Zhao, Dong-Dong Xue, Ye-Ran Mao, Ling-Yun Cao, Ye Zhang, Guang-Yue Zhu, Qi Yang, Dong-Sheng Xu. Nerve root magnetic stimulation improves locomotor function following spinal cord injury with electrophysiological improvements and cortical synaptic reconstruction [J]. Neural Regeneration Research, 2022, 17(9): 2036-2042.
[5]	Chao-Hua Yang, Zheng-Xue Quan, Gao-Ju Wang, Tao He, Zhi-Yu Chen, Qiao-Chu Li, Jin Yang, Qing Wang. Elevated intraspinal pressure in traumatic spinal cord injury is a promising therapeutic target [J]. Neural Regeneration Research, 2022, 17(8): 1703-1710.
[6]	Ting-Ting Cao, Huan Chen, Mao Pang, Si-Si Xu, Hui-Quan Wen, Bin Liu, Li-Min Rong, Mang-Mang Li. Dose optimization of intrathecal administration of human umbilical cord mesenchymal stem cells for the treatment of subacute incomplete spinal cord injury [J]. Neural Regeneration Research, 2022, 17(8): 1785-1794.
[7]	Kun Zhang, Wen-Can Lu, Ming Zhang, Qian Zhang, Pan-Pan Xian, Fang-Fang Liu, Zhi-Yang Chen, Chung Sookja Kim, Sheng-Xi Wu, Hui-Ren Tao, Ya-Zhou Wang. Reducing host aldose reductase activity promotes neuronal differentiation of transplanted neural stem cells at spinal cord injury sites and facilitates locomotion recovery [J]. Neural Regeneration Research, 2022, 17(8): 1814-1820.
[8]	Ye-Ran Mao, Zhong-Xia Jin, Ya Zheng, Jian Fan, Li-Juan Zhao, Wei Xu, Xiao Hu, Chun-Ya Gu, Wei-Wei Lu, Guang-Yue Zhu, Yu-Hui Chen, Li-Ming Cheng, Dong-Sheng Xu. Effects of cortical intermittent theta burst stimulation combined with precise root stimulation on motor function after spinal cord injury: a case series study [J]. Neural Regeneration Research, 2022, 17(8): 1821-1826.
[9]	Xuanyu Chen, Hedong Li. Neuronal reprogramming in treating spinal cord injury [J]. Neural Regeneration Research, 2022, 17(7): 1440-1445.
[10]	Jiaying Zheng, Madhuvika Murugan, Lingxiao Wang, Long-Jun Wu. Microglial voltage-gated proton channel Hv1 in spinal cord injury [J]. Neural Regeneration Research, 2022, 17(6): 1183-1189.
[11]	Yi-Xin Wang, Jin-Zhu Bai, Zhen Lyu, Guang-Hao Zhang, Xiao-Lin Huo. Oscillating field stimulation promotes axon regeneration and locomotor recovery after spinal cord injury [J]. Neural Regeneration Research, 2022, 17(6): 1318-1323.
[12]	Ying-Jie Zhao, Hao Qiao, Dong-Fan Liu, Jie Li, Jia-Xi Li, Su-E Chang, Teng Lu, Feng-Tao Li, Dong Wang, Hao-Peng Li, Xi-Jing He, Fang Wang. Lithium promotes recovery after spinal cord injury [J]. Neural Regeneration Research, 2022, 17(6): 1324-1333.
[13]	Wen-Yuan Shen, Xuan-Hao Fu, Jun Cai, Wen-Chang Li, Bao-You Fan, Yi-Lin Pang, Chen-Xi Zhao, Muhtidir Abula, Xiao-Hong Kong, Xue Yao, Shi-Qing Feng. Identification of key genes involved in recovery from spinal cord injury in adult zebrafish [J]. Neural Regeneration Research, 2022, 17(6): 1334-1342.
[14]	Melody N. Mickens, Paul Perrin, Jacob A. Goldsmith, Refka E. Khalil, William E. Carter III, Ashraf S. Gorgey. Leisure-time physical activity, anthropometrics, and body composition as predictors of quality of life domains after spinal cord injury: an exploratory cross-sectional study#br# [J]. Neural Regeneration Research, 2022, 17(6): 1369-1375.
[15]	Stuart I. Hodgetts, Sarah J. Lovett, D. Baron-Heeris, A. Fogliani, Marian Sturm, C. Van den Heuvel, Alan R. Harvey. Effects of amyloid precursor protein peptide APP96-110, alone or with human mesenchymal stromal cells, on recovery after spinal cord injury [J]. Neural Regeneration Research, 2022, 17(6): 1376-1386.

A comparative analysis of differentially expressed genes in rostral and caudal regions after spinal cord injury in rats

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments