癫痫与表观遗传学_Journal of Epilepsy

Authors：

孙丹 , 杨伟民 ,  刘智胜

华中科技大学同济医学院附属武汉儿童医院神经内科 (武汉 430016);

Corresponding author：

刘智胜, Email: liuzsc@126.com

Keywords：

表观遗传学; DNA甲基化; 组蛋白修饰; 癫痫

DOI：

10.7507/2096-0247.20170021

Video：

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Abstract Full text Figures/Tables Video References Cited by

癫痫是一种以反复刻板性发作为特征的慢性神经系统疾病，现仍有20%~30%为难治性癫痫患儿，且发病机制尚未完全阐明。目前研究发现癫痫发病过程中存在表观遗传修饰异常，主要包括DNA甲基化、染色质重组、组蛋白修饰和非编码RNA调控等。文章将讨论表观遗传学在癫痫发病机制中的调控作用，以及与局灶性癫痫和全面性癫痫的关系，期待能从表观遗传学的角度阐明癫痫的发病机制，从而为癫痫药理学治疗分子靶标的识别提供新方向。

Citation： 孙丹, 杨伟民, 刘智胜. 癫痫与表观遗传学. Journal of Epilepsy, 2017, 3(2): 141-144. doi: 10.7507/2096-0247.20170021 Copy

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2.	Huang Y, Zhao F, Wang L, et al. Increased expression ofhistone deacetylases 2 in temporal lobe epilepsy: a study of epileptic patients and rat models. Synapse, 2012, 66(2): 151-159.
3.	Xi ZQ, Sun JJ, Wang XF, et al. HSPBAPI is found extensively in the anterior temporal neocortex of patients with intractable epilepsy. Synapse, 2007, 61(9): 741-747.
4.	Senner CE. The role of DNA methylation in mammalian development. Reprod Biomed Online, 2011, 22(6): 529-535.
5.	Urdinguio RG, Fernandez AF, Lopez Nieva P, et al. Disrupted microRNA expression caused by Mecp2 loss in a mouse model of Rett syndrome. Epigenetics, 2010, 5 (2): 656-663.
6.	Roth TL, Zoladz PR, Sweatt JD, et al. Epigenetic modification of hippocampal BDNF DNA in adult rats in an animal model of post-traumatic stress disorder. J Psychiatr Res, 2011, 45(7): 919-926.
7.	Kobow K, Jeske I, Hildebraudt M, et al. Increased reelin promoter methylation is associated with granule cell dispersion in human temporal lobe epilepsy. J Neuropathol Exp Neurol, 2009, 68(4): 356-364.
8.	Imenez Mateos EM, Bray I, Sanz Rodriguez A, et al. miRNA Expression profile after status epilepticus and hippocampal neuroprotection by targeting miR-132. Am J Pathol, 2011, 179 (5): 2519-2532.
9.	Mercer TR, Dinger ME, Mattick JS. Long noncoding RNAs: insights into functions. Nat Rev Genet, 2009, 10(3): 155-159.
10.	Halil AM, Faghihi MA, Modarresi F, et al. A novel RNA transcrpt with antiapoptotic function is silenced in fragile X syndrome. PLoS One, 2008, 3(1): e1486.
11.	Ladd PD, Smith LE, Rabaia NA, et al. An antisense transcript spanning the CGG repeat region of FMRI is upregulated in premutation Cal Tiers but silenced in full mutation individuals. Hum Mol Genet, 2007, 16(24): 3174-3187.
12.	P Kwan, MJ Brodie. Early identification of refractory epilepsy. N Engl J Med, 2000, 342(20): 314-319.
13.	I Najm, L Jehi, A Palmini, et al. Temporal patterns and mechanisms of epilepsy surgery failure. Epilepsia, 2013, 54(3): 772-782.
14.	SF Berkovic, IE Scheffer. Genetics of the epilepsies. Epilepsia, 2001, 42(Suppl 5): 16-23.
15.	AJ Becker, J Chen, A Zien, et al. Correlated stage-and subfield-associated hippocampal gene expression patterns in experimental and human temporal lobe epilepsy. Eur J Neurosci, 2003, 18(2): 2792-2802.
16.	M Majores, J Eils, OD Wiestler, et al. Molecular profiling of temporal lobe epilepsy: comparison of data from human tissue samples and animal models. Epilepsy Res, 2004, 60(4): 173-178.
17.	K Kobow, I Blumcke. The methylation hypothesis: do epigenetic chromatin modifications play a role in epileptogenesis?. Epilepsia, 2011, 52(Suppl 4): 15-19.
18.	SF Miller-Delaney, K Bryan, S Das, et al. Differential DNA methylation profilesof coding and non-coding genes define hippocampal sclerosis in human temporal lobe epilepsy. Brain, 2005, 138(5): 616-631.
19.	C Nervi, E De Marinis, G Codacci-Pisanelli. Epigenetic treatment of solid tumours: a review of clinical trials. Clin Epigenet, 2015, 7(1): 127.
20.	M Szyf. Prospects for the development of epigenetic drugs for CNS conditions. Nat Rev Drug Discov, 2015, 14(5): 461-474.
21.	K Kobow, A Kaspi, KN Harikrishnan, et al. Deep sequencing reveals increased DNA methylation in chronic rat epilepsy. Acta Neuropathol, 2013, 126(5): 741-756.
22.	SF Berkovic, JC Mulley, IE Scheffer, et al. Human epilepsies: interaction of genetic and acquired factors. Trends Neurosci, 2006, 29(6): 391-397.

1. Guan JS, Haggarty SJ, Giacometti E, et al. HDAC2 negatively regulates memory formation and synaptic plasticity. Nature, 2009, 459(7243): 55-60.
2. Huang Y, Zhao F, Wang L, et al. Increased expression ofhistone deacetylases 2 in temporal lobe epilepsy: a study of epileptic patients and rat models. Synapse, 2012, 66(2): 151-159.
3. Xi ZQ, Sun JJ, Wang XF, et al. HSPBAPI is found extensively in the anterior temporal neocortex of patients with intractable epilepsy. Synapse, 2007, 61(9): 741-747.
4. Senner CE. The role of DNA methylation in mammalian development. Reprod Biomed Online, 2011, 22(6): 529-535.
5. Urdinguio RG, Fernandez AF, Lopez Nieva P, et al. Disrupted microRNA expression caused by Mecp2 loss in a mouse model of Rett syndrome. Epigenetics, 2010, 5 (2): 656-663.
6. Roth TL, Zoladz PR, Sweatt JD, et al. Epigenetic modification of hippocampal BDNF DNA in adult rats in an animal model of post-traumatic stress disorder. J Psychiatr Res, 2011, 45(7): 919-926.
7. Kobow K, Jeske I, Hildebraudt M, et al. Increased reelin promoter methylation is associated with granule cell dispersion in human temporal lobe epilepsy. J Neuropathol Exp Neurol, 2009, 68(4): 356-364.
8. Imenez Mateos EM, Bray I, Sanz Rodriguez A, et al. miRNA Expression profile after status epilepticus and hippocampal neuroprotection by targeting miR-132. Am J Pathol, 2011, 179 (5): 2519-2532.
9. Mercer TR, Dinger ME, Mattick JS. Long noncoding RNAs: insights into functions. Nat Rev Genet, 2009, 10(3): 155-159.
10. Halil AM, Faghihi MA, Modarresi F, et al. A novel RNA transcrpt with antiapoptotic function is silenced in fragile X syndrome. PLoS One, 2008, 3(1): e1486.
11. Ladd PD, Smith LE, Rabaia NA, et al. An antisense transcript spanning the CGG repeat region of FMRI is upregulated in premutation Cal Tiers but silenced in full mutation individuals. Hum Mol Genet, 2007, 16(24): 3174-3187.
12. P Kwan, MJ Brodie. Early identification of refractory epilepsy. N Engl J Med, 2000, 342(20): 314-319.
13. I Najm, L Jehi, A Palmini, et al. Temporal patterns and mechanisms of epilepsy surgery failure. Epilepsia, 2013, 54(3): 772-782.
14. SF Berkovic, IE Scheffer. Genetics of the epilepsies. Epilepsia, 2001, 42(Suppl 5): 16-23.
15. AJ Becker, J Chen, A Zien, et al. Correlated stage-and subfield-associated hippocampal gene expression patterns in experimental and human temporal lobe epilepsy. Eur J Neurosci, 2003, 18(2): 2792-2802.
16. M Majores, J Eils, OD Wiestler, et al. Molecular profiling of temporal lobe epilepsy: comparison of data from human tissue samples and animal models. Epilepsy Res, 2004, 60(4): 173-178.
17. K Kobow, I Blumcke. The methylation hypothesis: do epigenetic chromatin modifications play a role in epileptogenesis?. Epilepsia, 2011, 52(Suppl 4): 15-19.
18. SF Miller-Delaney, K Bryan, S Das, et al. Differential DNA methylation profilesof coding and non-coding genes define hippocampal sclerosis in human temporal lobe epilepsy. Brain, 2005, 138(5): 616-631.
19. C Nervi, E De Marinis, G Codacci-Pisanelli. Epigenetic treatment of solid tumours: a review of clinical trials. Clin Epigenet, 2015, 7(1): 127.
20. M Szyf. Prospects for the development of epigenetic drugs for CNS conditions. Nat Rev Drug Discov, 2015, 14(5): 461-474.
21. K Kobow, A Kaspi, KN Harikrishnan, et al. Deep sequencing reveals increased DNA methylation in chronic rat epilepsy. Acta Neuropathol, 2013, 126(5): 741-756.
22. SF Berkovic, JC Mulley, IE Scheffer, et al. Human epilepsies: interaction of genetic and acquired factors. Trends Neurosci, 2006, 29(6): 391-397.

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