Background: Approximately 30% of patients continue to have seizures despite optimized drug treatment. The responses to AEDs may differ in patients even with the same type of epilepsy. It is possible that genetic polymorphisms may, to certain degree, cause the response variability of the epilepsy pharmacotherapy. The ionotropic receptors of gamma-aminobutyric acid (GABAA) are among the most important target sites for AEDs. The most common subunit composition of GABAA receptors is two α, two β, and one other subunits. The α subunit family is the most diverse, with six different subtypes (α1–α6). GABA binding occurs at α subunits. Many lines of evidence indicate different GABAA receptors composed of different α subunits have different response to GABA and other AEDs. Aims: Here we hypothesize that genetic polymorphisms in α subunits may, to certain degree, explain variable responses in different epilepsy patients. Methods: 758 epilepsy patients, all with comprehensive clinical data, and 194 controls were enrolled in this study. We genotyped tagging SNPs at the 6 α subunits genes, GABRA1-GABRA6,and other SNPs in SCN1A,SCN2A,ABCB1,ABCC2 ,which have previously associated with epilepsy treatment outcome. Results: We demonstrated the association between phenobarbital response and a SNP (rs17599416) in the intron7 of GABRA4, a gene previously shown to be associated with autism. Patients with the “A allele” were more likely to be drug resistant (odds ratio 2.8261, 95% confidence interval: 1.1968 to 6.6736, nominal p-value=0.01792). rs511310 in the downstream region of GABRA2 also showed an effect on phenobarbital response. Patients with the “G allele” were more likely to be drug resistant (odds ratio 6.413, 95% confidence interval: 2.203-18.67，nominal p-value=0.000363). Using the logistic regression model, rs4828696 in intron1 of GABRA3 was associated with the drug response on different level in patients with different drug usage. Discussion and conclusion: This report, to our knowledge, is the first association study to have comprehensive coverage of all 6 α subunits of GABAA receptor genes and reasonably good sample size. Further replication using an independent sample collection will be essential to confirm our findings. Functional assays will help to illustrate how those associated genes influence the pharmacotherapy responses of AEDs.