The brown planthopper Nilaparvata lugens Stal(Homoptera: Delphacidae) can cause hopperburn by feeding on rice and also can transmit the grassy stunt disease. Resistant rice varieties have been developed, but several N. lugens strains can recover their virulence to these resistant rice varieties. In the present study, reference genes with stable expression levels in N. lugens populations showed different levels of virulence to susceptible and resistant rice varieties. The expression of six candidate reference genes in N. lugens feeding on susceptible and resistant rice varieties was analyzed. These genes were evaluated for their potential use in the analysis of differential gene expression. Polymerase chain reaction data was generated from N. lugens, including two different treatments(resistant or susceptible rice) and three virulent N. lugens populations. Three software programs(Best Keeper, Normfinder and ge Norm) were used to assess the candidate reference genes. Both ge Norm and Normfinder identified the genes 18 S, β-ACT, β-TUB and α-TUB as the most stable reference genes. Best Keeper identified ETIF1 as the optimal reference gene with the least overall variation, whereas 18 S and α-TUB were the second and third most stably expressed genes, respectively. Therefore, we concluded that the genes 18 S and α-TUB were the most suitable reference genes in N. lugens. These results will facilitate future transcript profiling studies on N. lugens populations that show variation in virulence levels on different rice varieties. The brown planthopper Nilaparvata lugens Stal (Homoptera: Delphacidae) can cause hopperburn by feeding on rice and also can transmit the grassy stunt disease. In the present study, reference genes with stable expression levels in N. lugens populations showed different levels of virulence to susceptible and resistant rice varieties. The expression of six candidate reference genes in N. lugens feeding on susceptible and resistant rice varieties was analyzed. These genes were evaluated for their potential use in the analysis of differential gene expression. Polymerase chain reaction data was generated from N. lugens, including two different treatments (resistant or susceptible rice) and three virulent N. lugens populations. Three software programs (Best Keeper , Normfinder and ge Norm) were used to assess the candidate reference genes. Both ge Norm and Nor mRNA identified the genes 18 S, β-ACT, β-TUB and α-TUB as the most stable reference genes. Best Keeper identified ETIF1 as the optimal reference gene with the least overall variation, whereas 18 S and α-TUB were the second Thus, we concluded that the genes 18 S and α-TUB were the most suitable reference genes in N. lugens. These results will facilitate future transcript profiling studies on N. lugens populations that show variation in virulence levels on different rice varieties.