There are bountiful methods for detecting the interactions between genes and environmental factors. Genome-wide association studies (GWAS) have identified some chromosomal regions interacting with environmental factors that may be responsible for diseases or traits. However, the biological mechanisms underlying most published gene-environment interactions have been still unclear. To test for the interactions of single-nucleotide polymorphisms (SNPs) with environmental factors on traits of interest, we proposed a new statistical method, Adaptive Integration Method (AIM). Firstly, we predicted transcriptome by putative expression quantitative trait loci (eQTLs) of different tissues by using PrediXcan and the Genotype-Tissue Expression (GTEx) library. Next, we transformed the predicted transcriptome into transcriptome risk score (TRS) and tested associations between the trait of interest and TRS in each tissue. Because not all tissues are related to the trait of interest, only transcriptome from some tissues may serve as evidence of gene-environment interactions. Therefore, we adaptively integrated the gene-environment interaction signals from multiple tissues with our Adaptive Integration Method (AIM). As an example, we evaluated the interactions between genes and waist-to-hip ratio (WHR) on fasting glucose. Our analysis included 58,774 participants from the Taiwan Biobank 2.0 (TWB), with approximately 6 million imputed SNPs by the Michigan Imputation Server. By using our AIM, a total of 51 genes were identified at the significance level of 2 × 10-6. To replicate the results, we performed the analysis for 25,460 participants from the Taiwan Biobank 1.0. We replicated 10 significant genes with p-value<0.05. From the DNA perspective, 18 out of the 51 genes identified from TWB 2.0 were also confirmed to have interactions with WHR on fasting glucose according to current gene-based analysis methods. For example, the PPP1R3C (protein phosphatase 1 regulatory subunit 3C) gene was colocalized to exhibit significant interaction with WHR, from both the DNA level and the RNA level.