Diet adaptation is an important cause of host-associated differentiation. Many studies have focused on the species in which host specialization has driven speciation or population differentiation. However, it is still unknown the underlying genetic changes evolved earlier during specialization. In Drosophila, noni fruit is toxic to most species except very few species such as D. sechellia. Multiple mechanisms have been involved in the noni specialization in D. sechellia. To understand early genetic changes during diet adaptation, we chose D. melanogaster that exhibits some tolerance variation to noni fruit. We performed a genome-wide association study (GWAS) to reveal the genetic basis of noni-toxin tolerance in D. melanogaster using 117 DGRP (Drosophila Genetic Reference Panel) lines. We found considerable sexual and strain variation of noni-toxin tolerance. Among the ~4 million variants detected in the 117 DGRP lines, 116 candidate variants shared between the two sexes were associated with the noni-toxin tolerance. These candidate variants were mainly located in non-coding regions of the genome. The genetic basis of toxin tolerance in D. melanogaster is different from that in D. sechellia because most candidate variants were derived alleles, which were not present in the closely related species including D. sechellia. These candidate variants were mainly coming from standing variation, which also exists in ancestral African populations. The correction between these candidate variants identified from the American DGRP population and the observed noni-fruit tolerance in the two African DPGP2 populations, suggesting that the underlying genetic bases of tolerance are different. These findings advance our understanding of the underlying genetic change of early evolution in diet adaptation.