To evolutionary biologist, how a new species arise remains an interesting and important question to solve. Though many hypothetical scenarios were proposed, it is still limited to understand how speciation progresses and discover proper cases to support. Currently, it is easier to sample the considerable sequences with the development of massive parallel sequencing (MPS). These abundant sequences provide a superior opportunity to approach speciation questions which were hard to assay before. Here, two systems with speciation questions were studied via the help of MPS. First, to demonstrate the genic view of speciation, Drosophila simulans clade were used as a model to analyze. With the sequences of 4348 genes, significantly heterogeneous divergence was revealed by the speciation model test. In addition, the genome-wide mosaic nature of phylogeny inference was also discovered. These results demonstrate the discordance of topologies among loci at the genomic level and proposed the candidates which can be crucial during speciation. Second, to assay the mechanisms which play an important roles in speciation, the incipient speciation model of Drosophila melanogaster were analyzed. This model comprises two behavioral isolated races, M (for cosmopolitan) and Z (for Zimbabwe). In each race, the adaptive loci were suggested by using population genome sequence. Moreover, the differentially expressed genes were found by using RNA-seq. Interestingly, the genes upregulated in the Z race are enriched for vision whereas genes upregulated in the M race are enriched in metabolic processes. These results not only provide the genetic basis of behavior isolation but also suggest the driving force underlying racial differentiation.