The discovery and development of citrus genus has a long history, however, in most of the past studies, citrus classification was mainly based on appearance and chemical characteristics. Citrus hybrids and branch mutations have made us difficult to distinguish their origins and species using traditional methods. Following to the advancement of molecular technology, the molecular markers have become the most important methods at taxonomy in past decade. The cpDNA (chloroplast DNA) has become one of the most useful markers for classification due to its characters such as maternal inheritance and slow evolution, which suitable for genetic variation analysis. The region commonly used for phylogenetic relationship of cpDNA is trnL-trnL-trnF noncoding region. The other regions were less used in the researches of phylogenetic relationship and genetic variation. In this study, nuclear DNA and cpDNA were used for the analysis of genetic variation. The noncoding regions of cpDNA were used to study their phylogenetic relationship. The genetic variation of two nuclear genes related to the environment adatpation and the fruit characteristic after processing were also compared. In the first part, 9 noncoding regions of cpDNA were used for the analysis of phylogenetic relationship of citrus. It was found out that the trnL intron and trnL-trnF IGS which frequently analyzed in the past showed high haplotype diversity. Nevertheless, the sweet oranges, grapefruits and pummelos have the same haplotype in these regions. Accordingly, both trnL intron and trnL-trnF IGS could only used to distinguish mandarins and sweet oranges. To address different evolutional rates of different regions at cpDNA and accuracy for analysis, we further combined several other DNA sequences. Secondly, the cytosolic classI small heat shock protein (sHSP) was used to analyze citrus genetic variation. It was found that most of the nucleotide variations in the coding regions were transversion and transition, and there was no indel in these regions. Therefore, the amino acid sequences of cytosolic classI sHSP were rather conservative. There was an indel in the 3’-UTR (3’-untranlated region) of this gene. According to this variation, the pummelos, grapefruits and tangelos which originated from different regions and grow in different climates could be distinguished into different groups. Nevertheless, this finding was not similar in the groups of mandarins, sweet oranges, lemons and limes. Latter citrus species were rapidly worldwide distributed and genetically hybridized and adatped to different climate patterns. These situations made the DNA sequences of cytosolic classI sHSP in citrus not an optimum marker for phylogenetic analysis. The final part in this study was to analyze the genetic variation of LGTase (limonoid glucosyltransferase). Most of the citrus, such as sweet oranges, mandarins and grapefruit, have 2 types of LGTase gene. However, 2 pummelos (Siam and Shatianyu) and one citron (Bergamot) only have 1 type of LGTase gene. Comparing the DNA sequences of LGTase from 24 citrus, it was found that the bitterness of limonoids was caused by several other factors instead of LGTase alone, thus its variation did not contribute much on limonoid bitterness.