Abstract Analysis of hypervariable regions in the D-loop of mitochondrial genome Author: Mei-chen Lo Thesis advised by: Horng-Mo Lee, Ph.D., Chin- Yuan Tzen M.D., Ph.D. The displacement loop (D-loop) of the mitochondrial DNA (mtDNA), approximately 1.4 kb in length, is a noncoding control region. mtDNA is maternally inherited, and exhibits high degree of homoplasmy. Heteroplasmy has been observed to be an intermediate condition in which new mutations are in the process of segregation to homoplasmy through genetic drift after relatively few generations. The control region consists of three hypervariable regions; HVR-I?HVR-II and HVR-III. However, the specific ranges of these HVRs have never been defined. We analyzed the mtDNA HVR-I from 1762 unrelated individuals and precisely defined that the HVR-I. Ranged from nucleotide position 16051 to 16399 for HVR-I with genetic diversity was 0.941-0.999. Ranged from nucleotid position 52 to 309CC for HVR-II with genetic diversity was 0.950-0.993. The values for HVR-III with genetic diversity was 0.864. In this material, HVR-IV was investigated, the values for HVR-IV with genetic diversity was 0.614. The presence of a heteroplasmic site may complicate sequence analysis for forensic purpose when two samples were compared. We analyzed the hypervariable region of the displacement loop (D-loop) in a family with five individuals, i.e., grandmother, mother, one son and two daughters. The result showed a heteroplasmic site at the np 204, which located in hypervariable region II. The nucleotide at this position was predominately cytosine in some samples and predominately thymine in others. Using Bayesian inference to assess the significance of the mother-offspring pairs, the likelihood ratio was 1.78×105. The ratio is lower than previous report. We conclude that dHPLC analysis is a sensitive and specific method to detect heteroplasmic mtDNA mutation. The chromatogram shows a heteroplasmy at np 204 in this family. This study demonstrated that heteroplasmy is a common occurrence in tissue from normal individuals, and should be considered in forensic cases where two samples appear to differ at a single nucleotide position by direct sequencing.