Even though mitochondrial DNA analysis is performed in the field of molecular genetics, differences of the results exist regarding which nucleotide positions are analyzed. In this study, we strategically analyzed to find ethnic specific SNP of coding regions of mitochondrial DNA of Korean and Mongolian. Mitochondrial DNA was analyzed with PCR amplification and sequencing with 112 blood samples of Korean and 92 blood samples of Mongolian. As a result, the mutation which commonly appears both in Korean and Mongolian population is 17 nucleotide positions, and the one that shown in the only Korean is 13 nucleotide positions, the one that shown in the only Mongolian 26 nucleotide positions. However, it was thought as individual variation as most mutations are shown in a sample. Among them, it appears as 9% substitution rate in 10397, 4850 nucleotide position of Korean, whereas 12.3% or 15% substitution rate in 5108, 9950 nucleotide positions of Mongolian, respectively. Beside, we observed high level of heteroplasmy in 3546, 3553 nucleotide positions. Therefore, we suggest that these regions might be novel genetic markers for dividing mitochondrial haplogroup of Korean and Mongolian population, but additional analysis needs on several nucleotide positions in huge samples as analyzing on restricted nucleotide positions using restricted DNA samples.
Clinical Coding ; DNA ; DNA, Mitochondrial ; Genetic Markers ; Molecular Biology ; Polymerase Chain Reaction

As characterization of mitochondrial DNA (mtDNA) shows maternal inheritance and exists as more than thousands copies per cell, it is widely used for population genetics and forensic scientific field. However, mitochondrial DNA study has difficulties because heteroplasmy of mtDNA is being reported from coding and control region. In this study, we have analyzed 200 samples to examine heteroplasmy in mitochondrial DNA of Korean and Mongolian. The control region and coding region in mtDNA of blood from Koreans and Mongolians were analyzed with PCR amplication and sequencing. As a result, several heteroplasmy was observed from total 10 positions including 5 positions in coding region and 5 positions in control region, respectively. Moreover, it showed more than one heteroplasmy in coding region from 6 samples in Korean and 17 samples in Mongolian. Interestingly, heteroplasmy at 5178 position was shown in 6 samples among 23 samples. Considering that the position is important for deciding haplogroup D, we suggest that additional analysis on 4883 position needs for correct haplogrouping. Beside, we also found heteroplasmy in the other positions of 204, 4853, or 16249. Therefore, we suggest that it is required of combinatory analysis on several key nucleotide positions to obtain good results when determining mitochondrial haplogroups.
Clinical Coding ; Coat Protein Complex I ; DNA, Mitochondrial ; Genetics, Population ; Polymerase Chain Reaction ; Wills

Determination of male and female is important in anthropology, archeology and forensic science. This study was designed to compare genotype sex of improved amelogenin PCR amplication method with morphological sex of ancient human bones. Sixty human skulls which lived from the Bronze Age to twenties centuries and excavated in Uzbekistan were used in this study. Morphological sex was determined by Uzbekistan scientist, and genotype sex was determined by improved amelogenin PCR amplication developed in this study. Among 20 morphological males, 13 samples (65%) were genotypical male. Among 40 morphological females, 20 samples (50%) were genotypical male. In conclusion, morphological method might be inadequate for sex determination of ancient bones. The improved amelogenin PCR method will be useful in sex determination of ancient bones.
Amelogenin* ; Anthropology ; Archaeology ; Female ; Forensic Sciences ; Genotype* ; Humans ; Male ; Polymerase Chain Reaction* ; Skull ; Uzbekistan*

Many data from ancient human remains became useful by molecular approach for ancient human DNA. In anthropology, genetic sex is essential to understand marriage and burial patterns, differential mortality rates between sexes, and differential patterns by sex of disease, diet, status, and material possessions. This study was designed to determine genotype sex of 52 ancient human bones with well preserved skulls, and to compare with the orphological sex. Parts of femur and other bones were used as ancient bones excavated in Mongolia aged between bronze and Mongol period. Morphological sex was determined by Mongolian scientist, and genotype sex was determined by using biallelic marker RPS4Y for Y haplogroup. Of 52 genetic males, 10 samples were morphologically female. In conclusion, biallelic marker RPS4Y. PCR amplication method will be useful in sex determination of ancient bones.
Anthropology ; Burial ; Diet ; DNA ; Female ; Femur ; Genotype ; Humans* ; Male ; Marriage ; Mongolia ; Mortality ; Polymerase Chain Reaction ; Skull ; Y Chromosome