Abstract
It is widely known that people in Okinawa originated from the Jomon people, and are generally tolerant to alcohol. However, some individuals in mainland Japan lack alcohol tolerance due to a mutation in the human mitochondrial aldehyde dehydrogenase 2 (ALDH2) gene. Furthermore, the JC virus (JCV) genotype MY, which is related to the Jomon people, has not been found in Okinawa. In this study, to analyze the origin of the Okinawan people, we investigated the relationship between the JCV genotype and ALDH2 genotype. We collected 108 JCV positive samples from Okinawa. Only CY genotype JCV, and not the MY genotype, was detected. Among JCV-positive samples, a variant of ALDH2 (Glu/Lys heterozygote) was detected in 31 samples (29%) and wild-type ALDH2 (Glu/Glu homozygote) was detected in 77 samples (71%). Another variant of ALDH2 (Lys/Lys homozygote) was not detected. Among carriers of CY genotype JCV, wild-type ALDH2 was much more frequent in people living in Okinawa than in mainland Japan (Pā<ā0.05). Our results suggested that the original inhabitants of Okinawa were people who carried MY genotype JCV and wild-type ALDH2; and that after the extinction of these original inhabitants, people who carried CY genotype JCV and wild-type ALDH2 migrated to the area. Due to the founder effect, CY genotype JCV and wild-type ALDH2 became dominant. Over a long period, many people with the variant ALDH2 migrated to Okinawa; the variant allele increased in frequency, but other JCV genotypes were eliminated.
Similar content being viewed by others
Introduction
Modern Japanese people are descendants of the Jomon people and Yayoi people. Archaeological studies have indicated that these two populations moved from the Chinese continent to the Japanese archipelago long ago. The Jomon people first migrated from the Chinese continent through the Korean peninsula about 37,000ā38,000 BP1. The Jomon culture, who are known as hunter-gatherers and one of the older pottery cultures, then developed in 12,000 BP2. Long after the migration of the Jomon people, at 2,300 BP, the Yayoi people migrated from the Chinese continent to the Japanese archipelago. The migration of the Yayoi people resulted in the spread of the Jomon people to eastern Japan and the Okinawan islands (dual structure model)3. Genomic analyses of the ethnic origin of the Japanese population essentially support the dual structure model4,5,6,7.
In our previous study, we analyzed the relationship between mutations in the human mitochondrial aldehyde dehydrogenase 2 (ALDH2) gene and the JC virus (JCV) genotype to elucidate the ethnic origin of the Japanese population. Mitochondrial ALDH2 is located on chromosome 12 and consists of 13 exons. The SNP rs671 in the ALDH2 gene is a G-to-A substitution resulting in the ALDH2 Glu504Lys (originally, Glu487Lys) allele. This atypical ALDH2 variant (ALDH2 Glu504Lys) is prevalent in Asians and is a causal factor in the alcohol flush reaction when drinking8. The variant of ALDH2 has low levels of genetic diversity, suggesting a young haplotype9; it occurred in the Chinese Pai-Yuei tribe approximately 2,000ā3,000 BP and gradually spread to peripheral regions10. Thus, it is considered a genetic marker for analyses of Yayoi ancestry11.
We investigated human polyomavirus JCV genotypes around the world12. Homo sapiens began to migrate from Africa about 100,000 years ago, with human parasitic JCV13. Since the migration, H. sapiens with JCV spread to many places in the world. Unlike in the human genome, integration does not occur in the viral genome, and therefore the minor genotype of the virus is not passed on to progeny, and does not persist in a group. Therefore, JCV genotypes are each distributed in a distinct area or population. This enables simple analyses of human migration. In a detailed analysis, Kitamura et al.14 found that MY genotype JCV is prevalent in eastern Japan and CY genotype JCV is prevalent in western Japan. Based on the substitution rate in the JCV genome, it is estimated that the MY clade arose 10,000ā30,000 years ago15 and the CY clade arose 10,000 years ago. Therefore, archaeological findings combined with JCV evolution and distribution indicate that the Jomon people may be associated with MY genotype JCV and that the Yayoi people may be associated with CY genotype JCV.
We previously analyzed the relationship between JCV genotype and ALDH2 genotype in people who live in mainland Japan. We found that people who carry CY genotype JCV have a higher frequency of ALDH2 mutation than that of people who carry MY genotype JCV (Pā<ā0.05)16. This result suggested that the Jomon people initially carried MY genotype JCV and wild-type ALDH2 in the Japanese archipelago and, subsequently, Yayoi people who carried CY genotype JCV and a variant of ALDH2 migrated from the Chinese continent throughout the Korean peninsula. The migration of the Yayoi people resulted in the eastward migration of the Jomon people towards eastern Japan. However, according to the dual structure model developed by archaeologists, the Jomon people were forced to move to the Okinawa islands as well as to eastern Japan. This model cannot explain why only CY genotype JCV is detected in Okinawa14. Therefore, in this study, we investigated ALDH2 mutations associated with the Yayoi people among CY genotype JCV-positive people in Okinawa and discussed the origin of these populations.
Results
In the 108 JCV positive samples, only CY genotype JCV was detected (see Supplementary Fig.Ā S1). Among the JCV-positive samples, a variant of ALDH2 (Glu/Lys heterozygote) was detected in 31 samples (29%) and wild-type ALDH2 (Glu/Glu homozygote) was detected in 77 samples (71%). Another variant of ALDH2 (Lys/Lys heterozygote) was not detected. Among people who carried CY genotype JCV, wild-type ALDH2 was much more frequent in people living in Okinawa than in those in mainland Japan (TableĀ 1) (Pā<ā0.05).
Discussion
Jomon and Yayoi people and the JCV genotype
MY and CY JCV are related to the Jomon and Yayoi people, respectively14. Wild-type ALDH2 (Glu/Glu homozygote) and ALDH2 Glu/Lys heterozygotes are associated with the Jomon and Yayoi people, respectively11. Therefore, it is estimated that genotypes MY and CY are associated with wild-type and variant ALDH2, respectively.
People in mainland Japan
The MY clade of JCV arose 10,000ā30,000 years ago15 and the CY clade of JCV occurred 10,000 years ago17. The Yayoi people migrated to the Japanese archipelago, where the Jomon people carrying MY genotype JCV lived about 2,000ā3,000 years ago. The ALDH2 variant arose about 2,000ā3,000 years ago in the Chinese population10. The frequency of the ALDH2 variant is 31.9% in the Japanese population9. However, among people living in mainland Japan who carry CY genotype JCV, the frequency of the ALDH2 variant is 51.5%16. This frequency of the variant allele is much higher than that in the Chinese Guangdong Han (46.7%), and is the highest among Asian populations9,10. Therefore, when the Yayoi people first migrated to the western Japanese archipelago, they might have carried CY genotype JCV as well as the variant ALDH2. The group did not exchange genes immediately with the Jomon people, who carried MY genotype JCV and wild-type ALDH2; therefore, CY genotype JCV was not selected and the frequency of the ALDH2 variant became high in this group. The Jomon people might have moved to eastern Japan and Okinawa according to the dual structure model. In eastern Japan, gene admixture occurred between the Jomon people and other groups with variant ALDH2, resulting in a gradual decrease in the frequency of the variant allele.
People in Okinawa
The dual structure model predicts that the JCV genotype in Okinawa is MY. However, we only detected CY genotype JCV for all 100 JCV-positive samples, consistent with a previous report14. Additionally, the ALDH2 variant was detected in 29% of people in Okinawa, but 51.5% in mainland Japanese (Pā<ā0.05) (TableĀ 1).
ALDH2 mutations are related to drinking habits in the Japanese population18,19. Mutations at this locus are associated with hereditary diabetes20, risk factors for colon cancer21, esophageal melanosis22, hepatitis B virus infection23, and pancreatic cancer24. It is possible that these disease relationships influenced the mutation rate in the group.
Why was the frequency of the ALDH2 variant among people with CY genotype JCV much lower in Okinawa than in mainland Japan? Additionally, why was CY the only genotype detected in Okinawa? We considered several explanations for these observations. JCV is inherited from either parent to offspring25. Minor JCV alleles were selected26. Therefore, populations included individuals who carried CY genotype JCV as well as MY genotype JCV with wild-type ALDH2. MY genotype JCV was lost over time. Only people who carried CY genotype JCV survived and spread to the Okinawan islands (bottleneck effect). However, this does not explain why only people who carried CY genotype JCV survived. There is little evidence for the Yayoi culture in Okinawa; accordingly, it is unlikely that CY genotype JCV pre-existed in the area. Instead, people in Okinawa might instead have carried wild-type ALDH2. When people who carried CY genotype JCV migrated from mainland Japan to Okinawa, CY type JCV spread in Okinawa via the founder effect. Some people who migrated from mainland Japan carried the ALDH2 variant, and accordingly the frequency of the variant increased slightly in Okinawa by gene flow. However, considering that Homo sapiens migrated from Africa with JCV27, it is unlikely that the preexisting people in Okinawa did not carry JCV. In one scenario, Okinawa was uninhabited, and people from mainland Japan who carried CY genotype JCV and wild-type ALDH2 migrated to the Okinawan islands by chance. By the founder effect, CY genotype JCV and wild-type ALDH2 spread to in the Okinawan islands. Later, those who carried the variant ALDH2 migrated to the Okinawan islands, and the variant genotype increased in frequency. Though the alternative JCV genotype might have been introduced more recently, the minor genotype was selected relative to the major CY genotype. Accordingly, even today, MY genotype JCV is not detected in Okinawa. However, there is some archeological evidence supporting human populations in Okinawa in ancient times. This contradicts the dual structure model. To explain the relationship between the JCV genotype distribution and the ALDH2 variant in Okinawa, the following hypothesis was developed. People who carried MY genotype JCV and wild-type ALDH2 existed in Okinawa. After the extinction of the alleles on the island, people who carried CY genotype JCV and wild-type ALDH2 migrated. By the founder effect, CY genotype JCV and wild-type ALDH2 became dominant. In the long history that followed, many people with the ALDH2 variant migrated to Okinawa, resulting in an increase in the frequency of the allele. Although the alternative genotype of JCV might have been introduced to Okinawa, it was eliminated. In the history of Okinawa, a severe population decline occurred due to a tsunami and severe hunger caused by climate change. It is possible that early human populations were eradicated in Okinawa.
After the migration of the Yayoi people, gradual gene flow between the two populations might have occurred, influencing subsequent changes in the mutation rates of people in different areas in Japan. This is consistent with genomic comparisons among people living in Hokkaido, mainland Japan, and Okinawa1,7,28. However, the JCV genotype in a human population does not change easily26,29, it is ideal for population studies.
Materials and Methods
Materials
After obtaining informed consent, 50-mL urine samples were donated by 212 healthy volunteers who live in cities in Okinawa Island, Japan (Nago, Kita-Nakagusuku, Nakagusuku, Nishihara, Urazoe, Naha, Haebaru, and Tomigusuku). DNA samples extracted from urine were analyzed. The DNA extraction method was described by Kato et al.26. This study was approved by the Institutional Review Board of the Kyoto Prefectural University of Medicine (G-112). All methods were performed in accordance with the relevant guidelines and regulations.
JCV detection and genotype classification
The 610-bp IG region30 that encompasses the 3ā²-terminal regions of both T antigen and VP1 genes was PCR-amplified using the primers P1 and P2 and ExTaq Polymerase (TaKaRa Bio Inc., Kusatsu, Japan), as described by Kunitake et al.25. A total of 108 PCR-positive samples were used for genotype classification.
Amplified IG-region fragments were subjected to a cycle sequencing reaction using a BigDYE Terminator Cycle Sequencing Kit v. 3.1 (Applied Biosystems, Foster City, CA). Primers P1 and P2 were also used for sequencing, which was carried out with an automated DNA sequencer (3130 Genetic Analyzer, Applied Biosystems).
DNA sequences were aligned using the CLUSTALW program31, phylogenetic relationships among DNA sequences were evaluated using the neighborjoining (NJ) method32 via Kimuraās two-parameter distance method33. The phylogenetic tree was visualized using the NJ plot program34. To assess confidence levels within the phylogenetic tree, bootstrap probabilities (BPs) were estimated with 1,000 bootstrap replicates35. And finally, JCV genotype of each strain was confirmed.
ALDH2 genotype classification
A total of 108 JCV-positive samples were analyzed by real-time PCR, and the G-to-A substitution rs671 (i.e., the Glu504Lys or Glu487Lys polymorphism) in ALDH2 was detected and classified. A fluorescence melting curve analysis was performed using a LightCycler (Roche Diagnostics GmbH, Mannheim, Germany) with primers and probes obtained from Takara Bio Inc. (TaKaRa Cycleave Human ALDH2 Typing Probe/Primer Set).
PCR conditions were as follows: 95āĀ°C for 10āsec, followed by 60 cycles of denaturation at 95āĀ°C for 5āsec, annealing at 53āĀ°C for 10āsec, and extension at 72āĀ°C for 20āsec. Fluorescence was measured during this process.
To confirm results of the above-mentioned method, we also analyzed the whole samples using the PCR-CTPP method as described36.
Statistical analysis
The chi-square test for independence with Yatesā correction was utilized to compare the presence of the wild-type allele (i.e., normal ALDH2 activity) in samples with JCV genotype CY collected in mainland Japan and Okinawa. A significant association between ALDH2 genotypes and JCV genotypes was detected when Pā<ā0.05. All analyses were performed using Microsoft Excel.
References
Matsumura, H. Differentials of Yayoi immigration to Japan as derived from dental metrics. Homo. 52, 135ā156 (2001).
Ono, A., Sato, H., Tsutsumi, T. & Kudo, Y. Radiocarbon dates and archaeology of the late Pleistocene in the Japanese Islands. RADIOCARBON. 44(2), 477ā494 (2002).
Hanihara, K. Dual structure model for the population history of Japanese. Anthropological Sci. 2, 1ā33 (1991).
Sokai, R. R. & Horai, S. Spatial genetic structure of human populations in Japan. Human Biology. 70, 1ā22 (1998).
Shimoda, K. Ancient DNA analysis of skeletal samples recovered from the Kuma-Nishioda Yayoi site. Bulletin of National Science Museum Tokyo, Series D 30, 1ā8 (2004).
Hammer, M. F. et al. Dual origins of the Japanese: common ground for hunter-gatherer and farmer Y chromosomes. Hum. Genet. 51, 47ā58 (2006).
Rasteiro, R. & Chikhi, L. Revisiting the peopling of Japan: an admixture perspective. J. Hum. Genet. 54(6), 349ā354 (2009).
Goedde, H. W. et al. Distribution of ADH2 and ALDH2 genotypes in different populations. Hum. Genet. 88, 344ā346 (1992).
Oota, H. et al. The evolution and population genetics of the ALDH2 locus: random genetic drift, selection, and low levels of recombination. Ann. Hum. Genet. 68(2), 93ā109 (2004).
Luo, H. R. et al. Origin and dispersal of atypical aldehyde dehydrogenase ALDH2487Lys. Gene. 435(1-2), 96ā103 (2009).
Li, H. et al. Refined geographic distribution of the oriental ALDH2*504Lys (nee 487Lys) variant. Ann. Hum. Genet. 73(3), 335ā345 (2009).
Yogo, Y. et al. JC virus genotyping offers a new paradigm in the study of human populations. Rev. Med. Virol. 14(3), 179ā191 (2004).
Agostini, H. T., Yanagihara, R., Davis, V., Ryschkewitsch, C. F. & Stoner, G. L. Asian genotypes of JC virus in Native Americans and in a Pacific Island population: markers of viral evolution and human migration. Proc. Natl. Acad. Sci. U S A. 94, 14542ā14546 (1997).
Kitamura, T. et al. Peopling of Japan as revealed by genotyping of urinary JC virus DNA. Anthropological Sci. 106, 311ā325 (1998).
Zheng, H. Y. et al. Phylogenetic relationships among JC virus strains in Japanese/Koreans and Native Americans speaking Amerind or Na-Dene. J. Mol. Evol. 56(1), 18ā27 (2003).
Miyamori, D. et al. Tracing Jomon and Yayoi ancestries in Japan using ALDH2 and JC virus genotype distributions. Investig. Genet. 6, 14 (2015).
Zheng, H. Y. et al. Regional distribution of two related Northeast Asian genotypes of JC virus, CY-a and -b: implications for the dispersal of Northeast Asians. Microbes Infect. 6(6), 596ā603 (2004).
Matsuo, K. et al. Alcohol dehydrogenase 2 His47Arg polymorphism influences drinking habit independently of aldehyde dehydrogenase 2 Glu487Lys polymorphism: analysis of 2,299 Japanese subjects. Cancer Epidemiol. Biomarkers Prev. 15(5), 1009ā1013 (2006).
Santos, B. R., Monteiro, M. G. & Thomasson, H. R. Allele frequency of ADH2 and ALDH2 among Brazilians of different ethnic groups. Alcohol. 14(3), 205ā207 (1997).
Suzuki, Y. et al. Association of aldehyde dehydrogenase with inheritance of NIDDM. Diabetologia. 39(9), 1115ā1118 (1996).
Kuriki, K. et al. Relation of the CD36 gene A52C polymorphism to the risk of colorectal cancer among Japanese, with reference to with the aldehyde dehydrogenase 2 gene Glu487Lys polymorphism and drinking habit. Asian. Pac. J. Cancer Prev. 6(1), 62ā68 (2005).
Yokoyama, A. et al. Esophageal melanosis, an endoscopic finding associated with squamous cell neoplasms of the upper aerodigestive tract, and inactive aldehyde dehydrogenase-2 in alcoholic Japanese men. J. Gastroenterol. 40(7), 676ā684 (2005).
Lin, Y. P. & Cheng, T. J. Why canāt Chinese Han drink alcohol? Hepatitis B virus infection and the evolution of acetaldehyde dehydrogenase deficiency. Med. Hypotheses. 59(2), 204ā207 (2002).
Miyasaka, K. et al. Association of aldehyde dehydrogenase 2 gene polymorphism with pancreatic cancer but not colon cancer. Geriatr. Gerontol. Int. 10, S120ā126 (2010).
Kunitake, T. et al. Parent-to-child transmission is relatively common in the spread of the human polyomavirus JC virus. J. Clin. Microbiol. 33(6), 1448ā1451 (1995).
Kato, A. et al. Lack of evidence for the transmission of JC polyomavirus between human populations. Arch. Virol. 142(5), 875ā882 (1997).
Sugimoto, C. et al. Typing of urinary JC virus DNA offers a novel means of tracing human migrations. Proc. Natl. Acad. Sci. USA. 94(17), 9191ā9196 (1997).
Jinam, T. A., Kanzawa-Kiriyama, H. & Saitou, N. Human genetic diversity in the Japanese Archipelago: dual structure and beyond. Genes Genet. Syst. 90, 147ā152 (2015).
Suzuki, M. et al. Asian genotypes of JC virus in Japanese-Americans suggest familial transmission. J. Virol 76(19), 10074ā10078 (2002).
Ault, G. S. & Stoner, G. L. Two major types of JC virus defined in progressive multifocal leukoencephalopathy brain by early and late coding region DNA sequences. J. Gen. Virol. 73, 2669ā2678 (1992).
Thompson, J. D., Higgins, D. G. & Gibson, T. J. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, positionspecific gap penalties and weight matrix choice. Nucleic Acids Res. 22, 4673ā4680 (1994).
Saitou, N. & Nei, M. The neighbor-joining method: a new method for reconstructing phylogenetic trees. Mol. Biol. Evol. 4, 406ā425 (1987).
Kimura, M. A simple method for estimating evolutionary rates of base substitutions through comparative studies of nucleotide sequences. J. Mol. Evol. 16, 111ā120 (1980).
PerriĆ©re, G. & Gouy, M. WWW-Query: an on-line retrieval system for biological sequence banks. Biochimie. 78, 364ā369 (1996).
Felsenstein, J. Confidence limits on phylogenies: an approach using the bootstrap. Evolution. 39, 783ā791 (1985).
Matsuo, K. et al. Gene-environment interaction between an aldehyde dehydrogenase-2 (ALDH2) polymorphism and alcohol consumption for the risk of esophageal cancer. Carcinogenesis. 22(6), 913ā916 (2001).
Author information
Authors and Affiliations
Contributions
T. Kitamura: sample collection. Y.Tanaka and D.Miyamori, N.Ishikawa: sample analysis and statistical analysis H. Ikegaya: sample analysis, conceptualization, funding acquisition, writing manuscript and supervision
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisherās note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the articleās Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the articleās Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Miyamori, D., Tanaka, Y., Ishikawa, N. et al. Population history in Okinawa based on JC virus and ALDH2 genotypes. Sci Rep 10, 7331 (2020). https://doi.org/10.1038/s41598-020-64194-y
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-020-64194-y
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.