Length mutations in human mitochondrial DNA: direct sequencing of enzymatically amplified DNA

Mitochondrial DNA polymorphism in the Vietnamese population

The mitochondrial DNA variation was screened in a sample of 50 unrelated individuals of the Vietnamese population originating from Hanoi. A combination of long and standard PCR and restriction endonuclease digests with the enzymes HpaI, BamHI, HaeII, MspI, AvaII and HincII were used to reveal mtDNA variation. Twenty enzyme morphs were detected, three of which (HaeII-13Viet, MspI-19Viet and MspI-20Viet) are new and are produced by a single mutational event in already known enzyme morphs. Ten already known and four new mitotypes [93Viet (1-1-2-4-1), 94Viet (2-1-13Viet-1-1), 95Viet (2-1-13Viet-19Viet-1) and 96Viet (1-1-2-20Viet-12)] were found in the Vietnamese population. The 9-bp deletion occurring in the COII/tRNALys region of the mitochondrial genome was also analysed and 10 samples were found to have this deletion. The comparison of the Vietnamese with other East Asian populations showed a close genetic relationship of the population under investigation with other Orientals. However, the Vietnamese population can be differentiated by the significantly higher frequency of the enzyme morph HincII-5 and by seven new markers. These results strongly support the hypothesis of a dual ethnic origin of the Vietnamese population from the Chinese and Thai-Indonesian populations based on HLA markers and linguistic evidence.

Relationship between productive HIV-1 infection of macrophages and CCR5 utilization

HIV-1 isolates exhibit specificity for infection of immortalized T-cell lines and macrophages. The distinct cellular tropisms have been attributed to expression of coreceptors CXCR4 or CCR5, respectively. However, it is unclear whether or not other tissue-specific determinants regulate entry. The current study uses a panel of viruses to analyze the relationship between CCR5 utilization and macrophage infection. Only chimeric viruses with the entire V3 loop from macrophage-tropic isolates, ADA or SF162, were able to infect macrophages. In contrast, chimeric viruses with smaller portions of the ADA V3 loop or the V3 loop of SF2, sufficient to allow CCR5 use, were insufficient for macrophage infection. PCR analysis showed that the defect in macrophage infection of the latter viruses was due to a defect in entry. Moreover, strains capable of infecting macrophages showed relative resistance to neutralization by anti-CCR5 antibody, 2D7, compared to strains which utilize CCR5 but are incapable of macrophage infection.

Mitochondrial DNA variation in human evolution and disease

Analysis of mitochondrial DNA (mtDNA) variation has permitted the reconstruction of the ancient migrations of women. This has provided evidence that our species arose in Africa about 150000 years before present (YBP), migrated out of Africa into Asia about 60000 to 70000 YBP and into Europe about 40000 to 50000 YBP, and migrated from Asia and possibly Europe to the Americas about 20000 to 30000 YBP. Although much of the mtDNA variation that exists in modern populations may be selectively neutral, studies of the mildly deleterious mtDNA mutations causing Leber's hereditary optic neuropathy (LHON) have demonstrated that some continent-specific mtDNA lineages are more prone to manifest the clinical symptoms of LHON than others. Hence, all mtDNA lineages are not equal, which may provide insights into the extreme environments that were encountered by our ancient ancestor, and which may be of great importance in understanding the pathophysiology of mitochondrial disease.

mtDNA history of the Cayapa Amerinds of Ecuador: detection of additional founding lineages for the Native American populations

mtDNA variation in the Cayapa, an Ecuadorian Amerindian tribe belonging to the Chibcha-Paezan linguistic branch, was analyzed by use of hypervariable control regions I and II along with two linked regions undergoing insertion/deletion mutations. Three major maternal lineage clusters fit into the A, B, and C founding groups first described by Schurr and colleagues in 1990, whereas a fourth lineage, apparently unique to the Cayapa, has ambiguous affinity to known clusters. The time of divergence from a common maternal ancestor of the four lineage groups is of sufficient age that it indicates an origin in Asia and supports the hypothesis that the degree of variability carried by the Asian ancestral populations into the New World was rather high. Spatial autocorrelation analysis points out (a) statistically significant nonrandom distributions of the founding lineages in the Americas, because of north-south population movements that have occurred since the first Asian migrants spread through Beringia into the Americas, and (b) an unusual pattern associated with the D lineage cluster. The values of haplotype and nucleotide diversity that are displayed by the Cayapa appear to differ from those observed in other Chibchan populations but match those calculated for South American groups belonging to various linguistic stocks. These data, together with the results of phylogenetic analysis performed with the Amerinds of Central and South America, highlight the difficulty in the identification of clear coevolutionary patterns between linguistic and genetic relationships in particular human populations.

Multiple origins of the mtDNA 9-bp deletion in populations of South India

The origins and genetic affinities of the more than 500 tribal populations living in South Asia are widely disputed. This may reflect differential contributions that continental populations have made to tribal groups in South Asia. We assayed for the presence of the intergenic COII/tRNALys 9-bp deletion in human mtDNA in 646 individuals from 12 caste and 14 tribal populations of South India and compared them to individuals from Africa, Europe, and Asia. The 9-bp deletion is observed in four South Indian tribal populations, the Irula, Yanadi, Siddi, and Maria Gond, and in the Nicobarese. Length polymorphisms of the 9-bp motif are present in the Santal, Khonda Dora, and Jalari, all of whom live in a circumscribed region on the eastern Indian coast. Phylogenetic analyses of mtDNA control region sequence from individuals with the 9-bp deletion indicate that it has arisen independently in some Indian tribal populations. Other 9-bp deletion haplotypes are likely to be of Asian and African origin, implying multiple origins of the 9-bp deletion in South India. These results demonstrate varying genetic affinities of different South Indian tribes to continental populations and underscore the complex histories of the tribal populations living in South Asia.

Inherited susceptibility to aminoglycoside ototoxicity: genetic heterogeneity and clinical implications

PURPOSE

Aminoglycoside-induced ototoxicity appears to have a genetic susceptibility in some individuals, and the A1555G mutation in the mitochondrial 12S ribosomal RNA gene has been shown to be responsible for this susceptibility in all familial cases. An Italian family with 5 family members who became deaf after aminoglycoside exposure presented to us, and molecular analysis excluded the A1555G mutation. The purpose of this study is to identify the molecular basis for the aminoglycoside susceptibility in this family.

PATIENTS AND METHODS

Two sisters and three of their children developed severe to profound high-frequency hearing loss after aminoglycoside exposure. DNA was extracted from the blood of these individuals and their unaffected relatives, and analyzed for mitochondrial DNA mutations. The region around nucleotide 961 was also cloned and individual clones were sequenced.

RESULTS

Sequencing of the 12S ribosomal RNA gene revealed a thymidine deletion at position 961, with a complex pattern of sequence around this mutation. Sequencing of individual clones around the 961 mutation demonstrated a varying number of inserted cytosines in different mitochondrial molecules.

CONCLUSION

This family establishes the nucleotide 961 thymidine deletion associated with a varying number of inserted cytosines in the mitochondrial 12S ribosomal RNA gene as the second pathogenic mutation that can predispose to aminoglycoside ototoxicity. It demonstrates the clinical relevance of taking a family history before administering aminoglycosides to any patient. In addition, it would be desirable for sporadic patients with aminoglycoside-induced hearing loss to be screened with molecular tests for the presence of the 1555 and 961 mutations. Such screening could significantly decrease the prevalence of aminoglycoside-induced hearing loss.

Evidence for mitochondrial DNA recombination in a human population of island Melanesia

Mitochondrial DNA (mtDNA) analysis has proved useful in studies of recent human evolution and the genetic affinities of human groups of different geographical regions. As part of an extensive survey of mtDNA diversity in present-day Pacific populations, we obtained sequence information of the hypervariable mtDNA control region of 452 individuals from various localities in the western Pacific. The mtDNA types fell into three major groups which reflect the settlement history of the area. Interestingly, we detected an extremely rare point mutation at high frequency in the small island of Nguna in the Melanesian archipelago of Vanuatu. Phylogenetic analysis of the mtDNA data indicated that the mutation was present in individuals of separate mtDNA lineages. We propose that the multiple occurrence of a rare mutation event in one isolated locality is highly improbable, and that recombination between different mtDNA types is a more likely explanation for our observation. If correct, this conclusion has important implications for the use of mtDNA in phylogenetic and evolutionary studies.

Molecular genetic evidence for the human settlement of the Pacific: analysis of mitochondrial DNA, Y chromosome and HLA markers

Present-day Pacific islanders are thought to be the descendants of Neolithic agriculturalists who expanded from island South-east Asia several thousand years ago. They speak languages belonging to the Austronesian language family, spoken today in an area spanning half of the circumference of the world, from Madagascar to Easter Island, and from Taiwan to New Zealand. To investigate the genetic affinities of the Austronesian-speaking peoples, we analysed mitochondrial DNA, HLA and Y-chromosome polymorphisms in individuals from eight geographical locations in Asia and the Pacific (China, Taiwan, Java, New Guinea highlands, New Guinea coast, Trobriand Islands, New Britain and Western Samoa). Our results show that the demographic expansion of the Austronesians has left a genetic footprint. However, there is no simple correlation between languages and genes in the Pacific.

HvrBase: compilation of mtDNA control region sequences from primates

HvrBase is a compilation of human and ape mtDNA control region sequences. Sequences and related information on individuals, such as from where the sequences were obtained, is stored in three ASCII files as described previously. Moreover, the collection is also available as Mac/PC database application with a graphical user interface. It can be accessed through the WWW at URL http://www.eva.mpg.de/hvrbase. The current collection comprises 5846 human sequences from hypervariable region I (HVRI) and 2302 human sequences from hypervariable region II (HVRII). From apes, 295 HVRI sequences and 13 HVRII sequences are available.

SCID mice containing muscle with human mitochondrial DNA mutations. An animal model for mitochondrial DNA defects

Defects of the mitochondrial genome are important causes of disease. Despite major advances in our investigation of patients, there is no effective therapy. Progress in this area is limited by the absence of any animal models in which we can evaluate treatment. To develop such a model we have injected human myoblasts into the tibialis anterior of SCID mice after inducing necrosis. After injection of normal human myoblasts, regenerating fibers expressed human beta-spectrin, confirming they were derived from fusion of human myoblasts. The stability of the muscle fibers was inferred by demonstrating the formation of motor end plates on the regenerating fibers. In addition, we show the presence of human cytochrome c oxidase subunit II, which is encoded by the mitochondrial genome, in the regenerated fibers. After injection of human myoblasts containing either the A8344G or the T8993C heteroplasmic mitochondrial DNA mutations, human beta-spectrin positive fibers were found to contain the mutation at a similar level to the injected myoblasts. These studies highlight the potential value of this model for the study of mitochondrial DNA defects.

Genetic evidence for the proto-Austronesian homeland in Asia: mtDNA and nuclear DNA variation in Taiwanese aboriginal tribes

Previous studies of mtDNA variation in indigenous Taiwanese populations have suggested that they held an ancestral position in the spread of mtDNAs throughout Southeast Asia and Oceania (Melton et al. 1995; Sykes et al. 1995), but the question of an absolute proto-Austronesian homeland remains. To search for Asian roots for indigenous Taiwanese populations, 28 mtDNAs representative of variation in four tribal groups (Ami, Atayal, Bunun, and Paiwan) were sequenced and were compared with each other and with mtDNAs from 25 other populations from Asia and Oceania. In addition, eight polymorphic Alu insertion loci were analyzed, to determine if the pattern of mtDNA variation is concordant with nuclear DNA variation. Tribal groups shared considerable mtDNA sequence identity (P>.90), where gene flow is believed to have been low, arguing for a common source or sources for the tribes. mtDNAs with a 9-bp deletion have considerable mainland-Asian diversity and have spread to Southeast Asia and Oceania through a Taiwanese bottleneck. Only four Taiwanese mtDNA haplotypes without the 9-bp deletion were shared with any other populations, but these shared types were widely dispersed geographically throughout mainland Asia. Phylogenetic and principal-component analyses of Alu loci were concordant with conclusions from the mtDNA analyses; overall, the results suggest that the Taiwanese have temporally deep roots, probably in central or south China, and have been isolated from other Asian populations in recent history.

Testing migration patterns and estimating founding population size in Polynesia by using human mtDNA sequences

The hypervariable 1 region of human mtDNA shows markedly reduced variability in Polynesians, and this variability decreases from western to eastern Polynesia. Fifty-four sequences from New Zealand Maori show that the mitochondrial variability with just four haplotypes is the lowest of any sizeable human group studied and that the frequency of haplotypes is markedly skewed. The Maori sequences, combined with 268 published sequences from the Pacific, are consistent with a series of founder effects from small populations settling new island groups. The distributions of haplotypes were used to estimate the number of females in founding population of New Zealand Maori. The three-step simulation used a randomly selected founding population from eastern Polynesia, an expansionary phase in New Zealand, and finally the random selection of 54 haplotypes. The results are consistent with a founding population that includes approximately 70 women (between 50 and 100), and sensitivity analysis shows that this conclusion is robust to small changes in haplotype frequencies. This size is too large for models postulating a very small founding population of "castaways," but it is consistent with a general understanding of Maori oral history as well as the results of recent canoe voyages recreating early trans-oceanic voyages.

Molecular instability in the COII-tRNA(Lys) intergenic region of the human mitochondrial genome: multiple origins of the 9-bp deletion and heteroplasmy for expanded repeats

We have identified two individuals from Glasgow in Scotland who have a deletion of one of two copies of the intergenic 9-bp sequence motif CCCCCTCTA, located between the cytochrome oxidase II (COII) and lysine tRNA (tRNA(Lys)) genes of the human mitochondrial genome. Although this polymorphism is common in Africa and Asia, it has not been reported in Northern Europe. Analysis of the mitochondrial DNA control region sequences of these two individuals suggests that they belong to a lineage that originated independently of the previously characterized African and Asian 9-bp deleted lineages. Among the Scottish population we have also identified a maternal lineage of three generations exhibiting heteroplasmy for two, three and four copies of the CCCCCTCTA motif. Polymerase chain reaction amplification across the COII-tRNA(Lys) intergenic region of these individuals gives different ratios of the three product lengths that are dependent on the concentration of the DNA-binding dye crystal violet. To investigate whether changes in repeat number were generated de novo, we constructed clones containing known numbers of the CCCCCTCTA motif. In the presence of high concentrations of crystal violet we obtained two, three and four copies of this motif when the amplification template contained only four copies. Various DNA-binding drugs are known to stabilize bulged structures in DNA and contribute to the process of slipped-strand mispairing during DNA replication. These results suggest that the COII-tRNA(Lys) intergenic region is unstable owing to slipped-strand mispairing. Although sequences containing four copies of the CCCCCTCTA motif are less stable in vitro, we observed an increase in the proportion of mitochondrial genomes with four repeats between-a mother and a daughter in the heteroplasmic lineage. From this we conclude that drift in the germ-line lineage is a main factor in the maintenance or loss of heteroplasmy.

mtDNA analysis of a prehistoric Oneota population: implications for the peopling of the New World

mtDNA was successfully extracted from 108 individuals from the Norris Farms Oneota, a prehistoric Native American population, to compare the mtDNA diversity from a pre-Columbian population with contemporary Native American and Asian mtDNA lineages and to examine hypotheses about the peopling of the New World. Haplogroup and hypervariable region I sequence data indicate that the lineages from haplogroups A, B, C, and D are the most common among Native Americans but that they were not the only lineages brought into the New World from Asia. The mtDNA evidence does not support the three-wave hypothesis of migration into the New World but rather suggests a single "wave" of people with considerable mtDNA diversity that exhibits a signature of expansion 23,000-37,000 years ago.

mtDNA and language support a common origin of Micronesians and Polynesians in Island Southeast Asia

The origins and relationships among Micronesians, Polynesians, and Melanesians were investigated. Five different mtDNA region V length polymorphisms from 873 individuals representing 24 Oceanic and Asian populations were analyzed. The frequency cline of a common deletion and the distributions of a rare expanded length polymorphism support the origin of both Micronesians and Polynesians in Island Southeast Asia. Genetic, linguistic, and geographic distances were compared to assess the relative importance of isolation and gene flow during the prehistory of 19 Austronesian-speaking populations subdivided into five potential spheres of interaction. We observed significant correlations (P < 0.05) between genetic and linguistic distances in four of five comparisons. These data indicate extensive gene flow throughout much of Micronesia, but substantial isolation in other Pacific regions. Although recent advancements in our understanding of intentional voyaging within Remote Oceania have challenged the existence of the "myth of the primitive isolate," we caution against the adoption of panmictic alternatives.

Mitochondrial control-region sequence variation in aboriginal Australians

The mitochondrial D-loop hypervariable segment 1 (mt HVS1) between nucleotides 15997 and 16377 has been examined in aboriginal Australian people from the Darling River region of New South Wales (riverine) and from Yuendumu in central Australia (desert). Forty-seven unique HVS1 types were identified, varying at 49 nucleotide positions. Pairwise analysis by calculation of BEPPI (between population proportion index) reveals statistically significant structure in the populations, although some identical HVS1 types are seen in the two contrasting regions. mt HVS1 types may reflect more-ancient distributions than do linguistic diversity and other culturally distinguishing attributes. Comparison with sequences from five published global studies reveals that these Australians demonstrate greatest divergence from some Africans, least from Papua New Guinea highlanders, and only slightly more from some Pacific groups (Indonesian, Asian, Samoan, and coastal Papua New Guinea), although the HVS1 types vary at different nucleotide sites. Construction of a median network, displaying three main groups, suggests that several hypervariable nucleotide sites within the HVS1 are likely to have undergone mutation independently, making phylogenetic comparison with global samples by conventional methods difficult. Specific nucleotide-site variants are major separators in median networks constructed from Australian HVS1 types alone and for one global selection. The distribution of these, requiring extended study, suggests that they may be signatures of different groups of prehistoric colonizers into Australia, for which the time of colonization remains elusive.

Compilation of human mtDNA control region sequences

This paper describes the organisation of a database for human mitochondrial control-region sequences. The data are divided into three ASCII files that contain aligned sequences from the hypervariable region I (HVRI), from the hypervariable region II (HVRII), and the available information about the individuals, from whom the sequences stem. The current collection comprises 4079 HVRI and 969 HVRII sequences. From 728 individuals sequences of both HVRI and HVRII are available. For easy access, the collection is made available to the scientific community via World Wide Web at URL http://www.zi.biologie.uni-muenchen.de/[symbol: see text]meyers/mtdna.html

Mitochondrial D-loop 3' (CA)n repeat polymorphism: optimization of analysis and population data

We report a dinucleotide repeat polymorphism in the 3' area of the mitochondrial control region. The fragments obtained using a new primer set could be reliably separated by polyacrylamide gel electrophoresis (PAGE) using nondenaturing gels. A total of five alleles [(CA)3 to (CA)7] were detected on silver-stained gels. The 90 bp product corresponds to allele 5. Samples from one African and three European populations were characterized. Significant differences could be demonstrated as to the incidence of single alleles and allele distributions in different populations. These differences were found between the three European and one African Bantu population. For specific forensic questions the mitochondrial CA repeat is well suited. Gene diversities in populations of Germany, Hungary, the Russian Federation and Cameroon were 0.36, 0.40, 0.34, 0.52, respectively.

Mitochondrial DNA polymorphisms in Carib people of Belize

Analysis of mitochondrial DNA (mtDNA) control region polymorphisms in 28 Carib people of Belize, former British Honduras, revealed high levels of genetic admixture with West African populations. A previously characterized length mutation consisting of a deletion of nine base pairs in an intergenic mtDNA region was observed in two of the individuals. Phylogenetic analysis of mtDNA control region sequences associated with the mutation suggested that it arose independently in different geographical locations. Whereas in one individual the deletion reflects the Amerindian ancestry of the Caribs, in the second case it seems to be of African origin, as it occurred in conjunction with an mtDNA type found in sub-Saharan Africa. Our results agree with historical accounts on the origins of the Caribs of Belize.

Ancient and modern mitochondrial DNA sequences and the colonization of the Pacific

Mitochondrial DNA (mtDNA) is a valuable tool for the study of recent human evolution because it is easy to analyse, is inherited uniparentally and has a relatively rapid rate of evolution. mtDNA analysis has been used extensively for the elucidation of the pattern of migrations of human populations. Several studies have focused on the Pacific because Polynesia was settled by humans for the first time relatively recently and there is a wealth of archaeological and linguistic data to complement genetic data on the region. Results of mtDNA analyses on modern-day Pacific populations indicate reduced genetic variability, and suggest that the Polynesians descend from people who migrated relatively recently from island Southeast Asia and that a population bottleneck occurred during the settlement of the central Pacific. Several informative polymorphisms have been identified in the hypervariable control region of mtDNA in modern-day Pacific populations that are helpful in tracing the ancestral affinities of these people. Studies of these mtDNA polymorphisms in ancient bones of prehistoric Pacific islanders indicate that the proto-Polynesian colonizers may have descended from the early settlers of island Melanesia. Although fraught with technical difficulties, studies of ancient DNA can provide valuable evidence on the genetic affinities of past peoples.

Development of a direct DNA sequencing method for detecting heterozygous mutations of the human lipoprotein lipase gene

OBJECTIVE

The purpose of this study was to develop an improved method of direct DNA sequencing, which makes it possible to identify heterozygous mutations of the lipoprotein lipase (LPL) gene in order to understand the underlying genetic disorder of type IV hyperlipoproteinemia.

METHODS AND RESULTS

The direct sequencing method was improved by devising primers for amplifying the LPL gene and for sequencing DNA amplified by the polymerase chain reaction (PCR)T since the reported base sequences of the introns flanking exons of the LPL gene were limited to 40 bases. Improvement was achieved by attaching nine additional bases to both the PCR amplification primer and sequencing primer, and by optimizing the Tm value of the sequencing primers by adjusting the sequence of the nine extra bases. Use of the sequencing primers having suitable Tm values (48 degrees C-58 degrees C) made it possible to reduce nonspecific bands on the sequence ladder pattern and to identify heterozygous mutation sites in LPL gene exons 5 and 6 as model cases.

CONCLUSION

Our improved direct sequencing method is useful for identifying heterozygous mutation sites in human LPL gene exons and splicing consensus regions.

Human evolution and the mitochondrial genome

The use of mitochondrial DNA (mtDNA) continues to dominate studies of human genetic variation and evolution. Recent work has re-affirmed the strict maternal inheritance of mtDNA, yielded new insights into the extent and nature of intra-individual variation, supported a recent African origin of human mtDNA, and amply demonstrated the utility of mtDNA in tracing population history and in analyses of ancient remains.

Thermal cycle dideoxy DNA sequencing

Thermal cycle dideoxy DNA sequencing eliminates the requirements for independent primer annealing and double-stranded DNA denaturation steps. The method enables sequencing from nanogram amounts of DNA from double-stranded and single-stranded PCR products, and plasmid or phage DNA templates. Thermal cycle sequencing also enables direct sequencing from bacterial colonies or phage plaques. Protocols using the Vent exo- DNA polymerase, helpful suggestions, and a troubleshooting guide are also presented.

A quick, direct method that can differentiate expressed mitochondrial genes from their nuclear pseudogenes

Direct sequencing of mitochondrial DNA (mtDNA) following amplification using the polymerase chain reaction (PCR) has found widespread use in population genetic and phylogenetic research over the past few years. Recently, nuclear copies of mitochondrial genes have been reported in diverse eukaryotic species, often confounding such research (reviewed in [2,3]). Under certain circumstances, nuclear pseudogenes can be amplified more efficiently than the intended mtDNA target, even when using as template mtDNA that has been purified by gradient centrifugation. If the transfer of the gene copy to the nucleus happened recently, it can be difficult-if not impossible-to identify the legitimate mitochondrial sequence. Here, we present a simple method that can identify expressed mitochondrial genes, using the cytochrome b gene of the particularly problematical proboscis monkey as an example. Because mtDNA is transcribed and processed into polyadenylated mRNAs reverse transcription coupled to PCR can be used to amplify the expressed mitochondrial version. This method produced an unambiguous sequence for the proboscis monkey mitochondrial cytochrome b gene; in contrast, traditional DNA-based PCR methods produced ambiguous sequence, because many nuclear pseudogenes were present. Phylogenetic analysis of the cytochrome b gene suggests that the proboscis monkey groups with the Asian langurs, rather than forming a sister taxon to all Asian and African colobines as was previously suggested. Reverse transcriptase-coupled PCR should be applicable to many other cases of nuclear transfer of mtDNA, including those involving ribosomal genes.

Phylogenetic analysis of mtDNA lineages in South American mummies

Some studies of mtDNA propose that contemporary Amerindians have descended from four haplotype groups, each defined by specific sets of polymorphisms. One recent study also found evidence of other potential founder haplotypes. We wanted to determine whether the four haplotypes in modern populations were also present in ancient South American aboriginals. We subjected mtDNA from Colombian mummies (470 to 1849 AD) to PCR amplification and restriction endonuclease analysis. The mtDNA D-loop region was surveyed for sequence variation by restriction analysis and a segment of this region was sequenced for each mummy to characterize the haplotypes. Our mummies exhibited three of the four major characteristic haplotypes of Amerindian populations defined by four markers. With sequence data obtained in the ancient samples and published data on contemporary Amerindians it was possible to infer the origin of these six mummies.

Multiple founder haplotypes of mitochondrial DNA in Amerindians revealed by RFLP and sequencing

The mitochondrial DNA (mtDNA) of 139 individuals from eight tribes which belong to four linguistic groups of the Brazilian Amazon Region was studied both by RFLP and by sequencing of the D-loop region. RFLP analysis showed that 41 haplotypes (29%) belonged to haplogroup A, 39 (28%) to haplogroup B, 38 (27%) to haplogroup C, 19 (14%) to haplogroup D, and 2 (< 2%) could not be assigned to any of the four haplogroups. Among the 92 individuals analyzed by direct sequencing of the D-loop region, we observed 43 different haplotypes defined by 48 polymorphic points, while one haplotype could not be assigned to any of the clusters previously described. Joint analysis of data obtained by RFLP and by sequencing of mtDNA demonstrated that, regardless of the method of analysis, the mtDNA haplotypes of contemporary Amerindians cluster into four groups, similar to those previously described, even though 7% of the total sample or 12% of the haplotypes have discrepancies between results obtained by RFLP and sequencing. In addition to supporting the prevalence of four major haplogroups among contemporary Amerindians, our data are compatible with multiple founder haplotypes in each haplogroup, based on: i) a high prevalence of unusual haplotypes: ii) presence of multiple polymorphic sites shared by different haplogroups; iii) relative differences in nucleotide diversity based on RFLP or sequencing within the different haplogroups.

The genetic relationship between the Finns and the Finnish Saami (Lapps): analysis of nuclear DNA and mtDNA

The genetic relationships between two Finno-Ugric-speaking populations, the Finns and the Finnish Saami (Lapps), were studied by using PCR for six nuclear-DNA marker loci, mitochondrial restriction-site polymorphism, and sequence variation of a 360-bp segment of the mitochondrial control region. The allele frequencies of each of the nuclear-DNA marker loci and the frequencies of mtDNA restriction haplotypes were significantly different between the populations. The Saami showed exceptionally low variation in their mtDNA restriction sites. The 9-bp deletion common in East Asian populations was not observed, nor did the haplotype data fit into the haplogroup categorization of Torroni et al. The average number of nucleotide substitutions from the mtDNA haplotype data indicated that the Finnish Saami may be closer to the Finns than to the other reference populations, whereas nuclear DNA suggested that the Finns are more closely related to the European reference populations than to the Finnish Saami. The similarity of the Finns to the other Europeans was even more pronounced according to the sequence data. We were unable to distinguish between the Finns and either the Swiss or Sardinian reference populations, whereas the Finnish Saami clearly stood apart. The Finnish Saami are distinct from other Circumarctic populations, although two of the lineages found among the Saami showed closer relationship to the Circumarctic than to the European lineages. The sequence data indicated an exceptionally high divergence for the Saami mtDNA control lineages. The distribution of the pairwise nucleotide differences in the Saami suggested that this population has not experienced an expansion similar to what was indicated for the Finns and the reference populations.

Mutations in mitochondrial transfer ribonucleic acid genes in preeclampsia

OBJECTIVE

We investigated whether maternally inherited mitochondrial deoxyribonucleic acid mutations could be associated with preeclampsia because mendelian models fail to explain all the aspects of inheritance in preeclampsia.

STUDY DESIGN

In two families with a high occurrence of preeclampsia and eclampsia the 22 mitochondrial transfer ribonucleic acid genes were sequenced in eight and three women, respectively.

RESULTS

An A-to-G mutation in transfer ribonucleic acidleu[UUR] at nucleotide 3243 was found in one family, and in the other there was an A-to-G mutation at nucleotide 12308 in transfer ribonucleic acidleu[CUN]. Mutations of mitochondrial transfer ribonucleic acid genes are generally considered to have systemic consequences, which might explain the multiorgan involvement seen in preeclampsia.

CONCLUSION

We report for the first time mutations in mitochondrial transfer ribonucleic acid genes in two families with a high occurrence of preeclampsia and eclampsia. Mitochondrial dysfunction caused by point mutations of mitochondrial deoxyribonucleic acid is maternally inherited, but in the case of mutations of nuclear genes mitochondrial dysfunction can be inherited as an autosomal recessive or dominant trait.

Sequencing of double-stranded PCR products

Very often the experimental step following PCR is sequencing of the amplified fragment. Two protocols that allow direct sequencing of a double-stranded PCR product are described. The first involves removal of one strand of the PCR product using an M13 single-stranded DNA clone, allowing the second strand to be sequenced. The second protocol involves Maxam-Gilbert chemical sequencing after PCR amplification with one labeled primer. The advantages and disadvantages of the two protocols are compared, but both yield DNA sequence without cloning of the PCR product.

Ancient DNA analysis of Fremont Amerindians of the Great Salt Lake Wetlands

Skeletal remains of 47 individuals from the Great Salt Lake Wetlands, affiliated principally with Bear River (A.D. 400-1000) and Levee Phase (A.D. 1000-1350) Fremont cultural elements, were assessed for four mitochondrial DNA (mtDNA) markers that, in particular association, define four haplogroups (A, B, C, and D) widely shared among contemporary Amerindian groups. The most striking result is the absence of haplogroup A in this Fremont series, despite its predominance in contemporary Amerindian groups. Additionally, haplogroup B, defined by the presence of a 9bp deletion in region V, is present at the moderately high frequency of 60%. Haplogroups C and D are present at low frequencies. An additional haplotype, "N," observed in some modern populations and two other prehistoric samples, is also present in this Fremont skeletal collection.

mtDNA control-region sequence variation suggests multiple independent origins of an "Asian-specific" 9-bp deletion in sub-Saharan Africans

The intergenic COII/tRNA(Lys) 9-bp deletion in human mtDNA, which is found at varying frequencies in Asia, Southeast Asia, Polynesia, and the New World, was also found in 81 of 919 sub-Saharan Africans. Using mtDNA control-region sequence data from a subset of 41 individuals with the deletion, we identified 22 unique mtDNA types associated with the deletion in Africa. A comparison of the unique mtDNA types from sub-Saharan Africans and Asians with the 9-bp deletion revealed that sub-Saharan Africans and Asians have sequence profiles that differ in the locations and frequencies of variant sites. Both phylogenetic and mismatch-distribution analysis suggest that 9-bp deletion arose independently in sub-Saharan Africa and Asia and that the deletion has arisen more than once in Africa. Within Africa, the deletion was not found among Khoisan peoples and was rare to absent in western and southwestern African populations, but it did occur in Pygmy and Negroid populations from central Africa and in Malawi and southern African Bantu-speakers. The distribution of the 9-bp deletion in Africa suggests that the deletion could have arisen in central Africa and was then introduced to southern Africa via the recent "Bantu expansion."

The origins of the Polynesians: an interpretation from mitochondrial lineage analysis

Using mitochondrial lineage analysis of 1,178 individuals from Polynesia, the western Pacific, and Taiwan, we show that the major prehistoric settlement of Polynesia was from the west and involved two or possibly three genetically distinct populations. The predominant lineage group, accounting for 94% of Polynesian mtDNA, shares a 9-bp COII/tRNA(Lys) intergenic deletion and characteristic control region transition variants, compared to the Cambridge reference sequence. In Polynesia, the diversity of this group is extremely restricted, while related lineages in Indonesia, the Philippines, and Taiwan are increasingly diverse. This suggests a relatively recent major eastward expansion into Polynesia, perhaps originating from Taiwan, in agreement with archeological and linguistic evidence, but which experienced one or more severe population bottlenecks. The second mitochondrial lineage group, accounting for 3.5% of Polynesian mtDNA haplotypes, does not have the 9-bp deletion and its characterized by an A-C transversional variant at nt position 16265. Specific oligonucleotides for this variant were used to select individuals from the population sample who, with other sequences, show that the Polynesian lineages were part of a diverse group in Vanuatu and Papua New Guinea. The very low overall diversity of both lineage groups in Polynesia suggests there was severe population restriction during the colonization of remote Oceania. A third group, represented by only four individuals (0.6%) in Polynesia but also present in the Philippines, shares variants at nt positions 16172 and 16304. Two Polynesians had unrelated haplotypes matching published sequences from native South Americans, which may be the first genetic evidence of prehistoric human contact between Polynesia and South America.

Insertions and duplications of mtDNA in the nuclear genomes of Old World monkeys and hominoids

Using oligonucleotide primers designed to match conserved regions of mammalian mitochondrial DNA (mtDNA), we have amplified and sequenced two divergent cytochrome b nuclear pseudogenes from orangutan cellular DNA. Evolutionary analysis suggests that a nuclear transfer occurred about 30 million years ago on the lineage leading to the catarrhines (Old World monkeys and hominoids), and involved a long (at least 3 kilobases), probably damaged, piece of mtDNA. After this transfer, the pseudogene duplicated, giving rise to the two copies that are probably present in all hominoids, including humans. More recent transfers involving the entire cytochrome b gene have also occurred in the Old World monkeys. Such nuclear copies of mtDNA can confound phylogenetic and population genetic studies, and be an insidious source of DNA contamination of 'ancient' and forensic DNA. Indeed, contamination with these anciently transferred human pseudogenes is almost certainly the source of the cytochrome b sequences recently reported from 'dinosaur bone DNA'.

Sequence analysis of mitochondrial DNA in a new maternally inherited encephalomyopathy

A heteroplasmic insertion of a 9-bp tandem repeat element was detected in the mitochondrial DNA of the maternal members of a large family. The mutation was contained within the non-coding region between the genes specifying subunit II of cytochrome c oxidase and tR-NA(Lys). The proband and most of his maternal relatives were affected by a late-onset mitochondrial encephalomyopathy of variable severity, characterized by a unique combination of symptoms. Extensive screening of a large series of DNA samples, collected from unrelated normal individuals as well as patients affected by different neurological disorders, consistently failed to detect the 9-bp insertion, with two exceptions: a patient suffering from a syndrome virtually identical to that described in our original family and a child affected by bilateral striatal necrosis, a disorder which has been attributed to impairment of mitochondrial oxidative phosphorylation. These considerations suggest that the 9-bp insertion is pathogenic and that the region affected by the mutation may play a previously unsuspected functional role in mtDNA gene expression.

The 9-bp deletion in region V of mitochondrial DNA: evidence of mutation recurrence

A deletion of one of the two copies of a 9-bp direct repeat sequence (CCCCCTCTA) in region V of mitochondrial DNA has previously been used as a polymorphic anthropological marker for people of east Asian origin, and to a lesser extent, in Oceanian and African populations. We report the presence of the 9-bp deletion in homoplasmy in skeletal muscle fibers and lymphocytes of a Spanish Caucasian individual. Other mitochondrial DNA polymorphisms associated with the 9-bp deletion characteristic of other populations were not present. Our results suggest that the 9-bp deletion probably originated independently in the maternal lineage of the propositus, and that it can thus be described as a recurrent mutation.

Polynesian genetic affinities with Southeast Asian populations as identified by mtDNA analysis

Polynesian genetic affinities to populations of Asia were studied using mtDNA markers. A total of 1,037 individuals from 12 populations were screened for a 9-bp deletion in the intergenic region between the COII and tRNA(Lys) genes that approaches fixation in Polynesians. Sequence-specific oligonucleotide probes that identify specific mtDNA control region nucleotide substitutions were used to describe variation in individuals with the 9-bp deletion. The 9-bp deletion was not observed in northern Indians, Bangladeshis, or Pakistanis but was seen at low to moderate frequencies in the nine other Southeast Asian populations. Three substitutions in the control region at positions 16217, 16247, and 16261 have previously been observed at high frequency in Polynesian mtDNAs; this "Polynesian motif" was observed in 20% of east Indonesians with the 9-bp deletion but was observed in only one additional individual. mtDNA types related to the Polynesian motif are highest in frequency in the corridor from Taiwan south through the Philippines and east Indonesia, and the highest diversity for these types is in Taiwan. These results are consistent with linguistic evidence of a Taiwanese origin for the proto-Polynesian expansion, which spread throughout Oceania by way of Indonesia.

Analysis of mtDNA variation in African populations reveals the most ancient of all human continent-specific haplogroups

mtDNA sequence variation was examined in 140 Africans, including Pygmies from Zaire and Central African Republic (C.A.R.) and Mandenkalu, Wolof, and Pular from Senegal. More than 76% of the African mtDNAs (100% of the Pygmies and 67.3% of the Senegalese) formed one major mtDNA cluster (haplogroup L) defined by an African-specific HpaI site gain at nucleotide pair (np) 3592. Additional mutations subdivided haplogroup L into two subhaplogroups, each encompassing both Pygmy and Senegalese mtDNAs. A novel 12-bp homoplasmic insertion in the intergenic region between tRNA(Tyr) and cytochrome oxidase I (COI) genes was also observed in 17.6% of the Pygmies from C.A.R. This insertion is one of the largest observed in human mtDNAs. Another 25% of the Pygmy mtDNAs harbored a 9-bp deletion between the cytochrome oxidase II (COII) and tRNA(Lys) genes, a length polymorphism previously reported in non-African populations. In addition to haplogroup L, other haplogroups were observed in the Senegalese. These haplogroups were more similar to those observed in Europeans and Asians than to haplogroup L mtDNAs, suggesting that the African mtDNAs without the HpaI np 3592 site could be the ancestral types from which European and Asian mtDNAs were derived. Comparison of the intrapopulation sequence divergence in African and non-African populations confirms that African populations exhibit the largest extent of mtDNA variation, a result that further supports the hypothesis that Africans represent the most ancient human group and that all modern humans have a common and recent African origin. The age of the total African variation was estimated to be 101,000-133,000 years before present (YBP), while the age of haplogroup L was estimated at 98,000-130,000 YBP. These values substantially exceed the ages of all Asian- and European-specific mtDNA haplogroups.