The Role of Selection in the Evolution of Human Mitochondrial Genomes

doi:10.1534/genetics.105.043901

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The Role of Selection in the Evolution of Human Mitochondrial Genomes

Toomas Kivisild^*^,2^,1, Peidong Shen^,2, Dennis P. Wall^,3, Bao Do, Raphael Sung, Karen Davis, Giuseppe Passarino, Peter A. Underhill^*, Curt Scharfe, Antonio Torroni^**, Rosaria Scozzari, David Modiano, Alfredo Coppa, Peter de Knijff^***, Marcus Feldman, Luca L. Cavalli-Sforza^* and Peter J. Oefner^,2^,4

^* Department of Genetics, Stanford University School of Medicine, Stanford, California 94305, Stanford Genome Technology Center, Palo Alto, California 94304, Department of Biological Sciences, Stanford University, Stanford, California 94305, Dipartimento di Biologia Cellulare, Università della Calabria, 87036 Rende, Italy, ^** Dipartimento di Genetica e Microbiologia, Università di Pavia, 27100 Pavia, Italy, Dipartimento di Genetica e Biologia Molecolare, Università "La Sapienza," 00185 Rome, Italy, Dipartimento di Scienze di Sanità Pubblica, Sezione di Parassitologia, Università "La Sapienza," 00185 Rome, Italy, Dipartimento di Biologia Animale e dell'Uomo, Università "La Sapienza," 00185 Rome, Italy and ^*** Department of Human and Clinical Genetics, Leiden University Medical Center, 2333 AL Leiden, The Netherlands

^¹ Corresponding author: Department of Evolutionary Biology, Tartu University and Estonian Biocenter, Riia 23, Tartu 51010, Estonia.
E-mail: tkivisil{at}ebc.ee

Manuscript received March 30, 2005. Accepted for publication September 5, 2005.

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

High mutation rate in mammalian mitochondrial DNA generatesa highly divergent pool of alleles even within species thathave dispersed and expanded in size recently. Phylogenetic analysisof 277 human mitochondrial genomes revealed a significant (P< 0.01) excess of rRNA and nonsynonymous base substitutionsamong hotspots of recurrent mutation. Most hotspots involvedtransitions from guanine to adenine that, with thymine-to-cytosinetransitions, illustrate the asymmetric bias in codon usage atsynonymous sites on the heavy-strand DNA. The mitochondrion-encodedtRNA^Thr varied significantly more than any other tRNA gene.Threonine and valine codons were involved in 259 of the 414amino acid replacements observed. The ratio of nonsynonymouschanges from and to threonine and valine differed significantly(P = 0.003) between populations with neutral (22/58) and populationswith significantly negative Tajima's D values (70/76), independentof their geographic location. In contrast to a recent suggestionthat the excess of nonsilent mutations is characteristic ofArctic populations, implying their role in cold adaptation,we demonstrate that the surplus of nonsynonymous mutations isa general feature of the young branches of the phylogenetictree, affecting also those that are found only in Africa. Weintroduce a new calibration method of the mutation rate of synonymoustransitions to estimate the coalescent times of mtDNA haplogroups.

MITOCHONDRIAL DNA (mtDNA) encodes for 13 proteins, two ribosomalgenes, and 22 tRNAs that are essential in the energy productionof the human cell. Variation in the sequence of mtDNA has providedsignificant insights into the maternal history of anatomicallymodern humans (GILES et al. 1980; DENARO et al. 1981), complementingthe paternal legacy of the Y chromosome (UNDERHILL et al. 2000).Studies based on restriction fragment length polymorphism (RFLP)of the coding and direct sequencing of the noncoding controlregion have formed the basis of a hierarchical classificationof distinct geographic and ethnic affinities (TORRONI et al.1993, 1996; CHEN et al. 1995; WATSON et al. 1997; MACAULAY etal. 1999; FORSTER et al. 2001). Studies addressing sequencevariation in the mtDNA coding region have suggested that naturalselection has significantly shaped the course of human mtDNAevolution (CANN et al. 1984; NACHMAN et al. 1996; INGMAN andGYLLENSTEN 2001; MISHMAR et al. 2003; MOILANEN et al. 2003;MOILANEN and MAJAMAA 2003; ELSON et al. 2004; RUIZ-PESINI etal. 2004). These studies have disagreed, however, upon whetherthe distribution of specific human mtDNA clades or haplogroupsis due to an adaptation to different climates or if their distributionis a function of random genetic drift assisted by purifyingselection that eliminates nonsynonymous changes. In an attemptto clarify this disagreement and to study the mode of naturalselection in mtDNA variation in human populations, we providehere a phylogenetic analysis of a global sample of mtDNAs andinvestigate the position, chemical nature, and geographic distributionof recurrent and frequent mutations in the coding region.

MATERIALS AND METHODS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

DNA samples:
The ascertainment set comprised 277 individuals from the fivecontinents, including genomic DNA samples from 129 Africans(10 Biaka Pygmy, 15 Mbuti Pygmy, two Lisongo, six San, two Mandenka,four Ethiopian Jews, nine Sudanese, one Eritrean, one Ghanan,three Herero, one Ovambo, one Pedi, one Sotho, two Tswana, twoZulu, 10 Fulbe, 10 Mossi, 10 Rimaibe, one Berta, one Tuareg,37 Dominicans), 43 Asians (one Arab, one Kazak, one Druze, fourBedouin, one Sepharadim, one Yemenite Jew, two Pathan, fiveSindhi, two Burushaski, one Baluchi, one Brahui, two Makran,two Hazara, one Tamil, two Cambodians, one Hmong, one Atayal,one Ami, four Han Chinese, five Japanese, four Koreans), 76Europeans (five Northern Europeans, 12 Italians, one Greek,two Finns, two Ashkenazi, one Georgian, 17 Hungarians, threeIcelanders, three Czechs, one Sardinian, five Basque, one Iberian,23 Dutch), 13 Oceanians (four New Guineans, three Melanesians,six Australian Aborigines), and 16 Native Americans (one Auca,one Guarani, five Brazilian Indians, three Colombian Indians,two Mayan, one Piman, one Muskogee, one Navaho, one Quechua)(supplemental Table 1 at http://www.genetics.org/supplemental/).A subset of 103 sequences from these populations has been reportedelsewhere (SHEN et al. 2005). DNA was extracted using the QIAampDNA blood kit (QIAGEN, Valencia, CA). Immortalized cell lineshave been established for all individuals with the exceptionof the 17 Hungarians, the 23 Dutch, the 37 Dominicans, the 10Mossi, the 10 Rimaibe, and the 10 Fulbe.

PCR and DNA sequencing:
The 41 primer pairs used for bidirectional sequencing of mtDNAnucleotides 435–16,023, the PCR conditions, and the determinedcomplete coding region sequence information for 277 individualsamples are available at http://insertion.stanford.edu/primers_mitogenome.html.Amplicons were purified with QIAGEN QIAquick spin columns andsequenced with the Applied Biosystems (Foster City, CA) DyeTerminator Cycle sequencing kit and a model 3700 DNA sequencer.

Phylogenetic and statistical analyses:
An unrooted tree from a median-joining network (BANDELT et al.1999) was drawn and labeled following existing mtDNA haplogroupnomenclature (TORRONI et al. 1996, 2001; MACAULAY et al. 1999;KIVISILD et al. 2002, 2004; SALAS et al. 2002; YAO et al. 2002;KONG et al. 2003, 2004; SHEN et al. 2005). The tree was rootedusing nuclear inserts of mtDNA retrieved from human genomicsequence and the consensus sequence of the three chimpanzeemitochondrial genomes. The accession numbers, mtDNA positionalrange, and identity (ID) measures of the genomic contigs containingthe inserts that were used for rooting are as follows: NT_006713.14(bp 341–2697; ID 94%); NT_009237.17 (bp 521–2976;ID 94%); NT_006316.15 (bp 2899–3050; ID 94%); NT_077913.3(bp 3914–9756; ID 98%); and NT_034772.5 (bp 10,269–15,487;ID 94%). The assembled sequence of the inserts is availableat http://insertion.stanford.edu/mtDNA.html. The GenBank accessionnumbers of the two Pan troglodytes and one Pan paniscus sequencesthat were used are D38113, X93335, and D38116, respectively.Haplogroup divergence estimates ${rho}$ and their error ranges werecalculated as averages of the distances from the tips to themost recent common ancestor of the haplogroup (FORSTER et al.1996; SAILLARD et al. 2000). Two separate measures of nonsynonymous(N) to synonymous (S) substitution ratios were used: first,the M_N/M_S ratio estimates the number of mutational changes inferredfrom the phylogenetic tree (Figure 1), and second, the d_N/(d_S+ constant) refers as in MISHMAR et al. (2003) to the ratioof the average pairwise distances of N and S changes in thegiven sample. Statistical significance was determined from binomialor ${chi}$ ² probabilities. Disease-implicated substitutions were excludedfrom these analyses. For interspecies comparisons, mammalianmtDNA sequences were retrieved from the Mitochondriome website(http://bighost.area.ba.cnr.it/mitochondriome/Mt_chordata.htm).

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FIGURE 1.— Maximum parsimony tree of 277 human mtDNA coding region sequences. Locations of branch-defining mutations are listed relative to the revised reference sequence (ANDREWS et al. 1999). Transversions are specified in capital letters, del indicates deletion, and + indicates insertion. Amino acid replacements are specified in parentheses with threonine- and valine-affecting changes highlighted in red and blue, respectively. $~$ t, change in tRNA; $~$ r, change in rRNA gene. Haplogroup labels follow existing classifications (CHEN et al. 1995; TORRONI et al. 1993, 1996, 2001; WATSON et al. 1997; MACAULAY et al. 1999; BANDELT et al. 2001; FORSTER et al. 2001; KIVISILD et al. 2002, 2004; KONG et al. 2003; ACHILLI et al. 2004; PALANICHAMY et al. 2004; SHEN et al. 2004; TANAKA et al. 2004; FRIEDLAENDER et al. 2005). Substitutions at np 709, 3693, and 4715 in haplogroups B4, L2, and Z, respectively, are reconstructed less parsimoniously, yet in accordance with the phylogenetic relations suggested by additional data (FINNILÄ et al. 2001; TORRONI et al. 2001; KIVISILD et al. 2002; KONG et al. 2003). Coalescent estimates of haplogroups, shown in thousands of years in italics next to clade labels, are based on the average number of synonymous transitions to the root of the clade. The tree was rooted using as outgroup the nuclear inserts of mtDNA and the majority consensus of complete sequences of two P. troglodytes and one P. paniscus (for details see MATERIALS AND METHODS). The numbers in triangles indicate the additional mutational steps required in comparison to the optimally rooted tree using only the chimpanzee outgroup with red type indicating the root that was rejected (P < 0.01) under the assumption of equal evolutionary rate over branches. The positions at which the derived character states in humans and the chimpanzee consensus match are shown above the triangles. Disease-implicated substitutions confirmed by two independent studies (http://www.mitomap.org) are indicated by "#." Ad, Af, Am, As, Eu, and Oc correspond to African descent, African, Amerindian, Asian, European, and Oceanian, respectively. The continent of origin is distinguished for each individual sample by box color and subcontinental affiliation is indicated with letters below the boxes where N, E, W, S, C, and SW refer to north, east, west, south, central, and southwest parts of the continents, respectively. BP, Biaka Pygmies; MP, Mbuti Pygmies; A, Australian; P, Papuan; M, Melanesian; H, Hungarian LHON patients; G, Georgian. The two African mtDNAs (L0a2 and L1b1) found in West Asia (Pakistan) are likely due to recent admixture as indicated by their low genetic distance from related African samples presented in the tree and by the fact that they were detected in a Makrani and a Sindhi. According to QUINTANA-MURCI et al. (2004), the Makrani harbor an extremely high frequency (39%) of the African haplogroups L3d, L3b, L2a, and L1a, most likely as a result of the forced migration of slave women from Africa that began in the seventh century and increased considerably during the Omani Empire. European gene flow, on the other hand, may account for the presence of European K and X sequences in one Aboriginal Australian and in one Native American (Muskogee), respectively.

Tests for positive selection:
Seven primate taxa, namely Homo sapiens, P. troglodytes, Gorillagorilla, Papio hamadryas, Hylobates lar, Pongo pygmaeus, andMacaca sylvanus were chosen from GenBank (gi|17981852, gi|5835121,gi|5835149, gi|5835638, gi|5835820, gi|5835163, gi|14010693)and aligned using clustalW (THOMPSON et al. 1994) to test forthe historic occurrence of positive, directional selection onthe 13 coding regions of the primate mitochondrion using theprogram codeml of the PAML package (YANG 2002). In these tests,maximum-likelihood ratios of nonsynonymous-to-synonymous mutations( ${omega}$ ) exceeding 1 are consistent with the hypothesis of positiveselection, while values close to 1 indicate selective neutrality,and values converging on 0 suggest strong purifying selection.We conducted both lineage and site-specific tests. For the lineage-specifictests, we used a model in which all lineages have the same ${omega}$ (hereafter referred to as M0) and compared that with a modelin which ${omega}$ is estimated for each lineage (hereafter referredto as M1). To test for the action of selection among amino acidsites within a specific lineage, we compared a model that allowsfor heterogeneity in ${omega}$ among sites, but not among lineages, witha model that allows for variation in ${omega}$ along a predefined lineage(as in YANG and NIELSEN 2002). We assumed the following unrootedphylogeny (troglodytes, ((((macaca, papio), hylobates), pongo),gorilla), troglodytes), human). However, results of our analyseswere robust to minor fluctuations in the tree.

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

The deepest splits of the phylogeny constructed from 277 mtDNAcomplete coding region sequences (Figure 1) were sustained byAfrican mtDNAs, which belonged to previously defined haplogroupsL0–L5 (TORRONI et al. 2001; SALAS et al. 2002; MISHMARet al. 2003; KIVISILD et al. 2004; SHEN et al. 2005). A numberof new subclades were identified among these (see Figure 1.Haplogroup sharing between distinct geographic regions was generallylow. All European sequences could be assigned to clades N1,X, W, HV, TJ, and U (TORRONI et al. 1996; MACAULAY et al. 1999;FINNILÄ et al. 2001; HERRNSTADT et al. 2002). Asian, Amerindian,Oceanian, and Australian Aborigine sequences belonged to region-specifichaplogroups nested within macro-clades M and N (KIVISILD etal. 2002; YAO et al. 2002; KONG et al. 2003, 2004; FRIEDLAENDERet al. 2005). All Australian Aborigine M sequences (two fromthis study and one from INGMAN et al. (2000) share six mutationsthat define the new haplogroup M42. The majority of AustralianN and R sequences (INGMAN and GYLLENSTEN 2003) belong to cladesS and P defined by transitions at nucleotide positions (np)8404 and 15607, respectively (FORSTER et al. 2001; FRIEDLAENDERet al. 2005).

The most parsimonious root of the mtDNA tree using nuclear insertsof mtDNA and the chimpanzee consensus sequence as outgroupsappeared between haplogroup L0 and the rest of the phylogeny(Figure 1). Extensive interspecies homoplasy and mutationalsaturation was highlighted by the fact that for more than one-third(417/1292) of the variable sites, regardless of their phylogeneticposition on the tree, the derived allele among humans correspondedto the chimpanzee allele. In agreement with noncoding regioninformation (AQUADRO and GREENBERG 1983), a high ratio (21.5on average, 34.8 in synonymous positions) of transitions totransversions was observed in the coding region (577–16023).

Interspecies calibration of the molecular clock over the completemtDNA sequence (INGMAN et al. 2000; MISHMAR et al. 2003) isproblematic because of saturation of transitions at silent positionsand the effect of selection on the fixation rate of amino acidreplacement mutations (HO et al. 2005). Assuming 6 million yearsfor the human–chimp species split (GOODMAN et al. 1998)and 6.5 million years for the most recent common ancestor oftheir mtDNA lineages (MISHMAR et al. 2003), we estimated theaverage transversion rate at synonymous and rRNA positions as2.1 x 10^–9 and 4.1 x 10^–10/year/position, respectively.Using the observed relative rates of different substitutiontypes in humans (Table 1), the average transition rate at 4212synonymous positions is 3.5 x 10^–8 (SD 0.1 x 10^–8)/year/position.Over all genes in mtDNA this would be equivalent to accumulationof one synonymous transition/6764 (SD 140) years on average.The coalescent date of the human mitochondrial DNA tree usingthis rate is 160,000 (SD 22,000) years. This coalescent dateis broadly consistent with the dates of the Homo sapiens fossilsrecognized so far from Ethiopia (CLARK et al. 2003; WHITE etal. 2003; MCDOUGALL et al. 2005). The most recent common ancestorof all the Eurasian, American, Australian, Papua New Guinean,and African lineages in clade L3 dates to 65,000 ± 8000years while the average coalescent time of the three basic non-Africanfounding haplogroups M, N, and R is 45,000 years. These estimates,bracketing the time period for the recent out-of-Africa migration(STRINGER and ANDREWS 1988), are younger than those based oncalibrations involving all coding region sites (INGMAN et al.2000; MISHMAR et al. 2003) but are still in agreement with theearliest archaeological signs of anatomically modern humansoutside Africa (MELLARS 2004). The differences between the dateestimates of previous studies are most likely due to the overrepresentationof possibly slightly deleterious nonsynonymous mutations inthe younger branches of the tree (ELSON et al. 2004) that introducesa bias to the coalescent approach if all the sites of the codingregion are used.

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TABLE 1 Distribution of mtDNA mutations by recurrence

Of the 1788 mutations depicted in the tree, 1758 occurred at1292 variable sites in the coding region between np 577 and16023. Consistent with previous reports (MISHMAR et al. 2003;MOILANEN and MAJAMAA 2003; ELSON et al. 2004), there was a significantexcess of synonymous mutations in all genes coded by mtDNA,especially among those positions that defined the deeper branchesof the tree (Tables 2 and 3). In contrast to RUIZ-PESINI etal. (2004), we did not observe any significant regional (climatic)differences in the rate of nonsynonymous changes for mtDNA haplogroups.This discrepancy likely results from the fact that RUIZ-PESINIet al. (2004) compared region-specific haplogroups of differentdiversity levels: e.g., the "old" paragroup L in Africans vs."young" Arctic haplogroups (Table 4). Populations of Asian,European, and West African origin showed significantly negativeTajima's D values (Table 3), consistent with selection, populationgrowth, and/or population subdivision (RAY et al. 2003). Thatpopulation substructure accounts at least for part of the deviationfrom neutrality is obvious from the observation that it decreasesupon partitioning of West Africans into a sample from BurkinaFaso and one from the Dominican Republican.

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TABLE 2 Distribution of mutations as a function of derived-allele frequency in 277 mtDNAs

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TABLE 3 Ratios of numbers and rates of nonsynonymous over synonymous sites, nucleotide diversity, Tajima's D, Fu and Li's D and F, and number of changes from and to valine and threonine for the 13 protein-coding mitochondrial genes according to continental affiliation

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TABLE 4 The rate of nonsynonymous/synonymous changes in relation to continental geography and haplo-group diversity

Significant (P < 0.05) mutational bias toward specific (NNGto NNA and NNU to NNC) codon usage was observed in 27 of 32pairs of codons that differed by a transition in the third codonposition (Table 5). This relative preference of G-to-A and T-to-Cmutations (per existing nucleotide pool in the light strand)extends over the nonsilent positions and is characteristic ofthe noncoding D-loop region (AQUADRO and GREENBERG 1983; MALYARCHUKand ROGOZIN 2004). However, the general strand bias, known tobe reversed in some Metazoan genera, can be related to asymmetricmutational constraints involving deaminations of A and C nucleotidesduring the replication and/or transcription processes (HASSANINet al. 2005). Importantly, the ND6 gene, encoded by the heavystrand showed the opposite mutational bias, suggesting thatthe differences of codon usage in human mtDNA might be primarilya function of strand asymmetry rather than of differences inthe tRNA pools, as generally expected (TANAKA and OZAWA 1994).Notably, 16/18 nucleotide positions (Table 6) that had undergonefive or more recurrent changes involved the transition of guanineto adenine in the light strand.

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TABLE 5 Significant differences (P < 0.05) in mutational direction in synonymous sites

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TABLE 6 Number and location of recurrent mutations in the mtDNA coding region (577–16023)

Of the 1292 variable sites, 288 (22.2%) had mutated recurrently.Unexpectedly, the hotspots that had mutated five or more timeswere predominantly within mitochondrial rRNA (P < 5 x 10^–15)and showed a significantly higher ratio of nonsynonymous-to-silentmutations (90:32 hits, respectively) than polymorphic siteswith lower recurrence (608:1004) (Table 6). Finally, these hotspotsof mutational activity included positions where the human-derivedallele predominates in the mammalian consensus sequences (e.g.,np 709, 3010, 10398, and 13928), implying the effect of site-specificpositive selection. Among the six nonsynonymous substitutionsthat have recurred four or more times, five involved threonine(P < 6.1 x 10^–7). Overall, threonine and valine codonswere involved in 259 of the 414 amino acid replacements observedon the tree.

Lineage-specific tests failed to detect significant positiveselection along any unique lineage in the seven-taxon phylogenyof primates. A model fixing a single ratio of ${omega}$ to all lineages(M0) could not be rejected in favor of a model of different ${omega}$ 's on specified lineages (M1). The ${omega}$ estimated across all lineagesin the phylogeny was 0.35. A test of the previous model againsta model enforcing neutral selection, where ${omega}$ is expected to beequal to 1, showed that these data do not deviate significantlyfrom neutrality (M0 was rejected in favor of model where ${omega}$ =1; P ${approx}$ 0, d.f. = 1). Further tests for lineage-specific variationin ${omega}$ , including a model that assigned a different ${omega}$ to the humanlineage from the remaining primates, did not fit the data aswell as M1 did. However, site-specific model testing revealedsignificant positive selection across regions of the primatemitochondrion. A model enforcing a single ${omega}$ ratio on all codonsites was rejected in favor of a model allowing for three ratiosacross sites with three site classes (P ${approx}$ 0, d.f. = 5). The three-ratiomodel identified 16 codon sites to be under significant (posteriorprobabilities > 0.95; d_N/d_S = 2.02) positive selection (Table 7).Among these, four codon sites appeared to be among the nonsynonymoussites with recurrent mutation (particularly no. 114 in the ND3gene, np 10398 with seven recurrences) in human–humancomparisons (Table 6).

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TABLE 7 Codon sites found to be under positive selection in the mitochondrion-encoded protein genes in primates

A majority of the mitochondrial disease-related mutations havebeen detected in the tRNA genes, and they mainly affect thesecondary structure of the molecule (MCFARLAND et al. 2004 andreferences therein). Our global survey of natural variationin the tRNA genes showed a sevenfold excess of tRNA^Thr mutations(N = 28) over other tRNA genes (P < 10^–19). This findingwould suggest, at first glance, that this gene might have becomenonfunctional in the mitochondrion and that its encoded tRNAneeds to be imported from the nucleus. Evidence suggesting nucleartRNA import into mitochondria in marsupials has been obtainedpreviously (DÖRNER et al. 2001). However, plotting theobserved mutations in the tRNA^Thr gene against the mammalianconsensus sequences (HELM et al. 2000) showed that none of themutations that we have observed in 277 humans fell within the100% conserved regions of the tRNA (Figure 2). Most pathologicalmutations affecting tRNAs cluster in highly conserved regions(MCFARLAND et al. 2004), as illustrated in the case of tRNA^Leuin Figure 2. Four private mutations changed the nucleotide thatis >90% conserved in mammalian tRNA^Thr, while most of thefrequent and recurrent mutations in the data set affected theminor fraction of the sites that are not highly conserved inmammalian species. This argues against the proposition thathuman mitochondrial tRNA^Thr has lost function. A large fraction(12/28) of the mutations affecting tRNA^Thr occurred at threepositions, two of which have a different allele in consensushumans as compared to the 31 mammalian species analyzed by HELMet al. (2000). Similarly, a mutational hotspot at position 5821in tRNA^Cys showed a majority allele in humans different fromthat found in consensus mammalians (Figure 2). Surprisingly,in the latter tRNA we observed two parallel mutations at position5814 that have been previously reported pathogenic. Yet, becausethis position is not highly conserved in other mammalian species,its pathological role has to be questioned. No other tRNA sitethat has been confirmed as associated with mitochondrial diseasewas found to be variable in our data set. The only mutationalhotspot (12,172) affecting the human allele that matches theallele conserved in >90% of mammalian tRNA-s was found intRNA^His.

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FIGURE 2.— Natural and pathological variation in human mitochondrial species of tRNAs. Mutations observed in this study are in yellow; those with a status of confirmed pathological variation (http://www.mitomap.org) are in red triangles. Nucleotide positions that are 100% and 90% conserved in mammalian species (HELM et al. 2000) are highlighted in green and blue rectangles, respectively. Nucleotide positions at which the human and mammalian consensus differ from each other are in red type.

A comparison of the amino acid substitutions in the mtDNA-encodedproteins in humans, primates, carnivores, and artiodactyls revealedthat substitutions between threonine and alanine are significantlyoverrepresented in humans while changes between methionine andleucine are most common in other mammalian species (Table 8).The direction of threonine and valine substitution with otheramino acids was significantly different among populations withneutral and significantly negative Tajima's D values, respectively(Table 3), and among haplogroups: in H1 sequences sampled broadlyfrom Europe and the Near East, 7 of 11 nonsynonymous mutationsresulted in the replacement of threonine and valine with alanineand isoleucine, while only three mutations resulted in a changetoward threonine or valine (Figure 1). In contrast to this pattern,in haplogroup V sequences from Finland (FINNILÄ et al.2001), where populations continued to rely largely on huntingand fishing for subsistence even after the first contacts withfarmers, six of seven replacement polymorphisms resulted ina change to threonine and valine, and none resulted in the replacementof the latter two amino acids (P < 0.01). Similarly, L3 sequencesof West African origin showed a significantly lower (P <0.001) ratio of gains to losses of threonine and valine residues(13/14) than haplogroup L0 sequences from East and South Africa(22/2; Figure 1). East Asian sequences showed an increase ofvaline codons (9 mutations to and 2 from valine codons), butalso a significant (P < 0.01) decrease of threonine, with11 mutations from and 5 to threonine codons, while Native Americanshad 1 mutation from and 7 to threonine, respectively. Over allhaplogroups and genes, the direction of amino acid change wassignificantly (P < 0.02) biased toward replacement of isoleucineand methionine to valine, even when considering the transitionalpreferences observed in the mitochondrial D-loop (TAMURA andNEI 1993). The strand-specific mutational biases are unlikelyto explain this pattern because of the observed excess of mutationsinvolving valine codons (8/16 in our data set and 13/16 in thelist of ND6 polymorphic sites in MITOMAP) in the ND6 gene thatis encoded by the opposite strand.

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TABLE 8 Predominant amino acid replacement types in mitochondrial genes by intra- and interspecies comparisons

	DISCUSSION

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS LITERATURE CITED

In phylogenetic analysis of human mitochondrial DNA-coding regionsequences, two different spheres of character evolution canbe distinguished (HO et al. 2005; PENNY 2005). First, withinour species, at the population level, a relatively low levelof parallel mutations—as compared to the mtDNA control-region-basedphylogenies—enables the reconstruction of the unrootedtree from individual sequences without significant ambiguity.This tree is determined by a substantial fraction of amino acidreplacement mutations whose proportion to synonymous substitutionsincreases from the average of 0.37 in "older" clades to 0.62in "younger" ones. In the second sphere, a high level of homoplasywith chimpanzees, affecting at least one-third of the variablesites in humans, complicates detailed phylogenetic analysesat the interspecies level. Approximately 930 synonymous mutationsthat can be observed between human and chimpanzee mtDNA representonly the visible component of variation between the specieswhile the effective ratio of nonsynonymous-to-silent mutationsis expectedly significantly less than the observed value of0.2 due to the hidden load of synonymous mutations. These differencesbetween the two spheres imply that, even among the substitutionsthat define the deepest branches of the human mtDNA tree, asignificant excess of nonsynonymous mutations have not yet beeneliminated by purifying selection—assuming, of course,that they are generally deleterious, after all.

More than half of the amino acid replacements observed in thehuman mtDNA tree involved threonine and valine codons. Adaptivecorrelation with the elevated mutability in the mitochondrion-encodedtRNA^Thr, in principle, could be considered as one explanationfor the excess of mutations involving threonine codons. However,none of the highly conserved sites in the tRNA^Thr gene was foundto be different in humans from that of the consensus mammaliansand, instead, the excessive variability in this gene could beascribed largely to the presence of three hotspot positions.Furthermore, no such general molecular phenomenon or the characteristicG-to-A and T-to-C mutational bias on the light strand of mtDNAwould explain the pattern of differences of amino acid replacementdirections that were observed among human populations.

One factor that could explain, theoretically at least, the differentamino acid replacement patterns observed among populations andbetween humans and other mammals is diet. Threonine and valine,essential amino acids that must be taken in the diet, are abundantin meats, fish, peanuts, lentils, and cottage cheese, but deficientin most grains. Alternatively, or in combination with dietaryrestriction, other constraints of selection on slightly deleteriouspositions during the phases of population expansion and contractionmay be involved. Because of the specific compositional biasin mtDNA induced by characteristic mutational preferences differentfrom those observed in the nuclear genome, additional inter-and intraspecies comparisons of mtDNA-encoded amino acid replacementpatterns should be examined to gain deeper insights into thenonsynonymous character evolution in metazoan mitochondria,particularly in taxa with shifted strand symmetry (HASSANINet al. 2005).

Tests of neutrality based on the comparisons of the ratio ofnonsynonymous and synonymous mutations across all sites candetect only major effects of purifying (K_N/K_S approaches 0)or directional selection (K_N/K_S is significantly >1), whichaffect simultaneously a large number of codon positions. Consistentwith previous studies (CANN et al. 1984; NACHMAN et al. 1996;INGMAN and GYLLENSTEN 2001; MISHMAR et al. 2003; MOILANEN etal. 2003; MOILANEN and MAJAMAA 2003; ELSON et al. 2004; RUIZ-PESINIet al. 2004) human mtDNA-encoded proteins did not provide evidenceof directional selection. However, several hotspots of mutationalactivity included nonsilent substitutions susceptible to site-specificpositive selection. Comparing the mtDNA protein-encoding genesfrom several primates (Macaca, Papio, Hylobates, Pongo, Gorilla,and Pan) with human ones, we discovered significant positiveselection in several regions, generally nonmatching, however,with the codons displaying a high K_N/K_S ratio in human–humancomparisons. This difference might be explained by the dynamicpolarity of the amino acid replacements at the intra- and interspecieslevels whereby the constraint of selection is determined ineach lineage by the ancestral state of each codon position.

In conclusion, we have provided new evidence for nonrandom processesaffecting the evolution of the human mtDNA-encoded proteins.The potential role of selection in affecting fixation probabilitiesat different nonsilent positions undermines the appropriatenessof using the average mitochondrial clock over all sites in datingevents in human population history. Despite the evidence ofdepartures from neutrality and high levels of homoplasy at theinterspecies level, the phylogenetic approach for analyzingmtDNA sequence data at the intraspecies level remains viablebecause the reconstruction of the basic branches is robust andthe excess of nonsynonymous substitutions affects mainly theterminal branches of the tree.

ACKNOWLEDGEMENTS

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MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

We thank Richard Villems for useful comments. This work wassupported by National Institutes of Health grants GM28428, GM63883,and GM55273, European Commission research grant QLG2-CT-2002-90455,Progetto Consiglio Nazionale delle Ricerche-Ministero dell Istruzione,dell Universita e della Ricerca Genomica Funzionale-Legge 449/97,and Telethon-Italy E.0890. We thank Rita Horvath for providingDNA samples.

FOOTNOTES

² These authors contributed equally to this work.

³ Present address: Department of Systems Biology, Harvard MedicalSchool, Boston, MA 02115.

⁴ Present address: Institute of Functional Genomics, Universityof Regensburg, Josef-Engert-Strasse 9, 93053 Regensburg, Germany.

Complete coding region sequence information for 277 individualsamples have been submitted to GenBank under accession nos.DQ112686–DQ112962.

LITERATURE CITED

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