Chromosome-specific subfamilies within human alphoid repetitive DNA

Nucleotide sequence data of about 20 X 10(3) base-pairs of the human tandemly repeated alphoid DNA are presented. The DNA sequences were determined from 45 clones containing EcoRI fragments of alphoid DNA isolated from total genomic DNA. Thirty of the clones contained a complete 340 base-pair dimer unit of the repeat. The remaining clones contained alphoid DNA with fragment lengths of 311, 296, 232, 170 and 108 base-pairs. The sequences obtained were compared with an average alphoid DNA sequence determined by Wu & Manuelidis (1980). The divergences ranged from 0.6 to 24.6% nucleotide changes for the first monomer and from 0 to 17.8% for the second monomer of the repeat. On the basis of identical nucleotide changes at corresponding positions, the individual repeat units could be shown to belong to one of several distinct subfamilies. The number of nucleotide changes defining a subfamily generally constitutes the majority of nucleotide changes found in a member of that subfamily. From an evaluation of the proportion of the total amount of alphoid DNA, which is represented by the clones studied, it is estimated that the number of subfamilies of this repeat may be equal to or exceed the number of chromosomes. The expected presence of only one or a few distinct subfamilies on individual chromosomes is supported by the study, also presented, of the nucleotide sequence of 17 cloned fragments of alphoid repetitive DNA from chromosome 7. These chromosome-specific repeats all contain the characteristic pattern of 36 common nucleotide changes that defines one of the subfamilies described. A unique restriction endonuclease (NlaIII) cleavage site present in this subfamily may be useful as a genetic marker of this chromosome. A family member of the interspersed Alu repetitive DNA was also isolated and sequenced. This Alu repeat has been inserted into the human alphoid repetitive DNA, in the same way as the insertion of an Alu repeat into the African green monkey alphoid DNA.     

Nuclear counterparts of the cytoplasmic mitochondrial 12S rRNA gene: A problem of ancient DNA and molecular phylogenies

Monkey mummy bones and teeth originating from the North Saqqara Baboon Galleries (Egypt), soft tissue from a mummified baboon in a museum collection, and nineteenth/twentieth-century skin fragments from mangabeys were used for DNA extraction and PCR amplification of part of the mitochondrial 12S rRNA gene. Sequences aligning with the 12S rRNA gene were recovered but were only distantly related to contemporary monkey mitochondrial 12S rRNA sequences. However, many of these sequences were identical or closely related to human nuclear DNA sequences resembling mitochondrial 12S rRNA (isolated from a cell line depleted in mitochondria) and therefore have to be considered contamination. Subsequently in a separate study we were able to recover genuine mitochondrial 12S rRNA sequences from many extant species of nonhuman Old World primates and sequences closely resembling the human nuclear integrations. Analysis of all sequences by the neighbor-joining (NJ) method indicated that mitochondrial DNA sequences and their nuclear counterparts can be divided into two distinct clusters. One cluster contained all temporary cytoplasmic mitochondrial DNA sequences and approximately half of the monkey nuclear mitochondriallike sequences. A second cluster contained most human nuclear sequences and the other half of monkey nuclear sequences with a separate branch leading to human and gorilla mitochondrial and nuclear sequences. Sequences recovered from ancient materials were equally divided between the two clusters. These results constitute a warning for when working with ancient DNA or performing phylogenetic analysis using mitochondrial DNA as a target sequence: Nuclear counterparts of mitochondrial genes may lead to faulty interpretation of results.Correspondence to: A.C. van der Kuyl     

Palaeogenomics

In many ways, palaeogenomics began when the first ancient DNA sequence was reported. This first sequence was derived from a stuffed museum specimen of the quagga, an extinct mammal related to the zebra. Unspecified and unselected DNA was extracted from the quagga specimen, cloned into a bacterial library, and then sequenced. It took another 17 years and the development of PCR before two independent groups successfully sequenced the complete mitochondrial genomes from several extinct moa species. Only 4 years later, using the original approach of cloning nonspecific ancient DNA extract and shotgun sequencing, the first ancient nuclear DNA sequences were determined, this time from the extinct cave bear. Since these early successes, palaeogenomics has rapidly expanded, because of both technological development and increasing interest in ancient DNA research. New methods, developed since the cave bear sequence was reported, have produced nuclear DNA on a megabase scale from two extinct species, the mammoth and the Neanderthal, our closest relative. For both species, low-coverage genome-sequencing projects have been proposed. It is likely that these will be successful, given the rapid technical development in sequencing techniques. This review carefully examines both the promise and the current limitations of palaeogenomic analyses for both mitochondrial and nuclear DNA.     

Structural analysis of alphoid DNA of primates. I. Heterogeneity of nucleotide sequence of alphoid repeats in human DNA

The nucleotide sequence of two cloned fragments of human alphoid DNA was established. These fragments were earlier characterized in our laboratory as molecular markers of the 3rd (pHS05) and 11th (pHS53) chromosomes. Fragment pHS53 (2546 bp) contains alphoid repeats tandemly arranged and organized into three highly homologous pentamers. The heterogeneity of monomeric sequences within individual pentamers reaches 24-33%. Structural analysis of EcoRI subfragment pHS05 showed that this alphoid tetramer consists of two dimers 340 bp long. These dimers differ up to 16% from each other and from the so-called consensus sequence of the EcoRI-340 bp-restriction fragments family reported earlier by Wu and Manuelidis. The primary structure of four cloned fragments of EcoRI-340 bp-family was established. The data show that human alphoid DNA is highly heterogeneous. This conclusion is opposite to the view suggesting that alphoid DNA is a highly homogeneous class of reiterated sequences of the human genome.     

Structural analysis of alphoid DNA of primates. II. Evolution and possible origin of alphoid DNA of primates

A computer analysis of human and primate alphoid DNA was performed. The number and localization of short inverted complete repeats within alphoid DNA dimers (but not monomers) remain conserved. Thus, in spite of high heterogeneity of the primary structure the conserved secondary structure of alphoid DNA might be functionally important. The analysis of internal periodicity of the monomeric sequences of human and primate alphoid DNA revealed its potential ancient sequence, that is a simple satellite DNA with a reiterated heptanucleotide TGAAAAA, which is suggested to be the ancestor of satellite DNase of rodents. The facts reported propose the ancient origin and possible functional role of alphoid-like DNA as a universal pericentromeric superfamily of DNA.     

Isolation and characterization of an alphoid centromeric repeat family from the human Y chromosome

A collection of human Y-derived cosmid clones was screened with a plasmid insert containing a member of the human X chromosome alphoid repeat family, DXZ1. Two positive cosmids were isolated and the repeats they contained were investigated by Southern blotting, in situ hybridization and sequence analysis. On hybridization to human genomic DNAs, the expected cross-hybridization characteristic of all alphoid sequences was seen and, in addition, a 5500 base EcoRI fragment was found to be characteristic of a Y-specific alphoid repeat. Dosage experiments demonstrated that there are about 100 copies of this 5500 base EcoRI alphoid fragment on the Y chromosome. Studies utilizing DNA from human-mouse hybrids containing only portions of the Y chromosome and in situ hybridizations to chromosome spreads demonstrated the Y centromeric localization of the 5500 base repeat. Cross-hybridization to autosomes 13, 14 and 15 was also seen; however, these chromosomes lacked detectable copies of the 5500 base EcoRI repeat sequence arrangement. Sequence analysis of portions of the Y repeat and portions of the DXZ1 repeat demonstrated about 70% homology to each other and of each to the human consensus alphoid sequence. The 5500 base EcoRI fragment was not seen in gorilla, orangutan or chimpanzee male DNA.     

Nucleotide sequence heterogeneity of alpha satellite repetitive DNA: a survey of alphoid sequences from different human chromosomes.

The human alpha satellite DNA family is composed of diverse, tandemly reiterated monomer units of approximately 171 basepairs localized to the centromeric region of each chromosome. These sequences are organized in a highly chromosome-specific manner with many, if not all human chromosomes being characterized by individually distinct alphoid subsets. Here, we compare the nucleotide sequences of 153 monomer units, representing alphoid components of at least 12 different human chromosomes. Based on the analysis of sequence variation at each position within the 171 basepair monomer, we have derived a consensus sequence for the monomer unit of human alpha satellite DNA which we suggest may reflect the monomer sequence from which different chromosomal subsets have evolved. Sequence heterogeneity is evident at each position within the consensus monomer unit and there are no positions of strict nucleotide sequence conservation, although some regions are more variable than others. A substantial proportion of the overall sequence variation may be accounted for by nucleotide changes which are characteristic of monomer components of individual chromosomal subsets or groups of subsets which have a common evolutionary history.     

A large-subunit mitochondrial ribosomal DNA sequence translocated to the nuclear genome of two stone crabs (Menippe)

Two DNA sequences that appear to be homologous to large-subunit mitochondrial ribosomal RNA genes have been identified in the stone crabs Menippe mercenaria and M. adina. Amplification from whole genomic DNA by polymerase chain reaction (PCR) with oligonucleotide primers based on conserved portions of large-subunit mitochondrial rRNA genes consistently amplified two products of similar length (565 and 567 bp). These products differed at 3% of their nucleotide bases, and could be distinguished by a HindIII site. Only one of these sequences (designated the A sequence) was detected by PCR in purified mitochondrial DNA. The other (designated the B sequence) hybridized to total genomic DNA at a level consistent with a nuclear genome location. It is unlikely that the type B product would have been recognized as a nuclear copy by examination of its sequence alone. This is the first report of a mitochondrial gene sequence translocated into the nuclear genome of a crustacean.      

2000 Year-old ancient equids: an ancient-DNA lesson from pompeii remains

Ancient DNA extracted from 2000 year-old equine bones was examined in order to amplify mitochondrial and nuclear DNA fragments. A specific equine satellite-type sequence representing 3.7%-11% of the entire equine genome, proved to be a suitable target to address the question of the presence of aDNA in ancient bones. The PCR strategy designed to investigate this specific target also allowed us to calculate the molecular weight of amplifiable DNA fragments. Sequencing of a 370 bp DNA fragment of mitochondrial control region allowed the comparison of ancient DNA sequences with those of modern horses to assess their genetic relationship. The 16S rRNA mitochondrial gene was also examined to unravel the post-mortem base modification feature and to test the status of Pompeian equids taxon on the basis of a Mae III restriction site polymorphism.     

Spiking of contemporary human template DNA with ancient DNA extracts induces mutations under PCR and generates nonauthentic mitochondrial sequences

Proof of authenticity is the greatest challenge in palaeogenetic research, and many safeguards have become standard routine in laboratories specialized on ancient DNA research. Here we describe an as-yet unknown source of artifacts that will require special attention in the future. We show that ancient DNA extracts on their own can have an inhibitory and mutagenic effect under PCR. We have spiked PCR reactions including known human test DNA with 14 selected ancient DNA extracts from human and nonhuman sources. We find that the ancient DNA extracts inhibit the amplification of large fragments to different degrees, suggesting that the usual control against contaminations, i.e., the absence of long amplifiable fragments, is not sufficient. But even more important, we find that the extracts induce mutations in a nonrandom fashion. We have amplified a 148-bp stretch of the mitochondrial HVRI from contemporary human template DNA in spiked PCR reactions. Subsequent analysis of 547 sequences from cloned amplicons revealed that the vast majority (76.97%) differed from the correct sequence by single nucleotide substitutions and/or indels. In total, 34 positions of a 103-bp alignment are affected, and most mutations occur repeatedly in independent PCR amplifications. Several of the induced mutations occur at positions that have previously been detected in studies of ancient hominid sequences, including the Neandertal sequences. Our data imply that PCR-induced mutations are likely to be an intrinsic and general problem of PCR amplifications of ancient templates. Therefore, ancient DNA sequences should be considered with caution, at least as long as the molecular basis for the extract-induced mutations is not understood.     

Alpha satellite DNAs on chromosomes 10 and 12 are both members of the dimeric suprachromosomal subfamily, but display little identity at the nucleotide sequence level

We have investigated the organization and complexity of alpha satellite DNA on chromosomes 10 and 12 by restriction endonuclease mapping, in situ hybridization (ISH), and DNA-sequencing methods. Alpha satellite DNA on both chromosomes displays a basic dimeric organization, revealed as a 6- and an 8-mer higher-order repeat (HOR) unit on chromosome 10 and as an 8-mer HOR on chromosome 12. While these HORs show complete chromosome specificity under high-stringency ISH conditions, they recognize an identical set of chromosomes under lower stringencies. At the nucleotide sequence level, both chromosome 10 HORs are 50% identical to the HOR on chromosome 12 and to all other alpha satellite DNA sequences from the in situ cross-hybridizing chromosomes, with the exception of chromosome 6. An 80% identity between chromosome 6- and chromosome 10-derived alphoid sequences was observed. These data suggest that the alphoid DNA on chromosomes 6 and 10 may represent a distinct subclass of the dimeric subfamily. These sequences are proposed to be present, along with the more typical dimeric alpha satellite sequences, on a number of different human chromosomes.     

Chromosome-specific subsets of human alpha satellite DNA: Analysis of sequence divergence within and between chromosomal subsets and evidence for an ancestral pentameric repeat

Summary The centromeric regions of human chromosomes are characterized by diverged chromosome-specific subsets of a tandemly repeated DNA family, alpha satellite, which is based on a fundamental monomer repeat unit 171 bp in length. We have compared the nucleotide sequences of 44 alphoid monomers derived from cloned representatives of the multimeric higher-order repeat units of human chromosomes 1, 11, 17, and X. The 44 monomers exhibit an average 16% divergence from a consensus alphoid sequence, and can be assigned to five distinct homology groups based on patterns of sequence substitutions and gaps relative to the consensus. Approximately half of the overall sequence divergence can be accounted for by sequence changes specific to a particular homology group; the remaining divergence appears to be independent of the five groups and is randomly distributed, both within and between chromosomal subsets. The data are consistent with the proposal that the contemporary tandem arrays on chromosomes 1, 11, 17, and X derive from a common multimeric repeat, consisting of one monomer each from the five homology groups. The sequence comparisons suggest that this pentameric repeat must have spread to these four chromosomal locations many millions of years ago, since which time evolution of the four, now chromosome-specific, alpha satellite subsets has been essentially independent.     

Characterization of a human alphoid satellite DNA sequence: Potential use in assessing genetic diversity in Indian populations

Sequence analysis of a human repetitive DNA sequence (pTRF5.6) revealed considerable homology (76%) to the alphoid consensus sequence. Genomic blots of StuI-digested human DNA, hybridized to pTRF5.6, generated a ladder of bands with each band corresponding to oligodeoxyribonucleotide of an approx. 170-bp repeat, indicating a tandemly arrayed organization of this repeat element within the genome. Genomic hybridization analyses of unrelated individuals belonging to various geographical regions of India, using this alphoid satellite probe, revealed polymorphic bands ranging between 2 and 9 kb. Along with an individual-specific band pattern, several isomorphic bands below 2 kb were also evident. There was very little of genetic variability between populations, suggestive of low polymorphism at the inter-population level. Our result suggest that alphoid satellite sequence probe can be used in assessing the genetic diversity of various ethnic groups/populations belonging to different geographical regions.     

Characterization of Nucleotide Misincorporation Patterns in the Iceman's Mitochondrial DNA

Background

The degradation of DNA represents one of the main issues in the genetic analysis of archeological specimens. In the recent years, a particular kind of post-mortem DNA modification giving rise to nucleotide misincorporation (“miscoding lesions”) has been the object of extensive investigations.

Methodology/Principal Findings

To improve our knowledge regarding the nature and incidence of ancient DNA nucleotide misincorporations, we have utilized 6,859 (629,975 bp) mitochondrial (mt) DNA sequences obtained from the 5,350–5,100-years-old, freeze-desiccated human mummy popularly known as the Tyrolean Iceman or Ötzi. To generate the sequences, we have applied a mixed PCR/pyrosequencing procedure allowing one to obtain a particularly high sequence coverage. As a control, we have produced further 8,982 (805,155 bp) mtDNA sequences from a contemporary specimen using the same system and starting from the same template copy number of the ancient sample. From the analysis of the nucleotide misincorporation rate in ancient, modern, and putative contaminant sequences, we observed that the rate of misincorporation is significantly lower in modern and putative contaminant sequence datasets than in ancient sequences. In contrast, type 2 transitions represent the vast majority (85%) of the observed nucleotide misincorporations in ancient sequences.

Conclusions/Significance

This study provides a further contribution to the knowledge of nucleotide misincorporation patterns in DNA sequences obtained from freeze-preserved archeological specimens. In the Iceman system, ancient sequences can be clearly distinguished from contaminants on the basis of nucleotide misincorporation rates. This observation confirms a previous identification of the ancient mummy sequences made on a purely phylogenetical basis. The present investigation provides further indication that the majority of ancient DNA damage is reflected by type 2 (cytosine→thymine/guanine→adenine) transitions and that type 1 transitions are essentially PCR artifacts.     

Different subfamilies of alphoid repetitive DNA are present on the human and chimpanzee homologous chromosomes 21 and 22.

The alphoid repeat DNA on chimpanzee chromosome 22 was compared with alphoid repeat DNA on its human homologue, chromosome 21. Hybridization of different alphoid probes under various conditions of stringency show that the alphoid repeats of chimpanzee chromosome 22 are not closely related to those of human chromosome 21. Sequence analysis of cloned dimer and tetramer EcoRI fragments from chimpanzee chromosome 22 confirm the low overall level of homology, but reveal the presence of several nucleotide changes which are exclusive to the chromosome 21 subfamily of human alphoid DNA. Southern blot analysis of alphoid repeat DNA on the chimpanzee X chromosome suggests this subfamily has been strongly conserved during and since the separation of chimpanzee and man although the two subfamilies can be distinguished on the basis of Taq I restriction fragments.     

Molecular Characterization of Lengthy Mitochondrial DNA Duplications from the Parasitic Nematode Romanomermis Culicivorax

Complete nucleotide sequences, precise endpoints and coding potential of several 3.0-kilobase mitochondrial DNA (mtDNA) repeating units derived from two isofemale lineages of the mermithid nematode Romanomermis culicivorax have been determined. Endpoint analysis has allowed us to infer deletion and inversion events that most likely generated the present day repeat configuration. Each amplified unit contains the genes for NADH dehydrogenase subunits 3 and 6 (ND3 and ND6), an open reading frame (ORF 1) that represents a cytochrome P450-like gene, and three additional unidentified open reading frames. The primary nucleotide sequences of the R. culicivorax mt-repeat copies within individual haplotypes are highly conserved; three nearly complete copies of the repeat unit vary by 0.01% at the nucleotide level. These observations suggest that concerted evolution mechanisms may be active, resulting in sequence homogenation of these lengthy duplications.     

Structure, organization, and sequence of alpha satellite DNA from human chromosome 17: evidence for evolution by unequal crossing-over and an ancestral pentamer repeat shared with the human X chromosome.

The centromeric regions of all human chromosomes are characterized by distinct subsets of a diverse tandemly repeated DNA family, alpha satellite. On human chromosome 17, the predominant form of alpha satellite is a 2.7-kilobase-pair higher-order repeat unit consisting of 16 alphoid monomers. We present the complete nucleotide sequence of the 16-monomer repeat, which is present in 500 to 1,000 copies per chromosome 17, as well as that of a less abundant 15-monomer repeat, also from chromosome 17. These repeat units were approximately 98% identical in sequence, differing by the exclusion of precisely 1 monomer from the 15-monomer repeat. Homologous unequal crossing-over is suggested as a probable mechanism by which the different repeat lengths on chromosome 17 were generated, and the putative site of such a recombination event is identified. The monomer organization of the chromosome 17 higher-order repeat unit is based, in part, on tandemly repeated pentamers. A similar pentameric suborganization has been previously demonstrated for alpha satellite of the human X chromosome. Despite the organizational similarities, substantial sequence divergence distinguishes these subsets. Hybridization experiments indicate that the chromosome 17 and X subsets are more similar to each other than to the subsets found on several other human chromosomes. We suggest that the chromosome 17 and X alpha satellite subsets may be related components of a larger alphoid subfamily which have evolved from a common ancestral repeat into the contemporary chromosome-specific subsets.     

Sequence heterogeneity of the human alphoid satellite DNA and thermal stability of mismatched alphoid DNA duplexes

1. 340 bp (dimer) and 680 bp (tetramer) fractions of the human alphoid satellite DNA (h alpha RI DNA) were isolated after complete cleavage of total human DNA with EcoR I and cloned in pBR 32.5. 2. Ten clones containing 340 bp inserts and one clone containing 680 bp insert were sequenced in order to investigate the sequence heterogeneity of this satellite DNA and the sequence data were compared with the consensus h alpha RI DNA sequence of Wu and Manuelidis (1980). 3. It was shown that in all clones studied the mutations are nonrandomly distributed along the human alphoid monomers forming distinct conservative and variable regions. 4. This mutation distribution pattern was compared with the nucleotide variations between the consensus sequences of different primate alphoid DNAs and it was found that the interspecies nucleotide divergency of this satellite DNA is quite similar to the intragenomic one. 5. The sequenced h alpha RI DNA clones were used for preparation of DNA-DNA hybrids with a known percentage of base pair mismatching. 6. These hybrids were melted on hydroxyapatite (HAP) and the results obtained were used to determine the relationship between the thermal stability (Tm) and the extent of base pair mismatching for naturally diverged DNA sequences. 7. A value of 0.7 degrees C decrease in Tm per 1% base pair mismatching was found.     

Normal variants of human mitochondrial DNA and translation products: the building of a reference data base

Summary A good standard reference for the highly polymorphic human mitochondrial DNA (mtDNA) sequence is essential for studies of normal and disease-related nucleotide variants in the mitochondrial genome. A consensus sequence for the human mitochondrial genome has been derived from thirteen unrelated mtDNA sequences. We report 128 nucleotide variants of the human mtDNA sequence, and 62 amino acid variants of the human mitochondrial translation products, observed in the coding region of these mtDNA sequences.