Identification of novel CR1 subfamilies in an avian order with recently active elements

Chicken repeat 1 (CR1) is a taxonomically widespread non-LTR retrotransposon. Recent CR1 retrotranspositions in waterfowl suggested that, unlike chicken at least one subfamily remains active. Based on sequence information from 143 CR1 loci, six distinct groups of CR1 within the waterfowl coscoroba each with unique 3′ untranslated regions and distinct open reading frames are described. Through comparison to other previously described avian CR1 subfamilies, it is shown that five of the six coscoroba groups represent new subfamilies. At least one of these subfamilies is likely active and provides a target for future isolation of the first active member of this taxonomically widespread non-LTR family.     

More taxa,more characters: the hoatzin problem is still unresolved

The apparently rapid and ancient diversification of many avian orders complicates the resolution of their relationships using molecular data. Recent studies based on complete mitochondrial DNA (mtDNA) sequences or shorter lengths of nuclear sequence have helped corroborate the basic structure of the avian tree (e.g., a basal split between Paleognathae and Neognathae) but have made relatively little progress in resolving relationships among the many orders within Neoaves. We explored the potential of a moderately sized mtDNA data set ( approximately 5000 bp for each of 41 taxa), supplemented with data from a nuclear intron ( approximately 700 bp per taxon), to resolve relationships among avian orders. Our sampling of taxa addresses two issues: (1). the sister relationship and monophyly, respectively, of Anseriformes and Galliformes and (2). relationships of the enigmatic hoatzin Opisthocomus hoazin. Our analyses support a basal split between Galloanserae and Neoaves within Neognathae and monophyly of both Galliformes and Anseriformes. Within Galliformes, megapodes and then cracids branch basally. Within Anseriformes, mitochondrial data support a screamer (Anhimidae) plus magpie goose (Anseranatidae) clade. This result, however, may be an artifact of divergent base composition in one of the two anatids we sampled. With deletion of the latter taxon, Anseranas is sister to anatids as in traditional arrangements and recent morphological studies. Although our data provide limited resolution of relationships within Neoaves, we find no support for a sister relationship between either cuckoos (Cuculiformes) or turacos (Musophagiformes) and hoatzin. Both mitochondrial and nuclear data are consistent with a relationship between hoatzin and doves (Columbiformes), although this result is weakly supported. We also show that mtDNA sequences reported in another recent study included pervasive errors that biased the analysis towards finding a sister relationship between hoatzin and turacos.     

家鹅线粒体tRNAthr与tRNApro序列与结构分析

本研究采用PCR和DNA测序技术测定了6个中国家鹅品种和2个欧洲鹅品种25个个体线粒体DNA tRNApro（69bp）和tRNAthr（68bp）基因的完整序列,通过对家鹅线粒体基因组的研究,首次报道了家鹅线粒体tRNApro和tRNAthr基因的结构,对鸿雁家鹅、灰雁家鹅、白额雁（Anser albifrons,序列号为AF363031）种间的tRNApro和tRNAthr基因的二级结构及序列的变异特征进行了分析,并通过家鸡（Gallus gallus domesticus,序列号为NC001323）与鸿雁家鹅间tRNApro和tRNAthr基因二级结构的比较,初步进行了鸡形目与雁形目两个目间tRNApro和tRNAthr基因二级结构及序列变异的分析。结果表明：家鹅tRNApro和tRNAthr基因均可折叠成标准的三叶草形二级结构; 2个tRNA基因三叶草结构的氨基酸臂、反密码子环在鸿雁、灰雁和白额雁种间以及鸡形目与雁形目两个目间没有发生变异,具有高度的保守性。本研究的结果将为进一步探讨家鹅线粒体DNA tRNApro和tRNAthr基因序列与结构、功能的关系奠定基础。所测定的基因序列已登录国际GenBank数据库,序列号为AY427800～AY427805和AY427812～AY427814。     

NfCR1, the first non-LTR retrotransposon characterized in the Australian lungfish genome, Neoceratodus forsteri, shows similarities to CR1-like elements

The genomes of lungfish, together with those of some urodele amphibians, are the largest of all vertebrate genomes. It has been assumed that the bulk of the DNA making up these large genomes has been derived from repeat elements, like the noncoding DNA of those genomes that have been sequenced (e.g., human). In an attempt to characterize repeat sequences in the lungfish genome, we have isolated, by restriction enzyme digestion of genomic DNA, sequences of a repeat element in Neoceratodus forsteri, the most primitive of the living lungfishes. The fragments sequenced from the EcoRI and BglII digests were used to perform genome walking PCR in order to obtain the full sequence of the repeat element. This element shares homology with the non-LTR (LINE) element, Chicken Repeat 1 (CR1), described for several vertebrates and some invertebrates; we have called it N. forsteri CR1 (NfCR1). NfCR1 shares all the domains of other CR1 elements but it also has several unique features that suggest it may no longer be active in the lungfish genome. It occurs in both full-length and 5'-truncated versions and in its present "inactive" form represents approximately 0.05% of the lungfish genome.     

A CR1 element is embedded in a novel tandem repeat (HinfI repeat) within the chicken genome.

Highly repetitive DNA sequences constitute a significant portion of most eukaryotic genomes, raising questions about their evolutionary origins and amplification dynamics. In this study, a novel chicken repetitive DNA family, the HinfI repeat, was characterized. The basic repeating unit of this family displays a uniform length of 770 bp, which was defined by the recognition site of HinfI. The HinfI repeat was specifically localized in the pericentric region of chromosome 4 by fluorescence in situ hybridization and constitutes 0.51% of the chicken genome. Interestingly, a chicken repeat 1 (CR1) element has been identified within this basic repeating unit. Like other CR1 elements, this CR1 element also displays typical retrotransposition characteristics, including a highly conserved 3' region and a badly truncated 5' end. This direct evidence from sequence analysis, together with our Southern blot results, suggests that the HinfI repeat may originate from a unique region containing a retrotransposed CR1 element.     

A new repetitive element of the CR1 family downstream of the chicken vitellogenin gene.

We have analyzed a repetitive DNA sequence found in the 3'-flanking region of the chicken vitellogenin gene. By its sequence, the repetitive DNA has been identified as a hitherto unreported member of the chicken CR1 family of repetitive elements. The CR1 sequence displays the structural characteristics of a long terminal repeat located at the 3' end of an avian retrovirus. The CR1 element lies 2.2 kb downstream of the vitellogenin gene and 'points' away from the gene rather than toward it. In this respect, this element differs from other CR1 repeats. The CR1 element is embedded in a region showing changes in chromatin structure implying a potential role for this sequence in determining the structural state of the local chromatin.     

DNA sequence analysis of a 5.27-kb direct repeat occurring adjacent to the regions of S-episome homology in maize mitochondria.

The DNA sequence of the 5270-bp repeated DNA element from the mitochondrial genome of the fertile cytoplasm of maize has been determined. The repeat is a major site of recombination within the mitochondrial genome and sequences related to the R1(S1) and R2(S2) linear episomes reside immediately adjacent to the repeat. The terminal inverted repeats of the R1 and R2 homologous sequences form one of the two boundaries of the repeat. Frame-shift mutations have introduced 11 translation termination codons into the transcribed S2/R2 URFI gene. The repeated sequence, though recombinantly active, appears to serve no biological function.     

Phylogenetic relationships based on two mitochondrial genes and hybridization patterns in Anatidae

We produced DNA sequence data from two mitochondrial genes (cytochrome b and the NADH dehydrogenase subunit 2) to reconstruct the phylogenetic relationships among 121 species of the Anseriformes (waterfowls including ducks, geese, swans, the magpie goose and screamers). Phylogenetic analyses converged into a congruent topology and defined several well-supported clades. We calibrated a molecular clock and reconstructed ancestral biogeographical areas using Bayesian inference supporting an austral continental (Gondwanaland) origin of the waterfowls. Ducks, swans and geese might have diversified during the Miocene (23–5 Myr ago) reaching northern distributions in Holarctic and Afrotropical regions. The evolution of hybridization patterns in Anseriformes has been investigated using a cladistic analysis (morphology), which may underestimate or overestimate the phylogenetic divergence among species, or restricted only to ducks. Using a phylogenetic framework, genetic-based distances and a Bayesian time calibration, our data support the hypothesis based on immunological distances of slow rate of appearance of reproductive incompatibilities in waterfowls compared with other vertebrates and the view that these birds may be like frogs in having lost their interspecific hybridization potential more slowly than mammals.     

Insertion events of CR1 retrotransposable elements elucidate the phylogenetic branching order in galliform birds

Using standard phylogenetic methods, it can be hard to resolve the order in which speciation events took place when new lineages evolved in the distant past and within a short time frame. As an example, phylogenies of galliform birds (including well-known species such as chicken, turkey, and quail) usually show low bootstrap support values at short internal branches, reflecting the rapid diversification of these birds in the Eocene. However, given the key role of chicken and related poultry species in agricultural, evolutionary, general biological and disease studies, it is important to know their internal relationships. Recently, insertion patterns of transposable elements such as long and short interspersed nuclear element markers have proved powerful in revealing branching orders of difficult phylogenies. Here we decipher the order of speciation events in a group of 27 galliform species based on insertion events of chicken repeat 1 (CR1) transposable elements. Forty-four CR1 marker loci were identified from the draft sequence of the chicken genome, and from turkey BAC clone sequence, and the presence or absence of markers across species was investigated via electrophoretic size separation of amplification products and subsequent confirmation by DNA sequencing. Thirty markers proved possible to type with electrophoresis of which 20 were phylogenetically informative. The distribution of these repeat elements supported a single homoplasy-free cladogram, which confirmed that megapodes, cracids, New World quail, and guinea fowl form outgroups to Phasianidae and that quails, pheasants, and partridges are each polyphyletic groups. Importantly, we show that chicken is an outgroup to turkey and quail, an observation which does not have significant support from previous DNA sequence- and DNA-DNA hybridization-based trees and has important implications for evolutionary studies based on sequence or karyotype data from galliforms. We discuss the potential and limitations of using a genome-based retrotransposon approach in resolving problematic phylogenies among birds.     

Germ line insertion of mtDNA at the breakpoint junction of a reciprocal constitutional translocation

Constitutional chromosomal translocations are relatively common causes of human morbidity, yet the DNA double-strand break (DSB) repair mechanisms that generate them are incompletely understood. We cloned, sequenced and analyzed the breakpoint junctions of a familial constitutional reciprocal translocation t(9;11)(p24;q23). Within the 10-kb region flanking the breakpoints, chromosome 11 had 25% repeat elements, whereas chromosome 9 had 98% repeats, 95% of which were L1-type LINE elements. The breakpoints occurred within an L1-type repeat element at 9p24 and at the 3'-end of an Alu sequence at 11q23. At the breakpoint junction of derivative chromosome 9, we discovered an unusually large 41-bp insertion, which showed 100% identity to 12S mitochondrial DNA (mtDNA) between nucleotides 896 and 936 of the mtDNA sequence. Analysis of the human genome failed to show the preexistence of the inserted sequence at normal chromosomes 9 and 11 breakpoint junctions or elsewhere in the genome, strongly suggesting that the insertion was derived from human mtDNA and captured into the junction during the DSB repair process. To our knowledge, these findings represent the first observation of spontaneous germ line insertion of modern human mtDNA sequences and suggest that DSB repair may play a role in inter-organellar gene transfer in vivo. Our findings also provide evidence for a previously unrecognized insertional mechanism in human, by which non-mobile extra-chromosomal fragments can be inserted into the genome at DSB repair junctions.     

DNA element of Corynebacterium diphtheriae with properties of an insertion sequence and usefulness for epidemiological studies.

The segment of DNA which is inserted within the tox gene of bacteriophage gamma and is responsible for its Tox- phenotype was found to be present and repeated approximately 30 times in the chromosome of Corynebacterium diphtheriae Belfanti 1030. Other C. diphtheriae strains contained a variable number of copies (1 to 25) of the same element. Sequence analysis showed that this repeated and interspersed DNA element was flanked by 9-base-pair direct repeats and that the 5' and 3' ends of the insertion contained sequences forming an imperfect inverted repeat. Therefore, the DNA segment here described has most of the typical structural features of a bacterial insertion sequence element. We show that different C. diphtheriae isolates derived from the same outbreak of diphtheria have an identical genomic distribution of this DNA element and that such DNA can be useful for epidemiological studies.     

Chromosomal studies on Coscoroba coscoroba (Aves: Anseriformes) reinforce the Coscoroba–Cereopsis clade

The Coscoroba (Coscoroba coscoroba), endemic to southern South America, is traditionally considered as an early branch from the common ancestor leading to true geese and swans. Recently, an interesting association between the Coscoroba and Cape Barren goose (Cereopsis novaehollandiae) as sister groups has been proposed. We present here the characterization of the karyotype of C. coscoroba using whole chromosome probes derived from Gallus gallus macrochromosomes. Our data showed that C. coscoroba has the highest diploid number among Anseriformes (2n = 98), and the conservation of macrochromosome pairs 1–10 indicates that the increase in diploid number has occurred by fission events involving only the microchromosomes. Moreover, the similarity between the diploid numbers of C. coscoroba (2n = 98) and Cereopsis novaehollandiae (2n = 92) reinforces the phylogenetic position of these two species as sister groups, considering that other species of geese and swans have diploid numbers close to 2n = 80. © 2013 The Linnean Society of London, Biological Journal of the Linnean Society, 2014, 111 , 274–279.     

L1 repeat elements in the human epsilon-G gamma-globin gene intergenic region: sequence analysis and concerted evolution within this family

We have deduced the sequence of a composite long interspersed repeated DNA in primates and herein describe its relationship to a complex repeat element (L1Heg) located in the interval linking the human epsilon- and G gamma-globin genes. The main element of L1Heg is 3' truncated and interrupted by the insertion of the 3' end of a second L1 element. Transposition of L1Heg into this intergenic locus generated a 62-bp duplication of flanking sequences. In contrast, insertion of the second repeat may have been mediated by homology between donor and target sequences. The main repeat represents a novel class of abundant elements whose sequences have diverged from other rodent and primate LINES approximately 1.3 kb downstream from the 5' terminus of L1Heg. Comparison of L1Heg with the sequences of two other related L1 members revealed a complex set of rearrangements confined within a region that resembles the long terminal repeats of other types of retroposons. The boundaries of conversion-like events were defined on the basis of the clustering of nucleotide sequence variants common to two or more nonallelic 3' L1H elements. Several of these events are apparently initiated or resolved within a common 150-bp region that coincides with the 3' terminus of a pan-mammalian open reading frame. This analysis showed that concerted genetic interactions and random drift both contribute appreciably to sequence variation within this set of L1H members.     

Mitochondrial haplogroups, control region polymorphisms and malignant melanoma: a study in middle European Caucasians

Background

Because mitochondria play an essential role in energy metabolism, generation of reactive oxygen species (ROS), and apoptosis, sequence variation in the mitochondrial genome has been postulated to be a contributing factor to the etiology of multifactorial age-related diseases, including cancer. The aim of the present study was to compare the frequencies of mitochondrial DNA (mtDNA) haplogroups as well as control region (CR) polymorphisms of patients with malignant melanoma (n = 351) versus those of healthy controls (n = 1598) in Middle Europe.

Methodology and Principal Findings

Using primer extension analysis and DNA sequencing, we identified all nine major European mitochondrial haplogroups and known CR polymorphisms. The frequencies of the major mitochondrial haplogroups did not differ significantly between patients and control subjects, whereas the frequencies of the one another linked CR polymorphisms A16183C, T16189C, C16192T, C16270T and T195C were significantly higher in patients with melanoma compared to the controls. Regarding clinical characteristics of the patient cohort, none of the nine major European haplogroups was associated with either Breslow thickness or distant metastasis. The CR polymorphisms A302CC-insertion and T310C-insertion were significantly associated with mean Breslow thickness, whereas the CR polymorphism T16519C was associated with metastasis.

Conclusions and Significance

Our results suggest that mtDNA variations could be involved in melanoma etiology and pathogenesis, although the functional consequence of CR polymorphisms remains to be elucidated.     

A molecular phylogeny of anseriformes based on mitochondrial DNA analysis

To study the phylogenetic relationships among Anseriformes, sequences for the complete mitochondrial control region (CR) were determined from 45 waterfowl representing 24 genera, i.e., half of the existing genera. To confirm the results based on CR analysis we also analyzed representative species based on two mitochondrial protein-coding genes, cytochrome b (cytb) and NADH dehydrogenase subunit 2 (ND2). These data allowed us to construct a robust phylogeny of the Anseriformes and to compare it with existing phylogenies based on morphological or molecular data. Chauna and Dendrocygna were identified as early offshoots of the Anseriformes. All the remaining taxa fell into two clades that correspond to the two subfamilies Anatinae and Anserinae. Within Anserinae Branta and Anser cluster together, whereas Coscoroba, Cygnus, and Cereopsis form a relatively weak clade with Cygnus diverging first. Five clades are clearly recognizable among Anatinae: (i) the Anatini with Anas and Lophonetta; (ii) the Aythyini with Aythya and Netta; (iii) the Cairinini with Cairina and Aix; (iv) the Mergini with Mergus, Bucephala, Melanitta, Callonetta, Somateria, and Clangula, and (v) the Tadornini with Tadorna, Chloephaga, and Alopochen. The Tadornini diverged early on from the Anatinae; then the Mergini and a large group that comprises the Anatini, Aythyini, Cairinini, and two isolated genera, Chenonetta and Marmaronetta, diverged. The phylogeny obtained with the control region appears more robust than the one obtained with mitochondrial protein-coding genes such as ND2 and cytb. This suggests that the CR is a powerful tool for bird phylogeny, not only at a small scale (i.e., relationships between species) but also at the family level. Whereas morphological analysis effectively resolved the split between Anatinae and Anserinae and the existence of some of the clades, the precise composition of the clades are different when morphological and molecular data are compared.     

Molecular phylogeny of silkmoths reveals the origin of domesticated silkmoth, Bombyx mori from Chinese Bombyx mandarina and paternal inheritance of Antheraea proylei mitochondrial DNA

Molecular phylogeny of some of the economically important silkmoths was derived using three mitochondrial genes, 12S rRNA, 16S rRNA, and COI, and the control region (CR). Maximum likelihood (ML) analyses showed two distinct clades, one consisting of moths from Bombycidae family and the other from Saturniidae family. The mitochondrial CR showed length polymorphisms with indels. The ML analyses for complete mitochondrial genome sequences of Bombyx mori (strains Aojuku, C108, Backokjam, and Xiafang), Japanese and Chinese strains of B. mandarina (Japanese mandarina and Chinese mandarina) and, Antheraea pernyi revealed two distinct clades, one comprising of B. mori strains and the other with B. mandarina, and A. pernyi forming an outgroup. Pairwise distances revealed that all of the strains of B. mori studied are closer to Chinese than to Japanese mandarina. Phylogenetic analyses based on whole mitochondrial genome sequences, the finding of a tandem triplication of a 126bp repeat element only in Japanese mandarina, and chromosome number variation in B. mandarina suggest that B. mori must have shared its recent common ancestor with Chinese mandarina. Another wild species of the Bombycidae family, Theophila religiosa, whose phylogenetic status was not clear, clustered together with the other bombycid moths in the study. Analysis of the interspecific hybrid, A. proylei gave evidence for paternal inheritance of mitochondrial DNA.     

Sequence, organization, and evolution of the A+T region of Drosophila melanogaster mitochondrial DNA

The long (4.6-kb) A+T region of Drosophila melanogaster mitochondrial DNA has been cloned and sequenced. The A+T region is organized in two large arrays of tandemly repeated DNA sequence elements, with nonrepetitive intervening and flanking sequences comprising only 22% of its length. The first repeat array consists of five repeats of 338-373 bp. The second consists of four intact 464-bp repeats and a fifth partial repeat of 137 bp. Three DNA sequence elements are found to be highly conserved in D. melanogaster and in several Drosophila species with short A+T regions. These include a 300-bp DNA sequence element that overlaps the DNA replication origin and two thymidylate stretches identified on opposite DNA strands. We conclude that the length heterogeneity observed in the A+T regulatory region in mitochondrial DNAs from the genus Drosophila results from the expansion (and contraction) of the number of repeated DNA sequence elements. We also propose that the 300-bp conserved DNA sequence element, in conjunction with another primary sequence determinant, perhaps the adjacent thymidylate stretch, functions in the regulation of mitochondrial DNA replication.