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.     

The intragenomic polymorphism of a partially inverted repeat (PIR) in Gallus gallus domesticus, potential role of inverted repeats in satellite DNAs evolution

We report here the molecular characterization of the basic repeating unit of a novel repetitive family, partially inverted repeat (PIR), previously identified from chicken genome. This repetitive DNA family shares a close evolutionary relationship with XhoI/EcoRI repeats and chicken nuclear-membrane-associated (CNM) repeat. Sequence analyses reveal the 1430 bp basic repeating unit can be divided into two regions: the central region ( approximately 1000 bp) and the flanking region ( approximately 430 bp). Within the central region, a pair of repeats (86 bp) flanks the central core ( approximately 828 bp) in inversed orientation. Due to the tandem array feature shared by the repeating units, the inverted repeats fall between the central core and flanking region. Southern blot analyses further reveal the intragenomic polymorphism of PIR, and the molecular size of repeating units ranges from 1.1 kb to 1.6 kb. The identified monomer variants may result from multiple crossing-over events, implying the potential roles of inverted repeats in satellite DNAs variation.     

Organization, sequence and nuclease hypersensitivity of repetitive elements flanking the chicken apoVLDLII gene: extended sequence similarity to elements flanking the chicken vitellogenin gene.

Analysis of nuclease hypersensitivity of regions flanking the estrogen-dependent, chicken apoVLDLII gene has revealed an hepatic, DNaseI hypersensitive site whose sensitivity is influenced by both the developmental stage and sex of the bird. The site is located 3.0kb upstream from the gene, in a block of middle repetitive elements. Contact hybridization studies indicate that the block consists of contiguous copies of two elements with reiteration frequencies of 500-1000 and 10,000-30,000 copies per haploid genome. Sequencing of 1.8kb spanning the repeats has revealed that the higher frequency element is a member of the CR1 family. The adjacent lower frequency repeat can also be found next to another member of the CR1 family located in the 3' flanking region of the vitellogenin gene. The hypersensitive site has been mapped to one of the two most highly conserved regions of the CR1 element. This region displays homology with a silencer sequence recently identified in a CR1 element flanking the chicken lysozyme gene.     

Association of a truncated cytochrome c processed pseudogene with a similarly truncated member from a long interspersed repeat family of rat.

The cytochrome c multigene family of rat contains approximately 30 processed pseudogenes that represent genomic DNA copies of three alternate mRNAs. Here, the DNA sequence of an unusual processed pseudogene reveals that it has a complete 3' noncoding region including a short poly A tail but unlike the others is abruptly truncated at its 5' end, 19 amino acid codons from the translation terminator. At this position the pseudogene is fused through 17 consecutive adenylic acid residues to a 1.3 kb repetitive sequence. This repetitive element is flanked by direct repeats and represents a truncated member from a major long interspersed repeat family. The rat element is a composite of sequences observed in long interspersed repeats from both rodents and primates. Comparison to the equivalent mouse sequences shows that the 5' half of the repeat distal to the pseudogene has an open reading frame and is highly conserved whereas the half adjacent to the pseudogene is evolutionarily unstable. The proportion of cytochrome c pseudogene recombinant clones containing this repetitive DNA is 3 fold greater than observed in random isolates and may reflect a general tendency of processed pseudogenes to associate with other repetitive sequences in the genome.     

Evidence that chicken CR1 elements represent a novel family of retroposons.

We report the first precise delineation of a chicken CR1 element and show that it is flanked by a 6-base-pair target site duplication that occurred when this repetitive element transposed. The 3' end of this CR1 element is defined by an 8-base-pair imperfect direct repeat, and we infer that this sequence represents the 3' end of all intact CR1 elements. In contrast, the 5' ends are not unique, and we argue that this variation existed at the time each element transposed. We also provide evidence that CR1 elements transposed into preferred target sites. CR1 elements therefore appear to represent a novel class of passive retroposons.     

New tandem repeat region in the non-transcribed spacer of human ribosomal RNA gene.

A new repetitive DNA region was identified in the non-transcribed spacer of human rDNA, namely a long (4.6 kb) sequence motif (Xbal element) was present in two copies. The repeating unit composed of two parts. One of them consisted of unique nucleotide sequences, interrupted by some simple sequences. The other, about 3.1 kb long one assembled only from highly repeated simple sequences. The unique sequence region contained two, inverted copies of the human AluI type repetitive DNA family. The authors suggest that the XbaI elements may flank the tandem arrays of human rRNA genes as terminal repeats and they might function both as the origin of rDNA replication and/or site of homologous recombination.     

Tandem repeat DNA localizing on the proximal DAPI bands of chromosomes in Larix, Pinaceae.

Repetitive DNA was cloned from HindIII-digested genomic DNA of Larix leptolepis. The repetitive DNA was about 170 bp long, had an AT content of 67%, and was organized tandemly in the genome. Using fluorescence in situ hybridization and subsequent DAPI banding, the repetitive DNA was localized in DAPI bands at the proximal region of one arm of chromosomes in L. leptolepis and Larix chinensis. Southern blot hybridization to genomic DNA of seven species and five varieties probed with cloned repetitive DNA showed that the repetitive DNA family was present in a tandem organization in genomes of all Larix taxa examined. In addition to the 170-bp sequence, a 220-bp sequence belonging to the same DNA family was also present in 10 taxa. The 220-bp repeat unit was a partial duplication of the 170-bp repeat unit. The 220-bp repeat unit was more abundant in L. chinensis and Larix potaninii var. macrocarpa than in other taxa. The repetitive DNA composed 2.0-3.4% of the genome in most taxa and 0.3 and 0.5% of the genome in L. chinensis and L. potaninii var. macrocarpa, respectively. The unique distribution of the 220-bp repeat unit in Larix indicates the close relationship of these two species. In the family Pinaceae, the LPD (Larix proximal DAPI band specific repeat sequence family) family sequence is widely distributed, but their amount is very small except in the genus Larix. The abundant LPD family in Larix will occur after its speciation.     

Mer22-related sequence elements form pericentric repetitive DNA families in primates

We describe a novel repetitive DNA element isolated from three primate species belonging to the family Cercopithecidae. The unusually long 2.6-kb repeat unit of this DNA element is present in high copy number in the pericentromeric region of one pair of chromosomes in both baboon and macaque, forming chromosome-specific satellite-like DNA families. Besides these two very closely related species, the novel DNA element was also detected in the more distantly related African green monkey. However, the copy number of the repeat unit in this species is significantly lower than in macaque and baboon. Sequence analysis revealed that the repeat units of the new repetitive element show similarity to the human MER22 repeat and the Y chromosome-specific TTY2 element, which also exhibits retroelement-like features. Database searches indicate that tandemly arranged MER22-related DNA sequences can also be found in human, raising the possibility that these DNA elements may correspond to a novel primate-specific repetitive DNA group. Recent studies indicate that chromosome-specific pericentric repetitive elements, besides their potential involvement in centromere function, also facilitate homolog recognition during meiosis. In addition, rapid expansion of retroelements in the pericentric regions of chromosomes during interspecific hybridization has been described. In light of these data, we hypothesize that the novel repetitive element described here might have been involved in the speciation of the family Cercopithecidae.     

Characterization of CR1 repeat random PCR markers for mapping the chicken genome

Polymerase chain reaction (PCR) primers complementary to portions of the chicken repetitive element CR1 have been used previously to generate useful markers on the chicken genome linkage map. To understand better the genetic basis for this technique and to convert CR1–PCR loci to markers useful in physical genome mapping, five polymorphic CR1–PCR-generated DNAs were cloned and partially sequenced. Inverse PCR was then employed to clone the corresponding region of the genomes of both the Jungle Fowl (JF) and White Leghorn (WL) parental DNA templates. Our results demonstrate that some of the CR1–PCR-generated DNAs arise from priming at an endogenous CR1 element, whereas others are due to chance complementarity between the CR1–PCR primer in use and random annealing sites in the genome, unrelated to a demonstrable CR1 element. In all five instances, it was possible to identify the sequence difference between the JF and WL parental DNAs that gave rise to the initial polymorphism and design allele-specific PCR primer sets that uniquely detect that polymorphism. In four of the five instances, the polymorphism was a one or two basepair sequence difference within the primer annealing site, but in the fifth case the responsible difference was outside, but very close to, the annealing site. In all instances the allele-specific PCR for the sequence polymorphism mapped identically with the corresponding CR1–PCR amplification polymorphism. We conclude that CR1–PCR provides an efficient and reliable mechanism for genome mapping in avians that can correlate linkage and physical mapping approaches.     

DNase I sensitive domain of the gene coding for the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase

We have cloned a 36-kilobase segment of chicken DNA containing the gene coding for glyceraldehyde-3-phosphate dehydrogenase [GAPDH (EC 1.2.1.12)], a glycolytic enzyme which is expressed constitutively in all cell types. Using defined segments of this cloned DNA as probes, we have determined the DNase I sensitive domain of the GAPDH natural gene in the hen oviduct. When nuclei isolated from hen oviduct were treated with DNase I under conditions known to preferentially degrade actively transcribed genes (i.e., 15-20% of the DNA rendered perchloric acid soluble), a region of approximately 12 kilobase(s) (kb) containing the GAPDH coding sequences and flanking DNA was found to be highly susceptible to digestion by DNase I. Approximately 4 kb downstream from the end of the coding sequences, there was an abrupt transition from the DNase I sensitive or "open" configuration to the resistant or "closed" configuration. The chromatin then remained in a closed conformation for at least 10 kb further downstream. On the 5' side of the gene, the transition from a sensitive to a resistant configuration was located about 4 kb upstream from the gene. In addition, we have localized two repeated sequences in the area of DNA that was cloned. One of these is of the CR1 family of middle repetitive elements. It is located about 18 kb 3' to the gene and as such lies well outside of the DNase I sensitive region which encompasses GAPDH. The other repetitive element is of an uncharacterized family. It is located upstream from the gene and appears to be within a region of transition from the DNase I sensitive to resistant states.     

Molecular characterization of a mouse genomic element mobilized by advanced glycation endproduct modified-DNA (AGE-DNA).

BACKGROUND: DNA modified by advanced glycation endproducts (AGEs) undergoes a high frequency of insertional mutagenesis. In mouse lymphoid cells, these mutations are due in part to the transposition of host genomic elements that contain a DNA region homologous to the Alu family of repetitive elements. One particular 853 bp insertion, designated INS-1, was identified previously as a DNA element common to plasmids recovered from multiple, independent lymphoid cell transfections. MATERIALS AND METHODS: To characterize the genomic origin of this element, we used a 281-bp region of non-Alu-containing INS-1 sequence, designated. CORE, as a probe in Southern hybridization and for screening a bacteriophage mouse genomic DNA library. The resultant clones were sequenced and localized within the mouse genome. RESULTS: Two distinct genomic clones of 15 kB and 17 kB in size were isolated. A 522-bp unique region common to INS-1 and corresponding to the CORE sequence was identified in each clone. In both cases, CORE was found to be surrounded by repetitive DNA sequences: a 339-bp MT repeat at the 5' end, and a 150-bp B1 repeat at the 3' end. The CORE sequence was localized to mouse chromosome 1. CONCLUSIONS: These studies revealed that the CORE region of INS is present in low copy number but is associated with known repetitive DNA elements. The presence of these repetitive elements may facilitate the transposition of CORE by recombination or other, more complex rearrangement events, and explain in part the origin of AGE-induced insertional mutations.     

Molecular cloning and characterization of novel centromeric repetitive DNA sequences in the blue-breasted quail (Coturnix chinensis,Galliformes)

A new family of centromeric highly repetitive DNA sequences was isolated from EcoRI-digested genomic DNA of the blue-breasted quail (Coturnix chinensis, Galliformes), and characterized by filter hybridization and chromosome in situ hybridization. The repeated elements were divided into two types by nucleotide length and chromosomal distribution; the 578-bp element predominantly localized to microchromosomes and the 1,524-bp element localized to chromosomes 1 and 2. The 578-bp element represented tandem arrays and did not hybridize to genomic DNAs of other Galliformes species, chicken (Gallus gallus), Japanese quail (Coturnix japonica) and guinea fowl (Numida meleagris). On the other hand, the 1,524-bp element was not organized in tandem arrays, and did hybridize to the genomic DNAs of three other Galliformes species, suggesting that the 1,524-bp element is highly conserved in the Galliformes. The 578-bp element was composed of basic 20-bp internal repeats, and the consensus nucleotide sequence of the internal repeats had homologies to the 41-42 bp CNM repeat and the XHOI family repeat of chicken. Our data suggest that the microchromosome-specific highly repetitive sequences of the blue-breasted quail and chicken were derived from a common ancestral sequence, and that they are one of the major and essential components of chromosomal heterochromatin in Galliformes species.     

Isolation of a protein fraction that binds preferentially to chicken middle repetitive DNA

We have fractionated oviduct tissue extracts by using a combination of ion-exchange and DNA-Sephadex chromatography. By comparing the electrophoretic patterns of proteins eluted from competing specific and nonspecific DNA columns, we isolated a fraction which bound with specificity to columns containing the chicken middle repetitive sequence "CR1". This fraction showed a clear preference for binding to separate, cloned CR1 fragments derived from either the 5' or the 3' transition region of the ovalbumin gene domain when examined by using nitrocellulose filter binding assays. To localize the protein binding site, a CR1 clone was digested with various restriction enzymes, and the resulting fragments were examined for preferential protein binding. Results suggest that the binding site lies within a 39-nucleotide sequence which is highly conserved among different CR1 elements. This finding represents the first isolation of a protein which demonstrates a preference for binding to a middle repetitive sequence and suggests that this interaction may have a biological role. The DNA column competition adsorption method should have general application to the isolation of other gene-regulating proteins possessing DNA sequence preference.     

A recent chicken repeat 1 retrotransposition confirms the Coscoroba-Cape Barren goose clade

Chicken repeat 1 (CR1) is a member of the non-long terminal repeat class of retrotransposons. We have isolated a truncated CR1 element within the third intron of the lactate dehydrogenase B gene of the coscoroba and the Cape Barren goose (Anseriformes; Coscoroba coscoroba, Cereopsis novaehollandiae). Because the element was absent in orthologous loci within mallard (Anas platyrhynchos), snow goose (Anser caerulescens), and tundra swan (Cygnus columbianus), it provides strong support to the recent novel proposal by Donne-Goussé et al. [Donne-Goussé, C., Laudet, V., H?nni, C., 2002. A molecular phylogeny of anseriformes based on mitochondrial DNA analysis. Mol. Phylogenet. Evol. 23, 339-356] that Cape Barren goose is the sister taxon to coscoroba. The time of insertion was approximately 10.5 Mya or less estimated from mitochondrial DNA sequence information. Because this is a recent event, the DNA sequence of this CR1 should be close to that existing at the time of its insertion. This is reflected by the consistency of several structural features expected in a new CR1 copy such as the unaltered flanking target site duplication and inverted repeats that lie 22 bp apart near the 3' end of the element. Hybridization experiments show that numerous copies of sequences closely related to the coscoroba CR1 element are dispersed throughout the genomes of tested Anseriformes, but none were detected in representatives of Galliformes and Struthioniformes.