Evidence that chicken CR1 elements represent a novel family of retroposons

Transposons-Based Clonal Diversity in Trematode Involves Parts of CR1 (LINE) in Eu- and Heterochromatin

Trematode parthenitae have long been believed to form clonal populations, but clonal diversity has been discovered in this asexual stage of the lifecycle. Clonal polymorphism in the model species Himasthla elongata has been previously described, but the source of this phenomenon remains unknown. In this work, we traced cercarial clonal diversity using a simplified amplified fragment length polymorphism (SAFLP) method and characterised the nature of fragments in diverse electrophoretic bands. The repetitive elements were identified in both the primary sequence of the H. elongata genome and in the transcriptome data. Long-interspersed nuclear elements (LINEs) and long terminal repeat retrotransposons (LTRs) were found to represent an overwhelming majority of the genome and the transposon transcripts. Most sequenced fragments from SAFLP pattern contained the reverse transcriptase (RT, ORF2) domains of LINEs, and only a few sequences belonged to ORFs of LTRs and ORF1 of LINEs. A fragment corresponding to a CR1-like (LINE) spacer region was discovered and named CR1-renegade (CR1-rng). In addition to RT-containing CR1 transcripts, we found short CR1-rng transcripts in the redia transcriptome and short contigs in the mobilome. Probes against CR1-RT and CR1-rng presented strikingly different pictures in FISH mapping, despite both being fragments of CR1. In silico data and Southern blotting indicated that CR1-rng is not tandemly organised. CR1 involvement in clonal diversity is discussed.

Helitrons, the Eukaryotic Rolling-circle Transposable Elements

Helitrons, the eukaryotic rolling-circle transposable elements, are widespread but most prevalent among plant and animal genomes. Recent studies have identified three additional coding and structural variants of Helitrons called Helentrons, Proto-Helentron, and Helitron2. Helitrons and Helentrons make up a substantial fraction of many genomes where nonautonomous elements frequently outnumber the putative autonomous partner. This includes the previously ambiguously classified DINE-1-like repeats, which are highly abundant in Drosophila and many other animal genomes. The purpose of this review is to summarize what we have learned about Helitrons in the decade since their discovery. First, we describe the history of autonomous Helitrons, and their variants. Second, we explain the common coding features and difference in structure of canonical Helitrons versus the endonuclease-encoding Helentrons. Third, we review how Helitrons and Helentrons are classified and discuss why the system used for other transposable element families is not applicable. We also touch upon how genome-wide identification of candidate Helitrons is carried out and how to validate candidate Helitrons. We then shift our focus to a model of transposition and the report of an excision event. We discuss the different proposed models for the mechanism of gene capture. Finally, we will talk about where Helitrons are found, including discussions of vertical versus horizontal transfer, the propensity of Helitrons and Helentrons to capture and shuffle genes and how they impact the genome. We will end the review with a summary of open questions concerning the biology of this intriguing group of transposable elements.

DINE-1, the highest copy number repeats in Drosophila melanogaster are non-autonomous endonuclease-encoding rolling-circle transposable elements (Helentrons)

Background

The Drosophila INterspersed Elements-1 (DINE-1/INE1) transposable elements (TEs) are the most abundant component of the Drosophila melanogaster genome and have been associated with functional gene duplications. DINE-1 TEs do not encode any proteins (non-autonomous) thus are moved by autonomous partners. The identity of the autonomous partners has been a mystery. They have been allied to Helitrons (rolling-circle transposons), MITEs (DNA transposons), and non-LTR retrotransposons by different authors.

Results

We report multiple lines of bioinformatic evidence that illustrate the relationship of DINE-1 like TEs to endonuclease-encoding rolling-circle TEs (Helentrons). The structural features of Helentrons are described, which resemble the organization of the non-autonomous partners, but differ significantly from canonical Helitrons. In addition to the presence of an endonuclease domain fused to the Rep/Helicase protein, Helentrons have distinct structural features. Evidence is presented that illustrates that Helentrons are widely distributed in invertebrate, fish, and fungal genomes. We describe an intermediate family from the Phytophthora infestans genome that phylogenetically groups with Helentrons but that displays Helitron structure. In addition, evidence is presented that Helentrons can capture gene fragments in a pattern reminiscent of canonical Helitrons.

Conclusions

We illustrate the relationship of DINE-1 and related TE families to autonomous partners, the Helentrons. These findings will allow their proper classification and enable a more accurate understanding of the contribution of rolling-circle transposition to the birth of new genes, gene networks, and genome composition.

The role of LINEs and CpG islands in dosage compensation on the chicken Z chromosome

Most avian Z genes are expressed more highly in ZZ males than ZW females, suggesting that chromosome-wide mechanisms of dosage compensation have not evolved. Nevertheless, a small percentage of Z genes are expressed at similar levels in males and females, an indication that a yet unidentified mechanism compensates for the sex difference in copy number. Primary DNA sequences are thought to have a role in determining chromosome gene inactivation status on the mammalian X chromosome. However, it is currently unknown whether primary DNA sequences also mediate chicken Z gene compensation status. Using a combination of chicken DNA sequences and Z gene compensation profiles of 310 genes, we explored the relationship between Z gene compensation status and primary DNA sequence features. Statistical analysis of different Z chromosomal features revealed that long interspersed nuclear elements (LINEs) and CpG islands are enriched on the Z chromosome compared with 329 other DNA features. Linear support vector machine (SVM) classifiers, using primary DNA sequences, correctly predict the Z compensation status for >60% of all Z-linked genes. CpG islands appear to be the most accurate classifier and alone can correctly predict compensation of 63% of Z genes. We also show that LINE CR1 elements are enriched 2.7-fold on the chicken Z chromosome compared with autosomes and that chicken chromosomal length is highly correlated with percentage LINE content. However, the position of LINE elements is not significantly associated with dosage compensation status of Z genes. We also find a trend for a higher proportion of CpG islands in the region of the Z chromosome with the fewest dosage-compensated genes compared with the region containing the greatest concentration of compensated genes. Comparison between chicken and platypus genomes shows that LINE elements are not enriched on sex chromosomes in platypus, indicating that LINE accumulation is not a feature of all sex chromosomes. Our results suggest that CpG islands are not randomly distributed on the Z chromosome and may influence Z gene dosage compensation status.

Evolution of serum albumin intron-1 is shaped by a 5' truncated non-long terminal repeat retrotransposon in western Palearctic water frogs (Neobatrachia)

A 5' truncated non-LTR CR1-like retrotransposon, named RanaCR1, was identified in the serum albumin intron-1 (SAI-1) of at least seven species of western Palearctic water frogs (WPWF). Based on sequence similarity of the carboxy-terminal region (CTR) of ORF2 and/or the highly conserved 3' untranslated region (3' UTR), RanaCR1-like elements occur also in the genome of Xenopus tropicalis and Rana temporaria. Unlike other CR1 elements, RanaCR1 contains a CA microsatellite in its 3' UTR. The low nucleotide diversity of the 3' UTR compared to the CTR and to SAI-1 suggests that this region still plays a role in WPWF, either as a structure-stabilizing element, or within a species-specific transcriptional network. Length variation of water frog SAI-1 sequences is caused by deletions that extend in some cases beyond the 5' or 3' ends of RanaCR1, probably a result of selection for structural and functional stability of the primary transcript. The impact of RanaCR1 on SAI-1 evolution is also indicated by the significant negative correlation between the length of both SAI-1 and RanaCR1 and the percentage GC content of RanaCR1. Both SAI-1 and RanaCR1 sequences support the sister group relationship of R. perezi and R. saharica, which are placed in the phylogenetic tree at a basal position, the sister clade to other water frog taxa. It also supports the monophyly of the R. lessonae group; of Anatolian water frogs (R. cf. bedriagae), which are not conspecific with R. bedriagae, and of the European ridibunda group. Within the ridibunda clade, Greek frogs are clearly separated, supporting the hypothesis that Balkan water frogs represent a distinct species. Frogs from Atyrau (Kazakhstan), the type locality of R. ridibunda, were heterozygous for a ridibunda and a cf. bedriagae specific allele.

Phylogenomic Investigation of CR1 LINE Diversity in Reptiles

It is unlikely that taxonomically diverse phylogenetic studies will be completed rapidly in the near future for nonmodel organisms on a whole-genome basis. However, one approach to advancing the field of "phylogenomics" is to estimate the structure of poorly known genomes by mining libraries of clones from suites of taxa, rather than from single species. The present analysis adopts this approach by taking advantage of megabase-scale end-sequence scanning of reptilian genomic clones to characterize diversity of CR1-like LINEs, the dominant family of transposable elements (TEs) in the sister group of mammals. As such, it helps close an important gap in the literature on the molecular systematics and evolution of retroelements in nonavian reptiles. Results from aligning more than 14 Mb of sequence from the American alligator (Alligator mississippiensis), painted turtle (Chrysemys picta), Bahamian green anole (Anolis smaragdinus), Tuatara (Sphenodon punctatus), Emu (Dromaius novaehollandiae), and Zebra Finch (Taeniopygia guttata) against a comprehensive library approximately 3000 TE-encoding peptides reflect an increasing abundance of LINE and non-long-terminal-repeat (non-LTR) retrotransposon repeat types with the age of common ancestry among exemplar reptilian clades. The hypothesis that repeat diversity is correlated with basal metabolic rate was tested using comparative methods and a significant nonlinear relationship was indicated. This analysis suggests that the age of divergence between an exemplary clade and its sister group as well as metabolic correlates should be considered in addition to genome size in explaining patterns of retroelement diversity. The first phylogenetic analysis of the largely unexplored chicken repeat 1 (CR1) 3' reverse transcriptase (RT) conserved domains 8 and 9 in nonavian reptiles reveals a pattern of multiple lineages with variable branch lengths, suggesting presence of both old and young elements and the existence of several distinct well-supported clades not apparent from previous characterization of CR1 subfamily structure in birds and the turtle. This mode of CR1 evolution contrasts with historical patterns of LINE 1 diversification in mammals and hints toward the existence of a rich but still largely unexplored diversity of nonavian retroelements of importance to advancing both comparative vertebrate genomics and amniote systematics.

Specific chicken repeat 1 (CR1) retrotransposon insertion suggests phylogenetic affinity of rockfowls (genus Picathartes) to crows and ravens (Corvidae)

While the monophyly of the order Passeriformes as well as its suborders suboscines (Tyranni) and oscines (Passeri) is well established, both on morphological and molecular grounds, lower phylogenetic relationships have been a continuous matter of debate, especially within oscines. This is particularly true for the rockfowls (genus Picathartes), which phylogenetic classification has been an ongoing puzzle. Sequence-based molecular studies failed in deriving unambiguously resolved and supported hypotheses. We present here a novel approach: use of retrotransposon insertions as phylogenetic markers in passerine birds. Chicken repeat 1 (CR1) is the most important non-LTR retrotransposon in birds. We present two truncated CR1 loci in passerine birds, not only found in representatives of Corvinae (jays, crows and allies), but also in the West-African Picathartes species which provide new evidence for a closer relationship of these species to Corvidae than has previously been thought. Additionally, we show that not only the absence/presence pattern of a CR1 insertion, but also the CR1 sequences themselves contain phylogenetic information.

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.Key words: satellite DNA, CR1 retrotransposon, HinfI repeat, Gallus gallus.

Cytogenetic repartition of chicken CR1 sequences evidenced by PRINS in Galliformes and some other birds

Chicken repeat 1 (CR1) belongs to the non-long repeat class of retrotransposons. Nearly 100000 repeats interspersed in the chicken genome are subdivided into at least six distinct subfamilies, each 300 bp long and all sharing substantial sequence similarity. CR1-like elements were found in genomes from invertebrates to mammals, suggesting their importance for genome structure and/or function. Moreover, numerous data support the hypothesis of their implication in regulation of gene expression. So, the chromosomal distribution of these CR1 sequences in vertebrates is of great interest to improve our knowledge about the genome structure, function and evolution. A comparison of the cytogenetic distribution of CR1 sequences was performed by PRINS using consensus chicken primers on the chromosomes of chicken and species of several bird orders: Galliformes, Anseriformes, Passeriformes and Falconiformes. The study revealed that CR1 repeats are spread over nearly all chicken chromosomes with a higher density on the macrochromosomes and in particular with hot spots on subtelomeric regions of chromosome 1, 2, 3q, 4q, 5q. Their distribution on the macrochromosomes forms a kind of banding pattern, which was not systematically matched with R- or G-banding. This banding pattern appears to be conserved on the chromosomes of the Galliformes studied, irrespective of their karyotypes, rearranged or not. CR1 primers also show similar signals on the chromosomes of birds phylogenetically more distant (Anseriformes, Passeriformes and Falconiformes). This fact confirms the importance of these sequences at the large scale of bird evolution and in the chromosomal structure. The location of CR1 sequences, and in particular of the hot spots, mainly within the richest CG areas are in conformity with the data on an epigenetic role of these highly conserved sequences.

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., Hänni, 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.

A new pair of CR1-like LINE and tRNA-derived SINE elements in Podarcis sicula genome

We have identified and characterized a new pair of LINE and SINE elements, called Lucy-1 CR1-like LINE and P.s.1/SINE, respectively, in Podarcis sicula genome. The 3'-tail region in the 3' untranslated region (UTR) of Lucy-1 element is almost identical to the of P.s.1/SINE element. This identity suggests that the P.s.1/SINE element, during evolution, has gained the 3'-end sequence of the Lucy-1 element and has exclusively recruited the enzymatic machinery of its partner CR1 LINE for retroposition. Moreover, the complex molecular organization around Lucy-1 insertion site is discussed and we found that Lucy-1 insertion is associated with the calcium binding transporter gene. Our results confirm that the retrotransposons can be an additional source of genomic diversification and the evolution of the retrotransposable elements can be a vector force shaping genomes by reassorting DNA domains thus forming a new DNA arrangement.

Cell type-specific expression of LINE-1 open reading frames 1 and 2 in fetal and adult human tissues

The LINE-1 (L1) family of non-long terminal repeat retrotransposons is a major force shaping mammalian genomes, and its members can alter the genome in many ways. Mutational analyses have shown that coexpression of functional proteins encoded by the two L1-specific open reading frames, ORF1 and ORF2, is an essential prerequisite for the propagation of L1 elements in the genome. However, all efforts to identify ORF2-encoded proteins have failed so far. Here, applying a novel antibody we report the presence of proteins encoded by ORF2 in a subset of cellular components of human male gonads. Immunohistochemical analyses revealed coexpression of ORF1 and ORF2 in prespermatogonia of fetal testis, in germ cells of adult testis, and in distinct somatic cell types, such as Leydig, Sertoli, and vascular endothelial cells. Coexpression of both proteins in male germ cells is necessary for the observed genomic expansion of the number of L1 elements. Peptide mass fingerprinting analysis of a approximately 130-kDa polypeptide isolated from cultured human dermal microvascular endothelial cells led to the identification of ORF2-encoded peptides. An isolated approximately 45-kDa polypeptide was shown to derive from nonfunctional copies of ORF2 coding regions. The presence of both ORF1- and ORF2-encoded proteins in vascular endothelial cells and its apparent association with certain stages of differentiation and maturation of blood vessels may have functional relevance for vasculogenesis and/or angiogenesis.

Subfamilies of CR1 non-LTR retrotransposons have different 5'UTR sequences but are otherwise conserved

CR1 elements and CR1-related (CR1-like) elements are a novel family of non-LTR retrotransposons that are found in all vertebrates (reptilia, amphibia, fish, and mammals), whereas more distantly related elements are found in several invertebrate species. CR1 elements have several features that distinguish them from other non-LTR retrotransposons. Most notably, their 3' termini lack a polyadenylic acid (poly A) tail and instead contain 2-4 copies of a unique 8 bp repeat. CR1 elements are present at approximately 100,000 copies in the chicken genome. The vast majority of these elements are severely 5' truncated and mutated; however, six subfamilies (CR1-A through CR1-F) are resolved by sequence comparisons. One of these subfamilies (i.e. CR1-B) previously was analyzed in detail. In the present study, we identified several full-length elements from the CR1-F subfamily. Although regions within the open reading frames and 3' untranslated regions of CR1-F and CR1-B elements are well conserved, their respective 5' untranslated regions are unrelated. Thus, our results suggest that new CR1 subfamilies form when elements with intact open reading frames acquire new 5' UTRs, which could, in principle, function as promoters.

Maque, a family of extremely short interspersed repetitive elements: characterization, possible mechanism of transposition, and evolutionary implications

Database analysis revealed a novel family of very short interspersed repetitive elements named Maque in the African malaria mosquito, Anopheles gambiae. Past mobility of Maque was demonstrated by evidence of its insertion that resulted in a target duplication. Approximately 220 copies of Maque were present in the A. gambiae genome. Although only approximately 60 bp long, Maque has the appearance of a distinct transposition unit. Eleven of the 12 Maque elements found in the database were flanked by 9-14 bp direct repeats, indicating that their transposition was relatively recent. Sequence comparison and phylogenetic analyses suggest that there are at least two subgroups within the Maque family, suggesting that they may have been originated from more than one source. Five of the 12 Maque elements had at least one other repetitive element nearby. Three of the Maque elements were found near genes. However, Maque was not found in the coding regions of genes or in any of the expressed sequence tags (ESTs), which is consistent with its significantly biased distribution toward A + T rich regions. Several characteristics of Maque indicate that it is likely a non-autonomous retro-element. The evolutionary origin of Maque and the differences between Maque and other known retro-elements including short interspersed repetitive elements (SINEs) are discussed. A hypothesis is proposed in which short sequences containing just the reverse transcriptase recognition signal (RTRS) could potentially contribute to exon shuffling and the genesis of some primordial SINEs.

Evolutionary inventions and continuity of CORE-SINEs in mammals

We characterized short interspersed elements (SINEs), of the CORE-suprafamily in egg-laying (monotremes), pouched (marsupials) and placental mammals. Five families of these repeats distinguished by the presence of distinct LINE-related 3'-segments shared tRNA-like promoter and the central core region. The putative active elements were reconstructed from the alignment of genomic repeats representing molecular fossils of sequences that amplified in the past and since then underwent multiple mutations. Their mode of proliferation by retroposition was indicated by the presence of: (1) internal RNA PolIII promoter; (2) simple sequence repeated tail; (3) direct repeats; and (4) subfamilies recording the evolution of elements. The copy number of CORE-SINEs in placental genomes was estimated at about 300,000; they were highly divergent and apparently ceased to amplify before radiation of these lineages. On the other hand, among almost half a million fossil elements present in marsupials and monotremes, the youngest subfamilies could still be retropositionally active. CORE-SINEs terminate in sequence repeats of a few nucleotides similar to their 3'-segment LINE-homologues, CR1, L2 and Bov-B. These three LINE elements fall into clades distinct from that of L1 elements which, similar to their co-amplifying SINEs, end in a poly(A) tail. We propose a model in which new CORE-families, with distinct 3'-segments, are created at the RNA level due to template switching between LINE and CORE-RNA during reverse transcription. The proposed mechanism suggests that such an adaptation to the changing amplification machinery facilitated the survival and prosperity of CORE-elements over long evolutionary periods in different lineages.

A sequence with homology to human HPFH-linked enhancer elements and to a family of G-protein linked membrane receptor genes is located downstream of the chicken beta-globin locus

We report 5805bp of novel sequence (GenBank/EMBL Accession No. AJ012570) from a region starting approx. 11.5kb downstream of the chicken beta-globin locus (map position approx. +30.8 to +36.6kb), which contains a 945bp open reading frame (map position approx. +33 to +33.9kb). This is predicted to encode a 315-residue protein containing seven hydrophobic helical regions and a 17 amino acid motif characteristic of the R7G family of G-protein coupled membrane-bound receptors. The open reading frame and some surrounding sequence also have significant homology with the breakpoint enhancer elements, which also contain open reading frames, implicated in the HPFH-1/2 and HPFH-6 deletional forms of the human syndrome, hereditary persistence of foetal haemoglobin (HPFH). The existence of similar sequences at similar distances downstream of the beta-globin genes in chickens and HPFH patients is intriguing.

Structure and evolution of the alternatively spliced fast troponin T isoform gene

The vertebrate fast skeletal muscle troponin T gene, TnTf, produces a complexity of isoforms through differential mRNA splicing. The mechanisms that regulate splicing and the physiological significance of TnTf isoforms are poorly understood. To investigate these questions, we have determined the complete sequence structure of the quail TnTf gene, and we have characterized the developmental expression of alternatively spliced TnTf mRNAs in quail embryonic muscles. We report the following: 1) the quail TnTf gene is significantly larger than the rat TnTf gene and has 8 non-homologous exons, including a pectoral muscle-specific set of alternatively spliced exons; 2) specific sequences are implicated in regulated exon splicing; 3) a 900-base pair sequence element, composed primarily of intron sequence flanking the pectoral muscle-specific exons, is tandemly repeated 4 times and once partially, providing direct evidence that the pectoral-specific TnT exon domain arose by intragenic duplications; 4) a chicken repeat 1 retrotransposon element resides upstream of this repeated intronic/pectoral exon sequence domain and is implicated in transposition of this element into an ancestral genome; and 5) a large set of novel isoforms, produced by regulated exon splicing, is expressed in quail muscles, providing insights into the developmental regulation, physiological function, and evolution of the vertebrate TnTf isoforms.

Retrotransposable CR1-like elements in crotalinae snake genomes

A part of the 3'-flanking region of BP-II gene, which is one of Trimeresurus flavoviridis venom gland phospholopase A2 (PLA2) isozyme genes, has a region homologous to avian chicken repeat 1 (CR1)-element. In the present study, ten CR1-like elements were further identified in T. gramineus venom gland PLA2 isozyme genes, T. flavoviridis PLA2 inhibitor (PLI) genes, and T. flavoviridis and T. gramineus TATA-box binding protein (TBP) genes. Southern blot analysis using a probe for CR1 showed that Crotalinae snake genomes contain a number of CR1-like elements.

Chicken repeat 1 (CR1) elements, which define an ancient family of vertebrate non-LTR retrotransposons, contain two closely spaced open reading frames

Chicken repeat 1 (CR1) elements comprise a family of non-long terminal repeat (LTR) retrotransposons that have several noteworthy features. For example, whereas most other non-LTR elements have poly(A) tracts or other simple A-rich repeats at their 3' ends, the 3' ends of CR1 elements conform to the consensus [(CATTCTRT)(GATTCTRT)1-3]. CR1 elements also display an unusual bias for severe 5' truncations: only approx. 30 (out of a total of approx. 30 000) CR1 elements in the chicken genome include significant portions of the pol-like open reading frame (ORF) that we previously identified and partially sequenced [Burch et al. (1993) Proc. Natl. Acad. Sci. USA 90, 8199-8203]. In the present study we derived a consensus sequence for this entire ORF (ORF2) as well as an upstream ORF (ORF1) and part of a 5' untranslated region (UTR). The conceptual translation product of ORF2 is predicted to contain an endonuclease domain in addition to a reverse transcriptase domain. These results suggest that CR1 elements retrotranspose using a "nick and prime" mechanism similar (but not identical) to other families of non-LTR elements.

Two chicken repeat one (CR1) elements lacking a silencer-like region upstream of the chicken avidin-related genes Avr4 and Avr5

Two repetitive elements of the chicken CR1 family, each located in the 5' flanking region of the avidin-related genes Avr4 and Avr5, have been cloned and sequenced. Both elements are 721 bp in length with 72% identity to a CR1 consensus sequence. They had a 191 bp deletion in a region corresponding to the functional silencer regions previously detected within the CR1 elements upstream of the chicken lysozyme and apoVLDLII genes.

Characterization of protein interactions with positive and negative elements regulating the apoVLDLII gene

Synthesis of avian apo very-low-density lipoprotein (apoVLDL)II is estrogen dependent and liver specific. Competence to express the apoVLDLII gene is not acquired until days 7-9 of embryogenesis and thus lags 5-6 days behind appearance of the liver primordial bud. It is not known whether the delayed ability to activate the gene is attributable to hepatic estrogen receptor profiles, or a requirement for other transcription factors not expressed at earlier stages of embryogenesis. The latter possibility is supported by developmental alterations in nuclease hypersensitivity flanking the gene that occur independently of estrogen administration. We have examined the influence of these hypersensitive regions on expression from the apoVLDLII promoter and have characterized novel protein-DNA interactions at two of them. One is located in a copy of the CR1 family of middle repetitive elements approximately 3.0 kb upstream from the start of the gene. We demonstrate by DNase I footprinting that the site contains an element which matches a predicted consensus silencer sequence. The other site contains no previously identified binding motifs. It is located between nucleotides -228 and -245 and is adjacent to an imperfect estrogen response element (ERE) that we demonstrate acts additively with a canonical ERE 30 nucleotides downstream. We have identified ubiquitous and liver-specific factors that display overlapping DNA contacts with the site. Mutation of G residues contacted by these proteins decreases hormone-inducible expression from the promoter 5- to 8-fold. Hepatic levels of the liver-enriched factor interacting with this site increase abruptly between days 7 and 9 of embryogenesis, suggesting that it may be an important determinant of the ability to express the apoVLDLII and possibly other liver-specific genes.

Primary sequence, evolution, and repetitive elements of the Gallus gallus (chicken) beta-globin cluster

The DNA sequence of the Gallus gallus (chicken) beta-globin cluster was completed and analyzed. This G + C-rich region is 23.7 kb in length and includes the rho-, beta H-, beta A-, and epsilon-globin genes, the enhancer found between the beta A and epsilon genes, and three upstream DNase I hypersensitive sites. The CpG dinucleotides are nonrandomly distributed, being present at an increased relative frequency near the promoters and upstream hypersensitive sites. The cluster has an unusually low TA dinucleotide frequency. The upstream hypersensitive sites (5'HS1, 5'HS2, and 5'HS3) contain DNA sequence motifs recognized by erythroid transcription factors. However, no significant sequence similarity was found among the upstream hypersensitive sites and the beta A/epsilon enhancer. The G. gallus upstream site sequences were not similar to the upstream sites of the mammalian globin clusters, probably due to the small size of the functional regions and large evolutionary distance between the classes. The avian cluster evolved by gene duplication from an ancestor beta-globin gene, first producing the epsilon and the rho/beta H/beta A ancestor genes, then the rho and the beta H/beta A ancestor genes, and finally the beta H- and beta A-globins. Four probable gene conversions can be documented: beta A to beta H, epsilon to beta H, and rho/epsilon (twice). The cluster shows a massive overrepresentation of a non-LTR retrotransposon, CR1, which accounts for 16% of the DNA. We suggest that the locus is a preferred site for CR1 insertion.

Conserved regulatory elements in the promoter region of the N-CAM gene

Genomic clones containing 5'-flanking sequences, the first exon, and the entire first intron from the chicken N-CAM gene were characterized by restriction mapping and DNA sequencing. A > 600-bp segment that includes the first exon is very G + C-rich and contains a large proportion of CpG dinucleotides, suggesting that it represents a CpG island. SP-1 and AP-1 consensus elements are present, but no TATA- or CCAAT-like elements were found within 300 bp upstream of the first exon. Comparison of the chicken promoter region sequence with similar regions of the human, rat, and mouse N-CAM genes revealed that some potential regulatory elements including a "purine box" seen in mouse and rat N-CAM genes, one of two homeodomain binding regions seen in mammalian N-CAM genes, and several potential SP-1 sites are not conserved within this region. In contrast, high CpG content, a homeodomain binding sequence, an SP-1 element, an octomer element, and an AP-1 element are conserved in all four genes. The first intron of the chicken gene is 38 kb, substantially smaller than the corresponding intron from mammalian N-CAM genes. Together with previous studies, this work completes the cloning of the chicken N-CAM gene, which contains at least 26 exons distributed over 85 kb.

The alpha A-crystallin gene: conserved features of the 5'-flanking regions in human, mouse, and chicken

Approximately 2 kb of 5'-flanking sequences of the lens-specific alpha A-crystallin genes from human and mouse are presented and compared with similar regions of the chicken gene. A repetitive element was found approximately 1 kb upstream from the coding sequences of the alpha A-crystallin gene in all three species (Alu in human, B2 in mouse, and CR1 in chicken), suggesting that they may have an important functional or structural role. Despite the ability of alpha A-crystallin promoters to function across species, dot matrix analyses show only limited similarity among the 600 bp 5' to the structural genes of these three species. The human 5'-flanking sequence is more similar to that of the mouse and chicken than the mouse and chicken are to each other. Numerous short sequences (8-13 bp) are common to all three genes but are distributed differently in each species. The locations and conservation of these sequence motifs suggest functional roles, possibly as cis-regulatory elements of transcription. One motif is similar to the alpha A-CRYBP1 binding site implicated earlier in the transcriptional regulation of the mouse alpha A-crystallin gene, and other motifs correspond to sites previously mapped by methylation interference studies in the mouse alpha A-crystallin promoter. The modular arrangement of conserved sequence motifs is consistent with evolutionary changes occurring at the level of gene regulation.

Association of a chicken repetitive element with the endogenous virus-21 slow-feathering locus

The DNA sequences of an endogenous virus ev21-cell junction fragment (JFIL-1), and the pristine ev21 unoccupied region were analyzed. Comparisons of 3' proviral sequences of JFIL-1 with comparable regions of ev2, the prototype Rous-associated provirus (RAV-0), revealed minor single-base substitutions in the transmembrane domain of proviral envelope glycoprotein and the long terminal repeat of ev21. In the cell component of the JFIL-1, insertion of a 9-bp direct repeat and deletion of a guanine deoxynucleotide abolished HaeIII and BalI recognition sites that were present in the pristine region. Upstream from the insertion site, a large region was 71 and 75% homologous with dispersed chicken repetitive (CR1) elements associated with vitellogenin and very low density apolipoprotein II genes, respectively. Southern blot hybridizations and comparisons of CR1 motifs such as polypurine tracts, a tandem imperfect octamer, and 6-bp duplications indicated that this sex-linked, CR1 element (CR1ev21) may be the longest member of this family reported thus far.