An abundant and heavily truncated non-LTR retrotransposon (LINE) family in Beta vulgaris

We describe a non-LTR retrotransposon family,BvL, of the long interspersed nuclear elements L1 clade isolated from sugar beet (Beta vulgaris). Characteristic molecular domains of three full-length BvL elements were determined in detail, showing that coding sequences are interrupted and most likely non-functionally. In addition,eight highly conserved endonuclease regions were defined by comparison with other plant LINEs. The abundant BvL family is widespread within the genus Beta, however, the vast majority of BvL copies are extremely 50 truncated indicating an error-prone reverse transcriptase activity. The dispersed distribution of BvL copies on all sugar beet chromosomes with exclusion of most heterochromatic regions was shown by fluorescent in situ hybridization. The analysis of BvL 30 end sequences and corresponding flanking regions, respectively, revealed the preferred integration of BvL into A/T-rich regions of the sugar beet genome, but no specific target sequences.

BNR - a LINE family from Beta vulgaris - contains a RRM domain in open reading frame 1 and defines a L1 sub-clade present in diverse plant genomes

We characterized a novel type of plant non-LTR retrotransposons, identified as the BNR family, in sugar beet (Beta vulgaris) genomes. Although their ORF2 sequences were similar to those of previously analysed LINEs (long interspersed nuclear elements) of the L1 clade, their ORF1 sequences differ strongly from those of most plant LINEs. Two novel domains were identified, containing a conserved secondary motif, known as the RNA recognition motif (RRM). ORF1 lacks the zinc finger motif that is typical of plant LINEs, but has an RRM that is likely to have a RNA-binding function. BNR LINEs are highly diverse, and were characterized by gel-blot and fluorescent in situ hybridization, showing a widespread occurrence and clustering along chromosome arms. Insertion of BNR1 into a well-described satellite repeat was detected in two cultivars only, indicating recent activity. Database searches revealed the existence of LINE families possessing an ORF1 sequence similar to that of BNR in the genomes of higher plants such as poplar, lotus and soybean. Comparing their reverse transcriptase regions with those of other retrotransposons, these LINEs were assigned to the L1 clade, but form a distinct group, providing evidence of a major separation of L1 elements in plants. This indicates a common origin of BNR-like LINEs, suggesting that these elements form a sub-clade designated as the BNR sub-clade.

Nested Ty3-gypsy retrotransposons of a single Beta procumbens centromere contain a putative chromodomain

LTR retrotransposons belong to a major group of DNA sequences that are often localized in plant centromeres. Using BAC inserts originating from the centromere of a monosomic wild beet (Beta procumbens) chromosome fragment in Beta vulgaris, two complete LTR retrotransposons were identified. Both elements, designated Beetle1 and Beetle2, possess a coding region with genes in the order characteristic for Ty3-gypsy retrotransposons. Beetle1 and Beetle2 have a chromodomain in the C-terminus of the integrase gene and are highly similar to the centromeric retrotransposons (CRs) of rice, maize, and barley. Both retroelements were localized in the centromeric region of B. procumbens chromosomes by fluorescence in-situ hybridization. They can therefore be classified as centromere-specific chromoviruses. PCR analysis using RNA as template indicated that Beetle1 and Beetle2 are transcriptionally active. On the basis of the sequence diversity between the LTR sequences, it was estimated that Beetle1 and Beetle2 transposed within the last 60,000 years and 130,000 years, respectively. The centromeric localization of Beetle1 and Beetle2 and their transcriptional activity combined with high sequence conservation within each family play an important structural role in the centromeres of B. procumbens chromosomes.

Structure and evolution of plant centromeres

Investigations of centromeric DNA and proteins and centromere structures in plants have lagged behind those conducted with yeasts and animals; however, many attractive results have been obtained from plants during this decade. In particular, intensive investigations have been conducted in Arabidopsis and Gramineae species. We will review our understanding of centromeric components, centromere structures, and the evolution of these attributes of centromeres among plants using data mainly from Arabidopsis and Gramineae species.

Haplotype divergence in Beta vulgaris and microsynteny with sequenced plant genomes

We characterized two overlapping sugar beet (Beta vulgaris) bacterial artificial chromosome (BAC) clones representing different haplotypes. A total of 254 kbp of the genomic sequence was determined, of which the two BACs share 92 kbp. Eleven of 15 genes discovered in the sequenced interval locate to the overlap region. The haplotypes differ in exons by 1% (nucleotide level) and in non-coding regions by 9% (6% mismatches, 3% gaps; alignable regions only). Large indels or high sequence divergence comprised 11% of either sequence. Of such indels, 68 and 45%, respectively, could be attributed to haplotype-specific integration of transposable elements. We identified novel repeat candidates by comparing the two BAC sequences to a set of genomic sugar beet sequences. Synteny was found with Arabidopsis chromosome 1 (At1), At2 and At4, Medicago chromosome 7, Vitis chromosome 15 and paralogous regions on poplar chromosomes II and XIV.

Mobilization and evolutionary history of miniature inverted-repeat transposable elements (MITEs) in Beta vulgaris L

We have identified three families of miniature inverted-repeat transposable elements (VulMITEs) in the genome of sugar beet (Beta vulgaris L.), evidently derived from a member of the Vulmar family of mariner transposons. While VulMITEs I are typical stowaway-like MITEs, VulMITEs II and VulMITEs III are rearranged stowaway elements of increased size. The integration of divergent moderately and highly repetitive sequences into VulMITEs II and, in particular in VulMITEs III, respectively, shows that amplification of repetitive DNA by MITEs contribute to the increase of genome size with possible implications for plant genome evolution. Fluorescent in-situ hybridization (FISH), for the first time visualizing stowaway MITE distribution on plant chromosomes, revealed a dispersed localization of VulMITEs along all B. vulgaris chromosomes. Analysis of the flanking sequences identified a dispersed repeat as target site for the integration of the stowaway element VulMITE I. Recent transposition of VulMITE I, which most likely occurred during the domestication of cultivated beets, was concluded from insertional polymorphisms between different B. vulgaris cultivars and species.

The origin, meiotic behavior, and transmission of a novel minichromosome in Arabidopsis thaliana

A plant carrying a small extra chromosome was found in Landsberg erecta ecotype of Arabidopsis thaliana. Fluorescence in situ hybridization revealed that this minichromosome was derived from the short arm of chromosome 4. The size of this "mini4S" chromosome was estimated to be approximately 7.5 Mb on the basis of previously reported data and the amount of the centromeric major satellite (180-bp family) present, which was determined to be about 1 Mb, or about one third of that in the normal chromosome 4. No pairing between mini4S and its original chromosome 4 was observed at pachytene and metaphase I stages. The transmission of mini4S through pollen was limited, but about 30% of selfed progeny carried the mini4S chromosomes. The transmission rates considerably increased when the mini4S chromosomes were transferred to plants with a Columbia background by successive backcrosses. This suggests that the stability of the minichromosomes is controlled genetically by factors that can vary between ecotypes.

A direct repeat sequence associated with the centromeric retrotransposons in wheat

A high-density BAC filter of Triticum monococcum was screened for the presence of a centromeric retrotransposon using the integrase region as a probe. Southern hybridization to the BAC digests using total genomic DNA probes of Triticum monococcum, Triticum aestivum, and Hordeum vulgare detected differentially hybridizing restriction fragments between wheat and barley. The fragments that hybridized to genomic DNA of wheat but not to that of barley were subcloned. Fluorescence in situ hybridization (FISH) analysis indicated that the clone pHind258 hybridized strongly to centromeric regions in wheat and rye and weakly to those in barley. The sequence of pHind258 was homologous to integrase and long terminal repeats of centromeric Ty3-gypsy retrotransposons of cereal species. Additionally, pHind258 has a pair of 192-bp direct repeats. FISH analysis indicated that the 192-bp repeat probe hybridized to centromeres of wheat and rye but not to those of barley. We found differential FISH signal intensities among wheat chromosomes using the 192-bp probe. In general, the A-genome chromosomes possess strong FISH signals, the B-genome chromosomes possess moderate signals, and the D-genome chromosomes possess weak signals. This was consistent with the estimated copy numbers of the 192-bp repeats in the ancestral species of hexaploid wheat.

Molecular characterization of Vulmar1, a complete mariner transposon of sugar beet and diversity of mariner- and En/Spm-like sequences in the genus Beta

Transposons of the Tc1-mariner superfamily are widespread in eukaryotic genomes. We have isolated the mariner element Vulmar1 from Beta vulgaris L., which is 3909 bp long and bordered by perfect terminal inverted repeats of 32 bp with homology to terminal inverted repeats of transposons from soybean and rice. According to a characteristic amino acid signature, Vulmar1 can be assigned to the DD39D group of mariner transposons. Vulmar1 is flanked by a 5'-TA-3' target site duplication that is typical for mariner transposons. Southern hybridization revealed that mariner-like copies are highly abundant in Beta species, and sequence analysis of 10 transposase fragments from representative species of the four Beta sections revealed an identity between 34% and 100% after conceptual translation. By fluorescent in situ hybridization, Vulmar1 was detected in distal euchromatin as well as in some intercalary and pericentromeric regions of all B. vulgaris chromosomes. In addition, using PCR, we were able to amplify fragments of the transposase gene of En/Spm-like transposons in the genus Beta. En/Spm-like transposase sequences are highly amplified in four Beta sections and showed a considerable degree of conservation (88.5-100%) at the protein level, while the homology to corresponding regions of En/Spm transposons of other plant species ranges from 49.5% to 62.5%. By fluorescent in situ hybridization, En/Spm-like transposon signals of strong intensity were detected on all chromosomes of B. vulgaris.