Diversity of LTR-retrotransposons and <Emphasis Type="Italic">Enhancer/Suppressor</Emphasis><Emphasis Type="Italic">Mutator</Emphasis>-like transposons in cassava (<Emphasis Type="Italic">Manihot esculenta</Emphasis> Crantz)

Cassava (Manihot esculenta Crantz), though a major world crop with enormous potential, is very under studied. Little is known about its genome structure and organisation. Transposable elements have a key role in the evolution of genome structure, and can be used as important tools in applied genetics. This paper sets out to survey the diversity of members of three major classes of transposable element within the cassava genome and in relation to similar elements in other plants. Members of two classes of LTR-retrotransposons, Ty1/copia-like and Ty3/gypsy-like, and of Enhancer/Suppressor Mutator (En/Spm)-like transposons were isolated and characterised. Analyses revealed 59 families of Ty1/copia, 26 families of Ty3/gypsy retrotransposons, and 40 families of En/Spm in the cassava genome. In the comparative analyses, the predicted amino acid sequences for these transposon classes were compared with those of related elements from other plant species. These revealed that there were multiple lineages of Ty1/copia-like retrotransposons in the genome of cassava and suggested that vertical and horizontal transmission as the source of cassava Mecops may not be mutually exclusive. For the Ty3/gypsy elements network, two groups of cassava Megyps were evident including the Arabidopsis Athila lineage. However, cassava En/Spm-like elements (Meens) constituted a single group within a network of plant En/Spm-like elements. Hybridisation analysis supported the presence of transposons in the genome of cassava in medium (Ty3/gypsy and En/Spm) to high (Ty1/copia) copy numbers. Thus the cassava genome was shown to contain diverse members of three major classes of transposable element; however, the different classes exhibited contrasting evolutionary histories.     

Evidence for the Role of Recombination in the Regulatory Evolution of Saccharomyces cerevisiae Ty Elements

The recent completion of the sequencing of the Saccharomyces cerevisiae genome provides a unique opportunity to analyze the evolutionary relationships existing among the entire complement of retrotransposons residing within a single genome. In this article we report the results of such an analysis of two closely related families of yeast long terminal repeat (LTR) retrotransposons, Ty1 and Ty2. In our study, we analyzed the molecular variation existing among the 32 Ty1 and 13 Ty2 elements present within the S. cerevisiae genome recently sequenced within the context of the yeast genome project. Our results indicate that while the Ty1 family is most likely ancestral to Ty2 elements, both families of elements are relatively recent components of the S. cerevisiae genome. Our results also indicate that both families of elements have been subject to purifying selection within their protein coding regions. Finally, and perhaps most interestingly, our results indicate that a relatively recent recombination event has occurred between Ty2 and a subclass of Ty1 elements involving the LTR regulatory region. We discuss the possible biological significance of these findings and, in particular, how they contribute to a better overall understanding of LTR retrotransposon evolution. Received: 30 September 1997 / Accepted: 3 February 1998     

A computational study of the dynamics of LTR retrotransposons in the Populus trichocarpa genome

Retrotransposons are an ubiquitous component of plant genomes, especially abundant in species with large genomes. Populus trichocarpa has a relatively small genome, which was entirely sequenced; however, studies focused on poplar retrotransposons dynamics are rare. With the aim to study the retrotransposon component of the poplar genome, we have scanned the complete genome sequence searching full-length long-terminal repeat (LTR) retrotransposons, i.e., characterised by two long terminal repeats at the 5′ and 3′ ends. A computational approach based on detection of conserved structural features, on building multiple alignments, and on similarity searches was used to identify 1,479 putative full-length LTR retrotransposons. Ty1-copia elements were more numerous than Ty3-gypsy. However, many LTR retroelements were not assigned to any superfamily because lacking of diagnostic features and non-autonomous. LTR retrotransposon remnants were by far more numerous than full-length elements, indicating that during the evolution of poplar, large amplification of these elements was followed by DNA loss. Within superfamilies, Ty3-gypsy families are made of more members than Ty1-copia ones. Retrotransposition occurred with increasing frequency following the separation of Populus sections, with different waves of retrotransposition activity between Ty3-gypsy and Ty1-copia elements. Recently inserted elements appear more frequently expressed than older ones. Finally, different levels of activity of retrotransposons were observed according to their position and their density in the linkage groups. On the whole, the results support the view of retrotransposons as a community of different organisms in the genome, whose activity (both retrotransposition and DNA loss) has heavily impacted and probably continues to impact poplar genome structure and size.     

Tempo and mode of Ty element evolution in Saccharomyces cerevisiae

The Saccharomyces cerevisiae genome contains five families of long terminal repeat (LTR) retrotransposons, Ty1-Ty5. The sequencing of the S. cerevisiae genome provides an unprecedented opportunity to examine the patterns of molecular variation existing among the entire genomic complement of Ty retrotransposons. We report the results of an analysis of the nucleotide and amino acid sequence variation within and between the five Ty element families of the S. cerevisiae genome. Our results indicate that individual Ty element families tend to be highly homogenous in both sequence and size variation. Comparisons of within-element 5' and 3' LTR sequences indicate that the vast majority of Ty elements have recently transposed. Furthermore, intrafamily Ty sequence comparisons reveal the action of negative selection on Ty element coding sequences. These results taken together suggest that there is a high level of genomic turnover of S. cerevisiae Ty elements, which is presumably in response to selective pressure to escape host-mediated repression and elimination mechanisms.     

Genome size and sequence composition of moso bamboo: A comparative study

Moso bamboo (Phyllostachys pubescens) is one of the world’s most important bamboo species. It has the largest area of all planted bamboo—over two-thirds of the total bamboo forest area—and the highest economic value in China. Moso bamboo is a tetraploid (4x=48) and a special member of the grasses family. Although several genomes have been sequenced or are being sequenced in the grasses family, we know little about the genome of the bambusoids (bamboos). In this study, the moso bamboo genome size was estimated to be about 2034 Mb by flow cytometry (FCM), using maize (cv. B73) and rice (cv. Nipponbare) as internal references. The rice genome has been sequenced and the maize genome is being sequenced. We found that the size of the moso bamboo genome was similar to that of maize but significantly larger than that of rice. To determine whether the bamboo genome had a high proportion of repeat elements, similar to that of the maize genome, approximately 1000 genome survey sequences (GSS) were generated. Sequence analysis showed that the proportion of repeat elements was 23.3% for the bamboo genome, which is significantly lower than that of the maize genome (65.7%). The bamboo repeat elements were mainly Gypsy/DIRS1 and Ty1/Copia LTR retrotransposons (14.7%), with a few DNA transposons. However, more genomic sequences are needed to confirm the above results due to several factors, such as the limitation of our GSS data. This study is the first to investigate sequence composition of the bamboo genome. Our results are valuable for future genome research of moso and other bamboos.     

Genome size and sequence composition of moso bamboo: A comparative study

Moso bamboo (Phyllostachys pubescens) is one of the world's most important bamboo species. It has the largest area of all planted bamboo―over two-thirds of the total bamboo forest area―and the highest economic value in China. Moso bamboo is a tetraploid (4x=48) and a special member of the grasses family. Although several genomes have been sequenced or are being sequenced in the grasses family, we know little about the genome of the bambusoids (bamboos). In this study, the moso bamboo genome size was estimated to be about 2034 Mb by flow cytometry (FCM), using maize (cv. B73) and rice (cv. Nipponbare) as internal references. The rice genome has been sequenced and the maize genome is being sequenced. We found that the size of the moso bamboo genome was similar to that of maize but significantly larger than that of rice. To determine whether the bamboo genome had a high proportion of repeat elements, similar to that of the maize genome, approximately 1000 genome survey sequences (GSS) were generated. Sequence analysis showed that the proportion of repeat elements was 23.3% for the bamboo genome, which is significantly lower than that of the maize ge-nome (65.7%). The bamboo repeat elements were mainly Gypsy/DIRS1 and Ty1/Copia LTR retrotrans-posons (14.7%), with a few DNA transposons. However, more genomic sequences are needed to con-firm the above results due to several factors, such as the limitation of our GSS data. This study is the first to investigate sequence composition of the bamboo genome. Our results are valuable for future genome research of moso and other bamboos.     

A Small Family of Sushi-Class Retrotransposon-Derived Genes in Mammals and Their Relation to Genomic Imprinting

Ty3/gypsy retrotransposons are rare in mammalian genomes despite their abundance in invertebrate and other vertebrate classes. Here we identify a family of nine conserved mammalian genes with homology to Ty3/gypsy retrotransposons but which have lost their ability to autonomously retrotranspose. Of these, five map to the X chromosome while the remaining four are autosomal. Comparative phylogenetic analyses show them to have strongest homology to the sushi-ichi element from Fugu rubripes. Two of the autosomal gene members, Peg10 and Rtl1, are known to be imprinted, being expressed from the paternally inherited chromosome homologue. This suggests, consistent with the host-parasite response theory of the evolution of the imprinting mechanism, that parental-origin specific epigenetic control may be mediated by genomic “parasitic” elements such as these. Alternatively, these elements may preferentially integrate into regions that are differentially modified on the two homologous chromosomes such as imprinted domains and the X chromosome and acquire monoallelic expression. We assess the imprinting status of the remaining autosomal members of this family and show them to be biallelically expressed in embryo and placenta. Furthermore, the methylation status of Rtl1 was assayed throughout development and was found to resemble that of actively, silenced repetitive elements rather than imprinted sequences. This indicates that the ability to undergo genomic imprinting is not an inherent property of all members of this family of retroelements. Nonetheless, the conservation but functional divergence between the different members suggests that they have undergone positive selection and acquired distinct endogenous functions within their mammalian hosts. The sequence data from this study have been submitted to Entrez/NCBI under accession nos. XXXXXX to XXXXXXX. [Reviewing Editor : Dr. Juergen Brosius]     

The varying microsporidian genome: existence of long-terminal repeat retrotransposon in domesticated silkworm parasite Nosema bombycis

Microsporidia are a group of intracellular parasites with an extremely compact genome and there is no confirmed evidence that retroelements are parasitised in these organisms. Using the dataset of 200,000 genomic shotgun reads of the silkworm pebrine Nosema bombycis, we have identified the eight complete N. bombycis long-terminal repeat retrotransposon (Nbr) elements. All of the Nbr elements are Ty3/gypsy members and have close relationships to Saccharomycetes long-terminal repeat retrotransposons identified previously, providing further evidence of their relationship to fungi. To explore the effect of retrotransposons in microsporidian genome evolution, their distribution was characterised by comparisons between two N. bombycis contigs containing the Nbr elements with the completed genome of the human parasite Encephalitozoon cuniculi, which is closely related to N. bombycis. The Nbr elements locate between or beside syntenic blocks, which are often clustered with other transposable-like sequences, indicating that they are associated with genome size variation and syntenic discontinuities. The ratios of the number of non-synonymous substitutions per non-synonymous site to the number of synonymous substitutions per synonymous site of the open reading frames among members of each of the eight Nbr families were estimated, which reveal the purifying selection acted on the N. bombycis long-terminal repeat retrotransposons. These results strongly suggest that retrotransposons play a major role in reorganization of the microsporidian genome and they might be active. The present study presents an initial characterization of some transposable elements in the N. bombycis genome and provides some insight into the evolutionary mechanism of microsporidian genomes.     

The Role of Interelement Selection in Saccharomyces cerevisiae Ty Element Evolution

Retrotransposons are mobile genetic elements that are ubiquitous components of eukaryotic genomes. The evolutionary success of retrotransposons is explained by their ability to replicate faster than the host genomes in which they reside. Elements with higher rates of genomic replication possess a selective advantage over less active elements. Retrotransposon populations, therefore, are shaped largely by selective forces acting at the genomic level between elements. To evaluate rigorously the effects of selective forces acting on retrotransposons, detailed information on the patterns of molecular variation within and between retrotransposon families is needed. The sequencing of the Saccharomyces cerevisiae genome, which includes the entire genomic complement of yeast retrotransposons, provides an unprecedented opportunity to access and analyze such data. In this study, we analyzed in detail the patterns of nucleotide variation within the open reading frames of two parental (Ty1 and Ty2) and one hybrid (Ty1/2) family of yeast retrotransposons. The pattern and distribution of nucleotide changes on the phylogenetic reconstructions of the three families of Ty elements reveal evidence of negative selection on both internal and external branches of the Ty phylogenies. These results indicate that most, if not all, Ty elements examined represent active or recently active retrotransposon lineages. We discuss the relevance of these findings with respect to the coevolutionary dynamic operating between genomic element populations and the host organisms in which they reside. Received: 5 November 1998 / Accepted: 17 March 1999