RiTE database: a resource database for genus-wide rice genomics and evolutionary biology

Copetti, Dario, Zhang, Jianwei, El Baidouri, Moaine, Gao, Dongying, Wang, Jun, Barghini, Elena, Cossu, Rosa M., Angelova, Angelina, Maldonado L., Carlos E., Roffler, Stefan, Ohyanagi, Hajime, Wicker, Thomas, Fan, Chuanzhu, Zuccolo, Andrea, Chen, Mingsheng, Costa de Oliveira, Antonio, Han, Bin, Henry, Robert, Hsing, Yue-ie, Kurata, Nori, Wang, Wen, Jackson, Scott A., Panaud, Olivier, Wing, Rod A.

January 2015

BACKGROUND: Comparative evolutionary analysis of whole genomes requires not only accurate annotation of gene space, but also proper annotation of the repetitive fraction which is often the largest component of most if not all genomes larger than 50 kb in size. RESULTS: Here we present the Rice TE database (RiTE-db) - a genus-wide collection of transposable elements and repeated sequences across 11 diploid species of the genus Oryza and the closely-related out-group Leersia perrieri. The database consists of more than 170,000 entries divided into three main types: (i) a classified and curated set of publicly-available repeated sequences, (ii) a set of consensus assemblies of highly-repetitive sequences obtained from genome sequencing surveys of 12 species; and (iii) a set of full-length TEs, identified and extracted from 12 whole genome assemblies. CONCLUSIONS: This is the first report of a repeat dataset that spans the majority of repeat variability within an entire genus, and one that includes complete elements as well as unassembled repeats. The database allows sequence browsing, downloading, and similarity searches. Because of the strategy adopted, the RiTE-db opens a new path to unprecedented direct comparative studies that span the entire nuclear repeat content of 15 million years of Oryza diversity.

Rice

Oryza

Transposable elements

Repeats

Genome

RiTE-db

The Role of Retrotransposons in Gene Family Expansions in the Human and Mouse Genomes

Janoušek, Václav, Laukaitis, Christina M., Yanchukov, Alexey, Karn, Robert C.

09 1900

Retrotransposons comprise a large portion of mammalian genomes. They contribute to structural changes and more importantly to gene regulation. The expansion and diversification of gene families have been implicated as sources of evolutionary novelties. Given the roles retrotransposons play in genomes, their contribution to the evolution of gene families warrants further exploration. In this study, we found a significant association between two major retrotransposon classes, LINEs and LTRs, and lineage-specific gene family expansions in both the human and mouse genomes. The distribution and diversity differ between LINEs and LTRs, suggesting that each has a distinct involvement in gene family expansion. LTRs are associated with open chromatin sites surrounding the gene families, supporting their involvement in gene regulation, whereas LINEs may play a structural role promoting gene duplication. Our findings also suggest that gene family expansions, especially in the mouse genome, undergo two phases. The first phase is characterized by elevated deposition of LTRs and their utilization in reshaping gene regulatory networks. The second phase is characterized by rapid gene family expansion due to continuous accumulation of LINEs and it appears that, in some instances at least, this could become a runaway process. We provide an example in which this has happened and we present a simulation supporting the possibility of the runaway process. Altogether we provide evidence of the contribution of retrotransposons to the expansion and evolution of gene families. Our findings emphasize the putative importance of these elements in diversification and adaptation in the human and mouse lineages.

gene families

transposable elements

retrotransposons

LINE

LTR

SINE

O sistema Mutator em cana-de-açúcar: uma análise comparativa com arroz / The Mutador system in sugarcane: a comparative analysis with rice

Saccaro Junior, Nilo Luiz

27 November 2007

Os elementos transponíveis (TEs) constituem grande parte do material genético de diversos eucariotos, alcançando entre 50-80% do genoma de gramíneas. Os projetos genoma proporcionaram um aumento das informações disponíveis sobre estes elementos, o que evidenciou sua importância e possibilitou o desenvolvimento de novas abordagens para seu estudo. O sistema Mutator (Mu) de milho é o mais ativo e mutagênico transposon de plantas. Além do elemento autônomo, MuDR, o sistema compreende ainda um conjunto de elementos bastante heterogêneo em sua seqüência e estrutura, chamados MuLEs, que podem conter até mesmo fragmentos de genes do hospedeiro. As seqüências de transposons mais abundantemente expressas no transcriptoma de cana-de-açúcar são relacionadas a MuDR e se agrupam em quatro clados (nomeados Classes I, II, II e IV), existentes antes da divergência entre Mono e Eudicotiledôneas. O trabalho apresentado aqui teve o objetivo de aprofundar o conhecimento sobre o sistema Mutator em cana-de-açúcar a partir da análise comparativa entre seqüências dessa planta e de arroz (cujo genoma está totalmente seqüenciado). Foi possível avaliar a abundância e diversidade do sistema Mu em gramíneas, ficando evidente uma amplificação de elementos clado-específica, tendo a Classe II sofrido uma explosão no número de cópias ao longo da evolução destas plantas. Análises estruturais revelaram que, enquanto as Classes I e II compreendem elementos com características de transposons, as Classes III e IV são, na verdade, transposases domesticadas. Foram completamente seqüenciados dois clones de BAC de cana-de-açúcar, um proveniente de cada parental do híbrido (Saccharum officinarum e Saccharum spontaneum), ambos contendo elementos da Classe III. Estes elementos foram caracterizados e a seqüência genômica de cana foi comparada com sua ortóloga em arroz, revelando um acúmulo de TEs nas regiões intergênicas. / Transposable elements (TEs) constitute great part of eukaryote genetic material, in grasses, they comprise between 50-80% of the genome. Genome projects have significantly increased the amount of information about these elements, revealing their importance and allowing the development of new approaches for their study. The Mutator system (Mu) of maize is the most active and mutagenic plant transposon. Beyond the autonomous element, MuDR, the system comprises a very heterogeneous, in sequence and structure, set of elements, called MuLEs, that can contain even host gene fragments. The most abundant transposon related sequences expressed in sugarcane transcriptoma are the MuDR-like. They group into four clades (called Classes I, II, III and IV) that exist prior to the Mono and Eudicot split. The aim of this work is to gain knowledge about the Mutator system in sugarcane through the comparative analysis against rice (whose genome is completely sequenced). The results described the abundance and diversity of the Mu system in grasses, evidencing a clado-specific amplification with a burst of Class II along the evolution of this plant group. Structural analyses showed that, while Classes I and II comprise elements with transposon characteristics, Classes III and IV are domesticated transposases. One BAC clone from each sugarcane parental genotype (Saccharum officinarum and Saccharum spontaneum) have been completely sequenced, both containing Class III elements. These elements have been characterized and the sugarcane genomic sequences were compared with their orthologues in rice. The comparative analyses showed an accumulation of TEs in the intergenic regions.

Saccharum

Saccharum

Elementos de transposição

Genômica

Genomics

Transposable elements

Comparative genomics of noncoding DNA

Manee, Manee

January 2016

High levels of primary sequence conservation are observed in many noncoding regions of eukaryotic genomes. These conserved noncoding elements (CNEs) have shown to be robust indicators of functionally constrained elements. Nevertheless, the function of only a small fraction of such CNEs is known and their role in genome biology remains largely a mystery. Comparative genomics analysis in model organisms can shed light on CNE function and evolution of noncoding DNA in general. Recently, it has been reported that short CNEs in the Drosophila genome are typically very AT-rich but have unusually high levels of GC content in a much larger (~500 bp) window around them. To understand whether these "side effects" are dependent on their CNE definition or are a more general feature of the Drosophila genome, we analysed base composition of CNEs from two different CNE detection methods. We found side effects are real, but are restricted to a subset of CNEs in the genome. An alternative hypothesis to explain the existence of CNEs is the mutational cold spot hypothesis. Previous work using SNPs was shown evidence that CNEs are not mutational cold spots. Here, non-reference transposable elements (TEs) were used to test cold spot hypothesis. A significant reduction in levels of non-reference TEs was found in intronic and intergenic CNEs compared to the expected number of insertions. TEs in intergenic CNEs were also found at lower allele frequencies than TEs in intergenic spacers. Furthermore, we used simulation to explore the effects of insertion/deletion (indel) evolution on noncoding DNA sequences with and without constrained noncoding elements. We assessed several indel-capable simulators to test expected outcomes with no selectively constrained elements. Simulations with constrained elements show that sequences grow in length even when the deletion rate is exactly the same as the insertion rate. This result can be interpreted as being due to purifying selection on CNEs acting to remove an excess of deletion over insertions. Together, the results presented here provide insights into the evolution of noncoding DNA in one of the most important model organisms.

Cut-and-paste transposable elements in the arbuscular mycorrhizal fungi Claroideoglomus claroideum

Xu, Wenbo

January 2019

Arbuscular mycorrhizal (AM) fungi are important symbionts to most of the terrestrial plants. Recent genome sequencing projects revealed that many AM fungi have repetitive genetic elements in their genomes and among these repetitive genetic elements, cut-and-paste DNA transposable elements were very prevalent. For example, in Rhizophagus irregularis, up to 21% of the genome assembly content was associated with cut-and-paste DNA transposable elements. In Diversispora epigaea, up to 23% of the genome content can also be attributed to cut-and-paste DNA transposable elements. While cut-and-paste DNA transposable elements are very abundant in AM fungi, detailed studies on these repetitive elements have been lacking. In this study, we revealed the diversity of cut-and-paste DNA transposable elements in Claroideoglomus claroideum and identified many potentially autonomous transposable elements in the genome assembly of C. claroideum. The evolutionary relationship between the DNA transposons we identified and the established sequences in public databases were also investigated.

Transposable elements

Arbuscular mycorrhizal fungi

Evolutionary Biology

Evolutionsbiologi

The exaptation of nitrate/carbon stress-induced smRNAs and their targets from transposable elements in the unicellular green alga Chlamydomonas reinhardtii

Tyra, Heather Marie

01 May 2009

Transposable elements (TEs) are acknowledged sources of genetic change within organisms. The effects of transposition can range from the disruption or creation of a single gene to large-scale genome rearrangements. Transposition events can result in beneficial mutations which allow an organism to adapt to a new environment. In the last three years, several studies have reported that some miRNAs, small RNAs involved in post-transcriptional gene regulation, have evolved from TEs. miRNAs play an important role in the stress responses of many organisms. Interestingly, TEs are derepressed under the same stress conditions that miRNAs are known to ameliorate. The observation that miRNAs are known to evolve from TEs and that TEs are derepressed under stress conditions lead me to question whether TEs play a role in environmental adaptation through the creation of small RNA networks. To test this idea, Chlamydomonas reinhardtii cultures were grown under low carbon, nitrate enriched conditions and the small RNA pool was analyzed. I found that these conditions do stimulate the expression of novel small RNAs and that some of these RNAs and their targets are derived from transposition events.

Chlamydomonas

low CO2

miRNA

nitrate

Transposable elements

Biology

Elucidating the Mechanisms of Transposable Elements using Experimental and Bioinformatic Approaches: The hAT Superfamily of Transposable Elements in the Genome of Aedes aegypti and TE Displayer

Rooke, Rebecca

19 December 2011

Transposable elements (TEs) are found in nearly all eukaryotic genomes and are a major driving force of genome evolution. The hAT superfamily of TEs are found in a variety of organisms, including plants, fungi, insects and animals. To date, only 14 hAT TEs in the Aedes aegypti genome have been annotated as having a hAT transposase coding sequence. In this study, extensive bioinformatic approaches have been employed to find hAT TEs that encode transposases in the A. aegypti genome. A total of six newly-identified TEs belonging to the hAT superfamily were discovered in the A. aegypti genome. Furthermore, a computer program called TE Displayer was developed to analyze TEs in genome sequences. TE Displayer detects TE-derived polymorphisms in genome datasets and presents the results on a virtual gel image. TE Displayer enables researchers to compare TE profiles in silico and provides a reference profile for experimental analyses.

Transposable Elements

Aedes aegypti

TE Displayer

Transposon Display

0307

0715

Elucidating the Mechanisms of Transposable Elements using Experimental and Bioinformatic Approaches: The hAT Superfamily of Transposable Elements in the Genome of Aedes aegypti and TE Displayer

Rooke, Rebecca

19 December 2011

Transposable elements (TEs) are found in nearly all eukaryotic genomes and are a major driving force of genome evolution. The hAT superfamily of TEs are found in a variety of organisms, including plants, fungi, insects and animals. To date, only 14 hAT TEs in the Aedes aegypti genome have been annotated as having a hAT transposase coding sequence. In this study, extensive bioinformatic approaches have been employed to find hAT TEs that encode transposases in the A. aegypti genome. A total of six newly-identified TEs belonging to the hAT superfamily were discovered in the A. aegypti genome. Furthermore, a computer program called TE Displayer was developed to analyze TEs in genome sequences. TE Displayer detects TE-derived polymorphisms in genome datasets and presents the results on a virtual gel image. TE Displayer enables researchers to compare TE profiles in silico and provides a reference profile for experimental analyses.

Transposable Elements

Aedes aegypti

TE Displayer

Transposon Display

0307

0715

TE variation in natural populations of Drosophila : copy number, transcription and chromatin state

Rebollo, Rita

26 October 2009

Transposable elements (TEs) are one major force of genome evolution thanks to theirability to create genetic variation. TEs are ubiquitous and their proportion is variable between species and also populations, suggesting that a tight relationship exists between genomes and TEs. The model system composed of the natural populations of the twin sisters Drosophila melanogaster and D. simulans is interesting to compare host/TE relationship, since both species harbour different amounts of TE copies. The helena element is nearly silenced in D.simulans natural populations despite a very high copy number. Such repression is associated to abundant internally deleted copies suggesting a regulatory mechanism of TEs based on DNA deletion. Another pathway of TE regulation is through epigenetics where the host genome is able to keep intact the DNA sequences of TEs and still silence their activities.Chromatin remodelling is well known in drosophila and specific histone modifications can be associated to specific chromatin domains. We observed an important variation on H3K27me3and H3K9me2, two heterochromatic marks, on TE copies in D. melanogaster and D. simulans natural populations. Also, we show that derepressed lines of D. simulans exist for specific elements, have high TE transcription rates and are highly associated to non constitutive heterochromatic marks. TEs are therefore controlled by the host genome through DNA deletion and a possible chromatin remodelling mechanism. Not only genetic variability is enhanced by TEs but also epigenetic variability, allowing the host genome to be partitioned into chromatin domains. TEs are therefore mandatory to gene network regulation through their ability of "jumping epigenetics".

[SDV] Life Sciences

Transposable elements

Drosophila

Natural populations

Deletion

Epigenetics

Exopolysaccharides of Mycoplasma pulmonis

Daubenspeck, James M.

January 2009

Thesis (Ph.D.)--University of Alabama at Birmingham, 2009. / Title from PDF title page (viewed on Feb. 2, 2010). Includes bibliographical references (p. 64-72).