Identification of transposons, retroelements, and a gene family predominantly expressed in floral tissues in chromosome 3DS of the hexaploid wheat progenitor Aegilops tauschii

Genome-wide characterization of long terminal repeat retrotransposons provides insights into trait evolution of four cucurbit species

Cucurbits are a diverse plant family that includes economically important crops, such as cucumber, watermelon, melon, and pumpkin. Knowledge of the roles that long terminal repeat retrotransposons (LTR-RTs) have played in diversification of cucurbit species is limited; to add to understanding of the roles of LTR-RTs, we assessed their distributions in four cucurbit species. We identified 381, 578, 1086, and 623 intact LTR-RTs in cucumber (Cucumis sativus L. var. sativus cv. Chinese Long), watermelon (Citrullus lanatus subsp. vulgaris cv. 97103), melon (Cucumis melo cv. DHL92), and Cucurbita (Cucurbita moschata var. Rifu), respectively. Among these LTR-RTs, the Ale clade of the Copia superfamily was the most abundant in all the four cucurbit species. Insertion time and copy number analysis revealed that an LTR-RT burst occurred approximately 2 million years ago in cucumber, watermelon, melon, and Cucurbita, and may have contributed to their genome size variation. Phylogenetic and nucleotide polymorphism analyses suggested that most LTR-RTs were formed after species diversification. Analysis of gene insertions by LTR-RTs revealed that the most frequent insertions were of Ale and Tekay and that genes related to dietary fiber synthesis were the most commonly affected by LTR-RTs in Cucurbita. These results increase our understanding of LTR-RTs and their roles in genome evolution and trait characterization in cucurbits.

Patterns of Evolutionary Trajectories and Domestication History within the Genus Hordeum Assessed by REMAP Markers

The patterns of genetic diversity related to the taxonomy and domestication history of 85 accessions representing the main four species of the genus Hordeum were examined by retrotransposon-microsatellite amplified polymorphism (REMAP) markers based on the retrotransposon BARE-1. A substantial level of genetic polymorphisms at among- and within-species level was observed showing that this retrotransposon family and its adjacent genomic regions has been a target for genome dynamics during the evolution and domestication of barley. The obtained data are consistent with the current taxonomic status within the genus Hordeum. Similar level of genetic diversity was observed between the wild and the domesticated barley accessions suggesting that transposable elements` activity and accumulation may counteract the decrease of genome-wide diversity following domestication. In addition, eco-geographical sub-genome pools of the cultivated barley were identified in support to the theory of multiple origins of domestication within the genus Hordeum. We also provide conclusions about the relationship between accessions of different species and the putative routes of barley domestication. In conclusion, the retrotransposon BARE-1 stands as a reliable and perspective DNA marker for the assessment of the phylogenetic and domestication history in the genus Hordeum and other crop species.

From FHB Resistance QTLs to Candidate Genes Identification in Triticum aestivum L

Fusarium head blight (FHB) caused by Fusarium graminearum is a worldwide destructive disease affecting cereals such as wheat. FHB resistance is a quantitative trait, and information for FHB resistance QTLs in wheat is available. However, little is known about genes underlying the FHB resistance QTL regions. Using a computational approach in this study, we have mined eight FHB resistance QTLs in wheat and predicted the candidate genes falling within these QTL intervals based on the available sequences and markers. A total of 18 genomic scaffolds located at chromosomes 2AL, 2DL, 3B and 4BS were prioritized to harbor FHB-resistant candidate genes. These genes are mainly involved in plant defense response, immune regulation and cellular detoxification. We believe that our results constitute a starting point for further validation to improve FHB-resistant bread wheat varieties.

Unpredictability of nectar nicotine promotes outcrossing by hummingbirds in Nicotiana attenuata

Many plants use sophisticated strategies to maximize their reproductive success via outcrossing. Nicotiana attenuata flowers produce nectar with nicotine at concentrations that are repellent to hummingbirds, increasing the number of flowers visited per plant. In choice tests using native hummingbirds, we show that these important pollinators learn to tolerate high-nicotine nectar but prefer low-nicotine nectar, and show no signs of nicotine addiction. Nectar nicotine concentrations, unlike those of other vegetative tissues, are unpredictably variable among flowers, not only among populations, but also within populations, and even among flowers within an inflorescence. To evaluate whether variations in nectar nicotine concentrations increase outcrossing, polymorphic microsatellite markers, optimized to evaluate paternity in native N. attenuata populations, were used to compare outcrossing in plants silenced for expression of a biosynthetic gene for nicotine production (Napmt1/2) and in control empty vector plants, which were antherectomized and transplanted into native populations. When only exposed to hummingbird pollinators, seeds produced by flowers with nicotine in their nectar had a greater number of genetically different sires, compared to seeds from nicotine-free flowers. As the variation in nectar nicotine levels among flowers in an inflorescence decreased in N. attenuata plants silenced in various combinations of three Dicer-like (DCL) proteins, small RNAs are probably involved in the unpredictable variation in nectar nicotine levels within a plant.

Quantification and organization of WIS2-1A and BARE-1 retrotransposons in different genomes of Triticum and Aegilops species

A real-time PCR approach was adopted and optimized to estimate and compare, through a relative quantification, the copy number of WIS2-1A and BARE-1 retrotransposons. The aim of this approach was to identify and quantify the presence of these retrotransposons in Triticum and Aegilops species, and to understand better the genome organization of these retroelements. The species were selected to assess and compare the evolution of the different types of genomes between the more recent species such as the diploid Triticum monococcum, tetraploid T. dicoccon and hexaploid T. spelta, and the corresponding genome donors of the ancient diploids Aegilops (Ae. speltoides, Ae. tauschii, Ae. sharonensis and Ae. bicornis) and T. urartu. The results of this study indicated the presence of great variation in copy number both within and among species, and the existence of a non-linear relationship between retrotransposon copy number and ploidy level. For WIS2-1A, as expected, T. monococcum showed the lowest copy number which instead was similar in T. dicoccon and T. spelta; also T. urartu (AA), Ae. speltoides (BB) and Ae. tauschii (DD) showed a higher WIS2-1A copy number. Similar results were observed for BARE-1 retroelements except for Ae. tauschii which as in T. monococcum showed lower retroelements content; a similar content for T. dicoccon and T. urartu, whereas a higher number was found in T. spelta and Ae. speltoides. The results presented here are in accord with previous studies and contribute to unravelling the structure and evolution of polyploidy and repetitive genomes.

Triticeae genomics: advances in sequence analysis of large genome cereal crops

Whole genome sequencing provides direct access to all genes of an organism and represents an essential step towards a systematic understanding of (crop) plant biology. Wheat and barley, two of the most important crop species worldwide, have two- to five-fold larger genomes than human - too large to be completely sequenced at current costs. Nevertheless, significant progress has been made to unlock the gene contents of these species by sequencing expressed sequence tags (EST) for high-density mapping and as a basis for elucidating gene function on a large scale. Several megabases of genomic (BAC) sequences have been obtained providing a first insight into the complexity of these huge cereal genomes. However, to fully exploit the information of the wheat and barley genomes for crop improvement, sequence analysis of a significantly larger portion of the Triticeae genomes is needed. In this review an overview of the current status of Triticeae genome sequencing and a perspective concerning future developments in cereal structural genomics is provided.

Capturing diversity in the cereals: many options but little promiscuity

It is generally recognized by geneticists and plant breeders alike that there is a need to further improve the ability to capture and manipulate genetic diversity. The effective harnessing of diversity in traditional breeding programmes is limited and, therefore, it is vital that meiotic recombination can be manipulated given that it plays a pivotal role in generating diversity. With the advent of a wider range of genomics technologies, our understanding of meiotic processes should increase rapidly. Although comparative genetics has been useful, particularly in the broader grass family, the development of physical maps, long-range sequencing and transcript profiles promises to unravel the complexities of genomes as large or larger than wheat. Highlighting the most significant findings to date, this review pools the knowledge on these tools and reproductive processes.