Genetic evidence for plural introduction pathways of the invasive weed Paterson's curse (Echium plantagineum L.) to southern Australia.

Paterson's curse (Echium plantagineum L. (Boraginaceae)), is an herbaceous annual native to Western Europe and northwest Africa. It has been recorded in Australia since the 1800's and is now a major weed in pastures and rangelands, but its introduction history is poorly understood. An understanding of its invasion pathway and subsequent genetic structure is critical to the successful introduction of biological control agents and for provision of informed decisions for plant biosecurity efforts. We sampled E. plantagineum in its native (Iberian Peninsula), non-native (UK) and invaded ranges (Australia and South Africa) and analysed three chloroplast gene regions. Considerable genetic diversity was found among E. plantagineum in Australia, suggesting a complex introduction history. Fourteen haplotypes were identified globally, 10 of which were co-present in Australia and South Africa, indicating South Africa as an important source population, likely through contamination of traded goods or livestock. Haplotype 4 was most abundant in Australia (43%), and in historical and contemporary UK populations (80%), but scarce elsewhere (< 17%), suggesting that ornamental and/or other introductions from genetically impoverished UK sources were also important. Collectively, genetic evidence and historical records indicate E. plantagineum in southern Australia exists as an admixture that is likely derived from introduced source populations in both the UK and South Africa.

Ecology and genetics affect relative invasion success of two Echium species in southern Australia.

Echium plantagineum and E. vulgare are congeneric exotics first introduced to Australia in the early 1800 s. There, E. plantagineum is now highly invasive, whereas E. vulgare has a limited distribution. Studies were conducted to evaluate distribution, ecology, genetics and secondary chemistry to shed light on factors associated with their respective invasive success. When sampled across geographically diverse locales, E. plantagineum was widespread and exhibited a small genome size (1 C = 0.34 pg), an annual life cycle, and greater genetic diversity as assessed by DNA sequence analysis. It was found frequently in areas with temperature extremes and low rainfall. In contrast, E. vulgare exhibited a larger genome size (1 C = 0.43 pg), a perennial lifecycle, less chloroplast genetic diversity, and occurred in areas with lower temperatures and higher rainfall. Twelve chloroplast haplotypes of E. plantagineum were evident and incidence aligned well with reported historical introduction events. In contrast, E. vulgare exhibited two haplotypes and was found only sporadically at higher elevations. Echium plantagineum possessed significantly higher levels of numerous pyrrolizidine alkaloids involved in plant defence. We conclude that elevated genetic diversity, tolerance to environmental stress and capacity for producing defensive secondary metabolites have contributed to the successful invasion of E. plantagineum in Australia.

Cloning and molecular characterization of a glycerol-3-phosphate O-acyltransferase (GPAT) gene from Echium (Boraginaceae) involved in the biosynthesis of cutin polyesters.

The glycerol-based lipid polyester called cutin is a main component of cuticle, the protective interface of aerial plant organs also controlling compound exchange with the environment. Though recent progress towards understanding of cutin biosynthesis has been made in Arabidopsis thaliana, little is known in other plants. One key step in this process is the acyl transfer reaction to the glycerol backbone. Here we report the cloning and molecular characterization of EpGPAT1, a gene encoding a glycerol-3-phosphate O-acyltransferase (GPAT) from Echium pitardii (Boraginaceae) with high similarity to the AtGPAT4/AtGPAT8 of Arabidopsis. Quantitative analysis by qRT-PCR showed highest expression of EpGPAT1 in seeds, roots, young leaves and flowers. Acyltransferase activity of EpGPAT1 was evidenced by heterologous expression in yeast. Ectopic expression in leaves of tobacco plants lead to an increase of C16 and C18 hydroxyacids and alpha,omega-diacids in the cell wall fraction, indicating a role in the biosynthesis of polyesters. Analysis of the genomic organization in Echium revealed the presence of EpGPAT2, a closely related gene which was found to be mostly expressed in developing leaves and flowers. The presence of a conserved HAD-like domain at the N-terminal moiety of GPATs from Echium, Arabidopsis and other plant species suggests a possible phosphohydrolase activity in addition to the reported acyltransferase activity. Evolutive implications of this finding are discussed.

Cloning and molecular characterization of the acyl-CoA: diacylglycerol acyltransferase 1 (DGAT1) gene from Echium.

Boraginaceae species, such as those from the genus Echium, contain high levels of the Delta(6)-desaturated gamma-linolenic (18:3n-6) and octadecatetraenoic (18:4n-3) acids. These are unusual fatty acids among the plant kingdom that are gaining interest due to their benefits to human health. The potential utility of acyltransferases aimed at an increase in oil yield and fatty acid profiling has been reported. In this work, a gene encoding an acyl-CoA:diacylglycerol acyltransferase (DGAT, EC 2.3.1.20) was cloned from Echium pitardii. Genomic and cDNA sequences obtained revealed a gene structure composed of 16 exons, yielding a protein (EpDGAT) of 473 amino acids with high similarity to DGAT1 enzymes of plants. Protein features such as a predicted structure with a highly hydrophilic N-terminus followed by 10 transmembrane domains, as well as the presence of diverse specific signatures, also indicate that EpDGAT belongs to the DGAT1 family. indeed. DGAT activity of the protein encoded by EpDGAT was confirmed by heterologous expression of the full-length cDNA in a yeast mutant (H1246) defective in the synthesis of triacylglycerols. Fatty acid composition of the triacylglycerols synthesized by EpDGAT in H1246 yeast cultures supplemented with polyunsaturated fatty acids suggest a substrate preference for the trienoic fatty acids alpha-linolenic acid (18:3n-3) and gamma-linolenic acid over the dienoic linoleic acid (18:2n-6). Site-directed mutagenesis has revealed the presence of a critical residue (P(178) in EpDGAT) within a reported thiolase signature for binding of acyl-enzyme intermediates that might be involved in the active site of the enzyme. Transcript analysis for EpDGAT shows an ubiquitous expression of the gene which is increased in leaves during senescence.

Delta6-desaturase sequence evidence for explosive Pliocene radiations within the adaptive radiation of Macaronesian Echium (Boraginaceae).

The oceanic islands of Macaronesia provide an ideal temporal and spatial context to test hypotheses of plant evolution using a novel set of phylogenetic markers, Delta(6)-desaturase sequences. In contrast to the limited resolution of standard molecular markers (nrDNA and plastid sequences), the Delta(6)-desaturase sequence phylogeny of Echium unequivocally reconstructs its active colonization across islands and archipelagos (Madeira, the Canary Islands, and Cape Verde), as well as its subsequent geographical and ecological speciation. Molecular-clock estimates using penalized likelihood and Bayesian inference reveal two radiation processes coincident with two dramatic climatic changes recorded in the region: the advent of the cold Canarian sea current (ca. 4 Ma) and the establishment of a strong seasonality in the Pleistocene (1.8 Ma). Though Echium had available all the diversity of present-day Macaronesian environments (xeric and mesic scrub, laurisilva, pine forest, and subalpine habitats) in the Miocene, evolutionary divergence appears to have been triggered by an extension of fluctuating xeric and mesic habitats with the advent of Pliocene conditions. These Echium radiations not only fulfill traditional predictions of adaptive radiation (i.e., common ancestry, rapid speciation, and phenotype-environment correlation), but also, uniquely among Macaronesian species, trait utility of woodiness. A Pliocene transition from annuality to a bush or tree-like condition occurred in early Echium lineages. Maintenance of woodiness in major lineages, and reversal to an herbaceous condition by three independent events, is reported for the first time in plants of oceanic islands.

Substrate specificity of acyl-Delta(6)-desaturases from Continental versus Macaronesian Echium species.

Echium (Boraginaceae) species from the Macaronesian islands exhibit an unusually high level of gamma-linolenic acid (18:3n-6; GLA) and relatively low content of octadecatetraenoic acid (18:4n-3; OTA) in the seed, while the amounts of both fatty acids in their Continental (European) relatives are rather similar. We have tested the hypothesis of whether a different specificity of the acyl-Delta(6)-desaturases (D6DES) towards their respective usual substrates, linoleic acid (18:2n-6; LA) for GLA and alpha-linolenic acid (18:3n-3; ALA) for OTA, was partly responsible for this composition pattern. To this aim we have expressed in yeast the coding sequences of the D6DES genes for the Continental species Echium sabulicola, and the Macaronesian Echium gentianoides. When the yeast cultures are supplemented with the two fatty acid substrates (LA and ALA), a similar utilization of both compounds was found for the D6DES of E. sabulicola, while a preference for LA over ALA was observed for the enzyme of E. gentianoides. This substrate preference must contribute to the increased accumulation of GLA in the seeds of the Macaronesian Echium species. Comparison among the amino acid sequences of these desaturases and other related enzymes, allowed us the discussion about the possible involvement of some specific positions in the determination of substrate specificity.

Heritability of nectar production in Echium vulgare.

Heritabilities of nectar production in the wild species Echium vulgare were estimated as realised heritability under controlled and field conditions. The nectar production of offspring from high- and low-nectar-producing parents was significantly different in both controlled and field conditions, indicating that nectar production is in part genetically determined. The present study is the first one to report a genetic component of variation of nectar production in a wild plant species in the field. Heritability estimated under controlled conditions was 0.13 and therewith less than the heritability estimated under field conditions, which amounted to 0.26. Offspring of high-nectar-producing plants produced comparable amounts of nectar in the growth chamber (1.28 microl) and in the field (1.22 microl). In contrast, the nectar production of offspring of low-nectar-producing plants was significantly higher in the growth chamber (0.95 microl) than in the field (0.55 microl), indicating a genotype by environment interaction. The level of heritability of nectar production was dependent on the environment. Under less favourable conditions, like those in the field, heritability of nectar production increased. Nectar production was not correlated with any of the vegetative or reproductive traits measured, and hence no costs of nectar production could be detected. Results obtained stress the importance of field measurements in determining heritabilities.