Your search keyword '"Pasteels JM"' showing total 3 results

1. To be or not to be convergent in salicin-based defence in chrysomeline leaf beetle larvae: evidence from Phratora vitellinae salicyl alcohol oxidase.

Author

Kirsch R, Vogel H, Muck A, Vilcinskas A, Pasteels JM, and Boland W

Subjects

Aldehydes chemistry, Aldehydes metabolism, Animals, Base Sequence, Bayes Theorem, Blotting, Western, Cell Line, Cluster Analysis, Coleoptera genetics, Coleoptera metabolism, Larva enzymology, Larva immunology, Larva metabolism, Models, Genetic, Molecular Sequence Data, Molecular Structure, Phylogeny, Sequence Analysis, DNA, Species Specificity, Tandem Mass Spectrometry, Alcohol Oxidoreductases genetics, Alcohol Oxidoreductases metabolism, Benzyl Alcohols metabolism, Coleoptera enzymology, Coleoptera immunology, Evolution, Molecular, Glucosides metabolism

Abstract

Glandular chemical defence relying on the action of salicylaldehyde is characteristic for Chrysomela leaf beetle larvae. The salicylaldehyde precursor salicin, sequestered from salicaceous host plants, is deglucosylated and the aglycon further oxidized by a salicyl alcohol oxidase (SAO) to the respective aldehyde. SAOs, key enzymes in salicin-based glandular chemical defence, were previously identified and shown to be of a single evolutionary origin in Chrysomela species. We here identified and characterized SAO of Phratora vitellinae, the only species outside the genus Chrysomela that produce salicylaldehyde as a defensive compound. Although Chrysomela and Phratora are not closest relatives, their SAOs share glucose-methanol-choline oxidoreductase (GMC) affiliation, a specific GMCi subfamily ancestor, glandular tissue-specific expression and almost identical gene architectures. Together, this strongly supports a single origin of SAOs of both Chrysomela and Phratora. Closely related species of Chrysomela and P. vitellinae use iridoids as defensive compounds, which are like salicylaldehyde synthesized by the consecutive action of glucosidase and oxidase. However, we elucidated SAO-like sequences but no SAO proteins in the glandular secretion of iridoid producers. These findings support a different evolutionary history of SAO, related genes and other oxidases involved in chemical defence in the glandular system of salicylaldehyde and iridoid-producing leaf beetle larvae.

Published

2011

2. Glucose and glucose esters in the larval secretion of Chrysomela lapponica; selectivity of the glucoside import system from host plant leaves.

Author

Tolzin-Banasch K, Dagvadorj E, Sammer U, Kunert M, Kirsch R, Ploss K, Pasteels JM, and Boland W

Subjects

Animals, Biological Transport, Butyrates chemistry, Butyrates metabolism, Coleoptera physiology, Esters, Larva metabolism, Larva physiology, Betula metabolism, Coleoptera metabolism, Glucose chemistry, Glucose metabolism, Glucosides metabolism, Plant Leaves metabolism

Abstract

Larvae of Chrysomela lapponica (Coleoptera: Chrysomelidae) sequester characteristic O-glucosides from the leaves of their food plants, namely Betula and/or Salix The present study focuses on birch-feeding larvae of C. lapponica from the Altai region in East Kazakhstan. As in other sequestering leaf beetle larvae, the compounds are transported intact via different membrane barriers into the defensive system, followed by glucoside cleavage and subsequent transformations of the plant-derived aglycones. Unlike previous studies with model compounds, we studied the sequestration of phytogenic precursors by analyzing the complex pattern of glucosides present in food plant Betula rotundifolia (39 compounds) and compared this composition with the aglycones present as butyrate esters in the defensive secretion. In addition to the analytic approach, the insect's ability, to transport individual glucosides was tested by using hydrolysis-resistant thioglucoside analogs, applied onto the leaf surface. The test compounds reach the defensive system intact and without intermediate transformation. No significant difference of the transport capacity and selectivity was observed between larvae of birch-feeding population from Kazakhstan, and previous results for larvae of birch-feeding population from the Czech Republic or willow-feeding populations. Overall, the transport of the phytogenic glucosides is highly selective and highly efficient, since only minor compounds of the spectrum of phytogenic glucoside precursors contribute to the limited number of aglycones utilized in the defensive secretion. Interestingly, salicortin 44 and tremulacin 60 were found in the leaves, but no aldehyde or esters of salicylalcohol. Surprisingly, we observed large amounts of free glucose, together with small amounts of 6-O-butyrate esters of glucose (27a/b and 28a/b).

Published

2011

3. A versatile transport network for sequestering and excreting plant glycosides in leaf beetles provides an evolutionary flexible defense strategy.

Author

Discher S, Burse A, Tolzin-Banasch K, Heinemann SH, Pasteels JM, and Boland W

Subjects

Animals, Biological Evolution, Biological Transport, Glucosides metabolism, Iridoids metabolism, Larva metabolism, Malpighian Tubules metabolism, Coleoptera metabolism, Glucosides chemistry, Plant Leaves chemistry

Abstract

The larval defenses of chrysomeline leaf beetles comprise components that are either synthesized de novo or sequestered from their food plants. Both biosynthetic modes are based on glucosides that serve as substrates and forms of transport. The defensive glands import the compounds through highly selective glucoside transporters from a circulating pool in the hemolymph. Here we address the selectivity of the different transport systems with larvae of Chrysomela populi, an obligate sequestering species, and with larvae of Phaedon cochleariae, producing monoterpene [corrected] iridoids. Both species possess an interconnected network of transport systems for uptake and excretion. The glucosides are imported by the gut membrane with low selectivity. Their excretion by the Malpighian tubules is similarly unselective, but the uptake of the glucosides from the hemolymph into the defensive system is specific. Only the genuine glucoside precursors made de novo or sequestered from the plant are imported. The successful combination of the precursor-adapted pathways of excretion and defense has probably allowed many leaf beetle species to adaptively radiate onto, and coevolve with plants that offer appropriate glucoside precursors.

Published

2009