Recent advances on proteins of plant terminal membranes

Integration of Plasma Membrane and Nuclear Signaling in Elicitor Regulation of Plant Secondary Metabolism

The plant kingdom represents a valuable source of natural products of commercial interest. These compounds, named secondary metabolites, are not essential for the survival of plants, but confer them some advantages that allow adaptation to changes in their environment. Nevertheless, yields of secondary metabolites are low for commercial purposes, so it has become important to design strategies for increasing their production. Plants manage to adapt to physical changes in their environment, defending themselves against pathogen attack or herbivore wounding. Such aggressive stimuli, also known as elicitors, initiate signaling metabolic cascades that induce accumulation of certain secondary metabolites. Progress has been recently achieved in the understanding of signaling events originating from elicitation and related transcriptional regulation. These advances will allow maneuvering expression of key enzymes implicated in biosynthetic pathways of secondary metabolites, thereby enhancing their accumulation.

Pathogen derived elicitors: searching for receptors in plants

SUMMARY Recognition of potential pathogens is central to plants' ability to defend themselves against harmful microbes. Plants are able to recognize pathogen-derived molecules; elicitors that trigger a number of induced defences in plants. Microbial elicitors constitute a bewildering array of compounds including different oligosaccharides, lipids, peptides and proteins. Identifying the receptors for this vast array of elicitors is a major research challenge. Only in a very few cases has the cognate receptor for a particular elicitor been identified. Biochemical studies have resulted in the characterization of some elicitor binding proteins that may be part of the recognition complex. Transmembrane receptor-like protein kinases (RLKs) constitute one of the most likely categories of receptors involved in pathogen perception. Some of these serine/threonine kinases have been identified as resistance or R genes, others as induced by pathogens or elicitors. One of the RLKs belonging to a leucine rich repeat (LRR) class of putative receptor kinases was recently identified as a receptor for bacterial flagellin, and the underlying signal pathway leading to activation of defence genes was elucidated. These and other recent studies have revealed intriguing similarities in elicitor recognition and defence signalling processes in plant and animal hosts suggesting a common evolutionary origin of eukaryotic defence mechanisms.

Plant ion channels: from molecular structures to physiological functions

Progress in identification of plant ion channels and development of electrophysiological analyses in heterologous expression systems and in planta, in combination with reverse genetic approaches, are providing the possibility of associating molecular entities with physiological functions. Recently, the first attempts to determine in vivo functions using knockout mutants demonstrated the roles of root ion channels. The search for proteins interacting with such channels leads to an even more complex view of the concerted action in protein networks.