Lund University is celebrating 350 years.


Javascript is not activated in your browser. This website needs javascript activated to work properly.
You are here

Plant interactions with antimicrobial peptides

Plant cellular resistance to antibiotic peptides

Antimicrobial peptides that attack biological membranes, and thus cell integrity, are synthesised by animals, plants, fungi and bacteria to fight other organisms, but what determines specificity of interactions between particular peptides and target membranes is little known. Trichoderma is a soil living fungus, which is usually benefical to plants. It is therefore used for biocontrol of plant pathogens. Trichoderma cells excrete antimicrobial peptides that attack and create pores in biological membranes. Surprisingly, we have observed that sterile-grown plant cells are susceptible to permeabilisation by the major Trichoderma viride peptide alamethicin. However, if plant cells are first treated with cellulase excreted by Trichoderma viride, they become resistant to the antimicrobial peptide from the same fungus. Plasma membranes from resistant cells contained less sterols and phosphatidylserine, which probably affects the channel formation activity of the peptide. As a consequence, the plant becomes resistant to alamethicin, whereas the pathogens may remain sensitive, adding to the biocontrolling function of Trichoderma. Present studies are aimed at elucidating the molecular mechanisms involved in this interaction, and to evidence if this has direct importance for biocontrol and for peptide-membrane interactions in other organisms.

Peptide permeabilisation for in situ analysis of cellular processes

In the cell, metabolic processes take place in a relatively crowded environment including weak protein interactions that are lost upon extraction of the proteins. We introduced alamethicin, a hydrophobic peptide secreted by Trichoderma viride that creates channels in membranes, to study cytosolic, mitochondrial and plasma membrane enzyme complexes inside otherwise intact organelles and cells. Using this technology, mitochondrial electron transport enzymes were found to have other properties than when observed by disruptive methods. Likewise, intact cells have been used for measuring synthesis of cell wall components and study how this synthesis responds to destabilisation of microtubules. Thus, alamethicin permeabilisation allows characterisations of complex soluble and membrane-located enzyme systems in their natural crowded cellular environment under conditions of minimal perturbance of cellular integrity.

Page Manager: