NoPv1: a synthetic antimicrobial peptide aptamer targeting the causal agents of grapevine downy mildew and potato late blight.

Grapevine (Vitis vinifera L.) is a crop of major economic importance. However, grapevine yield is guaranteed by the massive use of pesticides to counteract pathogen infections. Under temperate-humid climate conditions, downy mildew is a primary threat for viticulture. Downy mildew is caused by the biotrophic oomycete Plasmopara viticola Berl. & de Toni, which can attack grapevine green tissues. In lack of treatments and with favourable weather conditions, downy mildew can devastate up to 75% of grape cultivation in one season and weaken newly born shoots, causing serious economic losses. Nevertheless, the repeated and massive use of some fungicides can lead to environmental pollution, negative impact on non-targeted organisms, development of resistance, residual toxicity and can foster human health concerns. In this manuscript, we provide an innovative approach to obtain specific pathogen protection for plants. By using the yeast two-hybrid approach and the P. viticola cellulose synthase 2 (PvCesA2), as target enzyme, we screened a combinatorial 8 amino acid peptide library with the aim to identify interacting peptides, potentially able to inhibit PvCesa2. Here, we demonstrate that the NoPv1 peptide aptamer prevents P. viticola germ tube formation and grapevine leaf infection without affecting the growth of non-target organisms and without being toxic for human cells. Furthermore, NoPv1 is also able to counteract Phytophthora infestans growth, the causal agent of late blight in potato and tomato, possibly as a consequence of the high amino acid sequence similarity between P. viticola and P. infestans cellulose synthase enzymes.

An ON/OFF biosensor based on blockade of ionic current passing through a solid-state nanopore.

Single nanopores have attracted interest for their use as biosensing devices. In general, methods involve measuring ionic current blockades associated with translocation of analytes through the nanopore, but the detection of such short time lasting events requires complex equipment and setup that are critical for convenient routine biosensing. Here we present a novel biosensing concept based on a single nanopore in a silicon nitride membrane and two anchor-linked DNA species that forms trans-pore hybrids, realizing a stable blockade of ionic current through the pore. Molecular recognition events affecting the DNA hybrids cause a pore opening and the consequent establishment of an ionic current. In the present implementation of the device, we constructed a magnetic bead/streptavidin/biotin-DNA1/DNA2-biotin/streptavidin/Quantumdot-cluster complex (where DNA1 is a mismatched reverse complement of DNA2) through a sub-micrometric pore and monitored DNA strand displacement events occurring after addition of an oligonucleotide complementary to DNA2. The electric and mechanical aspects of the novel device, as well as its potential in biosensing are discussed.