Analysis of Defense-Related Gene Expression in Citrus Hybrids Infected by Xylella fastidiosa.

Resistance to Xylella fastidiosa was evaluated in 264 hybrids of crosses between Murcott tangor (Citrus reticulata × Citrus sinensis) and Pera sweet orange (C. sinensis) under field conditions. Uninfected hybrids were grafted with buds collected from Pera sweet orange plants infected with X. fastidiosa, forming a plant with two scions (i.e., hybrid branches and Pera sweet orange branches). From these plants, we chose 10 genotypes with three biological replicates. We evaluated gene expression, bacterial multiplication, and citrus variegated chlorosis (CVC) symptom development in both scions. X. fastidiosa was not detected in most hybrid scions and none showed disease symptoms. In contrast, all Pera sweet orange scions were infected with X. fastidiosa and expressed symptoms of CVC. We quantified the expression of 12 defense-related genes by qPCR comparing resistant to susceptible scions. We suggest that some of these genes are involved in resistance of the hybrids to X. fastidiosa, since their expression was significantly higher in the resistant hybrid scions than in tolerant hybrids and scions originated from CVC symptomatic Pera sweet orange buds. However, we note that these data should be interpreted carefully, as the plant genotypes tested are related but necessarily distinct (hybrids of C. reticulata and C. sinensis, in relation to a C. sinensis control). A principal component analysis revealed a relationship between the expression of these genes and hybrid scions, and between scions that originated from infected buds and the presence of the bacteria and plant symptoms. Multiyear field trials are necessary to develop plant resistance to X. fastidiosa. While the experimental design used here had limitations, it allowed us to identify a set of genes potentially involved in Citrus sp. resistance to this pathogen. Future work on the role of these genes in plant defenses to X. fastidiosa infection is necessary to confirm their importance in the displayed resistance phenotype.

Gyroxin and its biological activity: effects on CNS basement membranes and endothelium and protease-activated receptors.

Gyroxin is a glycoprotein isolated from rattlesnake venom, with known thrombin-like serine protease properties and behavioral action in the CNS. The mechanism of the latter has eluded experimenters for three decades. In this paper about the in vitro chick retina we demonstrate an excitotoxic CNS action of Gyroxin by observing retinal Intrinsic Optical Signals (IOS). These show sudden dynamic changes in the intact tissue due to gyroxin action. The very fast kinetics of this response precludes deep tissue penetration by the protein, a mechanism of tissue response described here for the first time. At nanomolar concentrations, Gyroxin alters profoundly the optical profiles of retinal spreading depression waves (RSDs), suggesting modulation of ionic transport and metabolism. This effect is reversible in contrast with the acute cell lysis induced with gyroxin pulses at higher concentration. Because there may be more than one target of Gyroxine at the retinal inner limiting membrane, additional biochemical assays were performed to study a possible Na/K-ATPase blockade and PAR receptor activation. We conclude that the Gyroxin interaction with basement membranes of CNS and endothelium triggers conformational phase transitions at basement membranes, with multiple functional consequences.

Biodistribution studies of bee venom and spider toxin using radiotracers

The use of radiotracers allows the understanding of the bioavailability process, biodistribution, and kinetics of any molecule labelled with an isotope, which does not alter the molecule's biological properties. In this work, technetium-99m and iodine-125 were chosen as radiotracers for biodistribution studies in mice using bee (Apis mellifera) venom and a toxin (PnTX2-6) from the Brazilian "armed" spider (Phoneutria nigriventer) venom. Incorporated radioactivity was measured in the blood, brain, heart, lung, liver, kidney, adrenal gland, spleen, stomach, testicle, intestine, muscle, and thyroid gland. Results provided the blood kinetic parameter, and different organs distribution rates.(AU)