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Defence Proteins (defence + protein)

Distribution by Scientific Domains
Life Sciences75%

Selected Abstracts

Crystallization and preliminary crystallographic analysis of recombinant VSP1 from Arabidopsis thaliana

ACTA CRYSTALLOGRAPHICA SECTION F (ELECTRONIC), Issue 2 2010
Zhu-Bing Shi
VSP1 is a defence protein in Arabidopsis thaliana that may also be involved in control of plant development. The recombinant protein has been overexpressed in Escherichia coli, purified and crystallized using the sitting-drop vapour-diffusion method. The crystal diffracted to 1.9,Å resolution and a complete X-ray data set was collected at 100,K using Cu,K, radiation from a rotating-anode X-ray source. The crystals belonged to space group C2. As there are no related structures that could be used as a search model for molecular replacement, work is in progress on experimental phasing using heavy-atom derivatives and selenomethionine derivatives. [source]

Antifungal Activity of a Bowman,Birk-type Trypsin Inhibitor from Wheat Kernel

JOURNAL OF PHYTOPATHOLOGY, Issue 7-8 2000
G. Chilosi
A trypsin inhibitor from wheat kernel (WTI) was found to have a strong antifungal activity against a number of pathogenic fungi and to inhibit fungal trypsin-like activity. WTI inhibited in vitro spore germination and hyphal growth of pathogens, with protein concentration required for 50% growth inhibition (IC50) values ranging from 111.7 to above 500 ,g/ml. As observed by electron microscopy, WTI determined morphological alterations represented by hyphal growth inhibition and branching. One of the fungal species tested, Botrytis cinerea produced a trypsin-like protease, which was inhibited by the trypsin inhibitor. WTI, as well as other seed defence proteins, appear to be an important resistance factor in wheat kernels during rest and early germination when plants are particularly exposed to attack by potential soil-borne pathogens. Zusammenfassung Ein Trypsinhemmer aus Weizenkörnern (WTI) zeigte eine starke antifungale Aktivität gegenüber verschiedenen pathogenen Pilzen und hemmte deren trypsinähnliche Aktivität. WTI hemmte in vitro die Sporenkeimung und das Hyphenwachstum der Pathogene, wobei die IC50 -Werte zwischen 111,7 und mehr als 500 ,g/ml lagen. Elektronenmikroskopische Untersuchungen zeigten, dai WTI morphologische Veränderungen bewirkte, die aus einer Hemmung des Hyphenwachstums und einer veränderten Verzweigung bestanden. Eine der untersuchten Pilzarten, Botrytis cinerea, bildete eine trypsinähnliche Protease, die durch den Trypsininhibitor gehemmt wurde. Ebenso wie andere sameneigene Abwehrproteine scheint WTI während der Keimruhe und in den frühen Stadien der Keimung, wenn die Pflanzen gegenüber möglichen bodenbürtigen Pathogenen besonders exponiert sind, ein wichtiger Resistenzfaktor in Weizenkörnern zu sein. [source]

The role of plant defence proteins in fungal pathogenesis

MOLECULAR PLANT PATHOLOGY, Issue 5 2007
RICARDO B. FERREIRA
SUMMARY It is becoming increasingly evident that a plant,pathogen interaction may be compared to an open warfare, whose major weapons are proteins synthesized by both organisms. These weapons were gradually developed in what must have been a multimillion-year evolutionary game of ping-pong. The outcome of each battle results in the establishment of resistance or pathogenesis. The plethora of resistance mechanisms exhibited by plants may be grouped into constitutive and inducible, and range from morphological to structural and chemical defences. Most of these mechanisms are defensive, exhibiting a passive role, but some are highly active against pathogens, using as major targets the fungal cell wall, the plasma membrane or intracellular targets. A considerable overlap exists between pathogenesis-related (PR) proteins and antifungal proteins. However, many of the now considered 17 families of PR proteins do not present any known role as antipathogen activity, whereas among the 13 classes of antifungal proteins, most are not PR proteins. Discovery of novel antifungal proteins and peptides continues at a rapid pace. In their long coevolution with plants, phytopathogens have evolved ways to avoid or circumvent the plant defence weaponry. These include protection of fungal structures from plant defence reactions, inhibition of elicitor-induced plant defence responses and suppression of plant defences. A detailed understanding of the molecular events that take place during a plant,pathogen interaction is an essential goal for disease control in the future. [source]

Infection of Arabidopsis thaliana leaves with Albugo candida (white blister rust) causes a reprogramming of host metabolism

MOLECULAR PLANT PATHOLOGY, Issue 2 2000
Hsueh-Mei Chou
Albugo candida (Pers.) (O.) Kunze is a biotrophic pathogen which infects the crucifer Arabidopsis thaliana (L.) Heynh forming discrete areas of infection. Eight days after inoculation of leaves, white blisters became visible on the under surface of the leaf although no symptoms were apparent on the upper surface. By day 14, the region of leaf invaded by fungal mycelium had become chlorotic. Recently it has been hypothesized that an accumulation of soluble carbohydrates, following an increase in invertase activity, may trigger sugar signal transduction pathways leading to the repression of photosynthetic gene expression and to the induction of defence proteins. This hypothesis was investigated by quantifying localized changes in carbohydrate and photosynthetic metabolism and the expression of genes encoding photosynthetic and defence proteins. Quantitative imaging of chlorophyll fluorescence revealed that the rate of photosynthesis declined progressively in the invaded regions of the leaf. However, in uninfected regions of the infected leaf the rate of photosynthesis was similar to that measured in the control leaf until late on during the infection cycle when it declined. Images of nonphotochemical fluorescence quenching (NPQ) suggested that the capacity of the Calvin cycle had been reduced in infected regions and that there was a complex metabolic heterogeneity within the infected leaf. A. candida also caused localized changes in the carbohydrate metabolism of the leaf; soluble carbohydrates accumulated in the infected region whereas the amount of starch declined. The reverse was seen in uninfected regions of the infected leaf; carbohydrates did not accumulate until late on during infection and the amount of starch increased as the infection progressed. There was an increase in the activity of invertases which was confined to regions of the leaf invaded by the fungal mycelium. The increase in apoplastic invertase activity was of host origin, as mRNA levels of the AT,FRUCT1 gene (measured by semiquantitative RT-PCR) increased 40-fold in the infected region. The increase in soluble invertase activity resulted from the appearance of a new isoform in the invaded region of the leaf. Current evidence suggests that this was of fungal origin. Northern blot analysis of cab and rbcS showed that photosynthetic gene expression was repressed in the infected leaf from 6 days after inoculation (DAI) when compared to control leaves. In contrast, there was no detectable induction of defence proteins in the infected leaf. These data are discussed in the context of the sugar-sensing hypothesis presented above. [source]