Functional Analysis of the Salicylic Acid-Responsive PR-1 Promoter in Arabidopsis thaliana / Funktionale Analyse des Salicylsäure-induzierbaren PR-1 Promotors in Arabidopsis thaliana

Pape, Sebastian

09 July 2009

No description available.

580 Pflanzen (Botanik)

Mathematics and Computer Science

NPR1

PR-1

TGA factors

SNI1

Salicylsäure

NPR1

PR-1

TGA factors

SNI1

Salicylic acid

42.43

42.13

Role of SABP2 in Systemic Acquired Resistance Induced by Acibenzolar-S-Methyl in Plants.

Tripathi, Diwaker

13 August 2010

Plants have evolved an efficient mechanism to defend themselves against pathogens. Many biotic and abiotic agents have been shown to induce defense mechanism in plants. Acibenzolar-S-Methyl (ASM) is a commercially available chemical inducer of local and systemic resistance (SAR) response in plants. ASM functioning at molecular level is mostly unclear. This research was designed to investigate the mechanism of ASM action in plants. It was hypothesized that SABP2, a plant protein, plays an important role in ASM-mediated defense signaling. Biochemical studies were performed to test the interaction between SABP2 and ASM. Transgenic SABP2-silenced tobacco plants were used to determine the role of SABP2 in SAR induced by ASM. The expression of PR-1 proteins was used as a marker for SAR induction. Results showed that SABP2 converts ASM into acibenzolar that induces the expression of PR-1 proteins and develops the SAR response in ASM-treated plants.

Resistance

Salicylic Acid

ASM

SAR

SABP2

Nicotiana tabacum

PR-1

Life Sciences

Plant Biology

Plant Sciences

Characterization of defense pathways and genes involved in host-pathovar level resistance using Arabidopsis-Pseudomonas system

Gangadharan, Anju

21 May 2014

No description available.

Plant Biology

Plant Sciences

Plant Pathology

Molecular Biology

Cucurbit Downy Mildew (Pseudoperonospora cubensis): Cucumber Resistance

Cooper, Jessica G.

23 January 2013

Pseudoperonospora cubensis (Bert. et Curt) Rost. is the causal agent of cucurbit downy mildew (CDM). It is the most damaging cucumber pathogen on the Eastern Shore of Virginia and eastern parts of the United States. Pseudoperonospora cubensis is an obligate oomycete pathogen, infecting crops within the Cucurbitaceae family. The disease is characterized by angular chlorotic lesions and a downy or felt-like appearance on the abaxial side of the leaf. Control of this pathogen includes use of resistant cucumber cultivars and costly fungicide programs. Continuous use has led to resistance to commonly used fungicides. This has become a major concern and in response, seed companies have developed cucumber cultivars which claim downy mildew resistance.  This study evaluates different cucumber cultivars and assesses their level of resistance to CDM. The results indicate that an integrated management approach of reduced fungicide application and the use of resistant cultivars can suppress levels of CDM and yield a cucumber crop. Additionally, a molecular study was conducted, comparing the relative expression of genes encoding a basic PR-1 protein, a cytosolic ascorbate peroxidase protein and three resistance (R) gene proteins, in nineteen cultivars. All of the selected genes were analyzed using real-time PCR. The relative expression levels of the R-genes varied between cultivars. The basic PR-1 protein decreased expression in the majority of the cultivars, suggesting no involvement in the first twenty-four hours. Cytosolic ascorbate peroxidase relative expression levels suggest an increase in susceptible cultivars and a decrease in tolerant cultivars. / Master of Science

cucurbit downy mildew

cucumber

CSA 06724

cyazofamid

fluopicolide

PR-1

cytosolic ascorbate peroxidase

CSA06758

CSA06757

Purification and characterisation of Tex31, a conotoxin precursor processing protease, isolated from the venom duct of Conus textile

Milne, Trudy Jane

January 2008

The venom of cone snails (predatory marine molluscs of the genus Conus) has yielded a rich source of novel neuroactive peptides or “conotoxins”. Conotoxins are bioactive peptides found in the venom duct of Conus spp. Like other neuropeptides, conotoxins are expressed as propeptides that undergo posttranslational proteolytic processing. Peptides derived from propeptides are typically cleaved at a pair of dibasic residues (Lys-Arg, Arg-Arg, Lys-Lys or Arg-Lys) by proteases found in secretory vesicles. However, many precursor peptides contain multiple sets of basic residues, suggesting that highly substrate specific or differentially expressed proteases can determine processing outcomes. As many of the substrate-specific proteases remain unidentified, predicting new bioactive peptides from cDNA sequences is presently difficult, if not impossible. In order to understand more about the substrate specificity of conotoxin substrate-specific proteases a characterisation study of one such endoprotease isolated from the venom duct of Conus textile was undertaken. The C. textile mollusc was chosen as a good source from which to isolate the endoprotease for two reasons; firstly, these cone shells are found in great abundance on the Great Barrier Reef (Queensland, Australia) and are readily obtainable and secondly, a number of conotoxin precursors and their cleavage products have been previously identified in the venom duct. In order to purify the endoprotease an activity-guided fractionation protocol that included a para-nitroanilide (p-NA) substrate assay was developed. The p-NA substrate mimicked the cleavage site of the conotoxin TxVIA, a member of the C. textile O-superfamily of toxins. The protocol included a number of chromatographic techniques including ion exchange, size-exclusion and reverse-phased HPLC and resulted in isolation of an active protease, termed Tex31, to >95% purity. The purification of microgram quantities of Tex31 made it possible to characterise the proteolytic nature of Tex31 and to further characterise the O-superfamily conopeptide propeptide cleavage site specificity. Specificity experiments showed Tex31 requires a minimum of four residues including a leucine in the P4 position (LNKR↓) for efficient substrate processing. The complete sequence of Tex31 was determined from cDNA. A BLAST search revealed Tex31 to have high amino acid sequence similarity to the CAP (abbreviated from CRISP (Cysteine-rich secretory protein), Antigen 5 and PR-1 (pathogenesis-related protein)) superfamily and most closely related to the CRISP family of mammalian and venom proteins that, like Tex31, have a cysteine-rich C-terminal domain. The CAP superfamily is widely distributed in the animal, plant and fungal kingdoms, and is implicated in processes as diverse as human brain tumour growth and plant pathogenesis. This is the first report of a biological role for the N-terminal domain of CAP proteins. A homology model of Tex31 constructed from two PR-1 proteins, Antigen 5 and P14a, revealed the highly conserved and likely catalytic residues, His78, Ser99 and Glu115. These three amino acids fall within a structurally conserved N-terminal domain found in all CAP proteins. It is possible that other CAP proteins are also substrate-specific proteases. With no homology to any known proteases, Tex31 may belong to a new class of protease. The sequence alignment of five Tex31-like proteins cloned from C. marmoreus, C. litteratus, C. arentus, C. planboris, and C. omaria show very high sequence similarity to Tex31 (~80%), but only one weakly conserved serine residue was identified when the conserved residues of the new Tex31-like protein sequences were aligned with members of the CAP superfamily. Future work to identify members of catalytic diad or triad, e.g. by site-directed mutagenesis, will rely on the expression of active recombinant Tex31. In this study neither Escherichia coli nor Pichia pastoris expression systems yielded active recombinant Tex31 protein, possibly due to the number of cysteine residues hindering the expression of correctly folded active Tex31. This study has shown Tex31 to be highly sequence specific in its cleavage site and it is likely that this high substrate specificity has confounded previous attempts to identify the proteolytic nature of other CAP proteins. With the proteolytic nature of one member of the CAP protein family confirmed, it is hoped this important discovery may lead the way to discovering the role of other CAP family members.

Plant-Pathogen Interactions: Turnip Crinkle Virus Suppression of the Hypersensitive Response in Arabidopsis thaliana

Christopher, Stephen James

29 April 2003

The presence of turnip crinkle virus (TCV) in Arabidopsis thaliana plants has previously been shown to suppress the ability of these plants to produce a hypersensitive response (HR) upon inoculation with pathogens that would normally elicit this defense response. The ecotype Colombia-0 was examined using wildtype TCV and non-pathogenic strains of Pseudomonas syringae pv. glycinea Race 4 containing virulence genes avrRpt2, avrRpm1 and avrRps4. Transgenic lines of A. thaliana that express the TCV proteins p8, p9 or CP were also examined in an attempt to determine if these proteins play a role in suppression of the HR. Crosses of these transgenic lines were made in order to determine if binary combinations of these proteins were sufficient for HR suppression. In addition, assays were completed to determine if the inhibition of the HR correlated with suppression of resistance to the virulent Pseudomonas syringae pv. maculicola ES4236 avrRpt2 growth in the plant. Finally, PR-1 protein expression was inspected by visual and quantitative GUS reporter gene assays to determine if TCV also played a role in inhibition of the plants ability to develop systemic acquired resistance (SAR).

Turnip crinkle virus

arabidopsis

thaliana

TCV

avrRpt2

avrRpm1

avrRps4

systemic acquired resistance

resistance

plant disease

susceptability

PR-1

transgenics

avirulence

virulence

Avr gene

R gene

pseudomonas syringae.

Plants

Virus resistance

Turnip crinkle virus

Arabidopsis