Nancy F. Silva scite author profile

We report the isolation and characterization of PERKI (Proline Extensin-like Receptor Kinase 1), a novel plant RLK from Brassica napus that is predicted to consist of a proline-rich extracellular domain with sequence similarity to extensins, a transmembrane region, and a catalytic domain possessing serine/threonine kinase activity. Database searches with the predicted PERK1 amino acid sequence also led to the identification of a predicted family of related genes in the Arabidopsis genome. Using biolistic bombardment of onion epidermal cells, we have shown that a PERK1-GFP fusion is localized to the plasma membrane as predicted for a receptor kinase. Given the similarity of PERK1's extracellular domain to extensins, a possible role in plant defense responses was investigated by treating B. napus tissue with mechanical stresses and infection with the fungal pathogen, Sclerotinia sclerotiorum. Various wounding stimuli resulted in a dramatic and rapid accumulation of PERK1 mRNA. Levels of PERK1 mRNA also increased moderately in response to infection by the fungal pathogen S. sclerotiorum. Given the kinetics of PERK1 mRNA accumulation in response to these treatments, PERK1 may be involved early on in the general perception and response to a wound and/or pathogen stimulus.

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Receptor kinase signalling in plants

Haffani¹,

Silva²,

Goring³

2004

Can. J. Bot.

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Recent plant genome analyses have revealed a large family of plant receptor kinases with very divergent extracellular domains. While a large proportion of this family remains uncharacterized, emerging functions for several plant receptor kinases reveal roles in a variety of biological processes including growth, development, hormone perception, and plantmicrobe interactions. Significant progress has also been made in the understanding of four plant receptor kinase systems including their respective ligands and signalling pathways. Interestingly, a wide range of signalling proteins have been identified as functioning with these receptor kinases. In this review, an overview of plant receptor kinases, their biological functions, and their signalling pathways is presented.Key words: plants, Arabidopsis, receptor kinase, signal transduction.

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Functional characterization of ARAKIN (ATMEKK1): a possible mediator in an osmotic stress response pathway in higher plants

Covic

Silva

Lew

1999

Biochimica et Biophysica Acta (BBA) - Molecular Cell Research

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The Arabidopsis thaliana ARAKIN (ATMEKK1) gene shows strong homology to members of the (MAP) mitogen-activated protein kinase family, and was previously shown to functionally complement a mating defect in Saccharomyces cerevisiae at the level of the MEKK kinase ste11. The yeast STE11 is an integral component of two MAP kinase cascades: the mating pheromone pathway and the HOG (high osmolarity glycerol response) pathway. The HOG signal transduction pathway is activated by osmotic stress and causes increased glycerol synthesis. Here, we first demonstrate that ATMEKK1 encodes a protein with kinase activity, examine its properties in yeast MAP kinase cascades, then examine its expression under stress in A. thaliana. Yeast cells expressing the A. thaliana ATMEKK1 survive and grow under high salt (NaCl) stress, conditions that kill wild-type cells. Enhanced glycerol production, observed in non-stressed cells expressing ATMEKK1 is the probable cause of yeast survival. Downstream components of the HOG response pathway, HOG1 and PBS2, are required for ATMEKK1-mediated yeast survival. Because ATMEKK1 functionally complements the sho1/ssk2/ssk22 triple mutant, it appears to function at the level of the MEKK kinase step of the HOG response pathway. In A. thaliana, ATMEKK1 expression is rapidly (within 5 min) induced by osmotic (NaCl) stress. This is the same time frame for osmoticum-induced effects on the electrical properties of A. thaliana cells, both an immediate response and adaptation. Therefore, we propose that the A. thaliana ATMEKK1 may be a part of the signal transduction pathway involved in osmotic stress.

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Characterization of a novel Brassica napus kinase, BNK1

et al. 2001

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Nancy F. Silva

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Receptor kinase signalling in plants

Functional characterization of ARAKIN (ATMEKK1): a possible mediator in an osmotic stress response pathway in higher plants

Characterization of a novel Brassica napus kinase, BNK1

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