Physical and Chemical Barriers in Root Tissues Contribute to Quantitative Resistance to F. Sp. in Pea

Overview

Journal Front Plant Sci

Date 2018 Mar 9

PMID 29515610

Citations 25

Authors

Moustafa Bani

Alejandro Perez-de-Luque

Diego Rubiales

Nicolas Rispail

Affiliations

Soon will be listed here.

Abstract

Fusarium wilt caused by f. sp. () is one of the most destructive diseases of pea worldwide. Control of this disease is difficult and it is mainly based on the use of resistant cultivars. While monogenic resistance has been successfully used in the field, it is at risk of breakdown by the constant evolution of the pathogen. New sources of quantitative resistance have been recently identified from a wild relative spp. collection. Here, we characterize histologically the resistance mechanisms occurring in these sources of quantitative resistance. Detailed comparison, of the reaction at cellular level, of eight pea accessions with differential responses to race 2, showed that resistant accessions established several barriers at the epidermis, exodermis, cortex, endodermis and vascular stele efficiently impeding fungal progression. The main components of these different barriers were carbohydrates and phenolic compounds including lignin. We found that these barriers were mainly based on three defense mechanisms including cell wall strengthening, formation of papilla-like structures at penetration sites and accumulation of different substances within and between cells. These defense reactions varied in intensity and localization between resistant accessions. Our results also clarify some steps of the infection process of in plant and support the important role of cell wall-degrading enzymes in pathogenicity.

Citing Articles

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