HvPap-1 C1A Protease and HvCPI-2 Cystatin Contribute to Barley Grain Filling and Germination

Overview

Journal Plant Physiol

Specialty Physiology

Date 2016 Feb 26

PMID 26912343

Citations 13

Authors

Mercedes Diaz-Mendoza

Jose D Dominguez-Figueroa

Blanca Velasco-Arroyo

Ines Cambra

Pablo Gonzalez-Melendi

Angeles Lopez-Gonzalvez

Antonia Garcia

Goetz Hensel

Jochen Kumlehn

Isabel Diaz

Manuel Martinez

Affiliations

Soon will be listed here.

Abstract

Proteolysis is an essential process throughout the mobilization of storage proteins in barley (Hordeum vulgare) grains during germination. It involves numerous types of enzymes, with C1A Cys proteases the most abundant key players. Manipulation of the proteolytic machinery is a potential way to enhance grain yield and quality, and it could influence the mobilization of storage compounds along germination. Transgenic barley plants silencing or over-expressing the cathepsin F-like HvPap-1 Cys protease show differential accumulation of storage molecules such as starch, proteins, and free amino acids in the grain. It is particularly striking that the HvPap-1 artificial microRNA lines phenotype show a drastic delay in the grain germination process. Alterations to the proteolytic activities in the over-expressing and knock-down grains associated with changes in the level of expression of several C1A peptidases were also detected. Similarly, down-regulating cystatin Icy-2, one of the proteinaceous inhibitors of the cathepsin F-like protease, also has important effects on grain filling. However, the ultimate physiological influence of manipulating a peptidase or an inhibitor cannot be always predicted, since the plant tries to compensate the modified proteolytic effects by modulating the expression of some other peptidases or their inhibitors.

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