The Small Subunit 1 of the Arabidopsis Isopropylmalate Isomerase Is Required for Normal Growth and Development and the Early Stages of Glucosinolate Formation

Janet Imhof,Kurt Lächler,Jonathan Gershenzon,Florian Huber,Stefan Binder,Christoph Wiegreffe,Michael Reichelt,Wagner L Araujo

doi:10.1371/journal.pone.0091071

Janet Imhof, Kurt Lächler + Show 6 more

Open Access

https://doi.org/10.1371/journal.pone.0091071

Copy DOI

Abstract

In Arabidopsis thaliana the evolutionary and functional relationship between Leu biosynthesis and the Met chain elongation pathway, the first part of glucosinolate formation, is well documented. Nevertheless the exact functions of some pathway components are still unclear. Isopropylmalate isomerase (IPMI), an enzyme usually involved in Leu biosynthesis, is a heterodimer consisting of a large and a small subunit. While the large protein is encoded by a single gene (ISOPROPYLMALATE ISOMERASE LARGE SUBUNIT1), three genes encode small subunits (ISOPROPYLMALATE ISOMERASE SMALL SUBUNIT1 to 3). We have now analyzed small subunit 1 (ISOPROPYLMALATE ISOMERASE SMALL SUBUNIT1) employing artificial microRNA for a targeted knockdown of the encoding gene. Strong reduction of corresponding mRNA levels to less than 5% of wild-type levels resulted in a severe phenotype with stunted growth, narrow pale leaf blades with green vasculature and abnormal adaxial-abaxial patterning as well as anomalous flower morphology. Supplementation of the knockdown plants with leucine could only partially compensate for the morphological and developmental abnormalities. Detailed metabolite profiling of the knockdown plants revealed changes in the steady state levels of isopropylmalate and glucosinolates as well as their intermediates demonstrating a function of IPMI SSU1 in both leucine biosynthesis and the first cycle of Met chain elongation. Surprisingly the levels of free leucine slightly increased suggesting an imbalanced distribution of leucine within cells and/or within plant tissues.

Highlights

Humans and other animals are not able to synthesize Leu, one of the essential amino acids, and depend on external sources for this aliphatic amino acid
Previous studies showed that an intact gene encoding the small subunit 1 of the isopropylmalate isomerase (IPMI SSU1) is essential for plant reproduction [3,5], which prevented any study of the specific function of this gene in vivo
While the large subunit of this enzyme (IPMI LSU1) operates both in Leu biosynthesis and Met chain elongation, there is a functional specification of the three small subunits (IPMI SSU1 to 3) [3,5]

Summary

Introduction

Humans and other animals are not able to synthesize Leu, one of the essential amino acids, and depend on external sources for this aliphatic amino acid. Ile and Val form the small group of branched-chain amino acids (BCAA) that is characterized by short aliphatic side chains These amino acids are often found in membrane-spanning domains of proteins [1]. IPMI SSU2 and IPMI SSU3 take part in the Met chain elongation pathway, but up to now, no direct evidence has been obtained for the function of IPMI SSU1 The knockout of this gene interferes with female gametophyte development, which contributes to mutant lethality and prevents establishment of homozygous knockout mutants.

Methods

Results

Conclusion