Differential RNA Editing and Intron Splicing in Soybean Mitochondria during Nodulation.

Yuzhe Sun,Boon Leong Lim,Koon Chuen Chan,Jia Yi Zhong,Hon-Ming Lam,Kejing Fan,Zhou Xu,Johanna Wong-Bajracharya,Min Xie

doi:10.3390/ijms21249378

Yuzhe Sun, Boon Leong Lim + Show 7 more

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https://doi.org/10.3390/ijms21249378

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Abstract

Nitrogen fixation in soybean consumes a tremendous amount of energy, leading to substantial differences in energy metabolism and mitochondrial activities between nodules and uninoculated roots. While C-to-U RNA editing and intron splicing of mitochondrial transcripts are common in plant species, their roles in relation to nodule functions are still elusive. In this study, we performed RNA-seq to compare transcript profiles and RNA editing of mitochondrial genes in soybean nodules and roots. A total of 631 RNA editing sites were identified on mitochondrial transcripts, with 12% or 74 sites differentially edited among the transcripts isolated from nodules, stripped roots, and uninoculated roots. Eight out of these 74 differentially edited sites are located on the matR transcript, of which the degrees of RNA editing were the highest in the nodule sample. The degree of mitochondrial intron splicing was also examined. The splicing efficiencies of several introns in nodules and stripped roots were higher than in uninoculated roots. These include nad1 introns 2/3/4, nad4 intron 3, nad5 introns 2/3, cox2 intron 1, and ccmFc intron 1. A greater splicing efficiency of nad4 intron 1, a higher NAD4 protein abundance, and a reduction in supercomplex I + III2 were also observed in nodules, although the causal relationship between these observations requires further investigation.

Highlights

Soybean is an important cash crop for protein and edible oil
Besides transcripts encoding for hypothetical proteins, we identified 14 transcripts differentially expressed between N and uninoculated roots (UR), Stripped roots (SR) and UR, or SR and N
Since RNA editing is an energy-consuming and complex process, it must serve important biological functions, or otherwise it should not be maintained in higher plants during evolution

Summary

Introduction

Soybean is an important cash crop for protein and edible oil. Its ability to perform symbiotic nitrogen fixation in root nodules makes it a nitrogen-rich food source. Root cells obtain photo-assimilates from source tissues and catabolize these chemical compounds through root mitochondria to generate the ATPs required for various physiological and biochemical processes. Cellular respiration mainly takes place inside mitochondria. The tricarboxylic acid (TCA) cycle and mitochondrial electron transport chain (mETC) convert biochemical energy from nutrients into ATP, which is an important energy currency of the cell. The energy demand in root nodules is much higher than in uninoculated roots, since nitrogen fixation consumes a tremendous amount of energy [1]. Substantial differences in carbon metabolism and mitochondrial activities between root nodules and uninoculated root cells are expected

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