Abstract
Under acid soil conditions, Al stress and proton stress can occur, reducing root growth and function. However, these stressors are distinct, and tolerance to each is governed by multiple physiological processes. To better understand the genes that underlie these coincidental but experimentally separable stresses, a genome-wide association study (GWAS) and genomic prediction (GP) models were created for approximately 200 diverse Arabidopsis thaliana accessions. GWAS and genomic prediction identified 140/160 SNPs associated with Al and proton tolerance, respectively, which explained approximately 70% of the variance observed. Reverse genetics of the genes in loci identified novel Al and proton tolerance genes, including TON1-RECRUITING MOTIF 28 (AtTRM28) and THIOREDOXIN H-TYPE 1 (AtTRX1), as well as genes known to be associated with tolerance, such as the Al-activated malate transporter, AtALMT1. Additionally, variation in Al tolerance was partially explained by expression level polymorphisms of AtALMT1 and AtTRX1 caused by cis-regulatory allelic variation. These results suggest that we successfully identified the loci that regulate Al and proton tolerance. Furthermore, very small numbers of loci were shared by Al and proton tolerance as determined by the GWAS. There were substantial differences between the phenotype predicted by genomic prediction and the observed phenotype for Al tolerance. This suggested that the GWAS-undetectable genetic factors (e.g., rare-allele mutations) contributing to the variation of tolerance were more important for Al tolerance than for proton tolerance. This study provides important new insights into the genetic architecture that produces variation in the tolerance of acid soil.
Highlights
Acid soil syndrome is a serious limiting factor for food production worldwide (von Uexküll and Mutert, 1995; Kochian et al, 2004)
The relative root length of seedlings grown in Al (RRLAl; pH 5.0 plus 5 μM Al to minus Al) and proton (RRLproton; pH 4.6 to pH 5.0) hydroponic culture correlates with the tolerance of Arabidopsis to Al (Kobayashi et al, 2005) and proton rhizotoxicities in acid soils
A genome-wide association study (GWAS) of Al and proton tolerance using the Relative root length (RRL) of Arabidopsis accessions identified various genes linked to the detected SNPs, which cumulatively explained approximately 70% of the phenotypic variations of each trait, which included some of major genes controlling each trait (Figure 3A)
Summary
Acid soil syndrome is a serious limiting factor for food production worldwide (von Uexküll and Mutert, 1995; Kochian et al, 2004). Plant root growth is inhibited by various stressors, such as rhizotoxicities of excess Al, proton, manganese (Mn), and iron (Fe), and deficiencies in the available phosphate (Pi) (Kochian et al, 2004). Plants have adapted to acidic environments by developing a number of stress tolerance mechanisms which can have pleiotropic effects on other traits. Identification of the molecular mechanisms which underlie tolerance to co-existing stress factors may allow for improved crop yields in acid soils, through the use of biotechnology and molecular breeding
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