Identification of oxalyl-CoA synthetase gene (LsAAE3) and its regulatory role in β-ODAP biosynthesis in grasspea (Lathyrus sativus L.)

Abstract

AbstractGrasspea is a popular pulse crop due to its hardiness and low cost of production. Presence of anti-nutritive factor ‘β-ODAP’ in its seeds and other plant parts hinder its widespread cultivation and usage. Oxalyl-CoA synthetase is one of the key enzyme of β-ODAP biosynthesis pathway, catalyses the conversion of oxalate to oxalyl-CoA. ACYL ACTIVATING ENZYME 3 (AAE3) gene has been characterised to encode an oxalyl-CoA synthetase enzyme in many plant species. We report here the isolation of full length AAE3 homolog in grasspea with a combination of PCR based strategy and in silico analysis. We first identified AAE3 homolog by PCR using degenerate primers. The partial LsAAE3 sequence showed 88% amino acids sequence identity with the characterised AAE3 gene of M. truncatula. We then predicted the full length AAE3 sequence using the publically available transcriptome datasets of grasspea. Determination of LsAAE3 gene and protein structure and phylogenetic relationship analysis strongly suggested that LsAAE3 is a true homolog of AAE3 gene. Expression profiling of LsAAE3 in grasspea varieties with contrast in β-ODAP content revealed its inverse relationship with the β-ODAP content, LsAAE3 thus negatively regulates the synthesis of β-ODAP. Involvement of AAE3 encoded oxalyl-CoA synthetase in a CoA-dependent pathway of oxalate degradation is well proven in many plant species. We also identified the CoA-dependent pathway of oxalate degradation in grasspea. Based on these observations, we hypothesized that LsAAE3 may regulate β-ODAP content, possibly, by CoA-dependent pathway of oxalate degradation in grasspea. If this hypothesis is substantiated, genetic manipulation of LsAAE3 presents viable option for reducing β-ODAP content in grass pea.