Analysis of β-amylase Gene () Variation Reveals Allele Association with Low Enzyme Activity and Increased Firmness in Cooked Sweetpotato () from East Africa

Overview

Journal J Agric Food Res

Date 2021 Jun 4

PMID 34085050

Citations 6

Authors

Linly Banda

Martina Kyallo

Jean-Baka Domelevo Entfellner

Mukani Moyo

Jolien Swanckaert

Robert O M Mwanga

Arnold Onyango

Esther Magiri

Dorcus C Gemenet

Nasser Yao

Roger Pelle

Tawanda Muzhingi

Affiliations

Soon will be listed here.

Abstract

β-amylase is a thermostable enzyme that hydrolyses starch during cooking of sweetpotato () storage roots, thereby influencing eating quality. Its activity is known to vary amongst genotypes but the genetic diversity of the beta-amylase gene () is not well studied. has a highly conserved region between exon V and VI, forming part of the enzyme's active site. To determine the gene diversity, a 2.3 kb fragment, including the conserved region of the gene was sequenced from 25 sweetpotato genotypes. The effect of sequence variation on gene expression, enzyme activity, and firmness in cooked roots was determined. Six genotypes carrying several SNPs within exon V, linked with an AT or ATGATA insertion in intron V were unique and clustered together. The genotypes also shared an A336E substitution in the amino acid sequence, eight residues upstream of a substrate-binding Thr344. The genotypes carrying this allele exhibited low gene expression and low enzyme activity. Enzyme activity was negatively correlated with firmness (R = -0.42) in cooked roots. This is the first report of such an allele, associated with low enzyme activity. These results suggest that genetic variation within the locus can be utilized to develop markers for firmness in sweetpotato breeding.

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