Abstract
SummaryAmino acids are both constituents of proteins, providing the essential nutrition for humans and animals, and signalling molecules regulating the growth and development of plants. Most cultivars of maize are deficient in essential amino acids such as lysine and tryptophan. Here, we measured the levels of 17 different total amino acids, and created 48 derived traits in mature kernels from a maize diversity inbred collection and three recombinant inbred line (RIL) populations. By GWAS, 247 and 281 significant loci were identified in two different environments, 5.1 and 4.4 loci for each trait, explaining 7.44% and 7.90% phenotypic variation for each locus in average, respectively. By linkage mapping, 89, 150 and 165 QTLs were identified in B73/By804, Kui3/B77 and Zong3/Yu87‐1 RIL populations, 2.0, 2.7 and 2.8 QTLs for each trait, explaining 13.6%, 16.4% and 21.4% phenotypic variation for each QTL in average, respectively. It implies that the genetic architecture of amino acids is relative simple and controlled by limited loci. About 43.2% of the loci identified by GWAS were verified by expression QTL, and 17 loci overlapped with mapped QTLs in the three RIL populations. GRMZM2G015534, GRMZM2G143008 and one QTL were further validated using molecular approaches. The amino acid biosynthetic and catabolic pathways were reconstructed on the basis of candidate genes proposed in this study. Our results provide insights into the genetic basis of amino acid biosynthesis in maize kernels and may facilitate marker‐based breeding for quality protein maize.
Highlights
Maize (Zea mays) is one of the most widely grown crops worldwide
Using an automatic amino acid analyzer L-8800 (L-8800, Hitachi Instruments Engineering, Tokyo, Japan), we assessed the variation in total amino acid content in dry matured maize kernels, which included an association panel (513 inbred lines) harvested from two environments and three recombinant inbred line (RIL) populations (169, 152, 146 lines for B73/BY804 (BB), KUI3/B77 (KB) and ZONG3/YU87-1 (ZY), respectively)
Variation ranged from a 1.2-fold difference in Phe/PT to 14.9-fold difference in Cys/Total, and 1.1-fold difference in GT/Total and Glx/GT to 5.7-fold difference in Met/Total in association and linkage mapping populations, respectively (Tables S1, S2)
Summary
Maize (Zea mays) is one of the most widely grown crops worldwide. It is a staple food for people and animals, and an important industrial material for fuel and other applications. The maize endosperm is ~10% protein, and seed storage proteins supply nitrogen for the germinating seedling and are an important protein source for humans and animals. The amino acid composition and quantity of seed storage proteins are related to the nutritional quality of seeds (Mandal and Mandal, 2000; Young and Pellett, 1994). The maize cultivars widely planted usually have insufficient levels of essential amino acids, such as lysine and tryptophan (Misra et al, 1972). In order to facilitate breeding for balanced amino acid composition, it is important to identify the genes controlling amino acid content in the maize kernel
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