Journal of Integrative Agriculture
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Effect of mechanical threshing on damage and vigor of maize seed threshed at different moisture contents
GU Ri-liang, HUANG Ran, JIA Guang-yao, YUAN Zhi-peng, REN Li-sha, LI Li, WANG Jian-hua
2019, 18 (7): 1571-1578.   DOI: 10.1016/S2095-3119(18)62026-X
Abstract274)      PDF in ScienceDirect      
Mechanical threshing used when preparing maize seeds for planting subjects seed to damage and reduces seed quality.  The purpose of this study was to assess the effect of mechanical threshing on the quality of maize seed threshed at different moisture contents (MCs).  Seeds of dent maize JK968 and flint maize DD2 were threshed at 12, 15, 18, 21, and 24% MC.  The damage degree was determined by iodine staining, and seed vigor was assessed by standard germination (SG), cold test germination (CTG), accelerated aging germination (AAG), seedling emergence rate, and seedling root and shoot length.  The results showed that the damage percentage increased, and the seed vigor parameters decreased with increasing seed MC during threshing in both cultivars.  For obtaining high seed quality, indicated by at least 90, 85, and 80% of SG, AAG, and CTG, respectively, JK 968 and DD2 should be threshed at MC lower than 15 and 18%, respectively.  Furthermore, the damage mainly occurred in the apical part of seeds, irrespective of the threshing MC in both cultivars.  When the embryo was damaged, seedling emergence rates were significantly reduced with great influence on shoot length.  Damage to the endosperm resulted in little effect on seedling performance.  Flint maize DD2 was more tolerant to mechanical threshing than dent maize JK968.  These results provided technical reference for the production and processing of high vigor maize seeds.
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Phenotypic characterization and genetic mapping of the dwarf mutant m34 in maize
LI Jie-ping, Soomro Ayaz Ali, XIAO Gui, CHEN Fan-jun, YUAN Li-xing, GU Ri-liang
2019, 18 (5): 948-957.   DOI: 10.1016/S2095-3119(18)61959-8
Abstract189)      PDF in ScienceDirect      
Plant height is one of the most important agronomic traits associated with yield in maize.  In this study, a gibberellins (GA)-insensitive dwarf mutant, m34, was screened from inbred line Ye478 by treatment with the chemical mutagen ethyl-methanesulfonate (EMS).  Compared to Ye478, m34 showed a dwarf phenotype with shorter internodes, and smaller leaf length and width, but with similar leaf number.  Furthermore, m34 exhibited smaller guard cells in internodes than Ye478, suggesting that smaller cells might contribute to its dwarf phenotype.  Genetic analysis indicated that the m34 dwarf phenotype was controlled by a recessive nuclear gene.  An F2 population derived from a cross between m34 and B73 was used for mutational gene cloning and this gene was mapped to a chromosome region between umc2189 and umc1553 in chromosome 1 bin1.10, which harbored a previously identified dwarf gene ZmVP8.  Sequencing analysis showed a nucleotide substitution (G1606 to A1606) in the sixth exon of ZmVP8, which resulted in an amino acid change (E531 to K531) from Ye478 to m34.  This amino acid change resulted in an α-helix changing to a β-sheet in the secondary protein structure and the ‘SPEC’ domain changed to a ‘BOT1NT’ domain in the tertiary protein structure.  Taken together, these results suggested that m34 is a novel allelic mutant originally derived from Ye478 that is useful for further ZmVP8 functional analysis in maize.
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Transcriptional Regulation of Expression of the Maize Aldehyde Dehydrogenase 7 Gene (ZmALDH7B6) in Response to Abiotic Stresses
AN Xia, DUAN Feng-ying, GUO Song, CHEN Fan-jun, YUAN Li-xing , GU Ri-liang
2014, 13 (9): 1900-1908.   DOI: 10.1016/S2095-3119(13)60518-3
Abstract1346)      PDF in ScienceDirect      
Aldehyde dehydrogenases (ALDHs) represent a large protein family, which includes several members that catalyze the oxidation of an aldehyde to its corresponding carboxylic acid in plants. Genes encoding members of the ALDH7 subfamily have been suggested to play important roles in various stress adaptations in plants. In this study, quantitative RT-PCR analysis revealed that a maize ALDH7 subfamily member (ZmALDH7B6) was constitutively expressed in various organs, including roots, leaves, immature ears, tassels, and developing seeds. The abundance of ZmALDH7B6 mRNA transcripts in maize roots was increased by ammonium, NaCl, and mannitol treatments. To further analyze tissue-specific and stress-induced expression patterns, the 1.5-kb 5´-flanking ZmALDH7B6 promoter region was fused to the β-glucuronidase (GUS) reporter gene and introduced into maize plants. In roots of independent transgenic lines, there was significant induction of GUS activity in response to ammonium supply, confirming ammonium-dependent expression of ZmALDH7B6 at the transcript level. Histochemical staining showed that GUS activity driven by the ZmALDH7B6 promoter was mainly localized in the vascular tissues of maize roots. These results suggested that ZmALDH7B6 is induced by multiple environmental stresses in maize roots, and may play a role in detoxifying aldehydes, particularly in vascular tissue.
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Copyright © Journal of Integrative Agriculture
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