Frontiers in Plant Science (Oct 2022)

Mining synergistic genes for nutrient utilization and disease resistance in maize based on co-expression network and consensus QTLs

  • Bowen Luo,
  • Bowen Luo,
  • Bowen Luo,
  • Jiaqian Li,
  • Jiaqian Li,
  • Binyang Li,
  • Binyang Li,
  • Haiying Zhang,
  • Haiying Zhang,
  • Ting Yu,
  • Ting Yu,
  • Guidi Zhang,
  • Guidi Zhang,
  • Shuhao Zhang,
  • Shuhao Zhang,
  • Javed Hussain Sahito,
  • Javed Hussain Sahito,
  • Xiao Zhang,
  • Xiao Zhang,
  • Dan Liu,
  • Dan Liu,
  • Ling Wu,
  • Ling Wu,
  • Duojiang Gao,
  • Duojiang Gao,
  • Shiqiang Gao,
  • Shiqiang Gao,
  • Shibin Gao,
  • Shibin Gao,
  • Shibin Gao

DOI
https://doi.org/10.3389/fpls.2022.1013598
Journal volume & issue
Vol. 13

Abstract

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Nutrient restrictions and large-scale emergence of diseases are threatening the maize production. Recent findings demonstrated that there is a certain synergistic interaction between nutrition and diseases pathways in model plants, however there are few studies on the synergistic genes of nutrients and diseases in maize. Thus, the transcriptome data of nitrogen (N) and phosphorus (P) nutrients and diseases treatments in maize, rice, wheat and Arabidopsis thaliana were collected in this study, and four and 22 weighted co-expression modules were obtained by using Weighted Gene Co-expression Network Analysis (WGCNA) in leaf and root tissues, respectively. With a total of 5252 genes, MFUZZ cluster analysis screened 26 clusters with the same expression trend under nutrition and disease treatments. In the meantime, 1427 genes and 22 specific consensus quantitative trait loci (scQTLs) loci were identified by meta-QTL analysis of nitrogen and phosphorus nutrition and disease stress in maize. Combined with the results of cluster analysis and scQTLs, a total of 195 consistent genes were screened, of which six genes were shown to synergistically respond to nutrition and disease both in roots and leaves. Moreover, the six candidate genes were found in scQTLs associated with gray leaf spot (GLS) and corn leaf blight (CLB). In addition, subcellular localization and bioinformatics analysis of the six candidate genes revealed that they were primarily expressed in endoplasmic reticulum, mitochondria, nucleus and plasma membrane, and were involved in defense and stress, MeJA and abscisic acid response pathways. The fluorescence quantitative PCR confirmed their responsiveness to nitrogen and phosphorus nutrition as well as GLS treatments. Taken together, findings of this study indicated that the nutrition and disease have a significant synergistic response in maize.

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