Fine-tuning the transcriptional regulatory model of adaptation response to phosphate stress in maize (Zea mays L.)

The post green revolution agriculture is based on generous application of fertilizers and high-yielding genotypes that are suited for such high input regimes. Cereals, like maize ( Zea mays L.) are capable of utilizing less than 20% of the applied inorganic phosphate (Pi) - a non-renewable fertilize...

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Published in:Physiology and molecular biology of plants 2022-04, Vol.28 (4), p.885-898
Main Authors: Yadava, Pranjal, Dayaman, Vikram, Agarwal, Astha, Kumar, Krishan, Singh, Ishwar, Verma, Rachana, Kaul, Tanushri
Format: Article
Language:English
Subjects:
Acid phosphatase
Biological and Medical Physics
Biomedical and Life Sciences
Biophysics
Cell Biology
Cereals
Corn
Deprivation
Fertilizer application
Fertilizers
Gene regulation
Genes
Genotypes
Green revolution
Homeostasis
Inbreeding
Leaves
Life Sciences
Molecular modelling
Phosphorus
Plant Physiology
Plant Sciences
Plant tissues
Research Article
Ribonuclease
Root hairs
Roots
Transcription
Zea mays
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Summary:The post green revolution agriculture is based on generous application of fertilizers and high-yielding genotypes that are suited for such high input regimes. Cereals, like maize ( Zea mays L.) are capable of utilizing less than 20% of the applied inorganic phosphate (Pi) - a non-renewable fertilizer resource. A greater understanding of the molecular mechanisms underlying the acquisition, transportation and utilization of Pi may lead to engineering genotypes with high phosphorus use efficiency. In this study, we carried out functional domain similarity analysis, promoter analysis and comparative transcriptional expression profiling of 12 selected Pi responsive genes in the Pi stress tolerant maize inbred line HKI-163 under sufficient and deficient Pi conditions. Pi starvation led to significant increase in root length; marked proliferation of root hairs and lesser number of crown roots. Eleven genes were significantly up or down regulated in Pi deficient condition. The putative acid phosphatase, ZmACP5 expression was up regulated by 162.81 and 74.40 fold in root and leaf tissues, respectively. The RNase, ZmRNS1 showed 115 fold up regulation in roots under Pi deprivation. Among the two putative high affinity Pi transporters ZmPht1;4 was found specific to root, whereas ZmPht2 was found to be up regulated in both root and leaf tissues. The genes involved in Pi homeostasis pathway ( ZmSIZ1, SPX1 and Pho2 ) were up regulated in root and leaf. In light of the expression profiling of selected regulatory genes, an updated model of transcriptional regulation under Pi starvation in maize has been presented.
ISSN:0971-5894
0974-0430
DOI:10.1007/s12298-022-01155-x