Abstract
Low phosphate availability is a major constraint on plant growth and agricultural productivity. Engineering a crop with enhanced low phosphate tolerance by transgenic technique could be one way of alleviating agricultural losses due to phosphate deficiency. In this study, we reported that transgenic maize plants that overexpressed the Thellungiella halophila vacuolar H+-pyrophosphatase gene (TsVP) were more tolerant to phosphate deficit stress than the wild type. Under phosphate sufficient conditions, transgenic plants showed more vigorous root growth than the wild type. When phosphate deficit stress was imposed, they also developed more robust root systems than the wild type, this advantage facilitated phosphate uptake, which meant that transgenic plants accumulated more phosphorus. So the growth and development in the transgenic maize plants were not damaged as much as in the wild type plants under phosphate limitation. Overexpression of TsVP increased the expression of genes involved in auxin transport, which indicated that the development of larger root systems in transgenic plants might be due in part to enhanced auxin transport which controls developmental events in plants. Moreover, transgenic plants showed less reproductive development retardation and a higher grain yield per plant than the wild type plants when grown in a low phosphate soil. The phenotypes of transgenic maize plants suggested that the overexpression of TsVP led to larger root systems that allowed transgenic maize plants to take up more phosphate, which led to less injury and better performance than the wild type under phosphate deficiency conditions. This study describes a feasible strategy for improving low phosphate tolerance in maize and reducing agricultural losses caused by phosphate deficit stress.
Highlights
Phosphorus (P) is one of the macronutrients that are essential for plant growth, development, and reproduction
The results showed that transgenic maize plants overexpressing TsVP were more tolerant than wild type to imposed Pi deficit stress
Polymerase chain reaction (PCR) and reverse transcriptionpolymerase chain reaction (RT-PCR) analyses were performed on a wild type and five homozygous transgenic lines
Summary
Phosphorus (P) is one of the macronutrients that are essential for plant growth, development, and reproduction. Phosphate (Pi) is the predominant form of P that is most readily taken up and transported within the plant, the concentration of available Pi in soil is very low, typically 1–10 mM, which cannot satisfy the demand of plants [1,2]. To cope with Pi limitation, plants have evolved a series of adaptive strategies to maintain internal Pi concentrations at levels that will support growth and reproduction. These responses include: remobilizing and conserving internal Pi and increasing acquisition of external Pi. Among the adaptive responses to low Pi stress, maintenance of root growth and expansion of root architecture are especially important for Pi acquisition because Pi is only taken up efficiently by root systems with large surface areas [3]
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