|Title||Organic Anion–Driven Solubilization of Precipitated and Sorbed Phytate Improves Hydrolysis by Phytases and Bioavailability to Nicotiana tabacum|
|Publication Type||Journal Article|
|Year of Publication||2012|
|Authors||Giles, CD, Richardson, AE, Druschel, GK, Hill, JE|
|Pagination||591 - 598|
Abstract: Improved plant access to native soil phosphorus (P) species such as phytate (metal ion derivatives of myo-inositol hexakisphosphate (IHP)) could minimize agricultural dependence on nonrenewable mineral phosphates and reduce surface water pollution. Nicotiana tabacum plant lines with unique organic anion (OA) and phytase production patterns were used to investigate the effect of OA-driven solubilization on the bioavailability of precipitated and sorbed IHP. Organic anions released IHP sorbed to goethite (Gt) by chelation or reductive dissolution mechanisms in the order: ascorbate > citrate > oxalate > pyruvate > acetate. Transgenic tobacco overexpressing Peniophora lycii phytase (PHY) and a MATE-type citrate transporter (CIT) exuded 2.2- to 2.6-fold higher OA compared with that of wild-type plants. The PHY plants had 33-fold higher exudate phytase activity (6.0 × 10−2 nkat plant−1 day−1) compared with those of wild-type and CIT plants, produced the largest zone of iron-IHP hydrolysis in agar media, and incorporated the most shoot P (2.3 μg) when grown on Gt-IHP. Plants grown on IHP at 2× Gt saturation (0.26 mmol/L) were 10-fold higher in shoot P compared with the 1× Gt condition (0.13 mmol/L IHP) with PHY plants approaching excess P status (1 % shoot P). The addition of Gt diminished shoot P in plants grown without P (−70 to −80 %) and with phosphate (−50 %) or IHP (−100 %); the exception was the high citrate–exuding plant line (21 nmol citrate plant−1 day−1), for which phosphate uptake was only 20 % reduced. Plant OA production mitigates P inhibition by Gt when weakly sorbing phosphate species are supplied or when high phytase production by plants can maximize the hydrolysis of IHP.
|Short Title||Soil Science|
Organic Anion–Driven Solubilization of Precipitated and Sorbed Phytate Improves Hydrolysis by Phytases and Bioavailability to Nicotiana tabacum