Amperometric Biosensor Approaches for Quantification of Indole 3-Acetic Acid in Plant Stress Responses

Amperometric biosensors are known to be sensitive, reliable, and inexpensive instruments for biomolecular detection. Recently, self-referencing amperometric biosensors have been utilized to quantify the endogenous apoplastic flux of plant hormone indole 3-acetic acid (IAA) in vivo. There is still a...

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Published in:Communications in Soil Science and Plant Analysis 2013-06, Vol.44 (11), p.1749-1763
Main Authors: Subraya, Krishnamurthy Kuntagod, Diggs, A, Porterfield, D. M
Format: Article
Language:English
Subjects:
Acids
Agronomy. Soil science and plant productions
Amperometric biosensor
Antibodies
Biological and medical sciences
biosensors
carbon nanotubes
Chromatography
coatings
corn
detection limit
ELISA
enzyme-linked immunosorbent assay
Enzymes
Fundamental and applied biological sciences. Psychology
high performance liquid chromatography
HPLC
indole acetic acid
Methods
nanomaterial
Nanomaterials
plant extracts
plant tissue
plant tissues
platinum
salt stress
shoots
silanization
Soil sciences
surface area
Zea mays
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creator Subraya, Krishnamurthy Kuntagod
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description Amperometric biosensors are known to be sensitive, reliable, and inexpensive instruments for biomolecular detection. Recently, self-referencing amperometric biosensors have been utilized to quantify the endogenous apoplastic flux of plant hormone indole 3-acetic acid (IAA) in vivo. There is still a significant need for sampling and testing methods to measure IAA concentrations in whole tissue samples. In the present study we used nanomaterial-modified platinum microelectrodes for the detection of IAA extracted from whole plant tissues. The key to the use of the nanomaterials was to enhance the surface area and thus the limit of detection for IAA. The nanoscale electrochemical interface was modified by the application of a layer of platinum black, followed by silanization overnight and a coating of multiwalled carbon nanotubes. Electroanalytical characterization of sensor performance was evaluated using both IAA standards and IAA extracted from corn plant samples, using a three-electrode scheme (reference, sensing, and auxillary). We compared tissue concentrations in water- and salt-stressed corn seedlings and compared these results to values measured using established enzyme-linked immunosorbent assay (ELISA) protocols. We found that the values obtained from both methods were comparable. The data obtained from the IAA sensor suggested that the electroanalytical biosensor approach was slightly more reliable and sensitive. Our results demonstrate a novel nanomaterial biosensor approach for IAA quantification in plant tissue extracts. The results of the stress study clearly indicated that root and shoot elongation and growth had significant positive correlation with IAA content in the raw plant tissue extracts. Water and salt stress both reduced root and shoot growth, which may be due to overaccumulation of IAA, resulting in inhibition of elongation. In comparison to established methods, such as high-performance liquid chromatography (HPLC) or ELISA, our approach is simple and inexpensive. Unlike HPLC, our approach does not require any elaborate sample purification, nor does it require antibody development as needed for ELISA. In summary, this electroanalytical biosensor method can be effectively utilized for simple, cheap, and reliable detection of IAA extracted from plant samples.
doi_str_mv 10.1080/00103624.2013.783920
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Electroanalytical characterization of sensor performance was evaluated using both IAA standards and IAA extracted from corn plant samples, using a three-electrode scheme (reference, sensing, and auxillary). We compared tissue concentrations in water- and salt-stressed corn seedlings and compared these results to values measured using established enzyme-linked immunosorbent assay (ELISA) protocols. We found that the values obtained from both methods were comparable. The data obtained from the IAA sensor suggested that the electroanalytical biosensor approach was slightly more reliable and sensitive. Our results demonstrate a novel nanomaterial biosensor approach for IAA quantification in plant tissue extracts. The results of the stress study clearly indicated that root and shoot elongation and growth had significant positive correlation with IAA content in the raw plant tissue extracts. 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M</creatorcontrib><title>Amperometric Biosensor Approaches for Quantification of Indole 3-Acetic Acid in Plant Stress Responses</title><title>Communications in Soil Science and Plant Analysis</title><description>Amperometric biosensors are known to be sensitive, reliable, and inexpensive instruments for biomolecular detection. Recently, self-referencing amperometric biosensors have been utilized to quantify the endogenous apoplastic flux of plant hormone indole 3-acetic acid (IAA) in vivo. There is still a significant need for sampling and testing methods to measure IAA concentrations in whole tissue samples. In the present study we used nanomaterial-modified platinum microelectrodes for the detection of IAA extracted from whole plant tissues. The key to the use of the nanomaterials was to enhance the surface area and thus the limit of detection for IAA. 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The results of the stress study clearly indicated that root and shoot elongation and growth had significant positive correlation with IAA content in the raw plant tissue extracts. Water and salt stress both reduced root and shoot growth, which may be due to overaccumulation of IAA, resulting in inhibition of elongation. In comparison to established methods, such as high-performance liquid chromatography (HPLC) or ELISA, our approach is simple and inexpensive. Unlike HPLC, our approach does not require any elaborate sample purification, nor does it require antibody development as needed for ELISA. In summary, this electroanalytical biosensor method can be effectively utilized for simple, cheap, and reliable detection of IAA extracted from plant samples.</description><subject>Acids</subject><subject>Agronomy. 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In the present study we used nanomaterial-modified platinum microelectrodes for the detection of IAA extracted from whole plant tissues. The key to the use of the nanomaterials was to enhance the surface area and thus the limit of detection for IAA. The nanoscale electrochemical interface was modified by the application of a layer of platinum black, followed by silanization overnight and a coating of multiwalled carbon nanotubes. Electroanalytical characterization of sensor performance was evaluated using both IAA standards and IAA extracted from corn plant samples, using a three-electrode scheme (reference, sensing, and auxillary). We compared tissue concentrations in water- and salt-stressed corn seedlings and compared these results to values measured using established enzyme-linked immunosorbent assay (ELISA) protocols. We found that the values obtained from both methods were comparable. 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subjects Acids
Agronomy. Soil science and plant productions
Amperometric biosensor
Antibodies
Biological and medical sciences
biosensors
carbon nanotubes
Chromatography
coatings
corn
detection limit
ELISA
enzyme-linked immunosorbent assay
Enzymes
Fundamental and applied biological sciences. Psychology
high performance liquid chromatography
HPLC
indole acetic acid
Methods
nanomaterial
Nanomaterials
plant extracts
plant tissue
plant tissues
platinum
salt stress
shoots
silanization
Soil sciences
surface area
Zea mays
title Amperometric Biosensor Approaches for Quantification of Indole 3-Acetic Acid in Plant Stress Responses
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