Quantitative imaging of oil storage in developing crop seeds

In this article, we present a tool which allows the rapid and non-invasive detection and quantitative visualization of lipid in living seeds at a variety of stages using frequency-selected magnetic resonance imaging. The method provides quantitative lipid maps with a resolution close to the cellular...

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Published inPlant biotechnology journal Vol. 6; no. 1; pp. 31 - 45
Main Authors Neuberger, Thomas, Sreenivasulu, Nese, Rokitta, Markus, Rolletschek, Hardy, Göbel, Cornelia, Rutten, Twan, Radchuk, Volodja, Feussner, Ivo, Wobus, Ulrich, Jakob, Peter, Webb, Andrew, Borisjuk, Ljudmilla
Format Journal Article
LanguageEnglish
Published Oxford, UK Oxford, UK : Blackwell Publishing Ltd 2008
Blackwell Publishing Ltd
Blackwell
Subjects
analysis
barley
Biological and medical sciences
Biotechnology
chemistry
electron microscopy
Fundamental and applied biological sciences. Psychology
gene expression
Glycine max
Glycine max - chemistry
Glycine max - growth & development
Glycine max - metabolism
growth & development
Hordeum
Hordeum - chemistry
Hordeum - growth & development
Hordeum - metabolism
Hordeum vulgare
image analysis
Liliopsida
lipids
magnetic resonance imaging
Magnetic Resonance Spectroscopy
Magnetic Resonance Spectroscopy - methods
Magnoliopsida
metabolism
methods
oil storage
oils
Plant Oils
Plant Oils - analysis
Plant Oils - metabolism
seed development
seed maturation
seeds
Seeds - chemistry
Seeds - growth & development
Seeds - metabolism
Soybean Oil
Soybean Oil - analysis
Soybean Oil - metabolism
soybeans
tissues
Monocotyledones
magnetic resonance imaging
Seeds
Hordeum vulgare
Vegetable oil
Glycine max
Nuclear magnetic resonance imaging
oil storage
Storage
Leguminosae
Gramineae
Dicotyledones
Angiospermae
seed development
Spermatophyta
Oil plant (vegetal)
Quantitative analysis
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Abstract In this article, we present a tool which allows the rapid and non-invasive detection and quantitative visualization of lipid in living seeds at a variety of stages using frequency-selected magnetic resonance imaging. The method provides quantitative lipid maps with a resolution close to the cellular level (in-plane 31 μm x 31 μm). The reliability of the method was demonstrated using two contrasting subjects: the barley grain (monocot, 2% oil, highly compartmentalized) and the soybean grain (dicot, 20% oil, economically important oilseed). Steep gradients in local oil storage were defined at the organ- and tissue-specific scales. These gradients were closely coordinated with tissue differentiation and seed maturation, as revealed by electron microscopy and biochemical and gene expression analysis. The method can be used to elucidate similar oil accumulation processes in different tissues/organs, as well as to follow the fate of storage lipids during deposition and subsequent mobilization.
AbstractList In this article, we present a tool which allows the rapid and non-invasive detection and quantitative visualization of lipid in living seeds at a variety of stages using frequency-selected magnetic resonance imaging. The method provides quantitative lipid maps with a resolution close to the cellular level (in-plane 31 μm x 31 μm). The reliability of the method was demonstrated using two contrasting subjects: the barley grain (monocot, 2% oil, highly compartmentalized) and the soybean grain (dicot, 20% oil, economically important oilseed). Steep gradients in local oil storage were defined at the organ- and tissue-specific scales. These gradients were closely coordinated with tissue differentiation and seed maturation, as revealed by electron microscopy and biochemical and gene expression analysis. The method can be used to elucidate similar oil accumulation processes in different tissues/organs, as well as to follow the fate of storage lipids during deposition and subsequent mobilization.
Summary In this article, we present a tool which allows the rapid and non‐invasive detection and quantitative visualization of lipid in living seeds at a variety of stages using frequency‐selected magnetic resonance imaging. The method provides quantitative lipid maps with a resolution close to the cellular level (in‐plane 31 µm × 31 µm). The reliability of the method was demonstrated using two contrasting subjects: the barley grain (monocot, 2% oil, highly compartmentalized) and the soybean grain (dicot, 20% oil, economically important oilseed). Steep gradients in local oil storage were defined at the organ‐ and tissue‐specific scales. These gradients were closely coordinated with tissue differentiation and seed maturation, as revealed by electron microscopy and biochemical and gene expression analysis. The method can be used to elucidate similar oil accumulation processes in different tissues/organs, as well as to follow the fate of storage lipids during deposition and subsequent mobilization.
In this article, we present a tool which allows the rapid and non-invasive detection and quantitative visualization of lipid in living seeds at a variety of stages using frequency-selected magnetic resonance imaging. The method provides quantitative lipid maps with a resolution close to the cellular level (in-plane 31 microm x 31 microm). The reliability of the method was demonstrated using two contrasting subjects: the barley grain (monocot, 2% oil, highly compartmentalized) and the soybean grain (dicot, 20% oil, economically important oilseed). Steep gradients in local oil storage were defined at the organ- and tissue-specific scales. These gradients were closely coordinated with tissue differentiation and seed maturation, as revealed by electron microscopy and biochemical and gene expression analysis. The method can be used to elucidate similar oil accumulation processes in different tissues/organs, as well as to follow the fate of storage lipids during deposition and subsequent mobilization.
In this article, we present a tool which allows the rapid and non‐invasive detection and quantitative visualization of lipid in living seeds at a variety of stages using frequency‐selected magnetic resonance imaging. The method provides quantitative lipid maps with a resolution close to the cellular level (in‐plane 31 µm × 31 µm). The reliability of the method was demonstrated using two contrasting subjects: the barley grain (monocot, 2% oil, highly compartmentalized) and the soybean grain (dicot, 20% oil, economically important oilseed). Steep gradients in local oil storage were defined at the organ‐ and tissue‐specific scales. These gradients were closely coordinated with tissue differentiation and seed maturation, as revealed by electron microscopy and biochemical and gene expression analysis. The method can be used to elucidate similar oil accumulation processes in different tissues/organs, as well as to follow the fate of storage lipids during deposition and subsequent mobilization.
In this article, we present a tool which allows the rapid and non-invasive detection and quantitative visualization of lipid in living seeds at a variety of stages using frequency-selected magnetic resonance imaging. The method provides quantitative lipid maps with a resolution close to the cellular level (in-plane 31 microm x 31 microm). The reliability of the method was demonstrated using two contrasting subjects: the barley grain (monocot, 2% oil, highly compartmentalized) and the soybean grain (dicot, 20% oil, economically important oilseed). Steep gradients in local oil storage were defined at the organ- and tissue-specific scales. These gradients were closely coordinated with tissue differentiation and seed maturation, as revealed by electron microscopy and biochemical and gene expression analysis. The method can be used to elucidate similar oil accumulation processes in different tissues/organs, as well as to follow the fate of storage lipids during deposition and subsequent mobilization.In this article, we present a tool which allows the rapid and non-invasive detection and quantitative visualization of lipid in living seeds at a variety of stages using frequency-selected magnetic resonance imaging. The method provides quantitative lipid maps with a resolution close to the cellular level (in-plane 31 microm x 31 microm). The reliability of the method was demonstrated using two contrasting subjects: the barley grain (monocot, 2% oil, highly compartmentalized) and the soybean grain (dicot, 20% oil, economically important oilseed). Steep gradients in local oil storage were defined at the organ- and tissue-specific scales. These gradients were closely coordinated with tissue differentiation and seed maturation, as revealed by electron microscopy and biochemical and gene expression analysis. The method can be used to elucidate similar oil accumulation processes in different tissues/organs, as well as to follow the fate of storage lipids during deposition and subsequent mobilization.
Author Rokitta, Markus
Sreenivasulu, Nese
Webb, Andrew
Radchuk, Volodja
Jakob, Peter
Rolletschek, Hardy
Wobus, Ulrich
Rutten, Twan
Neuberger, Thomas
Borisjuk, Ljudmilla
Göbel, Cornelia
Feussner, Ivo
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  fullname: Borisjuk, Ljudmilla
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Issue 1
Keywords Monocotyledones
magnetic resonance imaging
Seeds
Hordeum vulgare
Vegetable oil
Glycine max
Nuclear magnetic resonance imaging
oil storage
Storage
Leguminosae
Gramineae
Dicotyledones
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seed development
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Oil plant (vegetal)
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SSID ssj0021656
Score 2.1114893
Snippet In this article, we present a tool which allows the rapid and non-invasive detection and quantitative visualization of lipid in living seeds at a variety of...
Summary In this article, we present a tool which allows the rapid and non‐invasive detection and quantitative visualization of lipid in living seeds at a...
In this article, we present a tool which allows the rapid and non‐invasive detection and quantitative visualization of lipid in living seeds at a variety of...
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StartPage 31
SubjectTerms analysis
barley
Biological and medical sciences
Biotechnology
chemistry
electron microscopy
Fundamental and applied biological sciences. Psychology
gene expression
Glycine max
Glycine max - chemistry
Glycine max - growth & development
Glycine max - metabolism
growth & development
Hordeum
Hordeum - chemistry
Hordeum - growth & development
Hordeum - metabolism
Hordeum vulgare
image analysis
Liliopsida
lipids
magnetic resonance imaging
Magnetic Resonance Spectroscopy
Magnetic Resonance Spectroscopy - methods
Magnoliopsida
metabolism
methods
oil storage
oils
Plant Oils
Plant Oils - analysis
Plant Oils - metabolism
seed development
seed maturation
seeds
Seeds - chemistry
Seeds - growth & development
Seeds - metabolism
Soybean Oil
Soybean Oil - analysis
Soybean Oil - metabolism
soybeans
tissues
Title Quantitative imaging of oil storage in developing crop seeds
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fj.1467-7652.2007.00294.x
https://www.ncbi.nlm.nih.gov/pubmed/17894785
https://www.proquest.com/docview/48151474
https://www.proquest.com/docview/70102570
Volume 6
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