Plant Genome Size Estimation by Flow Cytometry: Inter-laboratory Comparison

Flow cytometry is a convenient and rapid method that has been used extensively for estimation of nuclear genome size in plants. In contrast to general expectations, results obtained in different laboratories showed some striking discrepancies. The aim of this joint experiment was to test the reliabi...

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Published in	Annals of botany Vol. 82; no. suppl-1; pp. 17 - 26
Main Authors	Doležel, J., Greilhuber, J., Lucretti, S., Meister, A., Lysák, M. A., Nardi, L., Obermayer, R.
Format	Journal Article
Language	English
Published	Oxford University Press 01.12.1998
Subjects	DAPI Feulgen densitometry flow cytometry nuclear DNA content plant genome size propidium iodide standardization
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Abstract	Flow cytometry is a convenient and rapid method that has been used extensively for estimation of nuclear genome size in plants. In contrast to general expectations, results obtained in different laboratories showed some striking discrepancies. The aim of this joint experiment was to test the reliability and reproducibility of methods. Care was taken to avoid a bias due to the quantity of DNA in the nucleus, the procedure for nuclei isolation or the type of instrument. Nuclear DNA content was estimated in nine plant species representing a typical range of genome size (2C = approx. 0·3–30 pg DNA). Each of the four laboratories involved in this study used a different buffer and/or procedure for nuclei isolation. Two laboratories used arc lamp-based instruments while the other two used laser-based instruments. The results obtained after nuclei staining with propidium iodide (a DNA intercalator) agreed well with those obtained using Feulgen densitometry. On the other hand, results obtained after staining with DAPI (binding preferentially to AT-rich regions) did not agree with those obtained using Feulgen densitometry. Small, but statistically significant, differences were found between data obtained with individual instruments. Differences between the same type of instruments were negligible, while larger differences were observed between lamp- and laser-based instruments. Ratios of fluorescence intensity obtained by laser instruments were higher than those obtained by lamp-based cytometers or by Feulgen densitometry. The results obtained in this study demonstrate that flow cytometry with DNA intercalators is a reliable method for estimation of nuclear genome size in plants. However, the study confirmed an urgent need for an agreement on standards. Given the small but systematic differences between different types of flow cytometers, analysis of very small differences in genome size should be made in the same laboratory and using the same instrument.
AbstractList	Flow cytometry is a convenient and rapid method that has been used extensively for estimation of nuclear genome size in plants. In contrast to general expectations, results obtained in different laboratories showed some striking discrepancies. The aim of this joint experiment was to test the reliability and reproducibility of methods. Care was taken to avoid a bias due to the quantity of DNA in the nucleus, the procedure for nuclei isolation or the type of instrument. Nuclear DNA content was estimated in nine plant species representing a typical range of genome size (2C = approx. 0·3–30 pg DNA). Each of the four laboratories involved in this study used a different buffer and/or procedure for nuclei isolation. Two laboratories used arc lamp-based instruments while the other two used laser-based instruments. The results obtained after nuclei staining with propidium iodide (a DNA intercalator) agreed well with those obtained using Feulgen densitometry. On the other hand, results obtained after staining with DAPI (binding preferentially to AT-rich regions) did not agree with those obtained using Feulgen densitometry. Small, but statistically significant, differences were found between data obtained with individual instruments. Differences between the same type of instruments were negligible, while larger differences were observed between lamp- and laser-based instruments. Ratios of fluorescence intensity obtained by laser instruments were higher than those obtained by lamp-based cytometers or by Feulgen densitometry. The results obtained in this study demonstrate that flow cytometry with DNA intercalators is a reliable method for estimation of nuclear genome size in plants. However, the study confirmed an urgent need for an agreement on standards. Given the small but systematic differences between different types of flow cytometers, analysis of very small differences in genome size should be made in the same laboratory and using the same instrument.
Author	Lucretti, S. Meister, A. Doležel, J. Greilhuber, J. Nardi, L. Obermayer, R. Lysák, M. A.
Author_xml	– sequence: 1 givenname: J. surname: Doležel fullname: Doležel, J. organization: De Montfort University Norman Borlaug Centre for Plant Science, Institute of Experimental Botany, Olomouc, Czech Republic – sequence: 2 givenname: J. surname: Greilhuber fullname: Greilhuber, J. organization: De Montfort University Norman Borlaug Centre for Plant Science, Institute of Experimental Botany, Olomouc, Czech Republic – sequence: 3 givenname: S. surname: Lucretti fullname: Lucretti, S. organization: De Montfort University Norman Borlaug Centre for Plant Science, Institute of Experimental Botany, Olomouc, Czech Republic – sequence: 4 givenname: A. surname: Meister fullname: Meister, A. organization: De Montfort University Norman Borlaug Centre for Plant Science, Institute of Experimental Botany, Olomouc, Czech Republic – sequence: 5 givenname: M. A. surname: Lysák fullname: Lysák, M. A. organization: De Montfort University Norman Borlaug Centre for Plant Science, Institute of Experimental Botany, Olomouc, Czech Republic – sequence: 6 givenname: L. surname: Nardi fullname: Nardi, L. organization: De Montfort University Norman Borlaug Centre for Plant Science, Institute of Experimental Botany, Olomouc, Czech Republic – sequence: 7 givenname: R. surname: Obermayer fullname: Obermayer, R. organization: De Montfort University Norman Borlaug Centre for Plant Science, Institute of Experimental Botany, Olomouc, Czech Republic
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Snippet	Flow cytometry is a convenient and rapid method that has been used extensively for estimation of nuclear genome size in plants. In contrast to general...
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SubjectTerms	DAPI Feulgen densitometry flow cytometry nuclear DNA content plant genome size propidium iodide standardization
Title	Plant Genome Size Estimation by Flow Cytometry: Inter-laboratory Comparison
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