The main aim of this work was to investigate previously published reports that an acidic mixture of 0.67 M phosphoric acid, 20% dimethyl sulphoxide, 2 M urea, 20 mM EDTA, 0.75 mM adenosine and 32.5 mM Zwittergent (termed the PA reagent) extracted up to 7 times more adenosine S-triphosphate (ATP) from soil than a reagent consisting of 0.5 M trichloroacetic acid (TCA), 0.25 M phosphate and 0.10 M paraquat (termed the TCA reagent). Several extraction tests were performed using both fresh and air-dried soils at different soil-to-extractant ratios. The ATP concentrations in the soil extracts were determined by the fire-fly hlciferin-luciferase system. In 5 fresh U.K. arable soils the amounts of ATP extracted, corrected for incomplete extraction by measurement of the recovery of an internal standard of added ATP (the spike), ranged from 1.29 to 7.80 and from 1.01 to 5.24 nmol ATP g-’ soil, for the TCA and PA reagent, respectively. In air-dried soils the range was from 0.35 to 1.11 and from 0.35 to 1.24 nmol ATP g-’ soil, respectively, for the TCA and PA reagent. Except for an acid soil, the amount of native ATP extracted from the soils by the two reagents and uncorrected for incomplete extraction was not significantly different within soils when a 1:5 soil-to-extractant ratio was used. However, the percentage recovery of added ATP as a spike was larger at higher soil-to-solution ratios with the TCA reagent but not with the PA reagent. The recoveries of the spike with the TCA reagent were always lower than with PA reagent. However, soil ATP, corrected for incomplete extraction, was always greater with the TCA reagent than with PA. The use of [14C]ATP as a spike showed that no appreciable dephosphorylation of ATP added as the spike occurred with either reagents. The main difference between PA and TCA reagents was that with PA a constant and high recovery of spike ATP (ca. 90%) was obtained at all soil-to-solution ratios tested, while TCA gave higher recoveries of spike ATP at higher soil-to-solution ratios. Paradoxically, the amounts of native ATP extracted at each soil-to-solution ratio were generally similar between PA and TCA, although increasing with increasing soil-to-solufon ratio. Correction for incomplete extraction of the spike with the TCA reagent gave very similar soil ATP concentrations while this was not the case with the PA reagent. We suggest that this is the main difference between the two reagents. We can find no evidence to support other work which suggested that the PA reagent extracts more ATP from soil than the TCA reagent.

COMPARISON OF TWO METHODS FOR EXTRACTION OF ATP FROM SOIL

CONTIN, Marco;DE NOBILI, Maria;
1995-01-01

Abstract

The main aim of this work was to investigate previously published reports that an acidic mixture of 0.67 M phosphoric acid, 20% dimethyl sulphoxide, 2 M urea, 20 mM EDTA, 0.75 mM adenosine and 32.5 mM Zwittergent (termed the PA reagent) extracted up to 7 times more adenosine S-triphosphate (ATP) from soil than a reagent consisting of 0.5 M trichloroacetic acid (TCA), 0.25 M phosphate and 0.10 M paraquat (termed the TCA reagent). Several extraction tests were performed using both fresh and air-dried soils at different soil-to-extractant ratios. The ATP concentrations in the soil extracts were determined by the fire-fly hlciferin-luciferase system. In 5 fresh U.K. arable soils the amounts of ATP extracted, corrected for incomplete extraction by measurement of the recovery of an internal standard of added ATP (the spike), ranged from 1.29 to 7.80 and from 1.01 to 5.24 nmol ATP g-’ soil, for the TCA and PA reagent, respectively. In air-dried soils the range was from 0.35 to 1.11 and from 0.35 to 1.24 nmol ATP g-’ soil, respectively, for the TCA and PA reagent. Except for an acid soil, the amount of native ATP extracted from the soils by the two reagents and uncorrected for incomplete extraction was not significantly different within soils when a 1:5 soil-to-extractant ratio was used. However, the percentage recovery of added ATP as a spike was larger at higher soil-to-solution ratios with the TCA reagent but not with the PA reagent. The recoveries of the spike with the TCA reagent were always lower than with PA reagent. However, soil ATP, corrected for incomplete extraction, was always greater with the TCA reagent than with PA. The use of [14C]ATP as a spike showed that no appreciable dephosphorylation of ATP added as the spike occurred with either reagents. The main difference between PA and TCA reagents was that with PA a constant and high recovery of spike ATP (ca. 90%) was obtained at all soil-to-solution ratios tested, while TCA gave higher recoveries of spike ATP at higher soil-to-solution ratios. Paradoxically, the amounts of native ATP extracted at each soil-to-solution ratio were generally similar between PA and TCA, although increasing with increasing soil-to-solufon ratio. Correction for incomplete extraction of the spike with the TCA reagent gave very similar soil ATP concentrations while this was not the case with the PA reagent. We suggest that this is the main difference between the two reagents. We can find no evidence to support other work which suggested that the PA reagent extracts more ATP from soil than the TCA reagent.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11390/683338
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