Adenine nucleotide extraction from multicellular organisms and beach sand: ATP recovery, energy charge ratios and determination of carbon/ATP ratios

Abstract

Investigations were conducted comparing the efficiency of adenine nucleotide extraction from bacteria, unicellular algae, invertebrates (copepods, isopods and polychaetes), and beach sand using boiling buffers and cold acid extraction procedures. Cellular levels of ATP, ADP, and AMP obtained by these procedures were used to calculate the adenylate energy charge ratio ( EC A = [ ATP] + 1 2 [ ADP]/[ ATP] + [ ADP] + [ AMP] ). Although both extraction procedures efficiently extract ATP from unicellular micro-organisms, the results with multicells and beach sand indicate that the cold acid procedure preserves a greater percentage of the total adenine nucleotides ([A T] = [ATP] + [ADP] + [AMP]) in the form of ATP, resulting in higher energy charge ratios. There were relatively large losses of ATP when multicellular organisms were extracted in boiling buffers. These data suggest that ATP hydrolysis may be important in certain fluid-solid mixtures, and also adds experimental support to the thermal gradient hypothesis. The C/ATP ratios calculated from these data indicate that multicellular organisms have C/ATP ratios < 100, as compared with the 250 ratio commonly found in micro-organisms. These results are discussed in terms of the proportion of structural (non-living) carbon vs protoplasm (living) carbon within each of these groups of organisms, as well as the relative intracellular levels of non-adenine nucleotide triphosphates. These differences in the C/ATP ratios must be considered whenever ATP measurements are used for biomass determinations.