On the mechanism of glycolate synthesis by Chromatium and Chlorella

Abstract

When cultures of the photosynthetic bacterium, Chromatium vinosum, capable of photosynthesizing glycolate at about 10 μmol/mg of bacteriochlorophyll/h were exposed to atmospheres enriched with 18O 2, one atom of oxygen-18 was incorporated into the car☐yl group of glycolate. Allowing for the small (3–5%) loss of oxygen-18 during the manipulations leading up to the mass spectrometric determination of the oxygen-18 content of the glycolate, the isotopic enrichment of the 18O-labeled glycolate synthesized by Chromatium was substantially (at least 94%) the same as the isotopic enrichment of the 18O 2. Similar results were obtained with the green alga, Chlorella fusca. The close agreement between the isotopic enrichments of the glycolate and the oxygen with which it was synthesized was independent of the oxygen concentration. The major pathway of glycolate synthesis by Chromatium therefore involves reaction(s) which bring about the incorporation of one atom of molecular oxygen into the car☐yl group of glycolate. The in vitro rate of ribulose 1,5-bisphosphate oxygenase in extracts of Chromatium, previously thought to be too low to account for the rates of glycolate synthesis in vivo, was shown to be adequate for this purpose when precautions were taken to fully activate the enzyme. Similarly, the activity of phosphoglycolate phosphatase, when assayed under optimal conditions, was also adequate to sustain the rates of glycolate formation observed i vivo. It is concluded that the oxygenolytic cleavage of ribulose 1,5-bisphosphate represents the major pathway of glycolate synthesis by Chromatium.