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. 1963 Jan;85(1):106–110. doi: 10.1128/jb.85.1.106-110.1963

PHOSPHORYLATION BY EXTRACTS OF NITROSOMONAS EUROPAEA

W D Burge a,1, E Malavolta a,2, C C Delwiche a
PMCID: PMC278095  PMID: 14016952

Abstract

Burge, W. D. (University of California, Berkeley), E. Malavolta, and C. C. Delwiche. Phosphorylation by extracts of Nitrosomonas europaea. J. Bacteriol. 85:106–110. 1963.—Cellfree preparations of Nitrosomonas europaea are capable of oxidizing hydroxylamine, but not ammonium ion, to nitrite. The quantity of nitrite formed by our preparations was, at most, equivalent to only 70% of the hydroxylamine added. Although the preparations had a strong phosphatase activity, resulting in a net loss of organic phosphate during the experimental period, P32-labeled inorganic phosphate was found to be incorporated into the organic fraction, including adenosine triphosphate (ATP) and adenosine diphosphate (ADP). The provision of hydroxylamine as substrate resulted in the formation of nitrite and an increased incorporation of P32 into the organic fraction. It is concluded that the chemosynthetic autotroph Nitrosomonas, in common with certain other autotrophic organisms and heterotrophs, is capable of converting energy released in the oxidation of its inorganic substrate into high-energy phosphate units (ATP and ADP) for the mediation of other energy-requiring reactions. The simultaneous formation of ATP and ADP is interpreted as evidence for an adenylate kinase activity. The preparations used exhibited a considerable endogenous incorporation of P32 into organic phosphate in the absence of added hydroxylamine. Cyanide inhibited both phosphorylation and the oxidation of hydroxylamine. Both the supernatant and particulate fractions of a Nitrosomonas extract subjected to centrifugal fields of 100,000 × g were active in phosphorylation and nitrite formation, but these activities appeared to be uncoupled in the particulate fraction and only partially coupled in the supernatant solution. This most likely reflects a significant endogenous respiration, and not a real lack of coupling between the two reactions.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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