PLoS ONE (Jan 2015)

An in vivo metabolic approach for deciphering the product specificity of glycerate kinase proves that both E. coli's glycerate kinases generate 2-phosphoglycerate.

  • Lior Zelcbuch,
  • Manuel Razo-Mejia,
  • Elad Herz,
  • Sagit Yahav,
  • Niv Antonovsky,
  • Hagar Kroytoro,
  • Ron Milo,
  • Arren Bar-Even

DOI
https://doi.org/10.1371/journal.pone.0122957
Journal volume & issue
Vol. 10, no. 3
p. e0122957

Abstract

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Apart from addressing humanity's growing demand for fuels, pharmaceuticals, plastics and other value added chemicals, metabolic engineering of microbes can serve as a powerful tool to address questions concerning the characteristics of cellular metabolism. Along these lines, we developed an in vivo metabolic strategy that conclusively identifies the product specificity of glycerate kinase. By deleting E. coli's phosphoglycerate mutases, we divide its central metabolism into an 'upper' and 'lower' metabolism, each requiring its own carbon source for the bacterium to grow. Glycerate can serve to replace the upper or lower carbon source depending on the product of glycerate kinase. Using this strategy we show that while glycerate kinase from Arabidopsis thaliana produces 3-phosphoglycerate, both E. coli's enzymes generate 2-phosphoglycerate. This strategy represents a general approach to decipher enzyme specificity under physiological conditions.