Abstract
Glycine cleavage system (GCS) plays a central role in one‐carbon (C1) metabolism and receives increasing interest as a core part of the recently proposed reductive glycine pathway (rGlyP) for assimilation of CO2 and formate. Despite decades of research, GCS has not yet been well understood and kinetic data are barely available. This is to a large degree because of the complexity of GCS, which is composed of four proteins (H, T, P, and L) and catalyzes reactions involving different substrates and cofactors. In vitro kinetics of reconstructed microbial multi‐enzyme glycine cleavage/synthase system is desired to better implement rGlyP in microorganisms like Escherichia coli for the use of C1 resources. Here, we examined in vitro several factors that may affect the rate of glycine synthesis via the reverse GCS reaction. We found that the ratio of GCS component proteins has a direct influence on the rate of glycine synthesis, namely higher ratios of P protein and especially H protein to T and L proteins are favorable, and the carboxylation reaction catalyzed by P protein is a key step determining the glycine synthesis rate, whereas increasing the ratio of L protein to other GCS proteins does not have significant effect and the ratio of T protein to other GCS proteins should be kept low. The effect of substrate concentrations on glycine synthesis is quite complex, showing interdependence with the ratios of GCS component proteins. Furthermore, adding the reducing agent dithiothreitol to the reaction mixture not only results in great tolerance to high concentration of formaldehyde, but also increases the rate of glycine synthesis, probably due to its functions in activating P protein and taking up the role of L protein in the non‐enzymatic reduction of Hox to Hred. Moreover, the presence of some monovalent and divalent metal ions can have either positive or negative effect on the rate of glycine synthesis, depending on their type and their concentration.
Highlights
Nowadays, most of the chemicals including fuels, solvents and plastics are produced from fossil carbons
We chose to start with a ratio of P:H:T:L = 1:2:1:1 to study the glycine synthesis, and varied the ratio to see the influences of the different Glycine cleavage system (GCS) proteins
We studied some key factors that may affect the rate of the glycine synthesis
Summary
Most of the chemicals including fuels, solvents and plastics are produced from fossil carbons. There is an urgent need to search for sustainable and cheap resources as feedstocks for the production of high-value chemicals at hundreds of millions of tons per year using microbial fermentation processes. One-carbon (C1) compounds, such as CO2 [2, 3], formate [4, 5] and methanol [6, 7] have been proposed as ideal feedstocks to alleviate global energy shortage and environmental pollution problems. These compounds are either naturally abundant, cheap to produce, or available as industrial by-products. In the rGlyP, formate is ligated to tetrahydrofolate (THF) and further reduced to N5, N10-methylene-THF (5,10-CH2THF), which is used for the synthesis of glycine by glycine synthase (the reverse glycine cleavage system, rGCS)
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