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Acta Cryst. (2014). A70, C1060
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Phosphorus is an essential element for all living cells and is usually taken up in the form of phosphate. A number of microorganisms, however, are capable of extracting phosphorous from organic phosphonate compounds, which are characterized by a stable carbon-phosphorus (C-P) bond (1). The metabolic pathway responsible for phosphonate degradation is still poorly understood, but the process is known to involve two reactions before the actual C-P bond cleavage, which has been proposed to take place via a radical mechanism. A key component in the process is C-P lyase, an enzyme encoded by phnJ within the phn operon (2). To get a better insight into the mechanism of this complex degradation pathway, we have determined the crystal structure of the core of a multi-subunit enzymatic complex including the C-P lyase component with a total molecular mass of 220 kDa (3). The structure reveals the overall architecture of the C-P lyase and has important implications for our understanding of enzyme mechanism and catalysis.

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Acta Cryst. (2014). A70, C1792
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Two high resolution crystal structures of isatin hydrolase (IH) from the Baltic seabed bacteria Labrenzia aggregata are presented. The crystals structure capture both the apo and the product state. This hydrolase present a new fold and the first metal-dependent hydrolase with this fold to be functionally characterized[1]. The Isatin hydrolase catalyze the reaction that convert isatin to isatinate and belongs to a novel family of metalloenzymes that include bacterial kynurenine formamidase (KynB) also recently published, however hoste a binclear zink site in the active site[2] as compared to a single manganese in IH. The product state, mimicked by thioisatinate, has captured an additional water molecule that bridges the thioisatinate to a water channel and that could act as a proton wire and thus allows the proton to be released during the hydrolysis reaction only when the product is formed. The functional proton wire is therefore locked by thioisatinate and represents a unique catalytic feature trapped and visualized. Biochemical evidence for the proton wire is also presented as single point mutation from S225C enhances the Vmax of the enzyme. Ser-225 is the only side chain residue that is included in the proton wire. The molecular basis for thioisatinate recognition allows stronger and more confident identification of orthologous genes encoding isatin hydrolases within the prokaryotic kingdom. The isatin hydrolase orthologues found in human gut bacteria raise the question as to whether the indole-3-acetic acid degradation pathway is present in human gut flora.
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