By using a bioinformatics screen of the Escherichia coli genome for potential molybdenum-containing enzymes, we have identified a novel oxidoreductase conserved in the majority of Gram-negative bacteria. The identified operon encodes for a proposed heterodimer, YedYZ in Escherichia coli, consisting of a soluble catalytic subunit termed YedY, which is likely anchored to the membrane by a heme-containing trans-membrane subunit termed YedZ. YedY is uniquely characterized by the presence of one molybdenum molybdopterin not conjugated by an additional nucleotide, and it represents the only molybdoenzyme isolated from E. coli characterized by the presence of this cofactor form. We have further characterized the catalytic subunit YedY in both the molybdenum-and tungsten-substituted forms by using crystallographic analysis. YedY is very distinct in overall architecture from all known bacterial reductases but does show some similarity with the catalytic domain of the eukaryotic chicken liver sulfite oxidase. However, the strictly conserved residues involved in the metal coordination sphere and in the substrate binding pocket of YedY are strikingly different from that of chicken liver sulfite oxidase, suggesting a catalytic activity more in keeping with a reductase than that of a sulfite oxidase. Preliminary kinetic analysis of YedY with a variety of substrates supports our proposal that YedY and its many orthologues may represent a new type of membrane-associated bacterial reductase.Molybdenum-coordinating enzymes fall within the broad class of enzymes associated with redox metabolic functions in prokaryotic and eukaryotic cells. The structurally characterized enzymes can be roughly grouped into three separate families (the bacterial/eukaryotic xanthine oxidase family, the eukaryotic sulfite oxidase family, and the bacterial Me 2 SO reductase family), each distinctive with respect to active site structure and the type of reaction they catalyze (1). The family of xanthine oxidases contains 1 eq of a pterin cofactor coordinated to the molybdenum metal with the typical pentavalent, approximately octahedral coordination sphere in the oxidized state completed not by any side chains from the enzyme but rather by a double-bonded sulfur atom, a double-bonded oxygen atom, and an oxygen atom with a single bond (2). Sulfite oxidases have 1 eq of a pterin cofactor with the molybdenum coordinated by a cysteine ligand from the enzyme and two oxo groups (3, 4). Kappler et al. (5) described the spectroscopic and enzymologic characterization of a member of the sulfite oxidase family from Thiobacillus novellus, and they showed that the enzyme contains a molybdopterin-type cofactor, but no structural data are available for bacterial sulfite oxidase family members to verify the nature of the cofactor or overall architecture of this enzyme. The Me 2 SO reductase family is diverse in both structure and function, but all members have 2 eq of the pterin cofactor, and the molybdenum coordination sphere is usually completed by a single oxo group ...
Bacterial protein secretion is important in the life cycles of most bacteria, in which it contributes to the formation of pili and flagella and makes available extracellular enzymes to digest polymers for nutritional purposes and toxins to kill host cells in infections of humans, animals and plants. It is generally accepted that nonpathogenic laboratory strains of Escherichia coli, particularly K12 strains, do not secrete proteins into the extracellular medium under routine growth conditions. In this study, we report that commonly used laboratory strains secrete YebF, a small (10.8 kDa in the native form), soluble endogenous protein into the medium, challenging the status quo view that laboratory strains do not secrete proteins to the medium. We further show that 'passenger' proteins linked to the carboxyl end of YebF are efficiently secreted. The function of YebF is unknown, but its use as a carrier for transgenic proteins provides a tool to circumvent toxicity and other contamination issues associated with protein production in E. coli.
We report the biochemical and biophysical characterization of YedYZ, a sulfite oxidase homologue from Escherichia coli. YedY is a soluble catalytic subunit with a twin arginine leader sequence for export to the periplasm by the Tat translocation system. YedY is the only molybdoenzyme so far isolated from E. coli with the Mo-MPT form of the molybdenum cofactor. The electron paramagnetic resonance (EPR) signal of the YedY molybdenum is similar to that of known Mo-MPT containing enzymes, with the exception that only the Mo(IV) --> Mo(V) transition is observed, with a midpoint potential of 132 mV. YedZ is a membrane-intrinsic cytochrome b with six putative transmembrane helices. The single heme b of YedZ has a midpoint potential of -8 mV, determined by EPR spectroscopy of YedZ-enriched membrane preparations. YedY does not associate strongly with YedZ on the cytoplasmic membrane. However, mutation of the YedY active site Cys102 to Ser results in very efficient targeting of YedY to YedZ in the membrane, demonstrating a clear role for YedZ as the membrane anchor for YedY. Together, YedYZ comprise a well-conserved bacterial heme-molybdoenzyme found in a variety of bacteria that can be assigned to the sulfite oxidase class of enzyme.
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