Aaron E. Ransome scite author profile

N5-carboxyaminoimidazole ribonucleotide (N5-CAIR) mutase (PurE) catalyzes the reversible interconversion of acid-labile compounds N5-CAIR and 4-carboxy-5-aminoimidazole ribonucleotide (CAIR). We have examined PurE from the acidophilic bacterium Acetobacter aceti (AaPurE), focusing on its adaptation to acid pH and the roles of conserved residues His59 and His89. Both AaPurE and Escherichia coli PurE showed quasi-reversible acid-mediated inactivation, but wt AaPurE was much more stable at pH 3.5, with a > or = 20 degrees C higher thermal unfolding temperature at all pHs. His89 is not essential and does not function as part of a proton relay system. The kcat pH-rate profile was consistent with the assignment of pK1 to unproductive protonation of bound nucleotide and pK2 to deprotonation of His59. A 1.85 A resolution crystal structure of the inactive mutant H59N-AaPurE soaked in CAIR showed that protonation of CAIR C4 can occur in the absence of His59. The resulting species, modeled as isoCAIR [4(R)-carboxy-5-iminoimidazoline ribonucleotide], is strongly stabilized by extensive interactions with the enzyme and a water molecule. The carboxylate moiety is positioned in a small pocket proposed to facilitate nucleotide decarboxylation in the forward direction (N5-CAIR --> CAIR) [Meyer, E., Kappock, T. J., Osuji, C., and Stubbe, J. (1999) Biochemistry 38, 3012-3018]. Comparisons with model studies suggest that in the reverse (nonbiosynthetic) direction PurE favors protonation of CAIR C4. We suggest that the essential role of protonated His59 is to lower the barrier to decarboxylation by stabilizing a CO2-azaenolate intermediate.

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Transcellular biosynthesis of cysteinyl leukotrienes in vivo during mouse peritoneal inflammation

Zarini

Gijón

Ransome

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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Leukotrienes (LTs) are lipid mediators of inflammation formed by enzymatic oxidation of arachidonic acid. One intriguing aspect of LT production is transcellular biosynthesis: cells expressing 5-lipoxygenase (5LO) form LTA4 and transfer it to cells expressing LTA4 hydrolase (LTA4H) or LTC4 synthase (LTC4S) to produce LTB4 or LTC4. This process has been demonstrated in vivo for LTB4, but not for cysteinyl LTs (cysLTs). We examined transcellular cysLT synthesis during zymosan-induced peritonitis, using bone marrow transplants with transgenic mice deficient in key enzymes of LT synthesis and analyzing all eicosanoids by liquid chromatography/ tandem mass spectrometry. WT mice time-dependently produced LTB4 and cysLTs (LTC4, LTD4, and LTE4). 5LO ؊/؊ mice were incapable of producing LTs. WT bone marrow cells restored this biosynthetic ability, but 5LO ؊/؊ bone marrow did not rescue LT synthesis in irradiated WT mice, demonstrating that bone marrow-derived cells are the ultimate source of all LTs in this model. Total levels of 5LO-derived products were comparable in LTA4H ؊/؊ and WT mice, but were reduced in LTC4S ؊/؊ animals. No differences in prostaglandin production were observed between these transgenic or chimeric mice. Bone marrow cells from LTA 4H ؊/؊ or LTC4S ؊/؊ mice injected into 5LO ؊/؊ mice restored the ability to synthesize LTB4 and cysLTs, providing unequivocal evidence of efficient transcellular biosynthesis of cysLTs. These results highlight the potential relevance of transcellular exchange of LTA 4 for the synthesis of LTs mediating biological activities during inflammatory events in vivo. chimeric mice ͉ leukotriene B4 ͉ mass spectrometry ͉ leukotriene E4 ͉ 5-lipoxygenase

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Structure of a NADH-Insensitive Hexameric Citrate Synthase that Resists Acid Inactivation

et al. 2006

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Acetobacter aceti converts ethanol to acetic acid, and strains highly resistant to both are used to make vinegar. A. aceti survives acetic acid exposure by tolerating cytoplasmic acidification, which implies an unusual adaptation of cytoplasmic components to acidic conditions. A. aceti citrate synthase (AaCS), a hexameric type II citrate synthase, is required for acetic acid resistance and, therefore, would be expected to function at low pH. Recombinant AaCS has intrinsic acid stability that may be a consequence of strong selective pressure to function at low pH, and unexpectedly high thermal stability for a protein that has evolved to function at approximately 30 degrees C. The crystal structure of AaCS, complexed with oxaloacetate (OAA) and the inhibitor carboxymethyldethia-coenzyme A (CMX), was determined to 1.85 A resolution using protein purified by a tandem affinity purification procedure. This is the first crystal structure of a "closed" type II CS, and its active site residues interact with OAA and CMX in the same manner observed in the corresponding type I chicken CS.OAA.CMX complex. While AaCS is not regulated by NADH, it retains many of the residues used by Escherichia coli CS (EcCS) for NADH binding. The surface of AaCS is abundantly decorated with basic side chains and has many fewer uncompensated acidic charges than EcCS; this constellation of charged residues is stable in varied pH environments and may be advantageous in the A. aceti cytoplasm.

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Draft Genome Sequence of Acetobacter aceti Strain 1023, a Vinegar Factory Isolate

et al. 2014

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Aaron E. Ransome

Biochemical and Structural Studies of N⁵-Carboxyaminoimidazole Ribonucleotide Mutase from the Acidophilic Bacterium Acetobacter aceti

Transcellular biosynthesis of cysteinyl leukotrienes in vivo during mouse peritoneal inflammation

Structure of a NADH-Insensitive Hexameric Citrate Synthase that Resists Acid Inactivation

Draft Genome Sequence of Acetobacter aceti Strain 1023, a Vinegar Factory Isolate

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Aaron E. Ransome

Biochemical and Structural Studies of N5-Carboxyaminoimidazole Ribonucleotide Mutase from the Acidophilic Bacterium Acetobacter aceti

Transcellular biosynthesis of cysteinyl leukotrienes in vivo during mouse peritoneal inflammation

Structure of a NADH-Insensitive Hexameric Citrate Synthase that Resists Acid Inactivation

Draft Genome Sequence of Acetobacter aceti Strain 1023, a Vinegar Factory Isolate

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Biochemical and Structural Studies of N⁵-Carboxyaminoimidazole Ribonucleotide Mutase from the Acidophilic Bacterium Acetobacter aceti