Discovery of a Substrate Selectivity Motif in Amino Acid Decarboxylases Unveils a Taurine Biosynthesis Pathway in Prokaryotes

Taurine, the most abundant free amino acid in mammals, with many critical roles such as neuronal development, had so far only been reported to be synthetized in eukaryotes. Taurine is the major product of cysteine metabolism in mammals, and its biosynthetic pathway consists of cysteine dioxygenase a...

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Published inACS chemical biology Vol. 8; no. 10; pp. 2264 - 2271
Main Authors Agnello, Giulia, Chang, Leslie L, Lamb, Candice M, Georgiou, George, Stone, Everett M
Format Journal Article
LanguageEnglish
Published United States American Chemical Society 18.10.2013
Subjects
Amino Acid Motifs
Amino Acid Sequence
Bacteria - enzymology
Carboxy-Lyases - chemistry
Carboxy-Lyases - genetics
Carboxy-Lyases - metabolism
Cells, Cultured
Drug Discovery
Enzyme Stability
Humans
Models, Molecular
Molecular Structure
Signal Transduction
Substrate Specificity
Taurine - biosynthesis
Taurine - chemistry
Taurine - genetics
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Summary:Taurine, the most abundant free amino acid in mammals, with many critical roles such as neuronal development, had so far only been reported to be synthetized in eukaryotes. Taurine is the major product of cysteine metabolism in mammals, and its biosynthetic pathway consists of cysteine dioxygenase and cysteine sulfinic acid decarboxylase (hCSAD). Sequence, structural, and mutational analyses of the structurally and sequentially related hCSAD and human glutamic acid decarboxylase (hGAD) enzymes revealed a three residue substrate recognition motif (X1aa19X2aaX3), within the active site that is responsible for coordinating their respective preferred amino acid substrates. Introduction of the cysteine sulfinic acid (CSA) motif into hGAD (hGAD-S192F/N212S/F214Y) resulted in an enzyme with a >700 fold switch in selectivity toward the decarboxylation of CSA over its preferred substrate, l-glutamic acid. Surprisingly, we found this CSA recognition motif in the genome sequences of several marine bacteria, prompting us to evaluate the catalytic properties of bacterial amino acid decarboxylases that were predicted by sequence motif to decarboxylate CSA but had been annotated as GAD enzymes. We show that CSAD from Synechococcus sp. PCC 7335 specifically decarboxylated CSA and that the bacteria accumulated intracellular taurine. The fact that CSAD homologues exist in certain bacteria and are frequently found in operons containing the recently discovered bacterial cysteine dioxygenases that oxidize l-cysteine to CSA supports the idea that a bona fide bacterial taurine biosynthetic pathway exists in prokaryotes.
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ISSN:1554-8929
1554-8937
DOI:10.1021/cb400335k