The urea carboxylase and allophanate hydrolase activities of urea amidolyase are functionally independent

Lin, Ying Wu; Boese, Cody J.; Maurice, Martin St.

doi:10.1002/pro.2990

Cited by 15 publications

(26 citation statements)

References 51 publications

(110 reference statements)

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“…If there is no covalent linkage between the AH and UC domains, the latter is not strong enough to hold them to form a stable complex. This suggests that AH and UC encoded by separated genes probably do not form a KlUA-like complex, consistent with studies on a number of such AH and UC proteins [ 16 , 18 , 32 ].…”

Section: Discussionsupporting

confidence: 87%

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Structure and function of urea amidolyase

et al. 2018

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Urea is the degradation product of a wide range of nitrogen containing bio-molecules. Urea amidolyase (UA) catalyzes the conversion of urea to ammonium, the essential first step in utilizing urea as a nitrogen source. It is widely distributed in fungi, bacteria and other microorganisms, and plays an important role in nitrogen recycling in the biosphere. UA is composed of urea carboxylase (UC) and allophanate hydrolase (AH) domains, which catalyze sequential reactions. In some organisms UC and AH are encoded by separated genes. We present here structure of the Kluyveromyces lactis UA (KlUA). The structure revealed that KlUA forms a compact homo-dimer with a molecular weight of 400 kDa. Structure inspired biochemical experiments revealed the mechanism of its reaction intermediate translocation, and that the KlUA holo-enzyme formation is essential for its optimal activity. Interestingly, previous studies and ours suggest that UC and AH encoded by separated genes probably do not form a KlUA-like complex, consequently they might not catalyze the urea to ammonium conversion as efficiently.

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Section: Discussionsupporting

confidence: 87%

“…Therefore, substrate channeling of allophanate within the same KlUA polypeptide or KlUA holo-enzyme is unlikely to play a role in the catalysis. A recent study on the Pseudomonas syringae UC and AH also ruled out the possibility that they form a transit complex to facilitate substrate channeling of allophanate during the catalysis [ 32 ].…”

Section: Discussionmentioning

confidence: 99%

Structure and function of urea amidolyase

et al. 2018

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“…However, the significance of this observation is unclear because inhibition was only observed when PxpB was expressed alone and not when PxpB and PxpC were co-expressed to form a complex, as our data show they normally would be. It has also recently been shown that certain fused pxpB and pxpC family genes, which cluster strongly with a urea carboxylase gene, are involved in urea catabolism and encode an enzyme with allophanate hydrolase activity (40,43). Allophanate hydrolase activity has only been demonstrated in a fused PxpBC homolog (43), but it is possible that other PxpB and PxpC proteins have dual roles in OP and urea metabolism.…”

Section: Discussionmentioning

confidence: 99%

“…It has also recently been shown that certain fused pxpB and pxpC family genes, which cluster strongly with a urea carboxylase gene, are involved in urea catabolism and encode an enzyme with allophanate hydrolase activity (40,43). Allophanate hydrolase activity has only been demonstrated in a fused PxpBC homolog (43), but it is possible that other PxpB and PxpC proteins have dual roles in OP and urea metabolism. Additionally, the prokaryote-type OPase genes of Ralstonia solanacearum were shown to be required for pathogenesis in tomato (44).…”

Section: Discussionmentioning

confidence: 99%

Discovery of a widespread prokaryotic 5-oxoprolinase that was hiding in plain sight

Niehaus

Elbadawi-Sidhu

Crécy‐Lagard

et al. 2017

Journal of Biological Chemistry

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5-Oxoproline (OP) is well-known as an enzymatic intermediate in the eukaryotic γ-glutamyl cycle, but it is also an unavoidable damage product formed spontaneously from glutamine and other sources. Eukaryotes metabolize OP via an ATP-dependent 5-oxoprolinase; most prokaryotes lack homologs of this enzyme (and the γ-glutamyl cycle) but are predicted to have some way to dispose of OP if its spontaneous formation is significant. Comparative analysis of prokaryotic genomes showed that the gene encoding pyroglutamyl peptidase, which removes N-terminal OP residues, clusters in diverse genomes with genes specifying homologs of a fungal lactamase (renamedrokaryotic 5-ooprolinase ,) and homologs of allophanate hydrolase subunits (renamed and). Inactivation of ,, or genes slowed growth, caused OP accumulation in cells and medium, and prevented use of OP as a nitrogen source. Assays of cell lysates showed that ATP-dependent 5-oxoprolinase activity disappeared when, , or was inactivated. 5-Oxoprolinase activity could be reconstituted by mixing recombinant PxpA, PxpB, and PxpC proteins. In addition, overexpressing genes in increased 5-oxoprolinase activity in lysates ≥1700-fold. This work shows that OP is a major universal metabolite damage product and that OP disposal systems are common in all domains of life. Furthermore, it illustrates how easily metabolite damage and damage-control systems can be overlooked, even for central metabolites in model organisms.

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“…To ensure vector compatibility, the pET-28a vector encoding ΔBCΔBCCP RePC was modified to replace the pBR322 origin of replication with a pSC101 origin of replication. The gene encoding ΔBCΔBCCP RePC was re-cloned into vector pKLD66nCBP 31 . The T882A mutation was introduced into both ΔBC RePC and ΔBCΔBCCP RePC by whole plasmid mutagenesis using the Quikchange method.…”

Section: Methodsmentioning

confidence: 99%

Allosteric regulation alters carrier domain translocation in pyruvate carboxylase

et al. 2018

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Pyruvate carboxylase (PC) catalyzes the ATP-dependent carboxylation of pyruvate to oxaloacetate. The reaction occurs in two separate catalytic domains, coupled by the long-range translocation of a biotinylated carrier domain (BCCP). Here, we use a series of hybrid PC enzymes to examine multiple BCCP translocation pathways in PC. These studies reveal that the BCCP domain of PC adopts a wide range of translocation pathways during catalysis. Furthermore, the allosteric activator, acetyl CoA, promotes one specific intermolecular carrier domain translocation pathway. These results provide a basis for the ordered thermodynamic state and the enhanced carboxyl group transfer efficiency in the presence of acetyl CoA, and reveal that the allosteric effector regulates enzyme activity by altering carrier domain movement. Given the similarities with enzymes involved in the modular synthesis of natural products, the allosteric regulation of carrier domain movements in PC is likely to be broadly applicable to multiple important enzyme systems.

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The urea carboxylase and allophanate hydrolase activities of urea amidolyase are functionally independent

Cited by 15 publications

References 51 publications

Structure and function of urea amidolyase

Structure and function of urea amidolyase

Discovery of a widespread prokaryotic 5-oxoprolinase that was hiding in plain sight

Allosteric regulation alters carrier domain translocation in pyruvate carboxylase

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