Ferry away a inhibitor proton from the substrate and facilitate a nucleophilic attack on AcCoA.Implications for CatalysisTo confirm the catalytic mechanism, several residues in this site were selected for biochemical studies. Tyr485, the equivalent residue of Tyr397 in mmNAGS/K and Tyr405 in xcNAGS/K, appears to act as a catalytic acid that donates a proton to the thiol group of CoA, playing an important role in the catalytic reaction (Figure 4A). This equivalent tyrosine could be identified in most GCN5-related acetyltransferases [14]. Indeed, the Y485F mutant showed 10 fold lower catalytic activity than wild-type protein (Table 4).Structure of Human N-Acetyl-L-Glutamate SynthaseTable 3. Interactions between N-acetyl-L-glutamate and protein atoms.?Distance (A) Subunit A Subunit B Subunit X Subunit Y N2 Asp443 O Arg474 O O7 OXT Phe445 N Lys444 NZ Wat258a O O Arg474 NE Wat258 O Wat9 O OE1 Asn479 ND Arg476 N OE2 Lys401 NZ Arg476 NEaArginine Protein3.37 3.23 2.96 3.08 2.47 2.94 3.22 2.64 2.96 2.98 2.64 2.3.41 3.19 3.00 2.61 3.37 3.16 2.3.29 3.23 3.04 2.3.29 3.33 3.24 3.2.96 2.47 4.95b 4.22b 2.28 2.2.3.48 3.10 3.31 3.3.43 3.19 4.01b 3.53bWater numbering for subunit A only. The distances are too far away for hydrogen bonding interactions. doi:10.1371/journal.pone.0070369.tbSince the a-amino group of L-glutamate has a pKa value that is close to 10, it seems clear that amine deprotonation must precede the acetyl group transfer. The highly conserved Tyr441 located in the water channel that connects to the a-amino group (see previous section), is positioned to play a role as the catalytic base in proton removal. The lower activity of Y441F mutant is consistent with this catalytic role of this tyrosine. The 7 fold lower activity for N479A mutant confirmed that it is a key residue to bind Lglutamate as found in the present structure (Figure 4A).abundance could compensate for lower activity. A more probable explanation is a regulatory role of the AAK domain in urea cycle flux. Complete hNAGS has two extra features relative to hNAT that may play a role in regulating urea cycle flux. First, the binding of L-arginine enhances NAGS activity and the arginine-binding site that is located in the AAK domain is conserved in NAGS across phyla [4]. In microorganisms, arginine biosynthesis is regulated via this arginine binding site because bound L-arginine is an allosteric inhibitor of NAGS activity [7]. It is therefore reasonable to assume that in mammals, urea cycle flux can be rapidly enhanced via increased NAGS activity by L-arginine binding at this site. Our N-carbamylglutamate (NCG) clinical trial experiments demonstrated that NCG could enhance urea cycle flux even in healthy individuals [15], implying that under normal conditions, CPSI is not fully saturated with NAG. Increasing NAG production will therefore increase urea production by activating additional CPSI molecules. Second, the presence of a proline-rich region in the N-terminal sequence of mammalian NAGS (AAK domain) may be important in interacting with CPSI to facilitate NAG translocation from NAGS to CPSI. Proline-rich motifs often serve 11138725 as targets for protein recognition and interaction since they are recognized by many proteins, including important signaling proteins such as Src homology 3 [16], the WW domain of a kinase-associated protein [17], Enabled/VASP (EVH1) [18] and ubiquitin-E2-like variant (UEV) domain of the tumor maintenance protein Tsg101 [19]. Crystal structures of these motifs demonst.Ferry away a proton from the substrate and facilitate a nucleophilic attack on AcCoA.Implications for CatalysisTo confirm the catalytic mechanism, several residues in this site were selected for biochemical studies. Tyr485, the equivalent residue of Tyr397 in mmNAGS/K and Tyr405 in xcNAGS/K, appears to act as a catalytic acid that donates a proton to the thiol group of CoA, playing an important role in the catalytic reaction (Figure 4A). This equivalent tyrosine could be identified in most GCN5-related acetyltransferases [14]. Indeed, the Y485F mutant showed 10 fold lower catalytic activity than wild-type protein (Table 4).Structure of Human N-Acetyl-L-Glutamate SynthaseTable 3. Interactions between N-acetyl-L-glutamate and protein atoms.?Distance (A) Subunit A Subunit B Subunit X Subunit Y N2 Asp443 O Arg474 O O7 OXT Phe445 N Lys444 NZ Wat258a O O Arg474 NE Wat258 O Wat9 O OE1 Asn479 ND Arg476 N OE2 Lys401 NZ Arg476 NEaArginine Protein3.37 3.23 2.96 3.08 2.47 2.94 3.22 2.64 2.96 2.98 2.64 2.3.41 3.19 3.00 2.61 3.37 3.16 2.3.29 3.23 3.04 2.3.29 3.33 3.24 3.2.96 2.47 4.95b 4.22b 2.28 2.2.3.48 3.10 3.31 3.3.43 3.19 4.01b 3.53bWater numbering for subunit A only. The distances are too far away for hydrogen bonding interactions. doi:10.1371/journal.pone.0070369.tbSince the a-amino group of L-glutamate has a pKa value that is close to 10, it seems clear that amine deprotonation must precede the acetyl group transfer. The highly conserved Tyr441 located in the water channel that connects to the a-amino group (see previous section), is positioned to play a role as the catalytic base in proton removal. The lower activity of Y441F mutant is consistent with this catalytic role of this tyrosine. The 7 fold lower activity for N479A mutant confirmed that it is a key residue to bind Lglutamate as found in the present structure (Figure 4A).abundance could compensate for lower activity. A more probable explanation is a regulatory role of the AAK domain in urea cycle flux. Complete hNAGS has two extra features relative to hNAT that may play a role in regulating urea cycle flux. First, the binding of L-arginine enhances NAGS activity and the arginine-binding site that is located in the AAK domain is conserved in NAGS across phyla [4]. In microorganisms, arginine biosynthesis is regulated via this arginine binding site because bound L-arginine is an allosteric inhibitor of NAGS activity [7]. It is therefore reasonable to assume that in mammals, urea cycle flux can be rapidly enhanced via increased NAGS activity by L-arginine binding at this site. Our N-carbamylglutamate (NCG) clinical trial experiments demonstrated that NCG could enhance urea cycle flux even in healthy individuals [15], implying that under normal conditions, CPSI is not fully saturated with NAG. Increasing NAG production will therefore increase urea production by activating additional CPSI molecules. Second, the presence of a proline-rich region in the N-terminal sequence of mammalian NAGS (AAK domain) may be important in interacting with CPSI to facilitate NAG translocation from NAGS to CPSI. Proline-rich motifs often serve 11138725 as targets for protein recognition and interaction since they are recognized by many proteins, including important signaling proteins such as Src homology 3 [16], the WW domain of a kinase-associated protein [17], Enabled/VASP (EVH1) [18] and ubiquitin-E2-like variant (UEV) domain of the tumor maintenance protein Tsg101 [19]. Crystal structures of these motifs demonst.