Journal of Bacteriology, July 2003, p . 4163-4171, Vol . 185, No . 14

 
The crystal structure of E . coli KPHMT (PDB code 1m3u) was solved to 1.9-Å resolution in complex with Mg²⁺ and the product ketopantoate (30) . KPHMT adopts a homodecameric quaternary structure . Based on the analysis of both the hydrophobic and polar interactions and the buried surface area between the subunits, it is best described as a pentamer of dimers . The protomeric tertiary structure of the subunits is a classical (ß)₈- or triosephosphate isomerase barrel fold with some minor but important variations (Fig . 2) . The helix, usually found between ß-strands 7 and 8, is here replaced by a loop, and an additional N-terminal -helix preceding the usual first ß-strand in the sequence is located at the base of the ß-barrel . The subunits are arranged in an orientation such that the vertical axis of the (ß)₈-barrel is perpendicular to the fivefold axis of the decamer . In the active site of KPHMT, magnesium is coordinated in an octahedral sphere with ketopantoate, occupying an axial and an equatorial coordination site (Fig . 2a; see also Fig . 5a) .

 
Although KPHMT belongs to the common (ß)₈- or triosephosphate isomerase barrel fold, sequence analysis failed to detect any enzymes similar or homologous to KPHMT . However, comparative analysis of X-ray structures is a powerful tool in identifying evolutionary relationships and in gaining insight into the mechanism . Here we have used this approach to identify homologues of KPHMT and to compare their active sites . Based on this analysis, we have been able to classify KPHMT as a member of a (ß)₈ superfamily, to draw conclusions about the evolutionary relationship of the enzymes within the superfamily, and to gain insight into the conservation of both substrate binding and mechanisms .

The SCOP database (23) superfamily classifications both of proteins considered homologues and of enzymes classified in the same Enzyme Commission group were investigated . Other members of the superfamily in which homologues of KPHMT were identified were subjected to the comparative structural analysis described above . In that way, more-distant homologues could potentially be identified and relationships within the superfamily be revealed . Particular attention was then paid to the conservation of the active-site residues common to homologues and positions in the structures of those having equivalent functions .

 
PEPM shows the closest similarity to ICL and vice versa . E . coli ICL and PEPM superimpose with a root mean square deviation (RMSD) of 1.51 Å for 221 structurally aligned residues, and the sequence identity between the two enzymes is 20.5% . The homotetrameric ICL is structurally the second-most similar enzyme to KPHMT . ICL catalyzes the reversible conversion of isocitrate into glyoxylate and succinate, the first step in the glyoxylate bypass pathway . The crystal structures of the E . coli enzyme in complex with Mg²⁺ and pyruvate (1), the Aspergillus nidulans enzyme in complex with Mn²⁺ and glyoxylate (PDB code 1dqu) (2), and the Mycobacterium tuberculosis enzyme in complex with Mg²⁺ and with two inhibitors have been solved (PDB code 1f8i) (26) . For the comparison with KPHMT in this paper, we used the E . coli ICL structure . Sequence conserved between ICL and KPHMT overlaps largely with the residues that are conserved between KPHMT and PEPM . In E . coli ICL there are three -helices before the first ß-strand, of which 3 lies across the N-terminal part of the barrel . As in PEPM, the chain folds in a series of -helices at the C terminus, and similarly, the 12 and 13 helices are involved in helix swapping . The conserved residues 194 to 199 in the region between ß4 and 5 in E . coli ICL are disordered in three out of four subunits . Comparison with PEPM shows that this region is spatially equivalent to the one expected to undergo conformational change in PEPM between ß4 and ß5 . The active site of ICL shows almost identical features to those of PEPM, and the key active-site residues in PEPM are also invariant in ICL (Fig . 5) . Similarly, the mode of ligand binding is essentially the same . The conserved Asp 157 after ß3 in E . coli ICL is equivalent to Asp 84 in KPHMT and Asp 85 in PEPM, as are the conserved Glu 186 after ß4, which is equivalent to Glu 114 in KPHMT and PEPM, and the conserved Ser 91, which is equivalent to Ser 46 in KPHMT and PEPM (Fig . 3) . The only difference in the coordination of Mg²⁺ between PEPM and E . coli ICL seems to be the conservative substitution of Asp 87 to its equivalent Glu 159 in the E . coli ICL structure, although in A . nidulans and M . tuberculosis ICLs, this residue is also an aspartate (Asp 170 and Asp 153, respectively) .

Mechanistic comparison with ICL and PEPM. Comparison of the mechanisms of both ICL and PEPM with KPHMT is not straightforward . The reaction mechanism in PEPM is not very well understood but has been proposed to involve a covalent phospho-enzyme intermediate of the phosphoryl group with Asp 58 . It is proposed that during formation of this phospho-enzyme intermediate, the Mg²⁺ ion shifts towards the position of the water to the left of the Mg²⁺ ion, as shown in Fig . 5b (10), interacting directly with the carboxylate groups of Asp 85, Asp 87, and Glu 114, a process for which no equivalent in KPHMT has been found so far . What seems to be much the same in KPHMT and PEPM is the need to stabilize an enolate intermediate . This is derived from pyruvate in PEPM (15) and from -KIVA in KPHMT . In ICL the initial step, as in KPHMT, is a proton abstraction . As for KPHMT and PEPM, the reaction intermediate for the reverse reaction in ICL involves an enolate, which then undergoes a Claisen condensation . For E . coli ICL, it has been suggested that Cys 195, which is located in the loop region between ß4 and ß5, is the base for the proton abstraction . In M . tuberculosis ICL, a large conformational movement of this cysteine-containing loop together with the ordering of the final helix at the C terminus could be observed . Neither ICL nor PEPM used any cofactor other than Mg²⁺ in the reaction .

Comparison with the other members of the PEP/pyruvate superfamily. The SCOP database currently distinguishes 25 superfamilies of (ß)₈-barrel proteins in which the members of the superfamily have a probable common evolutionary origin . Both ICL and PEPM are assigned to the PEP/pyruvate superfamily . Other members of this superfamily include E . coli 2-dehydro-3-deoxy-galactarate aldolase (DDGA; EC 4.1.2.20; PDB code 1dxf), E . coli PEP carboxylase (PEPC; EC 4.1.1.31; PDB code 1qb4), E . coli pyruvate kinase (PK; EC 5.4.2.9; PDB code 1pky), and pyruvate phosphate dikinase (PPDK; EC 2.7.9.1; PDB code 1kbl) from Clostridium symbiosum .

Like KPHMT, the hexameric (trimer of dimers) DDGA is a class 2 aldolase with a single-domain (ß)₈-fold (11) . It catalyzes the reversible aldol cleavage of 2-dehydro-3-deoxy-galactarate into pyruvate and semialdehyde and in the catabolic pathway for the utilization of D-glucarate/galactarate . The enzyme has a low substrate specificity, condensing a wide range of aldehydes with pyruvate . A DALI search with KPHMT listed DDGA (PDB code 1dxe) only as the 31st hit . However, PEPM is structurally the second-most similar enzyme to DDGA within the PEP/pyruvate superfamily . The two enzymes superimpose with an RMSD of 3.1 Å for 174 structurally aligned residues, whereas sequence identity between the two enzymes is not significant (percent identity, 12.8%) . DDGA shows some features in common with KPHMT, such as the N-terminal -helix . Analogous to findings for ICL and PEPM, helix swapping of the eighth -helix can be observed . The active-site Mg²⁺ ion is directly complexed by Glu 153 in the loop after ß5 and by Asp 179 in the -helix after ß6 (Fig . 5) . The cocrystallized pyruvate occupies two Mg²⁺ binding sites and hydrogen bonds to Ser 178 . Two water molecules complete the coordination sphere, one of which hydrogen bonds to Glu 49, which aligns with Asp 45 from KPHMT (Fig . 3) . Thus, the overall Mg²⁺ and ligand coordination bears some resemblance to that of KPHMT, but with inverted symmetry . The absolute position of the metal ion has moved from between ß3 and ß4 to a position between ß5 and ß6 (Fig . 4) . However, not only the absolute position but also the positions of the Asp and Glu residues relative to each other have changed . The possibility of a circular permutation was investigated; however, no evidence for such an event could be found . A circular permutation in which ß-strands are joined and the barrel is opened at another place would not explain why the relative positions of Asp and Glu have been exchanged .

The first step in the reaction catalyzed by DDGA involves the enolization of pyruvate in an aldol reaction chemically very similar to the one in KPHMT . However, no base close enough for the proton abstraction could be identified in the active site of the enzyme . Instead, a phosphate, which was observed in the active site in the ligand-free structure, is thought to accept the proton of the pyruvate's methyl group (11) .

PEPC, PK, and PPDK are structurally not very similar to KPHMT . However, investigation of the structural similarity relationships between the first three and DDGA shows that the closest structural similarity is between DDGA and E . coli PK (PDB code 1pky) . PK is the structurally most similar enzyme in both PEPC (PDB code 1qb4) and PPDK (PDB code 1kc7), and DDGA is the next most similar . The homotetrameric PK, a three-domain protein with a (ß)₈ core domain, catalyzes the conversion of PEP to pyruvate coupled to the synthesis of ATP (17, 20) . The homotetrameric PEPC catalyzes the irreversible carboxylation of PEP to form oxalacetate and inorganic phosphate (12, 19) . PPDK catalyzes the interconversion of ATP, phosphate, and pyruvate into AMP, pyrophosphate, and PEP (7, 8), respectively . Structure-based sequence alignment of the (ß)₈ domain and superpositions of the active sites show that the Mg²⁺-coordinating residues in PEPC, PK, and PPDK are in identical positions and align with those in DDGA (Fig . 5) . The mode of binding of the -ketoacid moiety of the cocrystallized ligands to Mg²⁺ is essentially the same in DDGA, PK, and PPDK . PEPC, PPDK, and PK, together with PEPM, also share the ligand PEP as their substrate or product . Whereas PK uses one ADP molecule and PPDK uses one ATP molecule in the course of the reaction, PPDC does not have any second substrate .

Comparison with other class 2 aldolases and THF binding enzymes. Apart from 2-dehydro-2-deoxy-galactarate aldolase, structures of four class 2 aldolases, all from E . coli, are available . These include fructose-1,6-biphosphate adolase (6, 24) and tagatose-1,6-biphosphate aldolase (5), both adopting a (ß)₈-fold as well as L-fuculose-1-phosphate aldolase (4) and L-ribulose-5-phosphate 4-epimerase (18) . As seen in the SCOP database, the latter two enzymes do not adopt the (ß)₈-fold and belong to the class 2 family in the class 2 superfamily within the and ß (/ß) fold . The dimeric fructose-1,6-biphosphate adolase and the tetrameric tagatose-1,6-biphosphate aldolase are assigned to the class 2 aldolase family in the aldolase superfamily in SCOP . In each of these structures, the catalytic Zn²⁺ metal ion has an environment different from that of the magnesium coordination site found in KPHMT . However, although all of these class 2 aldolases involve the same chemical mechanism as KPHMT, comparison of their active sites, overall three-dimensional structures, and functions with the respective properties of KPHMT did not show significant analogies . None of the class 2 aldolases use a second substrate that is even remotely similar to 5,10-methylene THF . As the class 2 aldolases appear to be spread out across folds and superfamilies, membership in this functional group is not a particularly helpful criterion in understanding structure and function in KPHMT . The identity of the second substrate or electrophilic donor was also not a basis for classification, as folate binding is not a trait of any existing (ß)₈ superfamily .

Conclusions. Comparative analysis of (ß)₈ structures requires careful attention to detail in the structure, as the overall folds can be very similar, even though there is no significant sequence identity among (ß)₈ enzymes . Comparison of the structure of KPHMT with the structures of PEPM and ICL has shown considerable similarity in the overall folds and, more importantly, convincing similarity in their active sites . The two Mg²⁺-coordinating carboxylate-containing residues, together with a Ser residue that interacts with the ligand, are completely conserved throughout the three enzymes . Additionally, an enolate is an intermediate in each of the reactions catalyzed by these enzymes . On these grounds, we propose that KPHMT should be assigned to the PEP/pyruvate superfamily and should form a family of its own within this superfamily . However, DDGA, PEPC, PPDK, and PK, which are all in the PEP/pyruvate superfamily, show a different active-site architecture, which appears as a distorted mirror image to the one found in KPHMT . A circular permutation cannot explain such a change, and we could not determine the evolutionary step behind such an alteration . Based on the latter observation, we propose that there should be a subdivision within the PEP/pyruvate superfamily into two groups, one comprising KPHMT, PEPM, and ICL and the other comprising DDGA, PEPC, PPDK, and PK . However, at this stage we cannot make any inferences from this for the mechanism in KPHMT . That KPHMT is a member of the PEP/pyruvate superfamily is yet another example of the catalytic proficiency of the enzymes of this particular superfamily and of the functional plasticity of the (ß)₈-fold in general . Though functionally distinct and mechanistically diverse, members of the PEP/pyruvate superfamily seem to exploit the same structural strategy, namely, the use of a catalytic Mg²⁺ ion in a very specific way, i.e., as an electron sink, and to position and orient the substrate, which always resembles an -ketoacid moiety . However, apart from KPHMT, only PK and PPDK have a second substrate .

The enzymes in the PEP/pyruvate superfamily appear to have evolved divergently while conserving modes of binding to substrates and producing similar reaction intermediates but not maintaining a similarity in their mechanisms, like proton abstraction . Also, selection for a specific cofactor does not seem to have played any role . The analysis thus stands in contradiction to recent studies (29) that supported the theory that chemistry and cofactor binding are more likely to be conserved during evolution than substrate binding . However, it is not possible to determine whether any enzyme might have evolved from another one within the PEP/pyruvate superfamily . There might have been a common ancestor which no longer exists . Given that pantothenate is likely to have existed in the prebiotic soup (13) and that the pantothenate pathway is part of primary metabolism, it seems reasonable to argue that KPHMT must be one of the oldest members of this superfamily . However, further insight into the reaction of KPHMT will require structural information about the cofactor-enzyme complex, which can then provide a basis for rational drug design .

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