Mutation analysis in nephronophthisis using a combined approach of homozygosity mapping, CEL I endonuclease cleavage, and direct sequencing.

Nephronophthisis (NPHP), an autosomal recessive kidney disease, is the most frequent genetic cause of chronic renal failure in the first three decades of life. Mutations in eight genes (NPHP1-8) have been identified. We here describe a combined approach for mutation screening of NPHP1, NPHP2, NPHP3, NPHP4, and NPHP5 in a worldwide cohort of 470 unrelated patients with NPHP. First, homozygous NPHP1 deletions were detected in 97 patients (21%) by multiplex PCR. Second, 25 patients with infantile NPHP were screened for mutations in inversin (NPHP2/INVS). We detected a novel compound heterozygous frameshift mutation (p.[Q485fs]+[R687fs]), and a homozygous nonsense mutation (p.R899X). Third, 37 patients presenting with NPHP and retinitis pigmentosa (Senior-Løken syndrome [SLS]) were screened for NPHP5/IQCB1 mutations by direct sequencing. We discovered five different (three novel) homozygous premature termination codon (PTC) mutations (p.F142fsX; p.R461X; p.R489X; p.W444X; and c.488-1G>A). The remaining 366 patients were further investigated for mutations in NPHP1, NPHP3, and NPHP4. We applied a "homozygosity only" strategy and typed three highly polymorphic microsatellite markers at the respective loci. A total of 32, eight, and 14 patients showed homozygosity, and were screened by heteroduplex crude celery extract (CEL I) endonuclease digests. The sensitivity of CEL I was established as 92%, as it detected 73 out of 79 different known mutations simply on agarose gels. A total of 10 novel PTC mutations were found in NPHP1 (p.P186fs, p.R347X, p.V492fs, p.Y509X, and c.1884+1G>A), in NPHP3 (c.3812+2T>C and p.R1259X), and in NPHP4 (p.R59X, p.T1004fs, and p.V1091fs). The combined homozygosity mapping and CEL I endonuclease mutation analysis approach allowed us to identify rare mutations in a large cohort of patients at low cost.

Evolution of enzymatic activities in the orotidine 5'-monophosphate decarboxylase suprafamily: enhancing the promiscuous D-arabino-hex-3-ulose 6-phosphate synthase reaction catalyzed by 3-keto-L-gulonate 6-phosphate decarboxylase.

3-Keto-l-gulonate 6-phosphate decarboxylase (KGPDC) and d-arabino-hex-3-ulose 6-phosphate synthase (HPS) are members of the orotidine 5'-monophosphate decarboxylase (OMPDC) suprafamily [Wise, E., Yew, W. S., Babbitt, P. C., Gerlt, J. A., and Rayment, I. (2002) Biochemistry 41, 3861-3869], a group of homologous enzymes that share the (beta/alpha)(8)-barrel fold. KGPDC catalyzes a Mg(2+)-dependent decarboxylation reaction in the catabolic pathway of l-ascorbate utilization by Escherichia coli K-12 [Yew, W. S., and Gerlt, J. A. (2002) J.Bacteriol. 184, 302-306]; HPS catalyzes a Mg(2+)-dependent aldol condensation between formaldehyde and d-ribulose 5-phosphate in formaldehyde-fixing methylotrophic bacteria [Kato, N., Ohashi, H., Hori, T., Tani, Y., and Ogata, K. (1977) Agric. Biol. Chem. 41, 1133-1140]. Our previous studies of the KGPDC from E. coli established the occurrence of a stabilized cis-enediolate intermediate [Yew, W. S., Wise, E., Rayment, I., and Gerlt, J. A. (2004) Biochemistry 43, 6427-6437; Wise, E., Yew, W. S., Gerlt, J. A., and Rayment, I. (2004) Biochemistry 43, 6438-6446]. Although the mechanism of the HPS-catalyzed reaction has not yet been investigated, it also is expected to involve a Mg(2+)-stabilized cis-enediolate intermediate. We now have discovered that the KGPDC from E. coli and the HPS from Methylomonas aminofaciens are both naturally promiscuous for the reaction catalyzed by the homologue. On the basis of the alignment of the sequences of orthologous KGPDC's and HPS's, four conserved active site residues in the KGPDC from E. coli were mutated to those conserved in HPS's (E112D/R139V/T169A/R192A): the value of the k(cat) for the promiscuous HPS activity was increased as much as 170-fold (for the E112D/R139V/T169A/R192A mutant), and the value of k(cat)/K(m) was increased as much as 260-fold (for the E112D/R139V/T169A mutant); in both cases, the values of the kinetic constants for the natural KGPDC activity were decreased. Together with the structures of mutants reported in the accompanying manuscript [Wise, E. L., Yew, W. S., Akana, J., Gerlt, J. A., and Rayment, I., accompanying manuscript], these studies illustrate that large changes in catalytic efficiency can be accomplished with only modest changes in active site structure. Thus, the (beta/alpha)(8)-barrel fold shared by members of the OMPDC suprafamily appears well-suited for the evolution of new functions.

Evolution of enzymatic activities in the orotidine 5'-monophosphate decarboxylase suprafamily: structural basis for catalytic promiscuity in wild-type and designed mutants of 3-keto-L-gulonate 6-phosphate decarboxylase.

3-Keto-L-gulonate 6-phosphate decarboxylase (KGPDC) and D-arabino-hex-3-ulose 6-phosphate synthase (HPS), members of the orotidine 5'-monophosphate decarboxylase (OMPDC) suprafamily, catalyze reactions that involve the formation of Mg(2+)-ion stabilized 1,2-enediolate intermediates. The active sites of KGPDC and HPS share several conserved residues, including the presumed ligands for the Mg(2+) and a catalytic histidine residue that has been implicated in protonation of the intermediate in the KGPDC-catalyzed reaction. As reported in the previous manuscript, both enzymes are naturally promiscuous, with KGPDC from Escherichia coli catalyzing a low level of the HPS reaction and the HPS from Methylomonas aminofaciens catalyzing a significant level of the KGPDC reaction. Interestingly, the promiscuous HPS reaction catalyzed by KGPDC can be significantly enhanced by replacing no more than four active site residues from KGPDC reaction with residues from HPS. In this manuscript, we report structural studies of wild-type and mutant KDGPC's that provide a structural explanation for both the natural promiscuity for the HPS reaction and the enhanced HPS activity and diminished KGPDC activity catalyzed by active site mutants.

Structure of D-ribulose 5-phosphate 3-epimerase from Synechocystis to 1.6 A resolution.

The crystal structure of D-ribulose 5-phosphate 3-epimerase (RPE) from the cyanobacterium Synechocystis was determined by X-ray crystallography to 1.6 A resolution. The enzyme, which catalyzes the epimerization of D-ribulose 5-phosphate and D-xylulose 5-phosphate, assembles as a hexamer of (beta/alpha)(8)-barrels in the crystallographic asymmetric unit. The active site is highly similar to those of two previously reported RPEs and provides further evidence for essential catalytic roles for several active-site residues.

Evolution of enzymatic activities in the orotidine 5'-monophosphate decarboxylase suprafamily: mechanistic evidence for a proton relay system in the active site of 3-keto-L-gulonate 6-phosphate decarboxylase.

3-Keto-L-gulonate 6-phosphate decarboxylase (KGPDC) and orotidine 5'-monophosphate decarboxylase (OMPDC) are homologous enzymes that share the (beta/alpha)(8)-fold but catalyze mechanistically distinct reactions [Wise, E., Yew, W. S., Babbitt, P. C., Gerlt, J. A., and Rayment, I. (2002) Biochemistry 41, 3861-3869]. KGPDC catalyzes the Mg(2+)-dependent decarboxylation of 3-keto-L-gulonate 6-phosphate, an intermediate in the catabolic pathway of L-ascorbate utilization by Escherichia coli K-12 [Yew, W. S., and Gerlt, J. A. (2002) J. Bacteriol. 184, 302-306]. OMPDC catalyzes a metal ion-independent reaction that likely proceeds without a vinyl anion intermediate [Appleby, T. C., Kinsland, C., Begley, T., and Ealick, S. E. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 2005-2010], although the mechanistic details are uncertain. An active site Lys located at the end of the third beta-strand in OMPDC has been proposed to be the general acid that delivers a solvent-derived proton to the UMP product; the active site of KGPDC contains a homologous Lys residue (Lys64). Herein, we report investigations of the KGPDC-catalyzed reaction that are consistent with a mechanism involving a Mg(2+)-stabilized cis-enediolate intermediate [Wise, E. L., Yew, W. S., Gerlt, J. A., and Rayment, I. (2003) Biochemistry 42, 12133-12142] and implicate waters proximal to His136 and Arg139, both located at the end of the sixth beta-strand, as the general acids that deliver a solvent-derived proton to the intermediate to form the L-xylulose 5-phosphate product. On the basis of our mechanistic investigations, Lys64 stabilizes the cis-enediolate intermediate by forming hydrogen bonds to both O1 and O2 of the intermediate. Thus, although the active sites of OMPDC and KGPDC contain a conserved Lys at the end of the third beta-strand, their roles in catalysis are not conserved. Furthermore, a conserved Asp at the end of the third beta-strand in OMPDC participates in a hydrogen-bonded network that positions the acidic Lys residue; in the active site of KGPDC, the homologous Asp67 participates in stabilization of the enediolate intermediate and enforces a cis geometry. We conclude that the conserved active site residues perform different functions in the OMPDC- and KGPDC-catalyzed reactions, so the mechanisms of their reactions are completely distinct. This study further highlights the opportunistic nature of divergent evolution in conscripting the active site of a progenitor to catalyze a mechanistically distinct reaction.

Evolution of enzymatic activities in the orotidine 5'-monophosphate decarboxylase suprafamily: crystallographic evidence for a proton relay system in the active site of 3-keto-L-gulonate 6-phosphate decarboxylase.

3-Keto-L-gulonate 6-phosphate decarboxylase (KGPDC), a member of the orotidine monophosphate decarboxylase (OMPDC) suprafamily, catalyzes the Mg(2+)-dependent decarboxylation of 3-keto-L-gulonate 6-phosphate to L-xylulose 5-phosphate. Structural and biochemical evidence suggests that the KGPDC reaction proceeds via a Mg(2+)-stabilized 1,2-cis-enediolate intermediate. Protonation of the enediolate intermediate occurs in a nonstereospecific manner to form L-xylulose 5-phosphate. Although the exact mechanism of proton delivery is not known, Glu112, His136, and Arg139 have been implicated in this process [Yew, W. S., Wise, E., Rayment, I., and Gerlt, J. A. (2004) Biochemistry 43, 6427-6437]. Surprisingly, single amino acid substitutions of these positions do not substantially reduce catalytic activity but rather alter the stereochemical course of the reaction. Here, we report the X-ray crystal structures of four mutants, K64A, H136A, E112Q, and E112Q/H136A, each determined in the presence of L-threonohydroxamate 4-phosphate, an analogue of the enediolate intermediate, to 1.7, 1.9, 1.8, and 1.9 A resolution, respectively. These structures reveal that substitutions of Lys64, Glu112, and His136 cause changes in the positions of the intermediate analogue and two active site water molecules that were previously identified as possible proton donors. These changes correlate with the observed alterations in the reaction stereochemistry for these mutants, thereby supporting a reaction mechanism in which water molecules competitively shuttle protons from the side chains of His136 and Arg139 to alternate faces of the cis-enediolate intermediate. These studies further underscore the wide variation in the reaction mechanisms in the OMPDC suprafamily.

Understanding the importance of protein structure to nature's routes for divergent evolution in TIM barrel enzymes.

It is widely agreed that new enzymes evolve from existing ones through the duplication of genes encoding existing enzymes followed by sequence divergence. While evolution is an inherently random process, studies of divergently related enzymes have shown that the evolution of new enzymes follows one of three general routes in which the substrate specificity, reaction mechanism, or active site architecture of the progenitor enzyme is reused in the new enzyme. Recent developments in structural biology relating to divergently related (beta/alpha)8 enzymes have brought new insight into these processes and have revealed that conserved structural elements play an important role in divergent evolution. These studies have shown that, although evolution occurs as a series of random mutations, stable folds such as the (beta/alpha)8 barrel and structural features of the active sites of enzymes are frequently reused in evolution and adapted for new catalytic purposes.

Structural evidence for a 1,2-enediolate intermediate in the reaction catalyzed by 3-keto-L-gulonate 6-phosphate decarboxylase, a member of the orotidine 5'-monophosphate decarboxylase suprafamily.

3-Keto-L-gulonate 6-phosphate decarboxylase (KGPDC) and orotidine 5'-phosphate decarboxylase (OMPDC) are members of an enzyme suprafamily, the OMPDC suprafamily, because they are homologous enzymes that catalyze mechanistically distinct reactions using different substrates. KGPDC catalyzes the Mg(2+) ion-dependent decarboxylation of 3-keto-L-gulonate 6-phosphate to yield L-xylulose 5-phosphate and CO(2); OMPDC catalyzes the metal ion-independent decarboxylation of OMP to UMP and CO(2). Structural studies have shown that KGPDC and OMPDC share several strictly conserved active site residues that are used differently by each enzyme to catalyze their mechanistically distinct reactions. Although the mechanism of the KGPDC-catalyzed reaction has yet to be elucidated, it is thought to proceed via a Mg(2+) ion-stabilized 1,2-enediolate intermediate. Here we report the crystal structures of KGPDC complexed with L-gulonate 6-phosphate, L-threonohydroxamate 4-phosphate, and L-xylitol 5-phosphate, analogues of the substrate, enediolate intermediate, and product, as well as with the product, L-xylulose 5-phosphate, at 1.2, 1.8, 1.7, and 1.8 A resolution, respectively. These structures support a mechanism that involves the formation of a cis-1,2-enediolate intermediate. Contrary to expectations, the geometry of the intermediate does not involve bidentate coordination of both enediolate oxygen atoms to the Mg(2+) ion but rather involves only the coordination of the oxygen on C2 to the Mg(2+) ion. The oxygen atom on C1 instead forms hydrogen bonds to both Lys64 and Asp67, two strictly conserved active site residues. Lys64 also interacts with the oxygen on C2 and may serve to stabilize a cis conformation of the 1,2-enediolate. These structures also implicate His136 to be the general acid that protonates the 1,2-enediolate intermediate. This study further demonstrates that multiple unrelated enzyme functions can evolve from a single active site architecture without regard for substrate binding affinity or mechanism.

The structural determination of phosphosulfolactate synthase from Methanococcus jannaschii at 1.7-A resolution: an enolase that is not an enolase.

Members of the enolase mechanistically diverse superfamily catalyze a wide variety of chemical reactions that are related by a common mechanistic feature, the abstraction of a proton adjacent to a carboxylate group. Recent investigations into the function and mechanism of the phosphosulfolactate synthase encoded by the ComA gene in Methanococcus jannaschii have suggested that ComA, which catalyzes the stereospecific Michael addition of sulfite to phosphoenolpyruvate to form phosphosulfolactate, may be a member of the enolase superfamily. The ComA-catalyzed reaction, the first step in the coenzyme M biosynthetic pathway, likely proceeds via a Mg2+ ion-stabilized enolate intermediate in a manner similar to that observed for members of the enolase superfamily. ComA, however, has no significant sequence similarity to any known enolase. Here we report the x-ray crystal structure of ComA to 1.7-A resolution. The overall fold for ComA is an (alpha/beta)8 barrel that assembles with two other ComA molecules to form a trimer in which three active sites are created at the subunit interfaces. From the positions of two ordered sulfate ions in the active site, a model for the binding of phosphoenolpyruvate and sulfite is proposed. Despite its mechanistic similarity to the enolase superfamily, the overall structure and active site architecture of ComA are unlike any member of the enolase superfamily, which suggests that ComA is not a member of the enolase superfamily but instead acquired an enolase-type mechanism through convergent evolution.