Structural basis of cooperativity in human UDP-glucose dehydrogenase

Background

UDP-glucose dehydrogenase (UGDH) is the sole enzyme that catalyzes the conversion of UDP-glucose to UDP-glucuronic acid. The product is used in xenobiotic glucuronidation in hepatocytes and in the production of proteoglycans that are involved in promoting normal cellular growth and migration. Overproduction of proteoglycans has been implicated in the progression of certain epithelial cancers, while inhibition of UGDH diminished tumor angiogenesis in vivo. A better understanding of the conformational changes occurring during the UGDH reaction cycle will pave the way for inhibitor design and potential cancer therapeutics.

Methodology

Previously, the substrate-bound of UGDH was determined to be a symmetrical hexamer and this regular symmetry is disrupted on binding the inhibitor, UDP-α-D-xylose. Here, we have solved an alternate crystal structure of human UGDH (hUGDH) in complex with UDP-glucose at 2.8 Å resolution. Surprisingly, the quaternary structure of this substrate-bound protein complex consists of the open homohexamer that was previously observed for inhibitor-bound hUGDH, indicating that this conformation is relevant for deciphering elements of the normal reaction cycle.

Conclusion

In all subunits of the present open structure, Thr131 has translocated into the active site occupying the volume vacated by the absent active water and partially disordered NAD⁺ molecule. This conformation suggests a mechanism by which the enzyme may exchange NADH for NAD⁺ and repolarize the catalytic water bound to Asp280 while protecting the reaction intermediates. The structure also indicates how the subunits may communicate with each other through two reaction state sensors in this highly cooperative enzyme.     

Computational analysis of the quaternary structural changes induced by point mutations in human UDP-glucose dehydrogenase

UDP-glucose dehydrogenase (UGDH) is an enzyme catalyzing the conversion of UDP-glucose to UDP-glucuronic acid. Site-directed mutagenesis studies have revealed that human UGDH (hUGDH) has distinct oligomeric states that vary with different point mutations. In this study we have investigated how the changes in the oligomer-forming propensity may be involved in the thermal motion of wild-type hUGDH and its mutants, using normal mode analysis (NMA). Our results show that the perturbation caused by the mutation of a residue at a considerably distant location from the oligomeric interfaces is preferentially distributed throughout specific sites, especially the large flexible regions in the hUGDH structure, thereby changing the motional fluctuation pattern at the oligomeric interfaces. A large-magnitude cooperative motion at the oligomeric interfaces is a critical factor in interfering with the hexamer formation of the enzyme. In particular, structural stability at the dimeric interface is necessary to retain the hexameric structure of hUGDH.     

The structure of apo human glutamate dehydrogenase details subunit communication and allostery

The structure of human glutamate dehydrogenase (GDH) has been determined in the absence of active site and regulatory ligands. Compared to the structures of bovine GDH that were complexed with coenzyme and substrate, the NAD binding domain is rotated away from the glutamate-binding domain. The electron density of this domain is more disordered the further it is from the pivot helix. Mass spectrometry results suggest that this is likely due to the apo form being more dynamic than the closed form. The antenna undergoes significant conformational changes as the catalytic cleft opens. The ascending helix in the antenna moves in a clockwise manner and the helix in the descending strand contracts in a manner akin to the relaxation of an extended spring. A number of spontaneous mutations in this antenna region cause the hyperinsulinism/hyperammonemia syndrome by decreasing GDH sensitivity to the inhibitor, GTP. Since these residues do not directly contact the bound GTP, the conformational changes in the antenna are apparently crucial to GTP inhibition. In the open conformation, the GTP binding site is distorted such that it can no longer bind GTP. In contrast, ADP binding benefits by the opening of the catalytic cleft since R463 on the pivot helix is pushed into contact distance with the beta-phosphate of ADP. These results support the previous proposal that purines regulate GDH activity by altering the dynamics of the NAD binding domain. Finally, a possible structural mechanism for negative cooperativity is presented.     

Importance of Gly-13 for the coenzyme binding of human UDP-glucose dehydrogenase

UDP-glucose dehydrogenase (UGDH) is the unique pathway enzyme furnishing in vertebrates UDP-glucuronate for numerous transferases. In this report, we have identified an NAD(+)-binding site within human UGDH by photoaffinity labeling with a specific probe, [(32)P]nicotinamide 2-azidoadenosine dinucleotide (2N(3) NAD(+)), and cassette mutagenesis. For this work, we have chemically synthesized a 1509-base pair gene encoding human UGDH and expressed it in Escherichia coli as a soluble protein. Photolabel-containing peptides were generated by photolysis followed by tryptic digestion and isolated using the phosphopeptide isolation kit. Photolabeling of these peptides was effectively prevented by the presence of NAD(+) during photolysis, demonstrating a selectivity of the photoprobe for the NAD(+)-binding site. Amino acid sequencing and compositional analysis identified the NAD(+)-binding site of UGDH as the region containing the sequence ICCIGAXYVGGPT, corresponding to Ile-7 through Thr-19 of the amino acid sequence of human UGDH. The unidentified residue, X, can be designated as a photolabeled Gly-13 because the sequences including the glycine residue in question have a complete identity with those of other UGDH species known. The importance of Gly-13 residue in the binding of NAD(+) was further examined with a G13E mutant by cassette mutagenesis. The mutagenesis at Gly-13 had no effects on the expression or stability of the mutant. Enzyme activity of the G13E point mutant was not measurable under normal assay conditions, suggesting an important role for the Gly-13 residue. No incorporation of [(32)P]2N(3)NAD(+) was observed for the G13E mutant. These results indicate that Gly-13 plays an important role for efficient binding of NAD(+) to human UGDH.     

Inhibitory effects of Aphanizomenon flos-aquae constituents on human UDP-glucose dehydrogenase activity

Objective: The purpose of this study was to investigate the in vitro inhibitory effects of the edible microalga Aphanizomenon flos-aquae (AFA) on human UDP-α-d-glucose 6-dehydrogenase (UGDH) activity, a cytosolic enzyme involved both in tumor progression and in phytochemical bioavailability.

Methods: Both the hydrophilic and ethanolic AFA extracts as well as the constitutive active principles phycocyanin (PC), phycocyanobilin (PCB) and mycosporine-like amino acids (MAAs) were tested.

Results: Among AFA components, PCB presented the strongest inhibitory effect on UGDH activity, acting as a competitive inhibitor with respect to UDP-glucose and a non-competitive inhibitor with respect to NAD⁺. In preliminary experiments, AFA PCB was also effective in reducing the colony formation capacity of PC-3 prostate cancer cells and FTC-133 thyroid cancer cells.

Conclusions: Overall, these findings confirmed that AFA and its active principles are natural compounds with high biological activity. Further studies evaluating the effects of AFA PCB in reducing tumor cell growth and phytochemical glucuronidation are encouraged.     

Alteration of the quaternary structure of human UDP-glucose dehydrogenase by a double mutation

There are conflicting views for the polymerization process of human UDP-glucose dehydrogenase (UGDH) and no clear evidence has been reported yet. Based on crystal coordinates for Streptococcus pyogenes UGDH, we made double mutant A222Q/S233G. The double mutagenesis had no effects on expression, stability, and secondary structure. Interestingly, A222Q/S233G was a dimeric form and showed an UGDH activity, although it showed increased Km values for substrates. These results suggest that Ala222 and Ser233 play an important role in maintaining the hexameric structure and the reduced binding affinities for substrates are attributable to its altered subunit communication although quaternary structure may not be critical for catalysis.     

Expression, purification, crystallization, and preliminary X-Ray analysis of the human UDP-glucose dehydrogenase

UDP-glucose dehydrogenase (UGDH) catalyzes the synthesis of UDP-glucuronic acid from UDP-glucose resulting in the formation of proteoglycans that are involved in promoting normal cellular growth and migration. Overproduction of proteoglycans has been implicated in the progression of certain epithelial cancers. Here, human UGDH (hUGDH) was purified and crystallized from a solution of 0.2 M ammonium sulfate, 0.1 M Na cacodylate, pH 6.5, and 21% PEG 8000. Diffraction data were collected to a resolution of 2.8 A. The crystal belongs to the orthorhombic space group P2(1)2(1)2(1) with unit-cell parameters a = 173.25, b = 191.16, c = 225.94 A, and alpha = beta = gamma = 90.0 degrees. Based on preliminary analysis of the diffraction data, we propose that the biological unit of hUGDH is a tetramer.     

Investigation of the UDP-glucose dehydrogenase reaction for a coupled assay of UDP-glucose pyrophosphorylase activities.

An optimized coupled enzyme assay for UDP-glucose pyrophosphorylase (EC 2.7.7.9) using UDP-glucose dehydrogenase (EC 1.1.1.22) is presented. This optimized assay was developed by a detailed investigation of the kinetics of the UDP-glucose dehydrogenase reaction. In addition the data provide a basis for the enzymatic synthesis of UDP-glucuronic acid. The results demonstrate that the two binding sites of the dehydrogenase differ since a different modulation of the enzyme activity and stability is observed after preincubation with UDP-glucose or NAD+ at various pH values. This is of general interest for the preparation of assay mixtures where UDP-glucose dehydrogenase is used as an auxiliary enzyme.     

Molecular packing and packing defects in helical membrane proteins

The packing of helices spanning lipid bilayers is crucial for the stability and function of alpha-helical membrane proteins. Using a modified Voronoi procedure, we calculated packing densities for helix-helix contacts in membrane spanning domains. Our results show that the transmembrane helices of protein channels and transporters are significantly more loosely packed compared with helices in globular proteins. The observed packing deficiencies of these membrane proteins are also reflected by a higher amount of cavities at functionally important sites. The cavities positioned along the gated pores of membrane channels and transporters are noticeably lined by polar amino acids that should be exposed to the aqueous medium when the protein is in the open state. In contrast, nonpolar amino acids surround the cavities in those protein regions where large rearrangements are supposed to take place, as near the hinge regions of transporters or at restriction sites of protein channels. We presume that the observed deficiencies of helix-helix packing are essential for the helical mobility that sustains the function of many membrane protein channels and transporters.     

Purification and kinetic properties of UDP-glucose dehydrogenase from sugarcane

In this study, UDP-glucose dehydrogenase has been purified to electrophoretic homogeneity from sugarcane (Saccharum spp. hybrid) culm. The enzyme had a pH optimum of 8.4 and a subunit molecular mass of 52 kDa. Specific activity of the final preparation was 2.17 micromol/min/mg protein. Apparent K(m) values of 18.7+/-0.75 and 72.2+/-2.7 microM were determined for UDP-glucose and NAD(+), respectively. The reaction catalyzed by UDP-glucose dehydrogenase was irreversible with two equivalents of NADH produced for each UDP-glucose oxidized. Stiochiometry was not altered in the presence of carbonyl-trapping reagents. With respect to UDP-glucose, UDP-glucuronic acid, and UDP-xylose were competitive inhibitors of UDP-glucose dehydrogenase with K(i) values of 292 and 17.1 microM, respectively. The kinetic data are consistent with a bi-uni-uni-bi substituted enzyme mechanism for sugarcane UDP-glucose dehydrogenase. Oxidation of the alternative nucleotide sugars CTP-glucose and TDP-glucose was observed with rates of 8 and 2%, respectively, compared to UDP-glucose. The nucleotide sugar ADP-glucose was not oxidized by UDP-glucose dehydrogenase. This is of significance as it demonstrates carbon, destined for starch synthesis in tissues that synthesize cytosolic AGP-glucose, will not be partitioned toward cell wall biosynthesis.     

Identification of a UDP-glucose-binding site of human UDP-glucose dehydrogenase by photoaffinity labeling and cassette mutagenesis

We have identified a UDP-glucose-binding site within human UDP-glucose dehydrogenase (hUGDH) by photoaffinity labeling with a specific probe, [(32)P]5N(3)UDP-glucose, and cassette mutagenesis using a synthetic hUGDH gene. Photolabel-containing peptides were generated by photolysis followed by tryptic digestion and isolated using the phosphopeptide isolation kit. Photolabeling of these peptides was effectively prevented by the presence of UDP-glucose during photolysis, demonstrating a selectivity of the photoprobe for the UDP-glucose-binding site. Amino acid sequencing and compositional analysis identified the UDP-glucose-binding site of hUGDH as the region containing the sequence, ASVGFGGSXFQK, corresponding to A268-K279 of the amino acid sequence of hUGDH. The unidentified residue, X, can be designated as a photolabeled C276 because the sequences including the cysteine residue in question have a complete identity with those of other UGDH species known. The importance of the C276 residue in the binding of UDP-glucose was further examined with mutant proteins at the C276 site. The mutagenesis at C276 has no effect on the expression of the mutants (C276G, C276K, C276E, C276L, and C276Y). Enzyme activities of the C276 mutants were not measurable under normal assay conditions, suggesting an important role for the C276 residue. No incorporation of [(32)P]5N(3)UDP-glucose was also observed for the mutants. These results indicate that C276 plays an important role for efficient binding of UDP-glucose to hUGDH.     

The effect of extracellular matrix modifications on UDP-glucose dehydrogenase activity in cultured human skin fibroblasts

The effect of modifications of the extracellular matrix on the biosynthesis of glycosaminoglycans was investigated in human skin fibroblast cultures by studying UDPGDH activity in order to evaluate: a), the histoenzymological and biochemical modifications induced by chondroitinase ABC treatment (new experimental conditions were developed in order to obtain minimum cell damage); b), the reversibility of these modifications; c), the effect of growing the cells in the presence of chondroitinsulfate; d), the specificity of the modifications induced. The results demonstrated that our experimental conditions specifically affected intracellular UDPGDH activity. Chondroitinase ABC treatment induced a reversible increase of UDP-glucuronic acid synthesis. On the contrary, the presence of chondroitinsulfate in the growth medium completely inhibited UDPGDH activity.     

Active site residues and mechanism of UDP-glucose dehydrogenase.

UDP-glucose dehydrogenase catalyzes the NAD+-dependent twofold oxidation of UDP-glucose to give UDP-glucuronic acid. A sequestered aldehyde intermediate is produced in the first oxidation step and a covalently bound thioester is produced in the second oxidation step. This work demonstrates that the Streptococcus pyogenes enzyme incorporates a single solvent-derived oxygen atom during catalysis and probably does not generate an imine intermediate. The reaction of UDP-[6",6"-di-2H]-d-glucose is not accompanied by a primary kinetic isotope effect, indicating that hydride transfer is not rate determining in this reaction. Studies with a mutant of the key active site nucleophile, Cys260Ala, show that it is capable of both reducing the aldehyde intermediate, and oxidizing the hydrated form of the aldehyde intermediate but is incapable of oxidizing UDP-glucose to UDP-glucuronic acid. In the latter case, a ternary Cys260Ala/aldehyde intermediate/NADH complex is presumably formed, but it does not proceed to product as both release and hydration of the bound aldehyde occur slowly. A washout experiment demonstrates that the NADH in this ternary complex is not exchangeable with external NADH, indicating that dissociation only occurs after the addition of a nucleophile to the aldehyde carbonyl. Studies on Thr118Ala show that the value of kcat is reduced 160-fold by this mutation, and that the reaction of UDP-D-[6",6"-di-2H]-glucose is now accompanied by a primary kinetic isotope effect. This indicates that the barriers for the hydride transfer steps have been selectively increased and supports a mechanism in which an ordered water molecule (H-bonded to Thr118) serves as the catalytic base in these steps.     

Characterization of UDP-glucose dehydrogenase isoforms in the medicinal legume Glycyrrhiza uralensis

Uridine 5′-diphosphate (UDP)-glucose dehydrogenase (UGD) produces UDP-glucuronic acid from UDP-glucose as a precursor of plant cell wall polysaccharides. UDP-glucuronic acid is also a sugar donor for the glycosylation of various plant specialized metabolites. Nevertheless, the roles of UGDs in plant specialized metabolism remain poorly understood. Glycyrrhiza species (licorice), which are medicinal legumes, biosynthesize triterpenoid saponins, soyasaponins and glycyrrhizin, commonly glucuronosylated at the C-3 position of the triterpenoid scaffold. Often, several different UGD isoforms are present in plants. To gain insight into potential functional differences among UGD isoforms in triterpenoid saponin biosynthesis in relation to cell wall component biosynthesis, we identified and characterized Glycyrrhiza uralensis UGDs (GuUGDs), which were discovered to comprise five isoforms, four of which (GuUGD1–4) showed UGD activity in vitro. GuUGD1–4 had different biochemical properties, including their affinity for UDP-glucose, catalytic constant, and sensitivity to feedback inhibitors. GuUGD2 had the highest catalytic constant and highest gene expression level among the GuUGDs, suggesting that it is the major isoform contributing to the transition from UDP-glucose to UDP-glucuronic acid in planta. To evaluate the contribution of GuUGD isoforms to saponin biosynthesis, we compared the expression patterns of GuUGDs with those of saponin biosynthetic genes in methyl jasmonate (MeJA)-treated cultured stolons. GuUGD1–4 showed delayed responses to MeJA compared to those of saponin biosynthetic genes, suggesting that MeJA-responsive expression of GuUGDs compensates for the decreased UDP-glucuronic acid pool due to consumption during saponin biosynthesis.     

Characterization of human UDP-glucose dehydrogenase reveals critical catalytic roles for lysine 220 and aspartate 280

Human UDP-glucose dehydrogenase (UGDH) is a homohexameric enzyme that catalyzes two successive oxidations of UDP-glucose to yield UDP-glucuronic acid, an essential precursor for matrix polysaccharide and proteoglycan synthesis. We previously used crystal coordinates for Streptococcus pyogenes UGDH to generate a model of the human enzyme active site. In the studies reported here, we have used this model to identify three putative active site residues: lysine 220, aspartate 280, and lysine 339. Each residue was site-specifically mutagenized to evaluate its importance for catalytic activity and maintenance of hexameric quaternary structure. Alteration of lysine 220 to alanine, histidine, or arginine significantly impaired enzyme function. Assaying activity over longer time courses revealed a plateau after reduction of a single equivalent of NAD+ in the alanine and histidine mutants, whereas turnover continued in the arginine mutant. Thus, one role of this lysine may be to stabilize anionic transition states during substrate conversion. Mutation of aspartate 280 to asparagine was also severely detrimental to catalysis. The relative position of this residue within the active site and dependence of function on acidic character point toward a critical role for aspartate 280 in activation of the substrate and the catalytic cysteine. Finally, changing lysine 339 to alanine yielded the wild-type Vmax, but a 165-fold decrease in affinity for UDP-glucose. Interestingly, gel filtration of this substrate-binding mutant also determined it was a dimer, indicating that hexameric quaternary structure is not critical for catalysis. Collectively, this analysis has provided novel insights into the complex catalytic mechanism of UGDH.     

Visualizing induced fit in early assembly of the human signal recognition particle

Assembly of almost all ribonucleoprotein complexes involves induced fit in the RNA and, thus, formation of one or more intermediate states. In assembly of the human signal recognition particle (SRP), we show that SRP19 binding to SRP RNA involves obligatory intermediates. An apparent discrepancy exists between the ratio of dissociation and association rate constants, determined in a partitioning experiment, and the equilibrium binding constant; this kinetic signature reflects formation of a stable intermediate in assembly of the ribonucleoprotein complex. Assembly intermediates were observed directly by time-resolved footprinting. SRP19 binds rapidly to SRP RNA to form an initial labile, but structurally specific, encounter complex involving both helices III and IV. Two subsequent steps of structural consolidation yield the native RNA-protein interface. SRP19 binding stabilizes helix IV in the region recognized by SRP54, consistent with protein-protein cooperativity mediated in part by mutual recognition of similar RNA structures. This mechanism illustrates principles general to ribonucleoprotein assembly reactions that rely on recruitment of architectural RNA binding proteins.     

Characterization of human UDP-glucose dehydrogenase. CYS-276 is required for the second of two successive oxidations

UDP-glucose dehydrogenase (UGDH) catalyzes two oxidations of UDP-glucose to yield UDP-glucuronic acid. Pathological overproduction of extracellular matrix components may be linked to the availability of UDP-glucuronic acid; therefore UGDH is an intriguing therapeutic target. Specific inhibition of human UGDH requires detailed knowledge of its catalytic mechanism, which has not been characterized. In this report, we have cloned, expressed, and affinity-purified the human enzyme and determined its steady state kinetic parameters. The human enzyme is active as a hexamer with values for Km and Vmax that agree well with those reported for a bovine homolog. We used crystal coordinates for Streptococcus pyogenes UGDH in complex with NAD+ cofactor and UDP-glucose substrate to generate a model of the enzyme active site. Based on this model, we selected Cys-276 and Lys-279 as likely catalytic residues and converted them to serine and alanine, respectively. Enzymatic activity of C276S and K279A point mutants was not measurable under normal assay conditions. Rate constants measured over several hours demonstrated that K279A continued to turn over, although 250-fold more slowly than wild type enzyme. C276S, however, performed only a single round of oxidation, indicating that it is essential for the second oxidation. This result is consistent with the postulated role of Cys-276 as a catalytic residue and supports its position in the reaction mechanism for the human enzyme. Lys-279 is likely to have a role in positioning active site residues and in maintaining the hexameric quaternary structure.     

Cloning and expression studies of the Dunaliella salina UDP-glucose dehydrogenase cDNA.

The enzyme UDP-glucose dehydrogenase (EC 1.1.1.22) converts UDP-glucose to UDP-glucuronate. Plant UDP-glucose dehydrogenase (UGDH) is an important enzyme in the formation of hemicellulose and pectin, the components of primary cell walls. A cDNA, named DsUGDH, (GeneBank accession number: AY795899) corresponding to UGDH was cloned by RT-PCR approach from Dunaliella salina. The cDNA is 1941-bp long and has an open reading frame encoded a protein of 483 amino acids with a calculated molecular weight of 53 kDa. The derived amino acids sequence shows high homology with reported plants UGDHs, and has highly conserved amino acids motifs believed to be NAD binding site and catalytic site. Although UDP-glucose dehydrogenase is a comparatively well characterized enzyme, the cloning and characterization of the green alga Dunaliella salina UDP-glucose dehydrogenase gene is very important to understand the salt tolerance mechanism of Dunaliella salina. Northern analyses indicate that NaCl can induce the expression the DsUGDH.