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Orotidine 5'-phosphate decarboxylase

Orotidine 5'-phosphate decarboxylase (ODCase or OMPDC; EC 4.1.1.23) is an enzyme that catalyzes the decarboxylation of orotidine 5'-monophosphate (OMP) to uridine 5'-monophosphate (UMP) and carbon dioxide, representing the sixth and final step in the de novo biosynthesis of pyrimidine nucleotides essential for RNA and DNA production. In prokaryotes and lower eukaryotes, it functions as a monofunctional enzyme encoded by genes such as pyrF in bacteria, whereas in higher eukaryotes including humans, it constitutes the C-terminal domain of the bifunctional uridine 5'-monophosphate synthase (UMPS), which also encompasses orotate phosphoribosyltransferase (EC 2.4.2.10) activity to convert orotic acid to OMP in the preceding step. This enzyme operates without cofactors and is conserved across species, underscoring its critical role in nucleotide metabolism. Structurally, ODCase adopts a triose phosphate isomerase (TIM) barrel fold consisting of eight α/β units, with the located at the C-terminal end of the β-barrel; the typically exists as a homodimer, where interactions across the subunit interface contribute to binding and . Upon binding, it undergoes a conformational change from an open to a closed state, involving loops that grip the substrate's ring and ribosyl , thereby excluding water and stabilizing the . Key residues, such as and aspartate side chains, form bonds and electrostatic interactions to delocalize charge in the , while inter-subunit residues like further enhance specificity and efficiency. The mechanism proceeds via a stepwise pathway involving a or zwitterionic intermediate at the C6 position of OMP, with the providing ~31 kcal/mol of stabilization relative to the free and through precise noncovalent interactions, rather than covalent or general acid-base assistance. This results in one of the largest known catalytic proficiencies of (k_cat / K_m) / k_non ≈ 10^{23} M^{-1} and a rate acceleration (k_cat / k_non) of ≈ 10^{17}-fold relative to the uncatalyzed reaction, making ODCase a prototypical "perfect " where the catalytic efficiency (k_{cat}/K_m) approaches the diffusion-controlled limit of ~10^8–10^9 M^{-1} s^{-1}. Such proficiency highlights evolutionary optimization for production, with implications for understanding metabolic disorders like hereditary caused by UMPS deficiencies in humans.

Biological Role

Function in Pyrimidine Biosynthesis

Orotidine 5'-phosphate decarboxylase (OMPDC), also known as orotidine monophosphate decarboxylase, catalyzes the of orotidine 5'-monophosphate (OMP) to 5'-monophosphate (UMP), serving as the sixth and final step in the pathway. This irreversible reaction eliminates the carboxyl group at the C6 position of the ring, yielding UMP as the direct product without requiring cofactors or metals, and it represents a pivotal commitment to production in cells. The pathway begins with the formation of and proceeds through the assembly of the ring, culminating in this that ensures efficient generation of the foundational . UMP produced by OMPDC functions as the essential precursor for all nucleotides in cellular , supporting nucleic acid synthesis and beyond. It is sequentially phosphorylated to uridine triphosphate (UTP), a key substrate for polymerization, and further aminated to (CTP), another component. For , UMP is reduced to deoxyuridine monophosphate (dUMP), which undergoes methylation to form deoxythymidine monophosphate (dTMP), the precursor to (dTTP). Additionally, UTP derivatives such as (UDP-glucose) play critical roles in , including synthesis and pathways. Disruptions in this step, as seen in hereditary , underscore UMP's indispensable role by leading to pyrimidine deficiency and accumulation of upstream intermediates. OMPDC exhibits remarkable evolutionary conservation across prokaryotes and eukaryotes, highlighting its ancient and indispensable function in . In prokaryotes, such as , OMPDC operates as a monofunctional, standalone encoded by genes like pyrF. In contrast, most eukaryotes, including humans, feature OMPDC fused to orotate phosphoribosyltransferase (OPRT)—the catalyzing the prior step (orotate to OMP)—forming a bifunctional UMP that coordinates the final two reactions of the pathway. This , which arose through independent gene events in eukaryotic lineages, enhances substrate channeling and regulatory efficiency, preventing intermediate leakage and optimizing flux through the pathway. The 's catalytic proficiency, providing one of the largest known rate enhancements (approximately 10^{23}-fold), further emphasizes its optimized role in sustaining demands across diverse organisms.

Relation to UMP Synthase

In eukaryotes, orotidine 5'-phosphate decarboxylase (ODCase) constitutes the C-terminal domain of the bifunctional enzyme uridine 5'-monophosphate synthase (UMPS), whose N-terminal domain encompasses orotate phosphoribosyltransferase (OPRT) activity, with both domains encoded by a single . This architectural fusion facilitates the coordinated catalysis of the final two steps in pyrimidine biosynthesis, converting orotate to uridine 5'-monophosphate (UMP) via the intermediate orotidine 5'-monophosphate (OMP). The integration of ODCase into UMPS enables substrate channeling of OMP directly from the OPRT active site to the ODCase site, minimizing its release into the cellular milieu where it could diffuse, accumulate, or undergo by phosphatases, potentially leading to wasteful degradation or cellular stress from unstable intermediates. This channeling mechanism enhances metabolic efficiency by maintaining low steady-state OMP concentrations, thereby optimizing flux through the pathway without requiring high local buildup. In humans, the UMPS gene resides on at locus 3q21.2, exemplifying this bifunctional organization common in higher eukaryotes, in contrast to prokaryotes where OPRT and ODCase exist as distinct, monofunctional enzymes. Similarly, in yeast such as , while the activities are encoded separately (URA5 for OPRT and for ODCase), the eukaryotic fusion in organisms like humans underscores evolutionary adaptations for pathway efficiency. The bifunctional structure also confers regulatory advantages, as the proximity of domains allows allosteric interactions that fine-tune activity based on cellular demands.

Molecular Structure

Overall Architecture

Orotidine 5'-phosphate decarboxylase (ODCase) exhibits a canonical (β/α)8 TIM-barrel fold, characterized by eight parallel β-strands arranged in a central barrel and surrounded by eight α-helices that connect consecutive strands. This architecture positions the substrate-binding site at the more open, C-terminal end of the barrel, facilitating access for the substrate orotidine 5'-monophosphate (OMP). The TIM barrel provides a stable scaffold for catalysis, with the β-strands contributing to the core while the α-helices shield the interior and contribute to subunit interactions. In prokaryotic organisms, such as Methanobacterium thermoautotrophicum, ODCase functions as a homodimer in structures, with each comprising approximately 220-250 and the s located at the dimer interface. The predominant oligomeric state observed crystallographically is dimeric, essential for stabilizing the catalytic environment. High-resolution structures, including one at 1.4 Å resolution for the M. thermoautotrophicum enzyme complexed with an , reveal detailed loop conformations and phosphate-binding loops that close over the upon binding. In eukaryotic , ODCase exists as the C-terminal domain of the bifunctional uridine 5'-monophosphate synthase (UMPS), which assembles into dimers. Crystal structures of yeast (Saccharomyces cerevisiae) ODCase, resolved at 2.1 , confirm the conserved TIM-barrel topology and highlight subtle variations in loop flexibility compared to prokaryotic counterparts. The TIM-barrel fold is highly conserved across diverse , from to humans, underscoring its evolutionary role in providing a versatile framework for decarboxylase activity and transition-state stabilization without requiring metal cofactors. This conservation is evident in sequence alignments and structural superimpositions, where core β-strands and α-helices align with root-mean-square deviations below 1.5 .

Active Site Features

The active site of orotidine 5'-phosphate decarboxylase (OMPDC) is located at the C-terminal end of the enzyme's TIM-barrel domain, forming a compact pocket that precisely positions the substrate orotidine 5'-monophosphate (OMP) for decarboxylation. Conserved residues, particularly in the yeast enzyme, play critical roles in substrate recognition and binding through hydrogen bonding networks. Asp37 forms a hydrogen bond with the carboxylate group at C6 of the orotate moiety, contributing to ground-state destabilization that facilitates catalysis. Thr100, contributed from the adjacent subunit in the dimeric enzyme, hydrogen bonds with the 2'-OH of the ribose ring, while Arg235 directly interacts with the 5'-phosphate group, anchoring the substrate's anionic moiety. These interactions ensure specific orientation of the substrate without the need for metal ions or cofactors. A hydrophobic pocket, lined by residues such as Ile96, Leu123, Val155, Pro180, Val182, Ile199, Val201, and Ile218 ( numbering), accommodates the uracil-like ring of OMP, shielding it from solvent and promoting desolvation of the . Upon binding, flexible — notably the Pro180-Asp188 and segments like 151-165—close over the , creating a sequestered environment that enhances binding affinity and excludes water, thereby stabilizing the . This closure is essential for the enzyme's conformational change from an open to a closed state. The exhibits a binding for OMP with Km values ranging from 5-20 μM across species such as (approximately 1.4-20 μM) and , reflecting efficient substrate capture without cofactors. Structural studies using substrate analogs, such as 6-hydroxyuridine 5'-phosphate (also known as or ), demonstrate how the stabilizes the intermediate at C6 through electrostatic interactions with residues like Lys93, without reliance on metal ions. These analogs bind with exceptionally high (Ki ≈ 9 × 10^{-12} M), mimicking the and highlighting the site's role in intermediate stabilization.

Catalytic Mechanism

Reaction Catalyzed

Orotidine 5'-phosphate decarboxylase (OMPDC), classified under EC 4.1.1.23 as a carboxy-lyase, catalyzes the decarboxylation of orotidine 5'-monophosphate (OMP) to uridine 5'-monophosphate (UMP) and carbon dioxide (CO₂). This reaction represents the final step in the de novo biosynthesis of pyrimidine nucleotides, converting the unstable OMP intermediate into the essential precursor UMP without requiring cofactors or external proton donors. The transformation is a unimolecular , where the C6-carboxyl group of OMP is eliminated as CO₂, leaving UMP as the product. OMPDC is renowned for its exceptional catalytic proficiency, achieving a second-order rate constant (k_cat/K_m) of approximately 10^8 M⁻¹ s⁻¹, which positions it among the most efficient enzymes known, with a rate acceleration of about 10^{23}-fold relative to the uncatalyzed reaction. The exhibits optimal activity at a range of 7.5-8.0, with stability influenced by species-specific adaptations; for instance, thermophilic variants maintain functionality up to 70°C or higher, reflecting structural robustness suited to extreme environments. Kinetic studies using labeling reveal a primary on the C4-carboxyl carbon (¹³C KIE ≈ 1.04), confirming that the step is rate-limiting in the .

Step-by-Step Process

The of orotidine 5'-phosphate decarboxylase (OMPDC) proceeds through a stepwise mechanism involving a intermediate at the position of the , orotidine 5'-monophosphate (OMP), without the formation of any covalent enzyme- . In the initial step, OMP binds to the enzyme's , where the is positioned for ; the conserved Asp70 residue contributes to ground-state destabilization through electrostatic interactions with the , facilitating the reaction. Following binding, the second step involves of the C6-carboxyl group, releasing CO₂ and generating an at C6; this intermediate is stabilized electrostatically by residues such as the positively charged Arg235 and the oxyanion hole formed by Thr100 and Lys93, which hydrogen-bond to the developing negative charge, thereby lowering the energy barrier for C-C bond cleavage. Quantum mechanical calculations indicate that the provides significant stabilization, equivalent to reducing the for by over 12 units relative to , primarily through desolvation and hydrogen bonding networks that enhance stability. The nature of the C6 intermediate ( or ) and the precise proton source remain subjects of debate, with recent studies (as of 2025) emphasizing dynamic protein networks in barrier reduction. In the final step, the C6 is , yielding 5'-monophosphate (UMP) as the product; this is proposed to occur through of a molecule or direct transfer from residues like . Evidence from studies supports the anionic form; for instance, the D70N variant exhibits a significant reduction in k_cat (approximately 10^3-fold), underscoring Asp70's in without affecting binding affinity.

Genetics and Regulation

Gene Organization and Expression

In humans, the UMPS gene, located on chromosome 3q21.2, encodes a bifunctional synthase protein consisting of 480 , where the orotidine 5'-phosphate decarboxylase (ODCase) domain spans residues 224 to 480. This gene produces multiple isoforms through , including at least four variants that may influence tissue-specific expression or function. In prokaryotes, such as , ODCase is encoded by the standalone pyrF gene, which directs the synthesis of a homodimeric protein comprising 245 . The pyrF gene is constitutively expressed at basal levels to support routine biosynthesis but undergoes transcriptional upregulation in response to pyrimidine limitation, ensuring adaptive increases in production when precursors are scarce. Eukaryotic organisms exhibit more complex regulatory mechanisms for ODCase expression. In the yeast , the enzyme is encoded by the URA3 gene, whose transcription is induced 3- to 5-fold during UMP starvation; this activation is mediated by the zinc-finger transcription factor Ppr1p, which binds to upstream activating sequences in the promoter to coordinate pyrimidine biosynthesis. In mammals, UMPS expression aligns with cellular proliferation demands and is modulated during the , with the bifunctional UMPS protein integrating into broader synthesis networks. Post-translational modifications of ODCase are infrequent across species, though limited evidence suggests site-specific may modulate protein stability in certain cellular contexts.

Role in Model Organisms

In Saccharomyces cerevisiae, the URA3 gene encodes orotidine 5'-phosphate decarboxylase, and mutations in URA3 result in uracil auxotrophy due to impaired biosynthesis. These ura3 mutants have been widely utilized as selectable markers in yeast , enabling efficient transformation, gene disruption, and maintenance by complementation with the wild-type URA3 gene on vectors. The auxotrophic allows positive selection for transformants on uracil-deficient media and negative selection using 5-fluoroorotic acid, which is toxic to URA3-expressing cells, facilitating counter-selection in iterative genetic manipulations. Historical studies in from the 1950s isolated auxotrophic mutants, including those defective in pathways, laying the groundwork for functional gene analysis. By the and , ura3 mutants proved instrumental in pioneering yeast cloning strategies; the cloning of itself in enabled the development of shuttle vectors for , revolutionizing eukaryotic gene and expression. This marker system supported early work, including the integration of exogenous DNA into yeast chromosomes and the construction of genomic libraries. In bacterial model organisms like , knockouts of the pyrF gene, which encodes orotidine 5'-phosphate decarboxylase, create auxotrophs useful for of production. These mutants accumulate upstream intermediates like orotidine 5'-phosphate, allowing flux redirection toward high-yield synthesis of or related compounds through pathway optimization and . In mammalian models such as mice, heterozygous UMPS mutations model partial enzyme deficiencies, exhibiting mild elevations in without overt pathology, providing insights into dosage effects on homeostasis. Conditional Umps strains further enable tissue-specific studies of enzyme function. Comparative genomics reveals that bifunctional UMPS enzymes in eukaryotes arose from ancient and events of separate orotate phosphoribosyltransferase and decarboxylase domains, as seen in prokaryotes, enhancing catalytic efficiency through substrate channeling. This evolutionary innovation is conserved across fungi and metazoans, with sequence divergence adapting the fused protein to compartmentalized cellular environments.

Clinical and Research Applications

Inhibitors and Therapeutic Targeting

Orotidine 5'-phosphate decarboxylase (ODCase) is targeted by several competitive inhibitors that mimic its substrate, orotidine 5'-monophosphate (OMP), and bind within the to prevent . One such inhibitor is 6-azauridine 5'-monophosphate (6-AzaUMP), an OMP analog that occupies the and blocks the formation of the substrate intermediate essential for ; it exhibits a Ki of 0.3 μM against ODCase. In human ODCase, halo-substituted UMP analogs like 6-iodo-UMP act as covalent inhibitors by forming a with Lys314 in the , providing insights into the enzyme's catalytic role. These inhibitors generally display micromolar to nanomolar affinities, with binding modes confirmed by showing overlap with the OMP and base recognition sites. Allopurinol ribonucleotide, a of the , serves as a competitive of ODCase with Ki values around 0.7 μM in human enzyme. This inhibition contributes to the therapeutic effects of in treating by disrupting pyrimidine , leading to elevated urinary orotidine levels without directly targeting for this effect. The form binds tightly to the , mimicking and competing with OMP for the enzyme's nucleotide-binding pocket. The therapeutic potential of ODCase inhibitors is particularly promising for applications, given the enzyme's essential role in biosynthesis in parasites like , which has low sequence identity (~20-30%) to the human ortholog, enabling selective targeting. Pyrazofurin 5'-monophosphate, a pyrazolo-based analog, potently inhibits PfODCase, far exceeding its affinity for the human enzyme and demonstrating activity in vitro. Similarly, pyrazolo[3,4-d] derivatives such as allopurinol-3-riboside 5'-monophosphate inhibit PfODCase with a Ki of 240 nM, highlighting their potential as leads for antimalarial drugs due to species-specific binding differences. Structure-based has advanced ODCase development through structures of complexes, including those with PfODCase bound to pyrazofurin 5'-monophosphate and ODCase with 6-halo-UMP analogs, revealing key residues like Lys and that guide rational modifications for improved selectivity and potency. These structures, resolved at resolutions below 2 Å, facilitate the of novel OMP mimics that exploit conformational flexibility in the enzyme's TIM-barrel fold for enhanced therapeutic targeting against pathogenic ODCase variants.

Associated Pathologies

Hereditary orotic aciduria type I is a rare autosomal recessive disorder resulting from mutations in the UMPS gene, which encodes the bifunctional synthase enzyme encompassing both orotate phosphoribosyltransferase and (ODCase) activities. These mutations primarily disrupt ODCase function, leading to impaired decarboxylation of orotidine 5'-monophosphate (OMP) to (UMP) and subsequent accumulation of OMP and in bodily fluids. For instance, the homozygous mutation c.1010C>G (p.Ala337Gly) has been identified in patients, severely reducing enzyme activity and causing pyrimidine biosynthesis defects. Clinically, this manifests as due to impaired nucleotide synthesis, growth failure, developmental delays, and occasional immune dysfunction such as T-cell impairment. The condition is exceedingly rare, with fewer than 30 cases reported worldwide as of 2023. Treatment involves oral supplementation at doses of 100-200 mg/kg/day, which bypasses the enzymatic defect by providing exogenous pyrimidines, leading to resolution of , improved growth, and reduced excretion. Diagnosis typically begins with detection of markedly elevated urinary levels, often exceeding 100 mmol/mol (normal <1 mmol/mol), alongside normal to differentiate from disorders. Confirmation involves enzymatic assay of UMPS activity in erythrocytes or genetic sequencing to identify biallelic UMPS variants. Early can facilitate prompt intervention, preventing irreversible complications; for example, in 2023, expanded screening in identified 10 cases among over 1.4 million neonates screened. Beyond hereditary , dysregulation of the biosynthesis pathway has been implicated in broader pathologies, though direct ODCase deficiencies are not typically causative. Potential associations with have been suggested through studies on nucleotide imbalances affecting systems, but these links remain unconfirmed and require further research. In cancer, upregulation of the pathway supports tumor proliferation and is observed in various malignancies.

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    Oct 12, 2016 · Purine and pyrimidine metabolites and their receptors have previously been shown to be associated with various neuropsychiatric disorders. The ...Missing: imbalance schizophrenia