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Carbamoyl phosphate synthetase I

Carbamoyl phosphate synthetase I (CPS1) is a mitochondrial enzyme that catalyzes the first and rate-limiting step of the urea cycle, facilitating the ATP-dependent condensation of ammonia and bicarbonate to form carbamoyl phosphate, which is essential for incorporating nitrogen into urea for excretion. Primarily expressed in the liver, where it constitutes 15–20% of mitochondrial protein, CPS1 plays a pivotal role in ammonia detoxification to prevent hyperammonemia, a condition that can lead to severe neurological damage. Structurally, CPS1 is a large homodimeric protein with a molecular weight of approximately 160–165 kDa, comprising distinct functional domains: an N-terminal glutaminase domain for ammonia activation and a C-terminal synthetase domain that handles phosphorylation steps, connected by an internal tunnel spanning 96 Å to shuttle intermediates efficiently. The enzyme's activity is allosterically regulated by N-acetylglutamate (NAG), which binds to enhance its function in response to cellular nitrogen levels. Encoded by the CPS1 gene on chromosome 2q34 (MIM #608307), the gene spans about 120 kb across 38 exons, producing a 5,761 bp mRNA that directs the synthesis of this critical urea cycle component. Deficiency in CPS1, an autosomal recessive disorder (MIM #237300), disrupts function and leads to , with an estimated prevalence of 1 in 50,000 to 1 in 100,000 live births. Neonatal-onset cases, which account for the majority, present with , , seizures, and , carrying a of up to 50% even with aggressive treatment involving dietary protein restriction, nitrogen-scavenging drugs, and sometimes as a curative option. Over 200 mutations have been identified in the CPS1 gene, including missense and truncation variants that impair enzyme stability or catalytic efficiency, underscoring the of this rare inborn error of metabolism.

Function

Role in metabolism

Carbamoyl phosphate synthetase I (CPS1) serves as the first and rate-limiting enzyme in the , catalyzing the initial commitment to urea synthesis by incorporating into . This enzyme is primarily localized in the of hepatocytes, where it constitutes approximately 15-20% of the total mitochondrial protein mass, underscoring its abundance and central role in hepatic ; lower expression occurs in enterocytes, contributing to local synthesis. In mammals, CPS1 plays a critical physiological role in detoxifying generated primarily from and , converting this neurotoxic compound into for safe through the kidneys. By facilitating this process, CPS1 prevents the accumulation of , which can lead to and associated neurological complications if unchecked. This function is vital under normal physiological conditions, where the handles the bulk of systemic clearance in the liver. Unlike carbamoyl phosphate synthetase II (CPSII), which participates in biosynthesis in the , CPS1 is uniquely dedicated to incorporation for production in mammals, highlighting evolutionary adaptations for terrestrial . The product of CPS1, , is directly transported to the enzyme , which combines it with to form , thereby integrating CPS1 into the sequential steps of the . This interconnection ensures efficient flux through the pathway, maintaining overall homeostasis.

Catalyzed reaction

Carbamoyl phosphate synthetase I (CPS1) catalyzes the committed first step of the urea cycle by synthesizing carbamoyl phosphate, a high-energy compound essential for nitrogen incorporation into urea. The overall reaction is: \ce{2 ATP + L-glutamine + HCO3^- + H2O -> carbamoyl phosphate + L-glutamate + 2 ADP + P_i + H^+} This net transformation reflects the enzyme's dual functionality, where two molecules of ATP are hydrolyzed to ADP and inorganic phosphate (Pᵢ) for each molecule of carbamoyl phosphate produced, establishing the stoichiometry of the process. CPS1 can also utilize free ammonium ions (NH₄⁺) directly in place of glutamine-derived ammonia, although the primary physiological source is glutamine deamination facilitated by the enzyme's intrinsic glutaminase domain. The resulting carbamoyl phosphate then acts as the activated nitrogen donor in the urea cycle, condensing with ornithine to form citrulline in a reaction mediated by ornithine transcarbamoylase. The reaction is thermodynamically unfavorable in isolation, as the formation of from and is endergonic; however, coupling to the exergonic of two ATP molecules drives the overall process forward. This energy investment ensures efficient of in hepatocytes, where CPS1 is localized in the . The precise coupling prevents wasteful uncoupled , maintaining the reaction's efficiency .

Structure

Domain organization

Human carbamoyl phosphate synthetase I (CPS1) is synthesized as a single polypeptide chain comprising 1500 in its form, following cleavage of the N-terminal mitochondrial targeting sequence, and is encoded by the CPS1 gene located on chromosome 2q34. This linear sequence organizes into a modular architecture with three core functional domains that reflect its evolutionary origins from fused prokaryotic subunits. The N-terminal glutaminase (GLN) domain spans residues 1–440 and is structurally homologous to active glutaminase domains found in bacterial CPS enzymes, where it would hydrolyze to glutamate and , but in human CPS1, this domain is catalytically inactive due to replacement of a key residue with serine (Ser294), relying instead on externally supplied for the reaction. The central small synthetase (sSYN) domain, encompassing residues 441–760, is responsible for the initial of to form carboxyphosphate using the first molecule of ATP. This domain adopts an ATP-grasp fold typical of carboxylate-amine ligases. The C-terminal large synthetase (lSYN) domain, covering residues 761–1479, catalyzes the subsequent of to produce utilizing a second ATP molecule. An additional C-terminal regulatory domain (residues 1400–1500) provides a site for allosteric activation by N-acetyl-L-glutamate (NAG), which binds to induce conformational changes that enhance catalytic efficiency across distant active sites. Key sequence motifs define the catalytic capabilities of these domains. Both the sSYN and lSYN domains contain conserved Walker A (P-loop) and Walker B motifs that coordinate Mg-ATP binding and hydrolysis, with the Walker A motif in sSYN facilitating bicarbonate activation and the corresponding motif in lSYN enabling carbamate phosphorylation. In the GLN domain, a conserved histidine residue (His417) participates in the structural mimicry of the glutamine-binding site, part of an incomplete catalytic triad that underscores the domain's evolutionary remnant status. Post-translational modifications on CPS1 are limited, with the enzyme primarily active in its unmodified state, though potential serine and threonine phosphorylation sites exist within the regulatory and integrating regions that may modulate NAG responsiveness. acylation, particularly succinylation and glutarylation, occurs on residues in the catalytic domains and is dynamically regulated by sirtuin 5 (SIRT5) deacylation, influencing enzyme stability and activity under metabolic stress.00118-1)

Quaternary structure

Carbamoyl phosphate synthetase I (CPS1) is a large, multidomain enzyme whose three-dimensional structure was determined by at resolutions of 2.4 Å for the apo form and 2.6 Å for the N-acetyl-L-glutamate (NAG)-bound form. The overall architecture consists of a single polypeptide chain folded into six globular domains organized into N-terminal (sSYN/S1, GLN/S2, and lSYN/L1) and C-terminal (lSYN/L3, regulatory/L4, and oligomerization/L5) moieties, connected by a flexible linker that imparts an elongated conformation to the molecule. The GLN domain adopts a fold characteristic of glutamine amidotransferases, featuring a but rendered inactive by substitution of the active-site with serine at position 294. Both the sSYN and lSYN domains exhibit ATP-grasp folds similar to those observed in carboxylase, enabling ATP-dependent reactions at their active sites. Inter-domain linkers, including a ~50 , 20-residue segment between the N- and C-terminal moieties, confer flexibility that accommodates conformational rearrangements, such as up to 7 displacements in domain positions upon ligand binding; this flexibility facilitates the formation of a ~35 linear tunnel for intermediate channeling, with a of 2.6–5 that is only well-defined in the active conformation. In solution, CPS1 exists predominantly as a functional monomer, as evidenced by and , though it maintains a weak monomer-dimer equilibrium involving ~3% of the molecular surface. Dimerization potential within the remains a subject of debate, potentially influenced by physiological conditions, in contrast to the stable heterodimeric assembly of the bacterial homolog comprising distinct small and large subunits. A key structural feature is the allosteric binding pocket in the C-terminal L4 domain, where NAG binds to induce a tense (T)-to-relaxed (R) state transition, involving movements such as a 9 Å shift in the side chain of Asn1440 and stabilization of the active conformation through interactions between the C-terminal tail and a flexible T'-loop. This allosteric mechanism propagates long-range effects to the distant phosphorylation domains, enabling efficient catalysis.

Mechanism

Partial reactions

Carbamoyl phosphate synthetase I (CPS1) catalyzes the formation of carbamoyl phosphate through a series of three sequential partial reactions, each utilizing ATP and occurring within distinct structural domains of the . The first partial reaction takes place in the small synthetase domain (sSYN), where is activated by with the first of ATP to form the unstable intermediate carboxyphosphate and . This step represents the initial activation of , enabling subsequent nucleophilic attack. In the second partial reaction, still within the sSYN domain, acts as a to attack the carboxyphosphate intermediate, yielding and inorganic phosphate (Pᵢ). This reaction is crucial for incorporating into the pathway, with the exhibiting a Michaelis constant (K_m) for ammonium of approximately 0.3-0.5 mM. The intermediates do not freely diffuse out of the but are channeled internally to prevent or loss. The third partial reaction occurs in the large synthetase domain (lSYN), where the carbamate intermediate binds and is phosphorylated by a second molecule of ATP to produce and another ADP. This step completes the synthesis, with the overall following an ordered : bicarbonate binds first, followed by the initial ATP, and product release (including the second ADP and ) occurs after the final . In liver extracts, the maximum (V_max) of the full reaction is approximately 1.2 μmol/min/mg protein, reflecting the enzyme's capacity in hepatic mitochondria.

Ammonia channeling

In carbamoyl phosphate synthetase I (CPS1), ammonia channeling refers to the directed internal of externally supplied through a dedicated protein , ensuring its efficient delivery to the for incorporation into without free diffusion in the . Unlike glutamine-hydrolyzing CPS variants, human CPS1 relies on free ions (NH₄⁺) generated nearby from or by mitochondrial enzymes such as , and the vestigial glutaminase (GLN) domain does not catalyze . This channeling mechanism is crucial for the enzyme's role in the , where CPS1 operates under high ammonia flux in hepatocytes. The channeling pathway begins with ammonia entry at the protein surface near the N-terminal vestigial GLN , traversing a hydrophobic approximately 30 in length to reach the region of the small synthetase (sSYN) . This , proposed to involve residues such as Glu82 and His142 at the entrance and extending to a formed by conserved residues, is lined by hydrophobic and charged residues that facilitate selective passage while excluding . Following 's reaction at the sSYN site to form , the intermediate is then channeled through a separate ~35 hydrophobic to the large synthetase (lSYN) site for , maintaining overall . These tunnels are structurally analogous to those in bacterial but adapted for external intake in CPS1. Channeling achieves high efficiency, minimizing losses to cellular and enabling the enzyme's low micromolar for . This is evidenced by the enzyme's basal activity being less than 2% without activators, rising sharply upon substrate binding to support rapid ureagenesis. Post-translational modifications, such as O-GlcNAcylation at residues like Thr109 and Thr110 near the tunnel entrance, further enhance kinetic efficiency for (increased kcat/), promoting better incorporation under physiological stress. Structurally, the tunnel assembles dynamically through conformational shifts induced by allosteric effector N-acetylglutamate (NAG) and substrates, which reorient domains and remodel loops (e.g., the tunnel-loop and T'-loop) to open a continuous pathway; in the apo-inactive state, the tunnel collapses into branched cavities, preventing premature access. crystal structures at 2.4–2.6 resolution reveal this on/off switch, with the tunnel shielded by residues including Arg721 and multiple glutamates (e.g., Glu440, Glu797). Mutations disrupting tunnel integrity, such as Arg1453Trp (abolishing activation), severely impair channeling and cause CPS1 deficiency, leading to . Physiologically, ammonia channeling in CPS1 confers a critical in the liver's mitochondrial environment, where ammonia levels can spike during ; by confining toxic to the enzyme interior, it prevents oxidative damage and neuronal toxicity while sustaining high-flux production (up to 20–30 g/day in adults). This mechanism supports efficient , with channeling efficiency correlating to reduced hyperammonemic crises in variant studies.

Regulation

Allosteric effectors

The primary allosteric activator of carbamoyl phosphate synthetase I (CPS1) is N-acetylglutamate (NAG), which is synthesized by the enzyme N-acetylglutamate synthase (NAGS) in response to elevated levels of and glutamate, thereby linking CPS1 activity to cellular status. NAG binds to a specific pocket in the C-terminal domain (L4 domain) of CPS1, involving key residues such as Trp1410, Thr1391, Thr1394, Asn1437, Asn1440, and Asn1449, with a dissociation constant (K_d) of approximately 100 μM. Binding of NAG stabilizes the active relaxed (R-state) conformation of CPS1, promoting long-range conformational changes that facilitate substrate access and , resulting in more than a 50-fold increase in maximum velocity (V_max), with the enzyme exhibiting less than 2% of its saturated activity in the absence of NAG, and enhanced affinity for substrates including ATP and . In the absence of NAG, CPS1 exhibits less than 2% of its saturated activity, underscoring the essential role of this effector in enabling efficient ureagenesis. Unlike some bacterial carbamoyl phosphate synthetases, mammalian CPS1 lacks direct by ATP or , although ATP can indirectly enhance NAG affinity. Physiologically, NAG levels rise in response to a , which increases load and thereby elevates demand through enhanced NAGS activity. This mechanism ensures CPS1 activation aligns with nutritional nitrogen influx, preventing while avoiding unnecessary energy expenditure on ureagenesis during low-protein states.

Feedback mechanisms

The expression of carbamoyl phosphate synthetase I (CPS1) is primarily regulated at the transcriptional level, where it is upregulated by glucocorticoids and cyclic AMP (cAMP) in response to elevated ammonia levels. Glucocorticoids bind to the glucocorticoid response unit (GRU) in the distal enhancer region of the CPS1 gene, facilitating recruitment of accessory transcription factors such as FoxA and C/EBP to promote hepatic expression. Similarly, cAMP, generated via glucagon signaling, activates protein kinase A (PKA), which phosphorylates and stimulates CREB to bind the cAMP response unit (CRU) in the promoter, enhancing transcription during states of high protein catabolism. The CPS1 promoter contains a specific CREB binding site within this CRU, confirming its role in cAMP-mediated induction. Post-transcriptional regulation of CPS1 involves modulation of mRNA stability, which contributes to sustained enzyme levels under varying metabolic conditions. During , CPS1 mRNA stability is enhanced, supporting increased flux; the of CPS1 mRNA in liver is approximately 6-12 hours under basal conditions, allowing for rapid adjustments in response to nutritional shifts. Hormonal further fine-tunes CPS1 expression, with insulin suppressing transcription to limit synthesis during fed states, while induces it through the pathway to promote detoxification. This reciprocal control ensures alignment with overall , as glucagon elevates levels to activate CREB-dependent transcription. Feedback mechanisms for CPS1 are predominantly indirect, involving intermediates that modulate activity without direct product inhibition. For instance, and other intermediates influence N-acetylglutamate (NAG) synthesis via N-acetylglutamate synthase, which allosterically activates CPS1; notably, CPS1 exhibits no direct inhibition by its product, , allowing unimpeded flux through the cycle. Developmentally, CPS1 expression is low in the fetal liver, where demands are minimal due to placental clearance, representing only 2-14% of adult levels in mRNA abundance as early as six days before birth. Expression peaks in the adult liver, driven by maturation of transcriptional regulators like C/EBPα, coinciding with the establishment of full ureogenic capacity postnatally.

Genetics and evolution

Gene structure

The CPS1 is located on the long arm of at position 2q34 and spans approximately 201 kilobases of genomic DNA. This consists of 38 s and 37 introns, with the exons ranging in size from 50 to 200 base pairs, collectively encoding a protein of 1,500 residues. The first exon is non-coding, primarily comprising the 5' untranslated region (UTR), while the coding sequence begins in exon 2. The promoter region of the CPS1 gene includes response elements (GREs) located in both proximal and distal enhancers, which facilitate hormone-dependent transcriptional activation in hepatic tissues. These regulatory elements, along with binding sites for transcription factors such as hepatocyte nuclear factor 3-beta (HNF3β), contribute to the tissue-specific and inducible expression of CPS1 in the liver. No pseudogenes for CPS1 have been identified in the , consistent with its high sequence conservation across vertebrate species, which underscores its essential role in function. Common single nucleotide polymorphisms (SNPs) in the CPS1 gene, such as rs1047891 (also known as T1405N), are associated with subtle variations in enzyme activity but do not cause pathogenic effects or urea cycle disorders.

Evolutionary history

Carbamoyl phosphate synthetase I (CPS1) traces its origins to an ancient event in prokaryotes, where an ancestral glutaminase merged with a synthetase to form the foundational structure of the . This , evidenced by sequence similarities between mammalian CPS1 domains and prokaryotic subunits, likely occurred early in cellular , predating the divergence of major kingdoms and enabling efficient incorporation into . The internal duplication within the synthetase domain, a hallmark of CPS enzymes, further supports this prokaryotic ancestry and has been proposed as a deep-rooting event in the . Subsequent gene duplications expanded the CPS family, with an ancestral CPS gene in the progenote giving rise to distinct isozymes adapted to specific metabolic needs. In eukaryotes, a key duplication after the divergence from plants but before fungal separation produced CPSII, dedicated to pyrimidine biosynthesis, and CPSI, specialized for the urea cycle to detoxify ammonia in ureotelic organisms. CPSIII represents an evolutionary intermediate, primarily found in fish and certain invertebrates, facilitating ammonia-dependent carbamoyl phosphate synthesis in aquatic environments before the full transition to CPSI in terrestrial vertebrates. CPS1 demonstrates remarkable sequence conservation across distant taxa, with the enzyme sharing approximately 25-31% identity with bacterial homologs in its glutaminase and synthetase domains, reflecting its essential role in nitrogen metabolism. The glutaminase (GLN) domain exhibits the greatest variability, likely due to adaptations in CPSI for direct utilization rather than hydrolysis as in CPSII. In eukaryotes, CPS1 evolved as a single-chain polypeptide, contrasting the heterodimeric structure (small glutaminase and large synthetase subunits) in , with the addition of an N-terminal mitochondrial targeting signal post-endosymbiosis to localize the enzyme to mitochondria for function. Phylogenetically, CPS1 is conserved across all metazoans, underscoring its fundamental importance in , but it has been lost in certain parasitic lineages, including obligate intracellular parasites like Chlamydiae and Mycoplasmatales, where streamlined genomes eliminate dependencies. This loss highlights evolutionary trade-offs in , where host-derived nutrients reduce the need for pathways.

Clinical aspects

Deficiency disorder

Carbamoyl phosphate synthetase I (CPS1) deficiency is an autosomal recessive disorder caused by pathogenic variants in the CPS1 gene, leading to impaired function of the enzyme in the . The estimated incidence is approximately 1 in 1,300,000 live births. Over 300 pathogenic variants have been reported, including missense mutations in the glutaminase (GLN) or small synthetase (sSYN) domains that disrupt enzyme activity. The disorder manifests in two primary forms: a severe neonatal type characterized by complete or near-complete loss of CPS1 activity, and a late-onset type with partial residual activity typically ranging from 5% to 20%. Neonatal cases present within the first few days of life with acute exceeding 1000 μM, progressing to , poor feeding, , seizures, and if untreated. In contrast, late-onset cases may appear in infancy, childhood, or adulthood, often triggered by stressors such as infections or high-protein intake, resulting in episodic with similar acute symptoms but potentially milder initial severity. Chronic manifestations in survivors include , developmental delays, and episodes of liver dysfunction or failure. Pathophysiologically, CPS1 deficiency blocks the first step of the , causing toxic accumulation of in the blood and tissues. Excess crosses the blood-brain barrier, leading to through osmotic swelling of due to buildup from astrocytic detoxification via . This disrupts balance and cerebral energy metabolism, contributing to and long-term neurological damage. Animal models, such as constitutive mice lacking Cps1, recapitulate the neonatal , exhibiting severe and within 36 hours of birth. These models demonstrate that survival can be extended in hypomorphic variants with partial activity, particularly when supported by a to reduce load. CPS1 deficiency is distinguished from N-acetylglutamate synthase (NAGS) deficiency in the by normal levels of N-acetylglutamate (NAG), the allosteric activator of CPS1, whereas NAGS deficiency features low NAG.

Diagnosis and management

Diagnosis of carbamoyl phosphate synthetase I (CPS1) deficiency typically begins with , which may detect low concentrations in blood spots from , often prompting confirmatory testing including measurement of elevated plasma levels. This screening is crucial since can manifest rapidly in neonates, often within the first few days of life. Confirmatory testing includes measurement of biochemical markers such as high glutamine levels, low and urea, which help differentiate CPS1 deficiency from other disorders (UCDs); notably, normal ornithine (OTC) activity distinguishes it from OTC deficiency. Enzyme assays on liver biopsy samples can directly assess CPS1 activity, providing definitive biochemical confirmation, while genetic sequencing using next-generation sequencing (NGS) panels identifies pathogenic variants in the CPS1 gene. Management of CPS1 deficiency focuses on rapid intervention to control and prevent neurological damage. In acute episodes, is employed to remove excess , alongside intravenous administration of and phenylacetate to scavenge nitrogenous waste. For chronic care, a restricted to 0.5-1 g/kg/day is essential to minimize production, supplemented with to support the and N-carbamylglutamate (NCG), which acts as a mimic of the natural activator N-acetylglutamate to stimulate residual CPS1 activity. Prognosis has improved significantly with early diagnosis and aggressive treatment; prior to widespread newborn screening, mortality exceeded 50%, but timely intervention now reduces it to less than 10%, though survivors may experience neurodevelopmental delays. Liver transplantation remains a curative option for severe, recurrent cases, offering long-term stabilization. Emerging therapies include gene therapy approaches using adeno-associated virus (AAV) vectors to deliver functional CPS1, with preclinical studies in murine models demonstrating sustained ammonia control and long-term survival; in May 2025, the first infant with CPS1 deficiency successfully received personalized CRISPR-based gene editing therapy at Children's Hospital of Philadelphia, showing promising early results in ammonia control and metabolic stabilization. Enzyme replacement therapy is under investigation but not yet clinically available.