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Aconitase

Aconitase is an (EC 4.2.1.3) that catalyzes the stereospecific of citrate to isocitrate via the intermediate cis-aconitate, serving as the second step in the tricarboxylic acid () cycle, also known as the citric acid or Krebs cycle, a central pathway for cellular energy production. This enzyme exists in multiple isoforms, including the mitochondrial aconitase (ACO2), which is essential for cycle function within mitochondria, and the cytosolic aconitase (ACO1), which participates in the synthesis of isocitrate in the and regulates citrate efflux from mitochondria. Structurally, aconitase features a cuboidal [4Fe-4S]^{2+} iron-sulfur coordinated by three residues, with the fourth iron site facilitating and through and rehydration steps; this renders the enzyme sensitive to from like or , which can disrupt the cluster and inactivate the enzyme. Notably, cytosolic aconitase exhibits a dual role, functioning as an iron regulatory protein 1 (IRP1) when the iron-sulfur cluster is in a [3Fe-4S] form due to or oxidative damage; in this state, IRP1 binds to iron-responsive elements in mRNA to modulate the expression of proteins involved in iron homeostasis, such as and . Aconitase's activity is crucial not only for metabolic flux in the TCA cycle but also for broader cellular processes, including sensing, maintenance, and responses to environmental stresses, with dysregulation linked to diseases such as neurodegeneration and cancer.

Structure and Composition

Protein Architecture

Aconitase is a monomeric consisting of a single polypeptide chain with an approximate molecular weight of 85 kDa in eukaryotic forms, as exemplified by the human mitochondrial isoform ACO2 ( entry Q99798). The protein features four structural domains: domains 1, 2, and 3 form a compact composed of folds that create a central cleft, while domain 4, located at the , functions as a swivel domain capable of rotational movement relative to the core during enzyme activation. This domain organization positions the at the interface between the domains, facilitating substrate binding and catalysis. Crystal structures have elucidated the architectural details of aconitase in both inactive and active states. The structure of the inactive form, represented by the bovine S642A mutant complexed with isocitrate (PDB entry 1C97), reveals a of 1.8 Å and highlights the domain interfaces that stabilize the overall fold, with the substrate-binding cleft partially occluded in the absence of full . In contrast, the active form, as seen in the porcine aconitase complex with isocitrate and nitroisocitrate (PDB entry 7ACN) at resolutions up to 1.9 Å, demonstrates the swivel domain's repositioning, which opens the cleft for efficient access and underscores the interfaces between domains 1–3 and the mobile domain 4. These structures illustrate how the protein's accommodates conformational changes essential for function. The folds of aconitase exhibit strong evolutionary across prokaryotes and eukaryotes, reflecting its ancient origin in central . Multiple alignments and structural comparisons reveal that the core domains and domain are preserved in bacterial aconitases (e.g., AcnA and AcnB) and archaeal homologs, with variations primarily in linker regions but retention of the overall four-domain scaffold. structures of aconitase X enzymes from diverse prokaryotic sources further confirm this , showing architectural variants that maintain the functional cleft while adapting to lineage-specific needs. The iron-sulfur cluster integrates into the at the domain interfaces to enable .

Iron-Sulfur Cluster

The iron-sulfur in aconitase serves as a critical cofactor, adopting a [4Fe-4S]^{2+} structure in its active form, where four iron atoms are bridged by four sulfide ions. This configuration is highly sensitive to , during which cause the labile iron atom to dissociate, converting the cluster to an inactive [3Fe-4S]^{+} form and rendering the apo-aconitase. Structural studies reveal that this interconversion involves minimal disruption, with the positions of the common atoms in the [3Fe-4S] and [4Fe-4S] cores aligning within 0.1 Å. Biosynthesis of the [4Fe-4S] cluster in aconitase occurs through the mitochondrial iron- cluster (ISC) assembly machinery, a multiprotein complex that coordinates iron and acquisition. The process begins with mobilization from by the pyridoxal phosphate-dependent desulfurase NFS1, which forms a complex with accessory proteins like ISD11 to generate persulfide intermediates. These intermediates transfer to scaffold proteins such as ISCU, where the cluster is transiently assembled before insertion into apo-aconitase, ensuring targeted delivery to the cleft. The [4Fe-4S] cluster is ligated to the protein by three conserved residues, such as Cys385, Cys448, and Cys451 in ACO2, which coordinate three of the iron atoms via thiolate bonds, leaving the fourth iron labile. Crystal structures of aconitase often feature a sulfate ion bound near the cluster, mimicking the substrate's hydroxyl group and highlighting the cofactor's role in substrate positioning within the . Spectroscopic analyses confirm the cluster's redox properties, with Mössbauer spectroscopy revealing distinct isomer shifts for the [4Fe-4S]^{2+} state in the activated enzyme and the [3Fe-4S]^{+} state in the inactive form. Electron paramagnetic resonance (EPR) spectra further characterize these states, showing a characteristic signal at g = 2.01 for the oxidized [3Fe-4S]^{+} cluster and reduced [4Fe-4S]^{+} signals upon activation.

Catalytic Function

Reaction Catalyzed

Aconitase catalyzes the stereospecific of citrate to isocitrate through the cis-aconitate as the second step in the tricarboxylic acid () cycle. This reversible dehydration-rehydration reaction rearranges the hydroxyl group on citrate from the pro-R arm to the pro-S arm, enabling subsequent oxidation in the cycle. The enzyme exhibits high stereospecificity, converting citrate to (2R,3S)-isocitrate, the naturally occurring isomer utilized by . At equilibrium, the reaction favors citrate, with an equilibrium constant K_{eq} \approx 0.07 for the forward direction (citrate to isocitrate), resulting in approximately 91% citrate, 6% isocitrate, and 3% cis-aconitate under standard conditions. Substrate binding involves coordination of citrate's central hydroxyl group and the \alpha-carboxyl group to a unique iron atom (Feα) in the [4Fe-4S]^{2+} cluster, which acts as a Lewis acid to facilitate the transformation. This interaction positions the substrate for dehydration to cis-aconitate and subsequent rehydration. Aconitase is strongly inhibited by fluorocitrate, a of fluoroacetate, which binds tightly to the and forms a stable dead-end complex, blocking the enzyme's activity. This reaction takes place in the for the ACO2 isoform.

Enzymatic Mechanism

The enzymatic mechanism of aconitase involves a process: of citrate to cis-aconitate followed by rehydration to form isocitrate. In the step, citrate binds to the [4Fe-4S]^{2+} in the , where the hydroxyl group on the pro-R arm (C3) abstracts a proton from His-101, facilitating its departure as water. Concurrently, Ser-642 acts as a to abstract a proton from the α-carbon (), leading to the formation of a and release of cis-aconitate, which remains coordinated to the iron-sulfur without . This step depends on the of the [4Fe-4S]^{2+} , as disruption to [3Fe-4S]^{+} inactivates the . The intermediate cis-aconitate then undergoes a 180° within the about the Cα-Cβ , repositioning it for the step. A molecule coordinated to Feα of the is activated, with the Fe^{3+} serving as a acid to polarize the incoming hydroxyl addition to the β-carbon, while His-101 (assisted by Asp-100) deprotonates the to generate the nucleophilic . Ser-642 subsequently donates a proton to the α-carbon, yielding isocitrate with inverted at the β-carbon compared to citrate. Notably, the [4Fe-4S]^{2+} undergoes no changes during catalytic turnover, relying solely on its acidity to facilitate binding and polarization of the C-OH bond. For the mammalian mitochondrial isoform (ACO2), kinetic studies reveal a (k_{cat}) of approximately 10 s^{-1} for citrate and a Michaelis constant (K_m) of about 0.95 mM, reflecting efficient within physiological concentrations. These parameters underscore the enzyme's role in maintaining through the tricarboxylic acid cycle, with the mechanism ensuring and minimal side reactions.

Isoforms and Evolution

Mitochondrial Aconitase (ACO2)

Mitochondrial aconitase, encoded by the , is the isoform specifically targeted to the mitochondria and plays a central role in cellular energy production. The is located on the long arm of human at position 22q13.2, spanning approximately 81 kilobases and comprising 18 exons. The gene produces a precursor protein of 780 , which includes an N-terminal mitochondrial targeting sequence () of 26 that directs the protein to the mitochondria and is cleaved upon import by the mitochondrial processing peptidase. This post-import processing yields the mature ACO2 protein consisting of 754 , with a of approximately 85 kDa. ACO2 is exclusively localized to the , where it functions as a key in the tricarboxylic acid () cycle, also known as the Krebs cycle. In this compartment, ACO2 catalyzes the stereospecific of citrate to isocitrate via the intermediate cis-aconitate, facilitating the oxidative decarboxylation steps essential for aerobic respiration and ATP generation. This localization distinguishes ACO2 from the cytosolic isoform ACO1, emphasizing its dedicated role in mitochondrial oxidative metabolism rather than extramitochondrial functions. The 's activity is crucial for maintaining efficient electron transport and in oxygen-utilizing cells. Evolutionarily, ACO2 traces its origins to bacterial ancestors, with clear homologs such as the acnA gene in , which encodes a similar aconitase involved in the cycle under aerobic conditions. This conservation extends across eukaryotes, where ACO2 homologs support oxidative metabolism in mitochondria, the endosymbiotic descendants of ancient . The preservation of ACO2's core structure and function underscores its indispensable role in adapting to oxygen-dependent production throughout eukaryotic . Recent structural analyses, as reviewed in 2024, highlight the sensitivity of ACO2 to in the oxygen-rich mitochondrial environment, more so than its cytosolic counterpart ACO1. The [4Fe-4S] cluster is vulnerable to disruption by (ROS), leading to enzyme inactivation and serving as a marker of mitochondrial status. These features underscore ACO2's role in sensing within mitochondria. ACO2 shares the fundamental catalytic with ACO1, relying on the labile iron in the iron-sulfur cluster to coordinate dehydration and rehydration.

Cytosolic Aconitase (ACO1)

Cytosolic aconitase, encoded by the ACO1 gene (also known as IRP1), is located on human chromosome 9p21.1 and consists of 889 , lacking a mitochondrial targeting sequence that distinguishes it from its mitochondrial counterpart. This protein exhibits structural similarity to mitochondrial aconitase (ACO2) but is localized primarily in the . ACO1 demonstrates a remarkable dual functionality dependent on cellular iron levels. In its holo-form, when bound to a [4Fe-4S] iron-sulfur cluster under iron-replete conditions, it acts as an catalyzing the reversible of citrate to cis-aconitate and then to isocitrate, contributing to cytosolic aconitate metabolism. In contrast, under , the apo-form devoid of the cluster adopts a conformation that enables it to bind iron-responsive elements (IREs) in the untranslated regions of target mRNAs, such as those encoding (which stores iron) and the (which facilitates iron uptake), thereby posttranscriptionally regulating iron homeostasis. This switch is mutually exclusive, with the iron-sulfur cluster assembly directly modulating the protein's enzymatic versus regulatory roles. Evolutionarily, ACO1's represents an eukaryotic absent in prokaryotic ancestors, where aconitases primarily functioned as dedicated enzymes without RNA-binding capability. Prokaryotic aconitase A homologs, found in , catalyze similar dehydration-hydration reactions but lack the IRE-binding domain, highlighting a that enabled eukaryotes to integrate aconitase activity with iron regulatory networks. In metazoans, this bifunctionality likely arose from events, as evidenced in where cytosolic aconitase variants specialized—one retaining enzymatic activity and the other evolving IRE-binding for iron control—facilitating coordinated responses to fluctuating iron availability. Expression of ACO1 is modulated by cellular iron status, with the protein's functional shift rather than transcriptional upregulation predominating in deficiency states to enhance IRE-binding activity. Post-2020 studies have further elucidated its enzymatic contributions to cytosolic aconitate flux, particularly in contexts like where iron perturbations influence cluster integrity and metabolic outcomes.

Biological Significance

Role in Energy Metabolism

Aconitase plays a pivotal role in cellular energy as the catalyzing the of citrate to isocitrate, the second committed step of the tricarboxylic acid () cycle. This reaction integrates the oxidation of , primarily derived from , into the cycle, generating NADH and FADH₂ that fuel in the mitochondrial to produce ATP. In mitochondrial metabolism, aconitase exerts substantial control over TCA cycle flux, with flux control coefficients exceeding 0.95 in high-energy-demand tissues such as brain and heart, highlighting its regulatory importance in maintaining efficient energy production. The aconitase reaction is reversible, enabling it to support anaplerotic functions by converting isocitrate back to citrate during gluconeogenesis, thereby replenishing TCA cycle intermediates depleted for glucose synthesis in fasting or low-carbohydrate states. In inflammatory conditions, particularly in activated macrophages, metabolic rewiring diverts the intermediate cis-aconitate toward itaconate synthesis via aconitate decarboxylase 1 (ACOD1); this adaptation limits oxidative metabolism while promoting and responses, as detailed in studies since around 2016, with key advancements from 2020 onward. Aconitase is indispensable in aerobic tissues for sustaining cycle-dependent , with genetic disruption leading to lethality in model organisms such as and systemic deficiency being incompatible with life in mammals, demonstrating its essentiality for organismal viability. This metabolic role is predominantly fulfilled by the mitochondrial isoform ACO2. Beyond its roles in energy production and iron regulation, aconitase contributes to broader cellular processes, including sensing through sensitivity of its iron-sulfur cluster to and , which signals ; it also aids in maintenance and responses to environmental stresses.

Involvement in Iron Homeostasis

Aconitase 1 (ACO1), in its apo form lacking the [4Fe-4S] cluster, functions as iron regulatory protein 1 (IRP1), a key regulator of cellular iron by binding to iron-responsive elements (IREs) in the untranslated regions (UTRs) of target mRNAs. Specifically, apo-IRP1 binds to the IRE in the 5' UTR of mRNAs, inhibiting their translation and thereby reducing iron storage capacity under iron-deficient conditions. Conversely, it binds to multiple IREs in the 3' UTR of 1 (TfR1) mRNA, stabilizing it against degradation and promoting iron uptake. This dual binding action coordinates the expression of iron storage and import proteins to maintain intracellular iron balance. The switch between the enzymatic aconitase and regulatory IRP1 forms of ACO1 is governed by iron availability, which controls the assembly and disassembly of the [4Fe-4S] cluster. In low-iron conditions, oxidative stress or iron deficiency promotes cluster disassembly, converting holo-ACOs to apo-IRP1, which then acquires high-affinity RNA-binding activity to modulate IRE-containing transcripts. This mechanism represses ferritin synthesis while enhancing TfR1 expression, effectively increasing the cytosolic labile iron pool (LIP) to support cellular needs. In iron-replete states, cluster reassembly restores aconitase activity, releasing IREs and allowing normal translation of ferritin while permitting TfR1 mRNA degradation. Disruptions in this regulation can lead to LIP imbalances, with the pool typically maintained at 1-10 μM in healthy cells; excesses promote Fenton chemistry, generating reactive oxygen species and causing oxidative damage to lipids, proteins, and DNA.00388-6) Recent research has highlighted ACO1's role in systemic iron disorders, particularly (FA), where frataxin deficiency impairs Fe-S cluster biogenesis. Frataxin, primarily mitochondrial but with extramitochondrial forms, facilitates cluster assembly for ACO1, and its loss in elevates apo-IRP1 activity, dysregulating iron homeostasis and contributing to iron accumulation and in affected tissues. Studies in 2023 demonstrated that human interacts with aconitase domains to support cluster insertion, underscoring how frataxin-mediated defects exacerbate IRP1 dysregulation in pathogenesis.

Regulation and Pathophysiology

Regulatory Mechanisms

Aconitase activity is highly sensitive to , where (ROS) oxidize the [4Fe-4S]^{2+} cluster of both ACO1 and ACO2 to an inactive [3Fe-4S]^{+} form, leading to enzymatic inactivation and serving as a for cellular status. This inactivation is reversible; for cytosolic ACO1 (also known as IRP1), repair involves transfer of Fe-S clusters from proteins like mitoNEET under reducing conditions, thereby linking signaling to iron regulatory functions. In mitochondria, similar repair mechanisms involving glutaredoxins and the iron-sulfur cluster assembly machinery restore ACO2 function under reducing conditions. Transcriptional regulation of aconitase isoforms responds to environmental cues like and nutrient availability. Nuclear factor erythroid 2-related factor 2 (NRF2) upregulates ACO2 expression as part of its broader control over and defenses, particularly under oxidative or where it promotes transcription. Similarly, NRF1 contributes to and may coordinately enhance ACO2 levels in response to . For ACO1, microRNA-210 (miR-210) is induced during and , suppressing iron homeostasis-related proteins and indirectly impairing ACO1's aconitase activity by disrupting iron-sulfur cluster biogenesis through targeting ISCU, thereby shifting ACO1 toward its iron-regulatory role. Post-translational modifications fine-tune aconitase activity to match metabolic demands. of serine residues, such as Ser138, on ACO1 destabilizes the [4Fe-4S] cluster, inhibiting aconitase activity and promoting a switch to the iron regulatory protein form. Similar post-translational modifications may regulate ACO2, though specific mechanisms require further study. Additionally, succination—a non-enzymatic modification by fumarate-derived succinyl groups—covalently adducts residues on ACO2, inhibiting its activity and reducing cycle flux in response to elevated fumarate levels, as observed in metabolic stress. The itaconate pathway provides an immunomodulatory branch point in aconitase regulation, particularly in macrophages. Aconitate decarboxylase 1 (ACOD1, also known as IRG1) competes with ACO2 for cis-aconitate, decarboxylating it to produce itaconate, an metabolite that diverts from the cycle and limits aconitase-mediated flux. This pathway, prominently studied from 2019 onward, integrates innate immune responses with , where itaconate accumulation inhibits and modulates ROS production without directly altering aconitase structure.

Implications in Disease

Aconitase dysregulation plays a critical role in neurodegenerative diseases, particularly through impairments in mitochondrial function and iron . In (PD), peripheral aconitase 2 (ACO2) activity is significantly reduced in patients compared to healthy controls, with lower levels correlating positively with earlier age of onset and longer disease duration. This deficiency exacerbates mitochondrial dysfunction and disrupts acetylation-mediated transcription of autophagy-related genes, increasing neuronal vulnerability to α-synuclein toxicity. Similarly, in (ALS), ACO2 undergoes oxidative inactivation, leading to in the and subsequent mitochondrial dysfunction, which serves as a potential for disease progression and survival. These pathological changes highlight ACO2 as a therapeutic target for mitigating neurodegeneration. In inflammatory and immune disorders, the interplay between aconitate decarboxylase 1 (ACOD1) and cytosolic aconitase 1 (ACO1) influences disease outcomes, notably in and . Recent research demonstrates that the ACOD1-derived metabolite itaconate suppresses signaling (via NRF2 activation and other pathways), reducing inflammatory responses in models of acute . This axis protects against dextran sulfate sodium-induced by attenuating and production, suggesting therapeutic potential for itaconate derivatives in . In , ACOD1 expression is upregulated in monocytes and macrophages; while it has dual roles, the itaconate pathway often exerts effects, potentially mitigating organ damage. Targeted modulation of the ACOD1 pathway is being explored for therapeutic benefit. Aconitase isoforms contribute to cancer progression by modulating iron metabolism and bioenergetics. ACO1 is upregulated in various tumors, including those under hypoxic conditions, where it enhances iron acquisition to support rapid proliferation and survival by stabilizing transferrin receptor mRNA and repressing ferritin translation. This iron-regulatory function of ACO1 facilitates tumor growth and metastasis, particularly in breast and renal cancers. Conversely, ACO2 knockdown impairs cell proliferation in breast cancer models by disrupting tricarboxylic acid cycle flux and increasing oxidative stress, as evidenced in triple-negative breast cancer cell lines where reduced ACO2 activity halts metabolic adaptation and tumor expansion. Recent reviews emphasize ACO2's tumor-suppressive role, positioning its modulation as a strategy to inhibit cancer progression without affecting normal cells. Mutations in ACO2 underlie severe metabolic disorders, including infantile cerebellar-retinal degeneration, a neurodegenerative condition characterized by progressive , optic , and retinal dystrophy. Biallelic ACO2 variants disrupt mitochondrial iron-sulfur cluster biogenesis and tricarboxylic acid cycle function, leading to cerebellar and psychomotor in affected infants. Additionally, aconitase deficiency links to through frataxin impairment, where reduced frataxin levels cause iron accumulation and oxidative inactivation of ACO2, exacerbating mitochondrial respiratory chain defects and contributing to and neurodegeneration. These associations reveal aconitase's central role in inherited metabolic pathologies, with potential for to restore enzymatic activity.

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