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Prosthetic group
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A prosthetic group is a non-amino acid component that is tightly linked to the apoprotein and forms part of the structure of the heteroproteins or conjugated proteins.

Not to be confused with the cosubstrate that binds to the enzyme apoenzyme (either a holoprotein or heteroprotein) by non-covalent binding a non-protein (non-amino acid)

A prosthetic group is a component of a conjugated protein that is required for the protein's biological activity.[1] It may be organic (such as a vitamin, sugar, RNA, phosphate or lipid) or inorganic (such as a metal ion). Prosthetic groups are bound tightly to proteins and may even be attached through a covalent bond. They often play an important role in enzyme catalysis. A protein without its prosthetic group is called an apoprotein, while a protein combined with its prosthetic group is called a holoprotein. A non-covalently bound prosthetic group cannot generally be removed from the holoprotein without denaturating the protein. Thus, the term "prosthetic group" is a very general one and its main emphasis is on the tight character of its binding to the apoprotein. It defines a structural property, in contrast to the term "coenzyme" that defines a functional property.

Prosthetic groups are a subset of cofactors. Loosely bound metal ions and coenzymes are still cofactors, but are generally not called prosthetic groups.[2][3][4] In enzymes, prosthetic groups are typically involved in the catalytic mechanism and are required for enzymatic activity; however, other prosthetic groups have structural properties. This is the case for the sugar and lipid moieties found in glycoproteins and lipoproteins or RNA in ribosomes. They can be very large, representing the major part of the protein in proteoglycans for instance.

The heme group in hemoglobin is a well-known example of a prosthetic group. Further examples of organic prosthetic groups are vitamin derivatives: thiamine pyrophosphate, pyridoxal-phosphate and biotin. Since prosthetic groups are often vitamins or made from vitamins, this is one of the reasons why vitamins are required in the human diet. Inorganic prosthetic groups are usually transition metal ions such as iron (in heme groups, for example in cytochrome c oxidase and hemoglobin), zinc (for example in carbonic anhydrase), copper (for example in complex IV of the respiratory chain) and molybdenum (for example in nitrate reductase).

List of prosthetic groups

[edit]

The table below contains a list of some of the most common prosthetic groups.

Prosthetic group Function Distribution
Flavin mononucleotide [5] Redox reactions Bacteria, archaea and eukaryotes
Flavin adenine dinucleotide [5] Redox reactions Bacteria, archaea and eukaryotes
Pyrroloquinoline quinone [6] Redox reactions Bacteria
Pyridoxal phosphate [7] Transamination, decarboxylation and deamination Bacteria, archaea and eukaryotes
Biotin [8] Carboxylation Bacteria, archaea and eukaryotes
Methylcobalamin [9] Methylation and isomerisation Bacteria, archaea and eukaryotes
Thiamine pyrophosphate [10] Transfer of 2-carbon groups, α cleavage Bacteria, archaea and eukaryotes
Heme [11] Oxygen binding and redox reactions Bacteria, archaea and eukaryotes
Molybdopterin [12][13] Oxygenation reactions Bacteria, archaea and eukaryotes
Lipoic acid [14] Redox reactions Bacteria, archaea and eukaryotes
Cofactor F430 Methanogenesis Archaea

References

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Prosthetic group

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A prosthetic group is a tightly bound, non-amino acid component of a , such as an or , that is essential for its biological function and often remains attached even after denaturation. These groups are distinguished from loosely associated cofactors or coenzymes by their permanent or covalent attachment to the protein's apoenzyme (the protein without the group), forming a holoenzyme that exhibits full activity. Prosthetic groups can be organic molecules derived from vitamins, carbohydrates, or , or inorganic elements like metal ions, and they typically facilitate processes such as , , or substrate binding. In enzymes, prosthetic groups play a by providing reactive sites or structural elements necessary for function; for instance, the group, an iron-containing ring, serves as the prosthetic group in hemoproteins like and , enabling oxygen binding and transport. Other notable examples include , which covalently attaches to carboxylases via a residue to aid in reactions, and (), an organic prosthetic group in oxidoreductases that participates in reactions. Inorganic prosthetic groups, such as in or magnesium in photosynthetic ), often stabilize active sites or mediate metal-dependent catalysis. The incorporation of prosthetic groups into proteins can occur co- or post-translationally, sometimes requiring specific enzymes for attachment, as seen with heme lyases that covalently link to apocytochromes in mitochondrial electron transport chains. This tight binding enhances protein stability and specificity, but removal—via harsh treatments like silver salt extraction—renders the protein inactive, underscoring their indispensability. Prosthetic groups are ubiquitous in biochemistry, contributing to diverse physiological processes from respiration and to metabolic .

Definition and Terminology

Definition

A prosthetic group is defined as a tightly bound, non-amino acid molecular component, either organic or inorganic, that becomes a permanent part of conjugated proteins, especially enzymes, and is essential for their biological activity. These groups are distinguished by their strong, often covalent or non-covalent yet stable, association with the protein, enabling functions that the polypeptide chain alone cannot perform. In protein nomenclature, the fully functional assembly consisting of the protein and its prosthetic group is termed a holoprotein, whereas the protein devoid of this group is called an apoprotein, which is typically inactive or lacks full functionality. This distinction highlights the prosthetic group's indispensable role in achieving the native, active conformation of the protein. Representative examples of conjugated proteins include hemoproteins, which incorporate as their prosthetic group for oxygen transport and storage; flavoproteins, featuring flavin derivatives for reactions; and metalloproteins, which utilize metal ions like iron or for catalytic purposes. Prosthetic groups are commonly derived from vitamins (such as flavins from vitamin B2), sugars, , or inorganic metal ions, but they are invariably integrated into the protein's native three-dimensional structure to exert their effects.

Historical Background

The concept of the prosthetic group emerged in late 19th- and early 20th-century protein chemistry as a way to describe the non-protein components essential to the structure and function of conjugated proteins, analogous to a "" that augments the protein's capabilities. The term "prosthetic group" was coined by biochemist around 1900. It first appeared in around 1895–1900, reflecting growing recognition of proteins as complex assemblies rather than simple polypeptides, with studies on substances like highlighting tightly bound, non-amino acid moieties. This development was intertwined with foundational work in protein chemistry, including Emil Fischer's investigations into and protein linkages in the 1900s. Early discoveries of specific prosthetic groups began in the mid-19th century, with Felix Hoppe-Seyler's isolation and naming of in 1864, where he identified its red pigment as a bound iron-containing component crucial for oxygen transport. Hoppe-Seyler's spectroscopic analyses in the and revealed hemoglobin's distinct absorption bands, leading to the broader appreciation of non-protein groups permanently associated with proteins, though the term "prosthetic" was not yet formalized. These observations shifted focus from isolated proteins to conjugated forms, setting the stage for enzyme studies in the early . The concept evolved significantly in the 1920s and 1930s through investigations into and vitamin-derived cofactors, transitioning from descriptive terminology to a standardized framework. Otto Warburg's work in the 1930s exemplified this, as he isolated (FMN) as the yellow prosthetic group in the "old yellow enzyme" from yeast, demonstrating its tight binding and role in . Warburg and Walter Christian's 1932 discovery of flavoproteins further solidified the prosthetic group as a distinct category, influenced by vitamin discoveries like , which provided organic moieties for activity. By the 1950s, prosthetic groups had become central to elucidating mechanisms, as evidenced in Albert Lehninger's research on mitochondrial , where groups like in were key to energy transduction pathways.

Characteristics and Binding

Key Characteristics

Prosthetic groups encompass both organic and inorganic components that are integral to the structure and function of conjugated proteins. Organic prosthetic groups are frequently derived from vitamins or other biomolecules, such as (FMN) synthesized from (vitamin B2), while inorganic ones include metal ions like Fe²⁺ and Zn²⁺ that coordinate within protein active sites. These groups are non-peptide in nature and distinguish themselves through their tight integration, often via covalent or coordinate bonds, which contrasts with more transient associations in proteins. A defining feature of prosthetic groups is their stability and permanence within the . Unlike loosely bound cofactors, they resist removal by dialysis or mild denaturation treatments, remaining associated even under conditions that dissociate weaker interactions. This durability contributes to and overall stability, as the prosthetic group often stabilizes the tertiary or conformation of the apoprotein (the protein without the group). Prosthetic groups are essential for the protein to attain its native, active conformation, enabling the holoprotein (the complete functional unit) to perform its biological roles. Prosthetic groups exhibit remarkable diversity in size and complexity, ranging from simple metal ions with atomic masses under 100 Da to elaborate organic structures like , a ring complexed with iron exceeding 600 Da. They typically comprise a minor fraction of the holoprotein's mass, often 1-10%, as exemplified by the four heme groups in , which account for approximately 4% of its total molecular weight. This variability allows prosthetic groups to adapt to diverse protein environments while maintaining efficiency. Prosthetic groups are ubiquitous across all domains of life, from and to eukaryotes, where they are indispensable for core metabolic processes such as and . Iron-sulfur clusters, for instance, represent ancient prosthetic groups found in nearly all organisms, underscoring their evolutionary conservation and fundamental role in sustaining .

Binding Mechanisms

Prosthetic groups bind to proteins through a variety of chemical interactions that ensure their stable integration, often rendering the association irreversible under physiological conditions. Covalent binding represents one primary mechanism, involving direct chemical bonds between the prosthetic group and specific residues in the protein. For instance, in c-type , the prosthetic group forms two thioether bonds between its vinyl groups and the sulfur atoms of residues within a CXXCH motif, stabilizing the complex during processes. Similarly, nucleotide-based prosthetic groups, such as 2'-(5''-phosphoribosyl)-3'-dephospho-CoA in the subunit of citrate lyase, attach via phosphodiester linkages to serine residues, facilitating transfer in metabolic pathways. Another example is , which covalently links to residues through an bond in the E2 subunits of 2-oxoacid complexes, enabling its role in redox reactions. Other covalent mechanisms include Schiff base formation, as in pyridoxal 5'-phosphate (PLP), where the aldehyde group of PLP reacts with the ε-amino group of a residue to form an linkage, essential for in enzymes like aspartate aminotransferase. In addition to covalent attachments, coordinate binding provides a tight, non-covalent mechanism, particularly for metal-containing prosthetic groups, where metal ions interact with atoms from protein side chains. This often involves coordination via or oxygen atoms, as seen in proteins where the iron atom forms a coordinate bond with the imidazole of a proximal residue, contributing to oxygen binding and transport in . Such interactions are strengthened by the dative nature of the bond, where the donates electrons to the metal center, resulting in high stability without full covalent character. The stability of these bindings is influenced by environmental factors such as , which can modulate states of coordinating residues; conditions, affecting the of metal ions or disulfide-containing groups; and protein conformation, which positions the precisely. These factors collectively ensure that dissociation is minimal during catalytic cycles, with high binding free energies (often 50-100 kJ/mol or more), far surpassing those of loosely associated cofactors and preventing loss under physiological stresses.

Versus Cofactors and Coenzymes

Cofactors represent a broad class of non-protein chemical entities essential for activity, serving as helpers that enable or enhance . These include both organic molecules, such as coenzymes derived from vitamins, and inorganic components like metal ions. Prosthetic groups form a specific subset of cofactors characterized by their tight, often covalent binding to the enzyme, distinguishing them from more loosely associated cofactors. In contrast, coenzymes are typically organic cofactors that act as transient carriers, diffusing between enzymes and undergoing repeated cycles of modification and regeneration, as exemplified by (NAD⁺), which shuttles electrons in reactions. The permanence of prosthetic groups contrasts sharply with the dynamic nature of coenzymes; while coenzymes bind reversibly and are released after facilitating a reaction, prosthetic groups remain integral to the structure throughout its functional lifecycle. This tight integration often results in the prosthetic group becoming a fixed component of the holoenzyme, the complete active form of the . For instance, metal ions like or magnesium may serve as loosely bound cofactors in hydrolases, whereas acts as a prosthetic group in and , permanently embedded to support oxygen transport or . Terminological ambiguities have persisted in biochemical literature, particularly regarding coenzymes that exhibit varying binding affinities. In some cases, organic coenzymes like are classified as prosthetic groups when they bind tightly and covalently in flavoproteins, such as , blurring the lines between transient coenzymes and permanent prosthetic groups. These inconsistencies stem from historical usage where the distinction depended on observed binding strength rather than a strict functional divide. From an evolutionary standpoint, prosthetic groups have enabled the development of specialized, efficient catalytic machinery within multi-subunit complexes, such as those in the respiratory chain. By providing stable, non-diffusible sites for reactions, they minimize intermediate loss and enhance overall metabolic flux, as evidenced in the modular of complex II enzymes like , where prosthetic groups like and iron-sulfur clusters integrate seamlessly across subunits.

Versus Apo- and Holoenzymes

Prosthetic groups are integral to the functional states of many proteins and enzymes, distinguishing between inactive and active forms. The protein component without its prosthetic group is termed the apoprotein (or apoenzyme in the case of enzymes), which typically lacks due to the absence of the essential non-protein moiety. For instance, in , the apoprotein cannot bind oxygen without its prosthetic group, rendering it incapable of oxygen transport. In contrast, the holoprotein (or holoenzyme) refers to the complete, functional unit comprising the apoprotein bound to its prosthetic group, which restores or enables full activity. This binary distinction highlights how prosthetic groups are not merely accessories but define the protein's operational capability. In settings, apoproteins are routinely isolated from holoproteins to study prosthetic group interactions and protein function. A common method involves extracting the prosthetic group, such as , using acid-acetone precipitation, which disrupts the heme-protein bonds without denaturing the apoprotein excessively. The resulting apoprotein can then be reconstituted with the prosthetic group to form the holoprotein, allowing researchers to investigate binding kinetics, structural changes, and functional restoration. This approach is particularly valuable for heme-containing proteins, where reconstitution confirms the prosthetic group's role in stabilizing the active conformation. Understanding the apo- and holo-states has significant implications for and biomedical applications. In , isolating apoproteins facilitates targeted modifications to the or scaffold, enabling the design of novel holoproteins with altered properties or substrate specificities, as seen in engineered hemoproteins for biocatalysis. Clinically, disruptions in prosthetic group incorporation, such as deficiencies, lead to apo-like states in proteins, contributing to disorders like congenital sideroblastic anemias, where impaired biosynthesis causes ineffective and . These insights underscore the prosthetic group's pivotal role in transitioning proteins from inert to functional forms.

Biological Functions

Catalytic Roles

Prosthetic groups play a pivotal in enzymatic by directly participating in the chemical transformations of substrates, often serving as transient carriers of reactive intermediates or equivalents within the . These tightly bound cofactors enable enzymes to achieve reaction rates far exceeding those of uncatalyzed processes, facilitating essential metabolic transformations through mechanisms such as shuttling, group transfer, and substrate activation. In , prosthetic groups like and (FMN) mediate between substrates and other cellular components. , containing an iron center, facilitates one-electron transfers in enzymes such as , where it cycles between Fe(III) and Fe(II) states to propagate electrons along the respiratory chain, and in monooxygenases, which use to activate molecular oxygen for substrate oxidation. Similarly, FMN acts as a redox mediator in flavoproteins, accepting and donating electrons via its isoalloxazine ring, which supports two-electron transfers critical for oxidative processes in various dehydrogenases and oxidases. A general representation of this process is: Oxidized prosthetic group+substrate (reduced)Reduced prosthetic group+substrate (oxidized)\text{Oxidized prosthetic group} + \text{substrate (reduced)} \rightleftharpoons \text{Reduced prosthetic group} + \text{substrate (oxidized)} This electron shuttling is fundamental to energy conservation in cellular respiration and photosynthesis, where prosthetic groups in complexes like cytochrome bc1 and b6f enable proton translocation and ATP synthesis. Prosthetic groups also catalyze group transfer reactions by temporarily binding and relocating functional moieties. For instance, biotin serves as a mobile carboxyl carrier in carboxylases, where it is first carboxylated at its ureido nitrogen using CO2 and ATP, then transfers the carboxyl group to acceptors like acetyl-CoA in fatty acid synthesis. In transaminases, pyridoxal phosphate (PLP) facilitates amino group transfer by forming a Schiff base with the substrate amino acid, enabling the exchange of the amino group with a keto group from an α-keto acid counterpart. In metalloenzymes, inorganic prosthetic groups such as Zn²⁺ directly activate substrates for or other reactions. In , the Zn²⁺ ion coordinates a to generate a nucleophilic that polarizes and attacks CO2, accelerating the hydration to by approximately 10⁶-fold compared to the uncatalyzed rate. These catalytic roles underscore the indispensability of prosthetic groups in core metabolic pathways, including respiration for ATP production and for carbon fixation.

Structural and Regulatory Roles

Prosthetic groups play crucial roles in maintaining the structural integrity of proteins beyond their catalytic functions. In , the prosthetic group stabilizes the native folding of subunits by facilitating the assembly of alpha-helical segments into the characteristic globin fold, which is essential for the protein's quaternary structure. Beyond , prosthetic groups enable transport functions in non-enzymatic proteins. The group in and reversibly binds oxygen, allowing these proteins to facilitate its transport from lungs to tissues while preventing oxidative damage through the hydrophobic environment provided by the globin chain. Prosthetic groups also serve as sensors in regulatory pathways. Heme acts as a regulatory prosthetic group in nitric oxide signaling by binding to the ferroheme in soluble guanylyl cyclase, triggering conformational changes that activate cyclic GMP production and vasodilation. In circadian rhythm regulation, heme binds to proteins like CLOCK and Rev-erbβ, modulating their interactions with DNA and influencing gene expression rhythms essential for metabolic homeostasis. In non-enzymatic proteins such as , the prosthetic group undergoes light-induced isomerization from 11-cis to all-trans, driving conformational changes in the protein that initiate visual in photoreceptor cells. Disruptions in prosthetic group integration, particularly , are linked to diseases. Mutations in enzymes of the heme biosynthetic pathway cause porphyrias, leading to accumulation of toxic intermediates and clinical manifestations like acute neurovisceral attacks due to impaired heme incorporation into proteins.

Types and Examples

Organic Prosthetic Groups

Organic prosthetic groups are tightly bound, non-protein organic molecules that are essential components of many enzymes and proteins, often derived from vitamins and playing critical roles in . These groups are distinguished by their carbon-based structures, which enable specific chemical reactivities, and their covalent or very tight non-covalent attachments to the protein moiety. Unlike inorganic prosthetic groups, which typically involve metal ions or clusters, organic ones frequently originate from dietary vitamins or endogenous synthesis pathways in organisms. One of the most prominent organic prosthetic groups is , a macrocycle consisting of four rings linked by methine bridges, with a central iron (Fe²⁺) atom coordinated to the atoms of the pyrroles. Heme is covalently bound via thioether linkages in some proteins or non-covalently associated in others, and it is found in , where it enables oxygen binding and transport, as well as in involved in during respiration. The iron in heme can switch between Fe²⁺ and Fe³⁺ oxidation states, facilitating reactions. Flavin mononucleotide (FMN) and are (vitamin B₂)-derived prosthetic groups characterized by an isoalloxazine ring system that undergoes reversible reduction and oxidation. FMN consists of the isoalloxazine ring linked to a phosphate group, while FAD features an additional moiety; both are often covalently bound to enzymes via or residues. These flavins serve as prosthetic groups in oxidoreductases, such as (which uses FAD) and (which incorporates FMN), enabling one- or two-electron transfer processes critical for metabolism. Approximately 75% of flavoproteins utilize FAD, with the remainder using FMN. Pyridoxal phosphate (PLP), the active form of B₆, features a pyridine ring with an aldehyde group at the 4' position and a phosphate ester at the 5' position, allowing it to form intermediates with amino groups. PLP is typically bound through non-covalent interactions, including hydrogen bonding and hydrophobic contacts, in the active sites of enzymes. It acts as a prosthetic group in aminotransferases, such as , where the aldehyde facilitates reactions by stabilizing intermediates during . PLP-dependent enzymes account for over 140 reactions across organisms, primarily in pathways, with approximately 50 in humans. Biotin, also known as vitamin H, is a with a ureido ring fused to a ring, attached to a . is covalently linked to a specific residue on enzymes via an amide bond formed by protein , creating a flexible "swinging arm" for substrate shuttling. As a in carboxylases like , mediates CO₂ transfer during and . The ureido ring's nitrogen atoms are key to its by . Thiamine pyrophosphate (TPP), derived from vitamin B₁ (), comprises a thiazolium ring linked to a ring and a group, with the thiazolium C2-H bond enabling nucleophilic formation. TPP is non-covalently but tightly bound in enzymes through interactions with the and heterocyclic rings. It functions as a prosthetic group in decarboxylases, such as , where it stabilizes intermediates during α-keto acid in energy metabolism. TPP's role is conserved across , reflecting its essentiality in . These organic prosthetic groups are predominantly derivatives, obtained through diet in animals or synthesized de novo in plants and microorganisms, underscoring their biochemical universality. Examples like , flavins, PLP, , and TPP illustrate how organic structures provide versatile reactivity while remaining stably integrated into protein frameworks.

Inorganic Prosthetic Groups

Inorganic prosthetic groups consist of metal ions or clusters that are covalently or tightly bound to proteins, enabling essential functions such as and through their unique coordination chemistry. These groups, often involving transition metals, are integral to the active sites of enzymes and are particularly prevalent in processes requiring activity or Lewis acid assistance. Unlike organic prosthetic groups, which rely on carbon-based frameworks, inorganic ones emphasize elemental metal centers and their ligands from protein residues like or . Iron-sulfur ([Fe-S]) clusters represent a prominent class of inorganic prosthetic groups, featuring iron atoms bridged by ions and coordinated by residues. In , [2Fe-2S] clusters, typically ligated by four cysteines, facilitate low-potential with reduction potentials ranging from -500 to -150 mV, supporting processes like and cofactor . Similarly, [4Fe-4S] clusters in and nitrogenases, coordinated by motifs such as Cys-X₂-Cys-X₂-Cys-Xₙ-Cys, enable electron shuttling from -650 to -250 mV, crucial for in anaerobic diazotrophs where electrons reduce N₂ to NH₃ via the enzyme's P-cluster. These clusters' cubane-like structures allow reversible Fe³⁺/Fe²⁺ cycling, underscoring their role in ancient metabolic pathways. The iron atom in serves as a key inorganic prosthetic component, embedded at the center of a ring and coordinated by four nitrogen atoms from the , with axial ligands often provided by protein histidines. This octahedral coordination enables the Fe²⁺/Fe³⁺ couple, facilitating oxygen binding in and or in cytochromes, where the metal's d-orbital overlap with ligands tunes reactivity. In hemoproteins, the central Fe coordination minimizes reorganization energy during events, enhancing efficiency in mitochondrial respiration. Zinc ions function as inorganic prosthetic groups in enzymes like (ADH) and (CA), adopting tetrahedral coordination geometries that polarize substrates. In ADH, the catalytic Zn²⁺ is bound by two cysteines, one , and a molecule, stabilizing the entatic state for hydride transfer during , while a structural Zn²⁺ with four cysteines maintains . In CA, Zn²⁺ coordinates three s (His94, His96, His119) and a , acting as a Lewis acid to lower the pKₐ of bound to ~7, generating nucleophilic for CO₂ hydration to . This coordination enhances catalytic rates up to 10⁶ s⁻¹, vital for pH regulation and respiration. Copper centers in proteins exemplify inorganic prosthetic groups for chemistry, classified as type I (blue ) or type II sites. Type I Cu in blue proteins like features a distorted tetrahedral geometry with two histidines, one , and one , enabling rapid outer-sphere with minimal structural change between Cu(I) and Cu(II) states (potentials ~+200 to +800 mV). Type II Cu in coordinates three histidines and a /, forming the Cu_B site that couples with a₃ for O₂ reduction to , driving proton pumping in aerobic respiration. These sites' ligand fields optimize potentials for efficient electron flow. Molybdenum acts as an inorganic prosthetic group in xanthine oxidase, where it coordinates a hybrid molybdopterin cofactor via dithiolene sulfurs from the pterin ring, plus an oxo, sulfido, and hydroxo in a distorted square-pyramidal geometry. This setup facilitates oxygen atom transfer, reducing Mo(VI) to Mo(IV) during purine (e.g., xanthine to urate), with electrons relayed through [Fe-S] clusters and . The Mo-pterin hybrid enhances substrate specificity and catalytic turnover (~10 s⁻¹), essential for purine . These inorganic prosthetic groups predominantly enable —such as Zn²⁺ polarizing substrates—or reactions via variable oxidation states, with [Fe-S] clusters particularly abundant in anaerobic due to their evolutionary antiquity. For instance, [Fe-S]-dependent enzymes like nitrogenases and hydrogenases underpin ancient pathways in oxygen-free environments, facilitating in microbial biogeochemical cycles such as and H₂ production. Their prevalence reflects an early geochemical role in prebiotic chemistry.

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