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Elongation factor

Elongation factors are a family of GTP-binding proteins essential for the phase of protein synthesis, where they facilitate the accurate and efficient addition of to the nascent polypeptide chain on the . These factors operate during , the process by which (mRNA) is decoded to produce proteins, by assisting in key steps such as aminoacyl-tRNA delivery to the ribosomal A-site, peptide bond formation, and translocation of the tRNA-mRNA complex. Highly conserved across prokaryotes and eukaryotes, elongation factors ensure translational fidelity and speed, with disruptions linked to cellular responses and diseases including cancer and neurodegeneration. Elongation factors were first identified in the 1960s through studies of protein mechanisms in bacterial cell-free systems, with key prokaryotic factors such as EF-Tu, EF-Ts, and isolated around 1964. Their eukaryotic counterparts, including eEF1A, eEF1B, and , were subsequently characterized, showing structural and functional . Additional specialized factors exist, such as EF-P and EF4 in prokaryotes, and eIF5A and eEF3 (in fungi) in eukaryotes.

Introduction

Definition and General Role

Elongation factors are a class of GTP-binding proteins essential for the stage of protein , where they facilitate the accurate and efficient addition of to the growing polypeptide chain. These factors play critical roles in (aa-tRNA) selection, proofreading to ensure fidelity, and ribosomal translocation, enabling the to move along the mRNA template. By hydrolyzing GTP, elongation factors drive conformational changes in the and associated tRNAs, ensuring the process proceeds rapidly and with high accuracy. The cycle comprises three main steps: decoding, peptidyl transfer, and translocation. During decoding, an delivers the cognate aa-tRNA to the ribosomal A-site in a codon-dependent manner, followed by to reject non-matching tRNAs. Peptidyl transfer then occurs, where the 's center catalyzes the formation of a between the incoming and the nascent chain. Finally, translocation shifts the tRNAs and mRNA by one codon, moving the peptidyl-tRNA to the and the deacylated tRNA to the E-site, priming the for the next . This repetitive process distinguishes from initiation factors, which assemble the ribosomal complex at the , and termination factors, which recognize stop codons and release the completed polypeptide. In , the phase sustains a high throughput, incorporating approximately 15-20 per second under optimal conditions, underscoring the of these factors in protein . All elongation factors share conserved structural motifs, notably the G-domain, a module that binds GTP and coordinates its to power the cycle's kinetic steps. Prokaryotic and eukaryotic variants, such as EF-Tu and eEF1A, respectively, perform analogous functions but with organism-specific adaptations.

Historical Discovery

The discovery of elongation factors emerged from pioneering studies on bacterial protein synthesis in the , revealing soluble components essential for polypeptide chain elongation beyond initiation and termination. In 1964, Yoshito Nishizuka and Fritz Lipmann identified a GTP-hydrolyzing 'G factor' in extracts that promoted the elongation phase in cell-free systems, marking the first recognition of a dedicated now known as . Subsequent work in 1966 by Joan Lucas-Lenard and Lipmann fractionated a 'T factor' from E. coli into two complementary components required for binding to ribosomes, distinguished by differential heat sensitivity: the thermo-unstable fraction and the thermo-stable Ts fraction. This separation highlighted their distinct roles, with facilitating GTP-dependent tRNA delivery and Ts promoting nucleotide exchange. In 1968, John Gordon formalized the as EF-Tu and EF-Ts, emphasizing their thermal properties during purification and confirming EF-Tu's involvement in forming a stable GTP complex with . Herbert Weissbach and colleagues further advanced characterization in 1967 by demonstrating these soluble factors' necessity in E. coli extracts for efficient chain elongation in poly(U)-directed assays. During the 1970s, refined systems elucidated the mechanistic contributions of these factors. Experiments showed EF-Tu's role in GTP-dependent binding to the ribosomal A-site, forming a ternary complex that ensured accurate codon recognition before triggered . Similarly, assays demonstrated EF-G's GTP-fueled translocation of peptidyl-tRNA from the A- to , advancing the mRNA and freeing the A-site for the next cycle. Parallel investigations transitioned to eukaryotic systems in the early , with Boyd Hardesty and Schweet isolating TF-1 and TF-2 from reticulocytes as GTP-requiring factors for tRNA binding and translocation, respectively, in synthesis assays. By the 1980s, these were redesignated eEF1 (encompassing eEF1A for tRNA delivery and eEF1B for exchange) and (for translocation) in mammalian studies, with cloning efforts confirming their structural homology to prokaryotic counterparts and roles in cytoplasmic .

Prokaryotic Elongation Factors

EF-Tu: Aminoacyl-tRNA Delivery

Elongation factor Tu (EF-Tu) is a multidomain essential for delivering (aa-tRNA) to the ribosomal A-site during prokaryotic protein synthesis. Structurally, EF-Tu comprises three domains: domain I, the GTP-binding G domain with conserved motifs G1 (P-loop) through G5 that coordinate the and Mg²⁺; domain II, a β-barrel structure; and domain III, an α-helical bundle. These domains undergo conformational changes upon GTP binding, adopting a compact active state that enables ternary complex formation. In the GTP-bound conformation, EF-Tu binds GTP and aa-tRNA to form the ternary EF-Tu·GTP·aa-tRNA, where EF-Tu interacts primarily with the acceptor and T-arm of aa-tRNA, stabilizing it for delivery while protecting the ester bond from . The of this reveals that EF-Tu clamps the tRNA acceptor end, positioning the anticodon for ribosomal without to the anticodon loop. This binds diffusively to the , entering the A-site in an initial, low-affinity state. Upon codon-anticodon base-pairing in the ribosomal decoding center, domain II of EF-Tu rearranges, aligning the sarcin-ricin loop of 23S rRNA to catalyze GTP hydrolysis. This hydrolysis triggers a conformational shift in EF-Tu to its inactive GDP-bound form, releasing aa-tRNA for peptidyl transfer and preventing non-cognate tRNAs from proceeding. The process incorporates kinetic proofreading through two fidelity checkpoints: initial selection, where mismatched codon-anticodon pairs dissociate rapidly, and GTPase activation, where hydrolysis is codon-dependent, enhancing accuracy. The kinetics of ternary complex formation are rapid, with an association rate constant (k_on) of approximately 6 × 10⁷ M⁻¹ s⁻¹ and rates of 20–25 s⁻¹ under physiological conditions, ensuring efficient aa-tRNA without rate-limiting the cycle. These parameters, combined with accelerated of near-cognate complexes post-GTP , reduce mistranslation errors to about 10⁻⁴ via kinetic , far below the binding error rate of 10⁻².95483-9/fulltext) Beyond translation, EF-Tu displays chaperone-like activity in certain , such as , where it binds unfolded or misfolded proteins, preventing aggregation and promoting refolding in an ATP-independent manner, particularly under heat stress. This accessory function leverages EF-Tu's high cellular abundance and nucleotide-dependent conformational flexibility.

EF-Ts: GTP Exchange Factor

EF-Ts serves as the (GEF) for EF-Tu in prokaryotic , facilitating the release of GDP from the inactive EF-Tu·GDP complex following GTP on the . This regeneration step is essential for recycling EF-Tu, enabling it to bind GTP and form the active EF-Tu·GTP· ternary complex for the next round of delivery. By accelerating the intrinsically slow GDP dissociation from EF-Tu, EF-Ts ensures efficient progression of the cycle without direct energy input, indirectly conserving the energy from prior GTP hydrolysis events. Structurally, EF-Ts is a monomeric protein in many bacteria, such as and , consisting of three domains that enable binding to EF-Tu·GDP and formation of a stable heterodimeric EF-Ts·EF-Tu·GDP complex. In contrast, in thermophilic bacteria like Thermus thermophilus, EF-Ts functions as a homodimer, where each subunit interacts with an EF-Tu molecule to form a heterotetrameric complex, providing enhanced stability under high-temperature conditions. The core-binding domain of EF-Ts mimics the switch regions of EF-Tu, allowing precise docking at the G-domain interface to disrupt nucleotide interactions. The mechanism of nucleotide exchange involves EF-Ts binding to the EF-Tu·GDP complex, which induces a conformational change that opens EF-Tu's nucleotide-binding pocket by displacing key switch I and II regions and flipping a peptide to sterically eject GDP. This dramatically accelerates the GDP dissociation rate by approximately 6 × 10⁴-fold compared to the spontaneous rate, while also enhancing GTP off-rate by about 3 × 10³-fold to allow rapid reloading with GTP. Once GTP binds, EF-Ts dissociates, yielding active EF-Tu·GTP ready for ternary complex assembly, thus integrating seamlessly into the elongation cycle after ribosomal release of EF-Tu·GDP. These variations in oligomeric state across prokaryotes reflect adaptations to environmental stresses, yet the core exchange mechanism remains conserved for translational fidelity.

EF-G: Translocation Mechanism

, or elongation factor G, is a multidomain essential for the translocation step in prokaryotic protein synthesis. It consists of five structural domains: domains I and II form the GTP-binding core, akin to other translational GTPases, while domain III connects to domain IV, which structurally resembles the anticodon stem-loop of a tRNA, and domain V interacts with the ribosomal stalk. This domain IV mimicry allows to occupy a position overlapping the A-site tRNA, facilitating displacement during movement. Following formation, the ribosome enters a pretranslocation state with peptidyl-tRNA in the A site and deacylated tRNA in the . bound to GTP then associates with this stalled complex near the A site, promoting the formation of tRNA positions: the peptidyl-tRNA shifts to an A/P (body in P site, anticodon in A site), and the deacylated tRNA to a P/E . GTP hydrolysis by , catalyzed upon ribosomal activation, powers a conformational change that drives the coupled movement of the mRNA and tRNAs, advancing the mRNA by three nucleotides and relocating the peptidyl-tRNA fully to the while ejecting the deacylated tRNA from the E site. This process is accelerated up to 30-fold by GTP hydrolysis compared to spontaneous translocation. The fidelity of translocation is maintained through precise timing of GTP , which prevents premature EF-G dissociation and ensures complete tRNA-mRNA shifting before the next elongation cycle. The ribosome's intersubunit ratcheting—rotation of the subunit relative to the 50S—occurs in the pretranslocation state but is locked until hydrolysis unlocks the complex, avoiding errors in reading frame advancement. Without hydrolysis, EF-G remains bound, blocking subsequent rounds of translocation and enforcing accuracy. Fusidic acid, a natural , inhibits by binding at the interface between domains I and III on the -associated factor, stabilizing the GDP-bound post- conformation and preventing release from the . This locks the translocation machinery, halting protein synthesis in sensitive without affecting GTP itself.

Eukaryotic Factors

eEF1A: Aminoacyl-tRNA Binding

eEF1A is a highly conserved GTPase in eukaryotes, characterized by three major structural domains that enable its multifaceted roles in translation. Domain I, spanning the N-terminal region, contains the GTP/GDP-binding pocket and exhibits GTPase activity essential for conformational changes during the translation cycle. Domain II, primarily a β-sheet structure, is crucial for binding aminoacyl-tRNA (aa-tRNA), while Domain III adopts an actin-like fold with antiparallel β-sheets, facilitating interactions with both tRNA and the cytoskeleton. In its GTP-bound conformation, eEF1A forms a stable ternary complex with GTP and aa-tRNA (eEF1A·GTP·aa-tRNA), which positions the anticodon of aa-tRNA for decoding at the ribosomal A-site. The primary mechanism of eEF1A involves delivering the ternary complex to the A-site of the eukaryotic 80S ribosome, where codon-anticodon recognition induces a ribosomal conformational change that stimulates GTP hydrolysis. This hydrolysis, catalyzed by the ribosomal GTPase-activating center, converts eEF1A to its inactive GDP-bound form, promoting eEF1A dissociation and subsequent accommodation of aa-tRNA into the peptidyl transferase center for peptide bond formation. The process incorporates kinetic proofreading, akin to that in prokaryotic EF-Tu, with initial selection rejecting non-cognate tRNAs followed by a proofreading step after GTP hydrolysis but before accommodation, ensuring translational fidelity; however, eukaryotic eEF1A exhibits slower overall kinetics compared to EF-Tu, with a turnover rate (k_cat ≈ 10 s⁻¹) adapted to the more complex cytoplasmic environment. Beyond translation, eEF1A interacts with the in the , binding and bundling F-actin filaments primarily through Domains II and III, which sequesters eEF1A from its ternary complex formation and may regulate localized near cytoskeletal structures. This actin-binding capability allows eEF1A to coordinate protein synthesis with cellular architecture, such as directing translation at sites of actin remodeling in motile cells or neuronal processes, thereby supporting spatially restricted proteome assembly. The eEF1B disrupts these actin interactions to prioritize translational activity. Eukaryotes express multiple isoforms of eEF1A, notably eEF1A1 and eEF1A2, which share over 90% sequence identity but display distinct tissue-specific expression patterns. eEF1A1 is ubiquitously expressed across most tissues, supporting general translational demands, whereas eEF1A2 is predominantly found in post-mitotic tissues like , , and neurons, where it contributes to specialized functions such as maintaining high-fidelity translation in energy-demanding cells. Dysregulated expression of these isoforms, particularly eEF1A2 overexpression, has been linked to cellular stress responses and , underscoring their adapted roles in eukaryotic .

eEF1B: Nucleotide Exchange Complex

The eEF1B complex is a heterotrimeric guanine nucleotide exchange factor (GEF) in eukaryotes, composed of the subunits eEF1Bα, eEF1Bβ, and eEF1Bγ, which collectively recycle eEF1A by exchanging GDP for GTP during translation elongation. The catalytic activity resides primarily in eEF1Bα, which directly interacts with eEF1A to promote nucleotide exchange, while eEF1Bβ and eEF1Bγ serve as accessory GEF components that enhance efficiency and provide structural scaffolding. In metazoans, an additional subunit eEF1Bδ may contribute GEF function in certain contexts, underscoring the complex's modular nature. The nucleotide exchange mechanism proceeds sequentially: eEF1Bβ initially accelerates the of GDP from the inactive eEF1A·GDP complex, destabilizing the nucleotide-binding site, after which eEF1Bα facilitates GTP loading to form the active eEF1A·GTP state capable of binding . This process overcomes the intrinsically slow spontaneous GDP release rate from eEF1A (with an equilibrium constant of approximately 10 × 10⁻⁷ M), providing a rate enhancement of several hundred-fold through eEF1Bα alone and further amplification by the full complex. Structural studies reveal that a C-terminal in eEF1Bα inserts into eEF1A's switch II region, reorganizing it to eject GDP and enable GTP binding. Regulation of eEF1B activity occurs via post-translational modifications, notably phosphorylation of eEF1Bβ by (PKC), which boosts GEF function and overall translation elongation rates by two- to three-fold. This integrates eEF1B into cellular stress responses, such as , where modulated activity helps adjust protein synthesis under adverse conditions. Evolutionarily, the multi-subunit architecture of eEF1B represents an elaboration over the monomeric prokaryotic EF-Ts, enabling tighter coupling with eukaryotic signaling networks that regulate in response to environmental cues and cellular demands.

eEF2: Ribosomal Translocation

Eukaryotic elongation factor 2 () is a highly conserved essential for the translocation step in protein synthesis on the . Structurally, consists of six domains, with the N-terminal G domain responsible for GTP binding and , and domain IV featuring a tRNA-mimicry loop that interacts with the ribosomal decoding center. A unique , diphthamide, occurs at 715 (His715) in the tip of domain IV, which is critical for ribosome-stimulated GTPase activation and ensuring translational fidelity. This modification enables to mimic the anticodon loop of tRNA, facilitating precise positioning during translocation. Following formation in the preceding decoding step mediated by eEF1A, ·GTP binds to the post-peptidyl transfer , where it stabilizes the rotated, state of the -tRNA-mRNA complex. Upon binding, catalyzes the ratcheting of the subunit relative to the 60S subunit, driving the unidirectional movement of the peptidyl-tRNA from the A site to the and the deacylated tRNA from the to the E site, while advancing the mRNA by one codon. GTP hydrolysis by provides the energy for this conformational change and unlocks the tRNA-mRNA complex from the decoding center, completing translocation before ·GDP release. eEF2 activity is tightly regulated by phosphorylation at threonine 56 (Thr56) by eEF2 kinase (eEF2K), which reduces eEF2's affinity for the ribosome and inhibits translocation. This phosphorylation is activated under cellular stress conditions, such as nutrient deprivation, where eEF2K helps conserve energy by slowing global protein synthesis and promoting cell survival. In addition to physiological regulation, eEF2 is targeted by bacterial toxins that modify diphthamide via ADP-ribosylation, such as diphtheria toxin from Corynebacterium diphtheriae, which transfers an ADP-ribose from NAD^+ to His715, thereby inactivating eEF2 and blocking ribosomal translocation to halt host protein synthesis. This modification prevents GTPase activation and traps eEF2 on the ribosome, leading to translational arrest and cell death.

Nomenclature and Evolutionary Aspects

Naming Conventions for Homologs

In prokaryotes, the primary elongation factors are designated EF-Tu, EF-Ts, and , reflecting their early characterization based on thermal stability and functional roles. EF-Tu, or elongation factor thermo-unstable, facilitates the delivery of to the , while EF-Ts, the thermo-stable factor, serves as its nucleotide exchange partner, and EF-G, the G-factor, promotes ribosomal translocation. These names originated from biochemical studies in the mid-20th century and have been widely used in the literature since. In phylogenetic and database contexts, such as , prokaryotic EF-Tu is classified under the EF1A family, EF-Ts under EF1B, and EF-G under EF2 to highlight with eukaryotic counterparts, though traditional names remain standard in prokaryotic studies and facilitate and structural analyses. In eukaryotes, the employs an "e" prefix to distinguish from prokaryotic forms: eEF1A (previously known as EF-1α) handles binding, eEF1B denotes the nucleotide exchange complex (formerly the EF-1βγδ subunits), and corresponds to the translocation factor (formerly EF-2). These terms were formalized in 1988 recommendations by the Nomenclature Committee of the International Union of Biochemistry, emphasizing functional while specifying eukaryotic context. The Human Genome Organisation (HUGO) further refined gene-level naming post-2000, approving symbols such as EEF1A1 for the primary eEF1A isoform and for the translocation factor, ensuring consistency in human genomics databases. Archaea exhibit a hybrid , with factors typically named as homologs of eukaryotic EF1A and EF2 due to closer phylogenetic relations, though prokaryotic-style designations appear in some contexts. Universal standardization occurs through databases like , which employs species-specific entries such as EFTU_ECOLI for bacterial EF-Tu and analogous formats like TUF_ARCFU for the Archaeoglobus fulgidus EF1A homolog, promoting interoperability across microbial genomes.

Structural and Functional Homology

Elongation factors across prokaryotes, , and eukaryotes share a core domain characterized by the conserved G1–G4 s, which are essential for binding and . The G1 (P-loop) interacts directly with the groups of GTP, while G3 and G4 stabilize the through magnesium coordination and bonding, respectively; G2 contributes to the overall fold. This domain exhibits approximately 30–50% sequence identity between prokaryotic factors like EF-Tu and EF-G and their eukaryotic counterparts eEF1A and eEF2, underscoring their ancient origin from the (). Functionally, prokaryotic EF-Tu parallels eukaryotic eEF1A in delivering to the ribosomal A-site in a GTP-dependent manner, while mirrors in catalyzing ribosomal translocation post-peptide bond formation. These parallels reflect conserved mechanisms for ensuring and . However, divergences arise in accessory s; for instance, eEF1A features unique zinc-binding sites in its C-terminal domain III, coordinated by residues and absent in EF-Tu, which may contribute to eukaryotic-specific interactions with the translation machinery. Similarly, includes additional structural elements, such as domain IV extensions, that accommodate eukaryotic ribosomal features not present in prokaryotes. Phylogenetic analyses reveal bacterial origins for elongation factors, with archaeal and eukaryotic lineages branching from a common prokaryotic ancestor near , as evidenced by in GTPase cores and co-evolution with ribosomal components. This branching is supported by molecular phylogenies in which bacterial branches basally relative to the archaeal aEF2 and eukaryotic , yet all sharing ribosomal interaction surfaces that have co-evolved to match expansion in eukaryotes. Such co-evolution is apparent in the synchronized divergence of factor domains and expansions across domains of life. Crystal structures further illuminate this , particularly the shared switch I and II regions in the GTPase , which undergo conformational changes upon GTP binding to activate . For example, the of EF-Tu in complex with Phe-tRNA and GDPNP (PDB: 1TTT) reveals switch I (residues ~40–55) forming a that stabilizes GTP, a feature conserved in eukaryotic eEF1A structures and essential for GTPase activation during . These regions enable allosteric communication between the factor and , a preserved despite domain divergences.

Regulation and Additional Functions

Regulatory Mechanisms

Elongation factors operate within a precisely controlled cycle that acts as an intrinsic timer for fidelity and speed. In prokaryotes, EF-Tu binds GTP and (aa-tRNA) to form a ternary complex, where the intrinsic GTP rate is exceedingly slow, on the order of minutes, ensuring stable delivery to the ribosomal A-site only upon codon recognition. The then catalyzes GTP by EF-Tu at rates accelerated by over 10,000-fold through interactions with the sarcin-ricin loop () of 23S rRNA, promoting aa-tRNA accommodation and preventing erroneous decoding. Similarly, EF-G's activity during translocation is intrinsically low but -stimulated upon binding to the post-peptidyl transfer state, facilitating tRNA-mRNA movement with rates enhanced up to 300-fold. Eukaryotic homologs eEF1A and follow analogous cycles, with -induced acceleration ensuring coordinated in the more complex environment. Post-translational modifications provide additional layers of regulation to elongation factors, modulating their activity in response to cellular needs. In eukaryotes, phosphorylation of at 56 by (eEF2K) under hypoxic conditions inactivates eEF2, slowing translocation to prioritize during oxygen limitation; this modification is reversed upon reoxygenation to restore elongation. Prokaryotic EF-Tu undergoes N-terminal by the RimI acetyltransferase, which fine-tunes its activation and complex dynamics without impacting protein stability, thereby influencing efficiency during aa-tRNA selection. These modifications integrate elongation control with broader metabolic states, ensuring adaptability without disrupting core timing. Environmental signals directly impinge on elongation factors to align with nutrient status. In , the stringent response alarmones (p)ppGpp, produced by upon amino acid starvation, inhibit EF-Tu by impairing ternary complex formation and reducing its affinity for GTP, thereby decelerating and reallocating resources from growth to survival. In eukaryotes, nutrient abundance activates the pathway, which phosphorylates eEF1 subunits—such as eEF1B via mTORC1-dependent —to enhance exchange and ternary complex recycling, boosting overall rates under favorable conditions. These mechanisms allow cells to sense and respond to extracellular cues, preventing wasteful during stress. Feedback loops involving aa-tRNA availability further regulate elongation factor engagement to match codon-specific demands and prevent ribosomal stalling. When charged tRNA levels drop for rare codons, EF-Tu/eEF1A ternary complex formation slows, creating pauses that signal upstream adjustments in tRNA charging and synthetase activity, thereby balancing elongation speed with proteome-wide codon usage biases. This adaptive modulation ensures efficient decoding of optimal codons while triggering for suboptimal ones, maintaining translational accuracy across varying amino acid supplies. As of 2025, ongoing research highlights potential new regulatory roles, such as novel inhibitors of eEF2K for therapeutic applications in cancer and neurodegeneration, emphasizing the continued relevance of elongation factor modulation in disease contexts.

Non-Canonical Roles

Elongation factors exhibit diverse moonlighting functions beyond their primary roles in protein synthesis. In bacteria, EF-Tu acts as a molecular chaperone during heat shock, binding to unfolded proteins to prevent their aggregation and promote proper folding, as demonstrated with citrate synthase and α-glucosidase under thermal stress conditions. The eukaryotic homolog eEF1A shares similar chaperone-like properties, interacting with nascent polypeptides to assist in their stabilization and folding. eEF1A also facilitates by directly interacting with viral components. In HIV-1 infection, eEF1A binds to the polyprotein (Pr55Gag), enhancing viral particle assembly and genome packaging, which is essential for efficient reverse transcription and progeny virus production. This interaction underscores eEF1A's role in host machinery for pathogen propagation. eEF2 participates in cellular stress responses through its , eEF2K. Under , of eEF2 by eEF2K inhibits global while promoting autophagosome formation, thereby enhancing cell survival by conserving energy and recycling cellular components. This dual regulation positions eEF2K as a key integrator of translation shutdown and autophagy activation during metabolic stress. Cytoskeletal dynamics represent another arena for elongation factor involvement. eEF1A binds and bundles filaments, modulating formation and in a Rho/Rho kinase-dependent manner, independent of its GTPase activity in . This function links translation machinery to , influencing processes like . In mitochondria, EF-G homologs such as mtEF-G2 contribute to by facilitating recycling after termination, preventing accumulation of stalled mitoribosomes and ensuring of respiratory chain components. mtEF-G1 supports translocation , indirectly aiding in the resolution of errors. Recent studies highlight eEF1A's emerging role in RNA granule assembly during stress. Post-2020 research shows eEF1A associates with defective ribosomal products and incorporates into , where it helps sequester translationally silenced mRNAs under oxidative or thermal , facilitating adaptive translational reprogramming. In bacterial infection models like , ADP-ribosylation of eEF1A triggers formation, linking elongation factor modification to host antiviral and stress responses.

Therapeutic and Clinical Relevance

As Targets for Therapeutics

Elongation factors have been exploited as targets for antibacterial antibiotics, particularly in prokaryotes. Kirromycin, a natural product antibiotic, targets bacterial EF-Tu by binding at the interface between domains 1 and 2, stabilizing the GTP-bound conformation even after GTP hydrolysis to GDP, thereby preventing the release of EF-Tu from the ribosome and inhibiting the delivery of aminoacyl-tRNA. Similarly, fusidic acid inhibits bacterial EF-G by trapping it on the ribosome in the post-hydrolysis state during translocation, blocking the factor's dissociation and halting protein synthesis elongation. These mechanisms demonstrate how antibiotics can specifically disrupt elongation factor dynamics to impair bacterial translation without affecting host machinery. In eukaryotes, elongation factors are targeted by inhibitors aimed at cancer , particularly through modulation of responses. eEF2 (eEF2K) inhibitors, such as NH125, block the of eEF2, which normally inactivates eEF2 under cellular to reduce ; by preventing this inactivation, these compounds can dysregulate protein synthesis in cancer cells, leading to under nutrient deprivation or . NH125 exhibits anticancer activity in models of and by altering eEF2 dynamics, though its precise cellular mechanism involves both direct inhibition and potential off-target effects. Developing selective inhibitors for elongation factors poses significant challenges due to structural similarities between prokaryotic and eukaryotic homologs, necessitating strategies that exploit unique features. For instance, achieves specificity by ADP-ribosylating exclusively at the diphthamide residue, a absent in prokaryotes and essential for toxin recognition, thereby inactivating only eukaryotic and halting . This highlights the potential for broad-spectrum inhibitors versus targeted ones, where fungal-specific elements like eEF3 could enable selectivity in design. Recent in the has explored small molecules targeting factors for applications, building on the essential role of eEF1A in fungal protein . While specific eEF1A inhibitors remain emerging, related efforts focus on fungal-unique components, such as derivatives of sordarins that inhibit eEF2 translocation in and species with low values (e.g., 0.016–0.5 μg/mL), demonstrating potent activity and low mammalian . As of 2025, ongoing research has advanced eEF2K inhibitors for cancers like pancreatic ductal and small-molecule inhibitors targeting eEF1A to suppress tumor growth via diverse pathways.

Implications in Disease

Dysregulation of elongation factors has been implicated in various cancers, particularly through overexpression that drives aberrant protein synthesis and . In gastrointestinal cancers, elevated levels of promote progression at the G2/M phase and enhance tumorigenicity by facilitating unchecked growth. Similarly, genetic amplification of the EEF1A2 gene occurs in approximately 25% of primary ovarian tumors, leading to overexpression that transforms normal cells and accelerates tumor development. In neurological disorders, hyperactivity of eEF2 kinase (eEF2K) contributes to synaptic dysfunction by increasing of , which impairs local mRNA translation essential for and neuronal . This mechanism is particularly relevant in , where elevated eEF2 disrupts synaptic protein synthesis and exacerbates cognitive decline. Defects in diphthamide modification of , a critical post-translational change, also underlie neurodevelopmental disorders; diphthamide deficiency enhances eEF2 association with , inducing p21 expression and causing defects that manifest as profound developmental delays and lethality. In infectious diseases, EF-Tu serves as a target for antibiotics in , with resistance mechanisms involving mistranslation and ribosomal adaptations promoting persistence under drug pressure. Recent research highlights eEF1A's role in and metabolic disturbances. The (NSP12) of hijacks eEF1A to modulate host mRNA translation efficiency, favoring viral protein production and exacerbating infection severity. In metabolic syndromes, eEF1A1 dysregulation promotes by mediating oxidative and stress in response to elevated free fatty acids, contributing to lipid accumulation and organ damage in conditions like non-alcoholic .

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