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Nucleotide excision repair

Nucleotide excision repair (NER) is a highly conserved DNA repair pathway present in all domains of life that removes a wide range of bulky, helix-distorting DNA lesions, such as cyclobutane pyrimidine dimers and 6-4 photoproducts induced by ultraviolet (UV) radiation, as well as adducts from environmental toxins like cisplatin and oxidative damages. This versatile mechanism operates by recognizing the damage, excising a short oligonucleotide segment containing the lesion (typically 24–32 nucleotides in eukaryotes), and resynthesizing the DNA gap through polymerase activity followed by ligation, thereby maintaining genomic stability and preventing mutations that could lead to cancer or other diseases. NER is essential for cellular survival, as defects in this pathway result in hypersensitivity to DNA-damaging agents and are linked to human disorders including xeroderma pigmentosum (XP), Cockayne syndrome (CS), and trichothiodystrophy (TTD), which manifest as increased skin cancer risk, neurodegeneration, and developmental abnormalities. The NER process is divided into two main subpathways: global genome NER (GG-NER), which scans and repairs s throughout the entire genome, and transcription-coupled NER (TC-NER), which prioritizes repair of the transcribed strand in actively expressed genes to quickly resume transcription. In GG-NER, damage recognition primarily involves the XPC-RAD23B-CETN2 complex, which detects thermodynamic destabilization of the DNA helix, often aided by UV-DDB (DDB1-DDB2) for certain s like UV photoproducts. TC-NER, in contrast, is triggered by stalling at a , recruiting factors like CSB (ERCC6) and (ERCC8) to facilitate repair, ensuring that essential genes are protected from prolonged transcriptional blocks. Both subpathways converge at a core repair machinery that includes the TFIIH complex (with XPB and XPD helicases for DNA unwinding), XPA and RPA for damage verification and scaffolding, and the endonucleases XPG and XPF-ERCC1 for dual incisions flanking the . Evolutionarily, NER exemplifies a "cut-and-paste" strategy adapted across , , and eukaryotes, with eukaryotic systems featuring more complex protein networks to handle diverse lesions while coordinating with transcription and replication. In humans, the pathway's efficiency is highlighted by its ability to excise lesions with , but impairments—often due to mutations in the seven XP complementation groups (XPA–XPG) or the XP variant, or related genes—severely compromise repair, leading to a >1,000-fold increased risk of UV-induced skin cancers in XP patients. Ongoing research using techniques like excision repair sequencing (XR-seq) has mapped NER activity genome-wide, revealing strand biases and repair hotspots that underscore its role in preventing and supporting organismal health.

Overview

Definition and process summary

Nucleotide excision repair (NER) is a versatile DNA repair pathway that excises and replaces short single-stranded DNA segments containing bulky, helix-distorting lesions, such as those induced by ultraviolet (UV) radiation or chemical agents. This mechanism is crucial for maintaining genomic integrity by targeting a broad spectrum of structurally diverse DNA damages that distort the double helix and impede normal cellular processes like transcription and replication. The general process of NER begins with the recognition of the damaged site, followed by dual incisions on both sides of the to excise a short containing the damage—typically 24-32 long in eukaryotes and 12-13 in prokaryotes. The resulting single-stranded gap is then filled by using the undamaged complementary strand as a template, and the repair is completed by to seal the nick. In prokaryotes, damage recognition often involves Uvr proteins, while in eukaryotes, it can occur via XPC complexes for global repair or stalling for transcription-coupled repair. NER is evolutionarily conserved across all domains of life—bacteria, archaea, and eukaryotes—highlighting its fundamental role in protecting genomes from environmental and endogenous threats. It is essential for removing UV-induced photoproducts like cyclobutane pyrimidine dimers, chemical adducts, and other bulky lesions that would otherwise lead to high mutation rates or cell death if unrepaired. Defects in NER components result in persistent DNA damage, elevated mutagenesis, and cytotoxicity, underscoring its necessity for cellular viability and organismal survival. The pathway was first identified in in the 1960s through studies observing unscheduled DNA synthesis and "dark repair" following UV irradiation, which demonstrated the excision of damaged nucleotides without light-dependent photoreactivation. This foundational work paved the way for mechanistic insights across species, culminating in the 2015 Nobel Prize in Chemistry awarded to , Paul Modrich, and for their elucidations of mechanisms, including NER.

Types of DNA damage targeted

Nucleotide excision repair (NER) primarily targets bulky DNA lesions that cause significant structural distortions in the double helix, including cyclobutane pyrimidine dimers (CPDs) and (6-4) photoproducts formed by ultraviolet (UV) radiation. These UV-induced lesions, particularly prevalent at dipyrimidine sites, block DNA replication and transcription, making them key substrates for NER to prevent mutagenesis and cell death. Additionally, NER repairs intrastrand crosslinks induced by chemotherapeutic agents like cisplatin, as well as bulky adducts from environmental carcinogens such as benzopyrene diol epoxide (BPDE) derived from polycyclic aromatic hydrocarbons in tobacco smoke. Certain oxidative damages that result in helix distortion, such as thymine glycol, can also serve as NER substrates, though less commonly than UV or chemical adducts. The structural criteria for NER substrates emphasize lesions that induce substantial helical distortion or destabilization of the DNA duplex, rather than specific chemical identities, allowing the pathway to accommodate a diverse array of damages. These distortions typically impede the progression of DNA or RNA polymerases, triggering repair, while NER exhibits flexibility in recognizing lesions of varying sizes as long as sufficient conformational change occurs. In contrast, non-bulky or minimally distorting modifications, such as simple base deaminations, are generally not effective NER substrates. Unlike (BER), which addresses small, non-helix-distorting base modifications like uracil or via glycosylases, NER specializes in excising large, obstructive adducts that BER cannot handle. Mismatch repair (MMR) focuses on replication errors and small mismatches, showing no overlap with NER's bulky lesion repertoire, while NER shares partial involvement with interstrand crosslink repair pathways but primarily processes intrastrand s and monoadducts. In humans, NER accounts for the majority of UV lesion removal, serving as the primary defense against sunlight-induced DNA damage and preventing signature such as C-to-T transitions at dipyrimidine sequences when . This underscores NER's critical role in mitigating environmental genotoxic stress from UV exposure and chemical pollutants.

Prokaryotic NER

UvrABC excinuclease system

The UvrABC excinuclease system is the primary machinery for nucleotide excision repair (NER) in prokaryotes, particularly in Escherichia coli, where it recognizes and excises a wide range of bulky DNA lesions such as those induced by ultraviolet light or chemical adducts. This ATP-dependent system consists of three core proteins—UvrA, UvrB, and UvrC—that work in a coordinated manner to detect DNA distortions, verify damage, and perform dual incisions flanking the lesion, thereby initiating repair. Accessory proteins facilitate the subsequent steps of oligomer removal, gap filling, and ligation. The system's efficiency and specificity arise from the sequential assembly and dissociation of protein-DNA complexes, ensuring precise removal of damaged oligonucleotides typically 12-13 nucleotides in length. UvrA, a 100 kDa protein, functions as an ATPase and initial damage sensor, forming a homodimer (UvrA₂) that scans double-stranded DNA for helical distortions rather than specific chemical modifications. Its structure includes two tandem ATP-binding cassette-like nucleotide-binding domains and C-terminal zinc finger motifs that regulate damage-specific binding, enabling the dimer to preferentially associate with damaged DNA up to 80 Å from the lesion site. UvrA lacks strong helicase activity but uses ATP hydrolysis to facilitate transient DNA unwinding and recruit UvrB, forming the UvrA₂UvrB complex (often as UvrA₂UvrB₂) that loads UvrB onto the damage site. Once UvrB is positioned, UvrA dissociates, highlighting UvrA's role as a mobile chaperone in the assembly process. UvrB, an 85 kDa protein, binds tightly to the lesion site after loading by UvrA, serving as the primary damage verifier and pre-incision complex stabilizer. It possesses ATPase activity but minimal helicase function, with key structural features including helicase-like domains and a β-hairpin motif that inserts into the DNA helix to separate strands and probe the lesion, often flipping the damaged base into a hydrophobic pocket for confirmation. This verification step distinguishes true damage from non-specific distortions, ensuring specificity. UvrB then recruits UvrC via direct protein-protein interactions at its C-terminal tail, maintaining the DNA in an open conformation for incision. UvrC, a 66 kDa endonuclease, catalyzes the dual incisions essential for excising the damaged segment, coupling to the UvrB-DNA complex in a 1:1 . Its structure features an N-terminal GIY-YIG domain for the 3' incision (3-5 3' to the ) and a C-terminal catalytic homologous to RNase H for the 5' incision (7-8 5' to the ), with a central inactive RNase H-like and (HhH)₂ motifs for DNA binding; these activities require divalent cations like Mg²⁺. The incisions release a short , completing the excision step. UvrC shares structural and functional conservation with eukaryotic endonucleases such as XPF-ERCC1, particularly in the (HhH)₂ and incision mechanism. Following incision, accessory factors complete the repair: UvrD, an ATP-dependent , unwinds the post-incision complex and displaces UvrC along with the excised oligomer; (Pol I) then fills the resulting single-stranded gap using the intact strand as a template; and seals the nick to restore continuity. These steps operate in an ATP-dependent manner, with the overall UvrABC system exhibiting a dynamic that transitions from UvrA₂UvrB to UvrB-UvrC, minimizing off-target activity.

Step-by-step mechanism

Nucleotide excision repair (NER) in prokaryotes, exemplified by the UvrABC system in Escherichia coli, proceeds through a series of ATP-dependent biochemical steps that identify, excise, and replace damaged DNA segments. This process ensures the removal of bulky or helix-distorting lesions, such as UV-induced cyclobutane pyrimidine dimers, with high specificity and minimal disruption to genomic integrity. The mechanism involves coordinated action of UvrA, UvrB, UvrC, and accessory proteins, culminating in the synthesis of a short patch to restore the original sequence. Step 1: Damage recognition. The process initiates with the formation of a UvrA dimer (UvrA₂), which binds non-specifically to double-stranded DNA in an ATP-dependent manner. This complex slides along the DNA helix, exhibiting a modest 2-5-fold preference for damaged sites due to conformational distortions caused by lesions. Upon encountering a potential lesion, UvrA₂ recruits UvrB to form the UvrA₂UvrB complex, where ATP hydrolysis by UvrA drives helicase-like movements and conformational changes that facilitate lesion localization. This initial scanning and recruitment step allows for broad surveillance of the genome without requiring high-affinity binding to undamaged DNA. Step 2: Verification and loading. Once at the lesion site, UvrB verifies the damage by inserting a β-hairpin structure into the DNA helix to probe for distortions, such as kinks or unwinding near the lesion. This verification involves local DNA unwinding (approximately 12-13 base pairs) powered by ATP hydrolysis from UvrB's helicase domains, which stalls progression at confirmed lesions. UvrA then dissociates from the complex, leaving UvrB clamped tightly onto the DNA in a stable, lesion-bound conformation that preps the site for incision. This step enhances specificity, rejecting non-damaging distortions through kinetic proofreading mechanisms. Step 3: Dual incision. UvrC binds to the UvrB-DNA complex, forming the pre-incision holoenzyme. UvrC's dual domains then catalyze two endonucleolytic cuts on the damaged strand: a 3′ incision 4-5 downstream of the via its GIY-YIG endonuclease , and a 5′ incision 7-8 upstream via its RNase H-like . These asymmetric incisions release a short of 12-13 containing the damaged bases, while UvrB remains bound to prevent reannealing. The precision of these cuts ensures minimal healthy DNA removal. Step 4: Removal and resynthesis. The excised oligomer is removed by UvrD (helicase II), which unwinds the DNA duplex in an ATP-dependent 3′→5′ manner, displacing the UvrB-UvrC-oligomer complex and releasing the damaged fragment for degradation by exonucleases. This creates a single-stranded gap of 10-12 nucleotides. DNA polymerase I (Pol I) then performs nick translation to fill the gap, synthesizing new DNA using deoxynucleotide triphosphates (dNTPs) and the undamaged complementary strand as a template. Finally, DNA ligase seals the remaining nick, restoring the intact duplex. Pol I's 5′→3′ exonuclease activity ensures accurate gap filling with high fidelity. In E. coli, this UvrABC-mediated NER efficiently repairs UV-induced lesions, with approximately 17% of cyclobutane pyrimidine dimers removed from non-transcribed strands within 15 minutes post-irradiation (equivalent to about 60-70% per hour under moderate UV doses), and faster rates on transcribed strands due to transcription-coupled bias.

Eukaryotic NER

Damage recognition pathways

In eukaryotic nucleotide excision repair (NER), damage recognition follows a "verify and unwind" model, where initial detection relies on structural distortions in the DNA helix rather than specific binding to the lesion itself. This approach allows the pathway to address a broad spectrum of bulky or helix-distorting adducts, such as those induced by ultraviolet light or chemical agents, by first probing for unpaired bases or bubbles in the double helix. The process begins with scanning for these distortions, followed by verification through localized unwinding to confirm the presence of damage, ensuring efficient recruitment of downstream repair factors without unnecessary energy expenditure on undamaged DNA. Global genomic NER (GG-NER) initiates through random scanning of the entire genome by the XPC-RAD23B-CETN2 complex, which binds preferentially to sites of unpaired bases adjacent to lesions, stabilizing a pre-unwound DNA conformation. Upon binding, this complex recruits the TFIIH helicase complex, whose XPB and XPD subunits further unwind the DNA to verify the distortion and expose the lesion for subsequent steps. This uniform surveillance ensures repair across both transcribed and non-transcribed regions, though it operates at a basal rate independent of transcriptional activity. In contrast, transcription-coupled NER (TC-NER) is triggered when RNA polymerase II stalls at a transcribing on the template strand, halting elongation and creating a natural recognition signal. The CSB protein (encoded by ERCC6) rapidly binds to the stalled polymerase, stabilizing the complex and recruiting (encoded by ERCC8), which forms part of a Cullin-RING that facilitates the handover to core NER machinery, including TFIIH. This pathway prioritizes actively transcribed genes, bypassing the need for random scanning. The two pathways differ fundamentally in scope and efficiency: GG-NER provides genome-wide coverage but repairs lesions more slowly across inactive regions, while TC-NER targets the transcribed strands of active genes, achieving repair rates several times higher—typically 5- to 10-fold faster—to maintain transcriptional fidelity and prevent prolonged stalling. This prioritization reflects the to protect essential , with TC-NER handling a subset of lesions more rapidly while GG-NER serves as a for the rest of the . Recent structural studies using cryo-electron microscopy (cryo-EM) have illuminated these processes, revealing how the XPC complex induces a ~30-base-pair DNA bubble at lesion sites to facilitate TFIIH engagement and verification. These high-resolution structures, captured post-2020, show dynamic interactions where XPC's β-hairpin inserts into the helix, prying apart strands to expose the damage. Additionally, ubiquitin signaling has emerged as a key regulator, with CSA-mediated ubiquitination of stalled RNA polymerase II in TC-NER promoting factor recruitment and complex remodeling, while similar modifications in GG-NER enhance XPC stability and chromatin accessibility at damage sites.

Global genomic NER (GG-NER)

Global genomic nucleotide excision repair (GG-NER) is the subpathway of nucleotide excision repair that scans and repairs DNA lesions across the entire genome, including both strands of non-transcribed regions, thereby maintaining genomic stability in areas not actively involved in transcription. Unlike transcription-coupled NER, which prioritizes lesions on transcribed strands for faster removal, GG-NER operates more slowly and contributes to the basal mutation load by addressing persistent damage in silent genomic regions. Defects in GG-NER, such as those arising from nucleotide excision repair deficiencies, have been linked to increased base substitution mutation loads in tissues like the liver. The process begins with damage recognition primarily mediated by the XPC-RAD23B-CETN2 complex, which detects helix-distorting lesions and recruits the TFIIH transcription factor II H complex. TFIIH, through its XPB and XPD ATPase/helicase subunits, then unwinds the DNA duplex to form an approximately 25-nucleotide bubble around the lesion site. Replication protein A (RPA) subsequently binds to the exposed single-stranded DNA to stabilize the structure, while XPA verifies the presence of the damage, ensuring accurate lesion confirmation before proceeding to excision. A distinctive feature of GG-NER is the involvement of the DDB1-DDB2 heterodimer (also known as XPE or UV-DDB), which enhances recognition specifically for cyclobutane (CPDs) induced by radiation. The DDB2 subunit, often referred to as p48, plays a crucial role in facilitating damage detection within contexts by promoting ubiquitination and to expose lesions. GG-NER accounts for a substantial portion of overall nucleotide excision repair activity in humans, estimated at around 50% in certain cellular contexts, though its efficiency is notably inhibited by chromatin compaction from nucleosomes. Regulation of GG-NER involves epigenetic modifications, with histone acetylation promoting decompaction to improve access to damaged sites; recent studies continue to elucidate these mechanisms in enhancing repair efficiency. in the XPC , central to GG-NER initiation, result in complementation group C and confer greater than 1000-fold increased sensitivity to light, underscoring the pathway's critical role in preventing UV-induced .

Transcription-coupled NER (TC-NER)

Transcription-coupled nucleotide excision repair (TC-NER) is a specialized subpathway of nucleotide excision repair that preferentially targets DNA lesions on the transcribed strand of active genes, triggered by the stalling of (RNA Pol II) at bulky, helix-distorting lesions such as cyclobutane pyrimidine dimers or platinum-DNA adducts. When RNA Pol II encounters such a lesion on the template strand during transcription elongation, the polymerase stalls and undergoes , which extrudes the damaged DNA segment from the active site and exposes it for recognition by repair factors. This coupling ensures that transcriptionally active regions are repaired more rapidly than non-transcribed genomic areas, prioritizing the maintenance of fidelity. The pathway is initiated by the binding of protein B (CSB, also known as ERCC6), an ATP-dependent remodeler, to the stalled RNA Pol complex, stabilizing it and facilitating the recruitment of additional factors. CSB then recruits protein A (CSA, also known as ERCC8), a WD40-repeat protein that forms part of the DDB1-CUL4 complex, which promotes the monoubiquitination of the RNA Pol large subunit (RPB1) and other associated factors. This ubiquitination event aids in the clearance of the stalled polymerase, either through proteasomal degradation or reversal, allowing access to the for subsequent repair steps. Additional factors like UV-stimulated scaffold protein A (UVSSA) stabilize the complex and prevent excessive degradation of RNA Pol . Following recognition, TC-NER integrates with the core nucleotide excision repair machinery shared with global genomic NER (GG-NER), including TFIIH for activity, XPA for , RPA for single-strand , and XPG/XPF-ERCC1 for incisions. This overlap enables efficient dual incision and lesion removal, but TC-NER specifically accelerates repair on the transcribed strand by 5-10-fold compared to the non-transcribed strand, as demonstrated in studies of cisplatin-DNA adducts in mammalian cells. Biologically, TC-NER plays a critical role in protecting cells from transcription-blocking lesions that could otherwise lead to prolonged stalling, transcriptional arrest, and accumulation of toxic R-loops or DNA breaks. It is essential for maintaining cell viability under genotoxic stress, such as UV , by ensuring rapid recovery of transcription and preventing or . Recent 2024 studies using cell-free systems have highlighted TC-NER's involvement in RNA Pol II restart mechanisms, where factors like STK19 position repair complexes to facilitate polymerase clearance and resumption of elongation post-lesion removal. Defects in TC-NER due to mutations in the or genes underlie , a rare autosomal recessive disorder characterized by transcription defects, premature aging, neurological degeneration, and UV hypersensitivity. These mutations impair the recruitment and ubiquitination steps, leading to persistent stalled RNA Pol II and unresolved lesions specifically on transcribed strands, which exacerbate cellular sensitivity to DNA damage.

Dual incision and gap-filling

In eukaryotic nucleotide excision repair (NER), the dual incision step occurs after damage recognition and involves the coordinated action of two structure-specific endonucleases to excise the damaged DNA segment. The XPF-ERCC1 heterodimer functions as the 5' endonuclease, making an incision approximately 20-22 nucleotides 5' to the lesion, while XPG acts as the 3' endonuclease, making an incision approximately 5-8 nucleotides 3' to the lesion during TFIIH-mediated DNA unwinding to create a single-stranded gap. These incisions are sequential, with the 5' cut by XPF-ERCC1 preceding the 3' cut by XPG, ensuring precise removal of the oligonucleotide containing the lesion. The excised fragment in eukaryotes is a 24-32 oligonucleotide, substantially larger than the 12-13 patch in prokaryotic NER, which allows for complete removal of bulky lesions and associated distortions while minimizing unnecessary DNA degradation. This larger patch size enhances repair efficiency for complex eukaryotic structures. Following excision, gap-filling resynthesis is initiated at the 3' hydroxyl end generated by XPF-ERCC1, primarily using DNA polymerases δ and ε, which are recruited by the clamp-loader complex and the sliding clamp. These components utilize deoxynucleotide triphosphates (dNTPs) as substrates for template-directed synthesis, with coordination to the replication fork in S-phase to avoid conflicts with ongoing . The repaired patch is sealed by DNA ligase I in proliferating cells or the XRCC1-DNA ligase III complex in quiescent or non-replicating contexts, completing the nick and restoring phosphodiester backbone integrity. Post-ligation, chromatin restoration involves histone chaperones such as chromatin assembly factor 1 (CAF-1), which deposits histones H3-H4 onto the newly synthesized DNA to reassemble nucleosomes and maintain epigenetic marks. NER exhibits due to its reliance on template-directed by replicative polymerases, which incorporate with error rates below 10^{-6} per base, far superior to error-prone pathways like translesion synthesis. Recent studies as of 2025 emphasize NER's role in preventing the formation of double-strand breaks that could trigger mutagenic alternative end-joining, thereby preserving genomic stability.

Clinical and Biological Implications

Role in cancer susceptibility and prognosis

Defects in nucleotide excision repair (NER) significantly contribute to cancer susceptibility by impairing the removal of bulky DNA adducts from environmental carcinogens such as (UV) radiation and . Polymorphisms in the XPD gene (also known as ERCC2), such as Asp312Asn and Lys751Gln, have been associated with increased risk of s, particularly non-melanoma and , especially in individuals with high sun exposure. Similar XPD variants elevate the risk of and cancers, with meta-analyses indicating odds ratios up to 1.5 for variant carriers exposed to smoking-related mutagens. For ERCC1 variants, such as rs11615, studies show a 20-50% higher odds of tobacco-related cancers like , as these polymorphisms reduce NER efficiency and allow accumulation of DNA damage from polycyclic aromatic hydrocarbons. The mechanistic link between NER defects and carcinogenesis involves unrepaired DNA adducts leading to specific and genomic instability. For instance, UV-induced cyclobutane persist in NER-deficient cells, causing characteristic C>T transitions at TC dinucleotides during replication, which drive oncogenic mutations in skin cancers. This unrepaired damage promotes chromosomal aberrations, , and overall genomic instability, accelerating tumor initiation and progression across multiple cancer types. Extreme NER deficiencies, as seen in (XP), exemplify heightened susceptibility, with population studies revealing latitude-dependent risks—higher incidence in equatorial regions due to increased UV exposure. In terms of prognosis, NER activity levels in tumors influence treatment outcomes, particularly for chemotherapies targeting DNA damage. High ERCC1 expression, a marker of robust NER, predicts resistance to platinum-based agents like cisplatin in non-small cell lung cancer and ovarian cancer, as it enhances repair of drug-induced interstrand crosslinks, leading to poorer survival in responsive cohorts. Conversely, low NER activity correlates with better chemotherapy response but underscores the underlying susceptibility to initial carcinogenesis. Recent advances (2022-2023) highlight NER-related single nucleotide polymorphisms (SNPs) as emerging biomarkers; for example, ERCC family mutations are associated with increased tumor immunogenicity and improved efficacy of immune checkpoint inhibitors in lung adenocarcinoma, potentially due to enhanced neoantigen presentation from unrepaired damage. Additionally, overlaps between NER defects and microsatellite instability phenotypes have been noted in colorectal cancers, where combined repair deficiencies amplify prognostic heterogeneity and immunotherapy sensitivity. A 2025 pooled analysis further supports NER capacity as a biomarker for cancer risk influenced by host factors.

Associations with genetic disorders

Nucleotide excision repair (NER) deficiencies are associated with several hereditary disorders, primarily autosomal recessive conditions arising from mutations in NER pathway genes. These disorders manifest as heightened sensitivity to (UV) radiation and other DNA-damaging agents, leading to a spectrum of clinical features including dermatological abnormalities, neurological degeneration, and developmental delays. Xeroderma pigmentosum (XP) is the most well-characterized NER-related disorder, caused by biallelic mutations in one of eight complementation groups (XPA through XPG and XPV). These mutations impair the NER machinery, resulting in defective repair of UV-induced DNA lesions such as cyclobutane . Clinically, XP patients exhibit extreme , with freckling, xerosis, and actinic keratoses appearing in early childhood upon minimal sun exposure; neurological abnormalities, including , , and , occur in approximately 30% of cases, particularly in groups XPA, XPD, and XPG. The disorder confers a greater than 1,000-fold increased risk of skin cancers, such as and , underscoring shared molecular vulnerabilities with oncogenesis. Complementation groups were delineated through assays, which restored NER proficiency in hybrid cells from different groups, confirming distinct genetic loci. XP incidence is estimated at 1 in 1,000,000 in the United States and . Cockayne syndrome (CS) arises from mutations in the CSA (ERCC8) or CSB (ERCC6) genes, which disrupt transcription-coupled NER (TC-NER), a subpathway prioritizing repair of actively transcribed genes. This uncoupling of transcription and repair leads to persistent DNA damage in transcribed regions, triggering cellular and tissue degeneration. Patients present with , progressive neurodegeneration, , retinal degeneration, and premature aging features like wrinkled skin and cataracts, alongside mild but notably without elevated cancer risk. Inheritance is autosomal recessive, with onset in infancy and median survival into the second decade. Trichothiodystrophy (TTD) results from mutations in XPB (ERCC3), XPD (ERCC2), or TTDA (MMS19) genes, which encode components of the complex also involved in NER. These alterations cause partial NER defects alongside impaired basal transcription, leading to brittle, sulfur-deficient (sulfur content <50% of normal), , nail dystrophy, and . affects about half of cases, but cancer incidence remains low; developmental delays and progeroid features predominate. The molecular basis involves disrupted activity in TFIIH, affecting both repair and . Overlapping phenotypes highlight NER pathway complexity; UV-sensitive syndrome (UVSS) stems from defects in CSB (ERCC6), XPG (ERCC5), or UVSSA genes, featuring mild and TC-NER impairment without neurodegeneration or cancer predisposition. Combined XP/CS presentations occur with specific mutations in XPB, XPD, or XPG, blending severe and cancer risk with CS-like neurological decline. Recent preclinical efforts, including viral vector-based XPC , advance potential therapies for XP, with studies demonstrating transient XPC expression in patient-derived cells as of 2024.

Contribution to aging processes

Nucleotide excision repair (NER) efficiency declines with chronological , leading to the accumulation of unrepaired DNA lesions that contribute to cellular dysfunction and tissue degeneration. In s, NER capacity decreases by approximately 25% from 20 to 60, as evidenced by slower removal of UV-induced cyclobutane (CPDs) in dermal fibroblasts from older individuals, which take 7–14 days compared to 4 days in young subjects. This decline is associated with reduced expression and activity of key NER proteins, such as XPA and XPC, resulting in increased persistence of oxidative DNA damage from (ROS). In model organisms like , NER rates drop by 30–50% in mid-life adults relative to young ones, mirroring patterns observed in cells. Several mechanisms underlie this age-related NER impairment. Epigenetic changes, including altered and modifications, hinder DNA damage recognition and access for repair factors, particularly in non-dividing cells. attrition with age exacerbates NER dysfunction by increasing genomic instability and limiting repair at telomeric regions, where NER pathways are essential for maintaining integrity. Additionally, mitochondrial dysfunction contributes indirectly through elevated ROS production, overwhelming NER and promoting oxidative buildup that NER would otherwise resolve. The diminished NER capacity has profound implications for age-related pathologies. In skin, impaired NER accelerates by failing to excise UV-induced adducts, leading to degradation, wrinkles, and pigmentation changes. In the brain, unrepaired DNA adducts accumulate in , contributing to neurodegeneration as seen in conditions like , where NER defects correlate with neuronal loss and cognitive decline. Progeroid syndromes such as (CS), caused by NER gene mutations, serve as extreme models of accelerated aging, featuring , demyelination, and shortened lifespan that mimic somatic aging processes. Supporting evidence comes from animal models, where NER deficiencies hasten aging phenotypes. For instance, Xpg-mutant mice exhibit a shortened median lifespan of about 18 weeks, along with progressive , , and liver degeneration due to unrepaired DNA damage. Longitudinal human studies further link low NER activity to increased frailty, with reduced repair correlating to higher composite frailty indices reflecting and functional decline. Interventions targeting NER hold promise for mitigating age-related decline. Caloric restriction enhances NER efficiency in aged cells by boosting sirtuin activity and reducing oxidative burden, as observed in NER-deficient mouse models where it extends healthspan. Similarly, NAD+ precursors like nicotinamide riboside elevate NAD+ levels, which decline with age, thereby activating PARP-dependent NER pathways and improving repair in senescent fibroblasts.

Key Components

Core genes and proteins in humans

Nucleotide excision repair (NER) in humans relies on a coordinated set of core genes and proteins that execute damage recognition, lesion verification, dual incision, and gap-filling synthesis. These components form the XPC-RAD23B-CETN2 complex for initial damage sensing in global genomic NER (GG-NER), while transcription-coupled NER (TC-NER) involves distinct factors like and CSB. In damage recognition, the XPC protein, encoded by the XPC gene, serves as the primary sensor for helix-distorting lesions in GG-NER, forming a complex with RAD23B and centrin-2 (CETN2) to detect and melt DNA at damage sites, thereby recruiting downstream factors. The DDB2 protein (XPE), encoded by DDB2, binds UV-induced cyclobutane (CPDs) in a complex with DDB1, facilitating access for XPC by kinking the DNA helix. For TC-NER, (encoded by ERCC8) and CSB (encoded by ERCC6) recognize stalled ; CSA functions in a complex to ubiquitinate factors for polymerase removal, while CSB alters DNA conformation and coordinates repair initiation. Lesion verification and unwinding involve XPA, encoded by XPA, which acts as a binding single-stranded DNA near the 's 5' side and interacting with TFIIH, RPA, and other components to confirm damage and assemble the pre-incision complex. Within the TFIIH complex, XPD (encoded by ERCC2) and XPB (encoded by ERCC3) are ATP-dependent helicases; XPB unwinds DNA to generate a 20-30 bubble around the , while XPD verifies the damage and contributes to unwinding. Incision is performed by structure-specific endonucleases: the ERCC1-XPF heterodimer (encoded by ERCC1 and ERCC4, respectively) makes the 5' incision ~24 nucleotides from the lesion, while XPG (encoded by ERCC5) incises at the 3' junction of single- and double-stranded DNA. Gap-filling synthesis utilizes RPA1 (encoded by RPA1), which coats the single-stranded DNA gap to protect it and coordinate repair; PCNA (encoded by PCNA) acts as a sliding clamp for polymerases. DNA polymerases such as POLD1 (pol δ) and (pol ε) fill the ~30-nucleotide gap, and LIG1 (encoded by LIG1) seals the nick in replicating cells, with LIG3 in quiescent ones. Mutations in these NER genes underlie (XP) and related disorders, with approximately 110 pathogenic or likely pathogenic variants reported across XP genes (XPA to XPG and POLH for XPV) in ClinVar as of 2024. mutations in NER genes are observed in various tumors, contributing to genomic instability and sensitivity to DNA-damaging agents. Databases such as ClinVar and HGMD document numerous disease-causing NER mutations, highlighting the genetic diversity in repair deficiencies.

Variations across organisms

In prokaryotes, nucleotide excision repair (NER) relies on a simpler UvrABC excinuclease system, consisting of UvrA for damage recognition, UvrB for verification and activity, and UvrC for dual incisions, although it includes a transcription-coupled variant mediated by the Mfd protein, without the complex subpathways of eukaryotes. This streamlined mechanism efficiently removes bulky lesions like UV-induced cyclobutane in bacteria such as , which serves as a primary for studying UV and repair kinetics due to its well-characterized and rapid growth. In the yeast , NER components include RAD homologs that correspond to human proteins, such as RAD14 as the ortholog of XPA for damage verification and RAD1/RAD10 as endonucleases analogous to XPF/ERCC1. The pathway distinguishes between global genomic NER, mediated by Rad7-Rad16 complexes for non-transcribed regions, and transcription-coupled NER involving Rad26 (CSB homolog) for faster repair of active genes. S. cerevisiae is widely used for of NER modulators, as demonstrated by deletion collection assays identifying repair-deficient strains resistant to DNA-damaging agents like IQ, highlighting genes such as NTG1 in crosstalk. In plants, such as , the XPC ortholog (AtRAD4) facilitates damage recognition in global NER, enabling repair of UV-induced lesions in both nuclear and chloroplast genomes to protect photosynthetic machinery. Chloroplast-targeted NER components, including helicases like AtXPD, contribute to excising under UV stress, complementing photoreactivation pathways. In nematodes like , NER is partially conserved with core factors such as XPA-1, but exhibits reduced efficiency compared to mammals, rendering mutants hypersensitive to carcinogens like UV and that form bulky adducts. Evolutionary divergence in NER is evident in the expansion of TFIIH subunits from to eukaryotes; archaeal systems employ UvrA-like proteins for basal damage scanning and incision, lacking the multi-subunit TFIIH core (with XPB, XPD helicases, and associated factors) that eukaryotes use for dual incision and transcription integration. This archaeal-eukaryotic split underscores NER's adaptation for complex environments in higher organisms. Model organisms provide insights into NER variations; Xpa^{-/-} knockout mice exhibit defective NER mimicking human xeroderma pigmentosum phenotypes, with heightened UV sensitivity and tumor susceptibility, validating mammalian repair pathways. Recent CRISPR studies in organoids, such as gastric models, reveal tissue-specific NER efficiencies, where editing DNA repair genes like those in the NER pathway shows convergence on cisplatin resistance, highlighting organ-dependent repair dynamics.

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