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Deoxyadenosine triphosphate

Deoxyadenosine triphosphate (dATP) is a purine nucleoside triphosphate consisting of the nitrogenous base adenine linked to a deoxyribose sugar and a triphosphate group, with the molecular formula C₁₀H₁₆N₅O₁₂P₃. It serves as one of the four essential deoxynucleotide triphosphates (dNTPs)—alongside dCTP, dGTP, and dTTP—that act as substrates for DNA polymerases during the synthesis, replication, and repair of deoxyribonucleic acid (DNA) in cells. The biosynthesis of dATP occurs primarily through the de novo pathway in the cytoplasm, where ribonucleotide reductase (RNR) catalyzes the reduction of adenosine diphosphate (ADP) to deoxyadenosine diphosphate (dADP), which is then phosphorylated by nucleoside diphosphate kinase to form dATP. A salvage pathway also contributes, recycling free deoxyadenosine via kinases to replenish dATP pools, particularly in response to cellular demands during DNA replication. Regulation of dATP levels is critical for maintaining genomic stability, as dATP binds allosterically to RNR to inhibit its activity, providing negative feedback that balances dNTP concentrations and prevents mutagenesis from imbalanced pools. In , dATP is incorporated opposite bases by , forming A-T base pairs that ensure faithful transmission of genetic information. Beyond synthesis, dATP influences cellular processes such as induction in lymphocytes when accumulated due to (ADA) deficiency, where it disrupts metabolism and triggers activation. Dysregulation of dATP, often observed in cancer cells with elevated RNR expression, can lead to excessive dNTP production that promotes tumor proliferation and genomic instability, highlighting its therapeutic targeting potential in .

Chemical Properties

Structure

Deoxyadenosine triphosphate (dATP), also known as 2'-deoxyadenosine 5'-triphosphate, has the molecular formula C₁₀H₁₆N₅O₁₂P₃. The molecule consists of three main components: the purine base , the pentose sugar , and a group. is attached to the C1' anomeric carbon of the sugar via a β-N-glycosidic bond at the N9 position of the purine ring. The sugar features a β-D configuration at the C1' carbon, with hydroxyl groups at the 3' and 5' positions; the 2' position lacks a hydroxyl group, distinguishing it from . The chain, comprising α, β, and γ groups linked by phosphoanhydride bonds, is esterified to the oxygen of the 5' hydroxyl group on the . A key structural difference between dATP and its ribonucleotide counterpart, adenosine triphosphate (ATP), is the absence of the 2'-hydroxyl group on the sugar moiety in dATP, which replaces ribose with deoxyribose and renders it suitable for incorporation into DNA rather than RNA. This deoxy form maintains the same β-D stereochemistry at C1' and the triphosphate linkage at 5' as in ATP but alters the sugar's reactivity and conformational preferences. The standard depiction of dATP illustrates as a fused pyrimidine-imidazole ring system, connected via the N9-C1' β-N-glycosidic bond to the ring of , with the triphosphate chain extending from the 5' position and a free 3'-OH group. This structure highlights the 2'-deoxy position (H instead of OH) as the primary distinction from ATP's sugar.

Physical Properties

Deoxyadenosine triphosphate (dATP), with the molecular formula C₁₀H₁₆N₅O₁₂P₃, has a molecular weight of 491.18 g/ for the free acid form. In its pure, state, dATP presents as a white to off-white powder, often supplied as a for practical handling. dATP demonstrates high solubility in aqueous environments, exceeding 50 mg/mL at neutral pH (around 7.0–7.5), enabling its use in buffered solutions at concentrations up to 100 as the disodium or trisodium salt. In contrast, its solubility in organic solvents like is limited due to its polar chain and charged nature, typically requiring aqueous media for dissolution. The compound exhibits hydrolytic instability under acidic conditions (pH <5), where the phosphoanhydride bonds in the triphosphate chain are prone to cleavage, but it remains stable in neutral to slightly alkaline buffers ( 7.5–8.2). In biological settings, dATP is susceptible to enzymatic by phosphatases and other hydrolases, necessitating careful to prevent by contaminating enzymes. Optimal stability occurs in neutral to slightly alkaline buffers ( 7.5–8.2) when protected from light and enzymes. Key acid dissociation constants (pKₐ) for dATP include values less than 2 for the inner phosphate groups, approximately 6.5 for the terminal γ-, and about 4.0 for of the moiety. These values reflect the compound's behavior, with multiple negative charges at physiological contributing to its reactivity and . dATP absorbs ultraviolet light with a maximum wavelength (λₘₐₓ) at 259 nm in neutral aqueous solution, characterized by a molar extinction coefficient (ε) of 15,400 M⁻¹ cm⁻¹ at this wavelength; this property facilitates spectrophotometric quantification in biochemical assays.

Biosynthesis and Metabolism

Biosynthetic Pathways

Deoxyadenosine triphosphate (dATP) is primarily synthesized in cells through two main pathways: de novo biosynthesis and the salvage pathway. The de novo route begins with the reduction of adenosine diphosphate (ADP) to deoxyadenosine diphosphate (dADP) catalyzed by the enzyme ribonucleotide reductase (RNR), which serves as the rate-limiting step in deoxyribonucleotide production. This reduction involves a radical-based mechanism where RNR uses a tyrosyl radical to abstract a hydrogen from the ribose ring, facilitated by a redox cofactor system. The balanced reaction for this step is: \text{ADP} + 2 \text{thioredoxin}_{\text{red}} \rightarrow \text{dADP} + 2 \text{thioredoxin}_{\text{ox}} The oxidized thioredoxin is subsequently regenerated by thioredoxin reductase using NADPH as the electron donor. Following reduction, dADP is phosphorylated to dATP by nucleoside diphosphate kinase (NDPK), which transfers a phosphate group from ATP: \text{dADP} + \text{ATP} \rightarrow \text{dATP} + \text{ADP} This equilibrium reaction ensures efficient conversion under cellular conditions. In the salvage pathway, exogenous or recycled is reclaimed and phosphorylated stepwise to dATP. The initial phosphorylation of to (dAMP) is mediated by deoxycytidine kinase (dCK), a key enzyme in salvage. Subsequent steps involve converting dAMP to dADP, followed by NDPK phosphorylating dADP to dATP, mirroring the final step of . This pathway is particularly active in tissues with high turnover, such as lymphoid cells, and helps maintain dNTP pools during or under nutrient limitation. RNR activity, central to de novo dATP production, is tightly regulated to balance dNTP levels and prevent mutagenesis from pool imbalances. The enzyme's allosteric site binds ATP as an activator to promote substrate reduction and dATP as an to suppress it when dNTPs are abundant, thus maintaining the ATP/dATP ratio. High dATP concentrations induce a conformational change in RNR, reducing its affinity for and halting further synthesis. This feedback mechanism ensures dATP levels align with cellular demands, primarily during S-phase of the . For laboratory and industrial applications, dATP can be chemically synthesized through multi-step processes starting from and . The is first formed via glycosidic coupling, followed by selective at the 5'-position using phosphorus oxychloride (POCl₃) to yield the monophosphate, and then triphosphorylation via the Ludwig-Eckstein method, which employs a cyclic phosphitylating agent like 2-chloro-4H-1,3,2-benzodioxaphosphorin-2-oxide to form the triphosphate in high yield. Recent advancements incorporate enzymatic cascades, such as those using whole-cell systems with ATP regeneration, achieving over 90% purity and gram-scale production without extensive purification. dATP synthesis occurs predominantly in the via the RNR complex (RRM1/RRM2), but mitochondrial pools are maintained separately to support mtDNA replication. In mitochondria, an alternative RNR subunit, p53R2 (RRM2B), forms a complex with RRM1 to generate dNTPs locally, as import of cytosolic dNTPs is limited. This compartmentalization ensures autonomous dATP supply for mitochondrial maintenance, with deficiencies in p53R2 leading to mtDNA depletion.

Degradation

Deoxyadenosine triphosphate (dATP) undergoes degradation primarily through sequential and in cellular . The process begins with of the triphosphate group by 5'-nucleotidases and nonspecific phosphatases, converting dATP to deoxyadenosine diphosphate (dADP), then to (dAMP), and finally to . The produced is further metabolized via the salvage and degradation pathways. (ADA) catalyzes the deamination of to deoxyinosine, which is then cleaved by purine nucleoside phosphorylase (PNP) to yield hypoxanthine and ribose-1-phosphate. Hypoxanthine is subsequently oxidized to and finally to by , completing the catabolic pathway: dATP → dADP → dAMP → → deoxyinosine → hypoxanthine → . Imbalances in this degradation pathway can lead to pathological accumulation of dATP. In adenosine deaminase (ADA) deficiency, a , the blocked deamination of results in elevated intracellular dATP levels, contributing to by inhibiting and impairing proliferation. The turnover rate of dATP varies by cellular state. In dividing cells during S-phase, dATP exhibits rapid degradation with a of approximately 4 minutes, primarily to deoxyadenosine, to match the demands of . In contrast, dATP pools remain stable in non-proliferating cells, where levels are maintained at low concentrations sufficient for and mitochondrial function. In extracellular environments, dATP is degraded by ectonucleotidases, such as NTPDases (e.g., CD39), which hydrolyze it to , followed by further breakdown to by ecto-5'-nucleotidase. This prevents accumulation of free that could signal immune responses or .

Biological Functions

Role in

Deoxyadenosine triphosphate (dATP) serves as a critical substrate in DNA synthesis, providing the base that pairs complementarily with in the template strand during replication. In eukaryotic cells, dATP is incorporated into the growing DNA chain by replicative DNA s, primarily polymerase α (Pol α), which initiates synthesis by extending RNA primers with deoxyribonucleotides, and polymerases δ (Pol δ) and ε (Pol ε), which perform the bulk of elongation on the lagging and leading strands, respectively. This incorporation ensures the faithful duplication of genetic information, with dATP's sugar and triphosphate group enabling the formation of phosphodiester bonds essential for strand extension. The mechanism of dATP incorporation involves a nucleophilic attack by the 3'-hydroxyl group of the terminal in the growing DNA chain on the α-phosphate of dATP, forming a new and releasing (PPi) as a . This reaction, catalyzed by the , proceeds in a 5' to 3' direction and can be represented as: (\text{DNA})_n + \text{dATP} \rightarrow (\text{DNA})_{n+1} + \text{PP}_\text{i} Fidelity is maintained through induced-fit base-pairing, where correct A-T pairing stabilizes a closed conformational state for efficient , and activity that excises mismatches post-incorporation, achieving error rates as low as 1 in 10^7 bases. During the S-phase of the , balanced dNTP pools, including dATP, are essential for efficient replication, with levels increasing up to 20-fold in mammalian cells compared to to meet the demands of fork progression. dATP concentrations peak in coordination with activity, supporting continuous synthesis without stalling. In , dATP is utilized in (BER), where β (Pol β) incorporates it to fill single-nucleotide gaps after damaged base removal, and in (NER), where replicative polymerases such as Pol δ and Pol ε contribute to patch resynthesis. Imbalances in dNTP pools, such as excess dATP, promote by increasing the likelihood of misincorporation opposite non-complementary bases, leading to elevated rates (up to 4-fold in model systems) without necessarily activating the S-phase checkpoint if replication is not limiting. This underscores the need for precise regulation of dATP levels to preserve genomic stability during synthesis and repair.

Regulatory Roles

Deoxyadenosine triphosphate (dATP) plays a critical role in the of (RNR), the enzyme responsible for catalyzing the conversion of ribonucleotides to , thereby controlling dNTP pool balance essential for . Specifically, dATP binds to the specificity on the RNR α subunit, promoting the of CDP and to dCDP and dUDP, which enhances production of to maintain balanced dNTP levels across the . This feedback mechanism ensures that dATP accumulation signals a sufficient deoxyribonucleotide supply, avoiding imbalances that could lead to or replication errors. In contrast, while ATP to the activity stimulates overall RNR enzymatic activity to promote nucleotide , dATP to the same induces an inhibitory conformation, such as stabilization of an inactive hexameric structure in human RNR, thereby downregulating the enzyme during periods of high dNTP availability. Beyond RNR modulation, elevated dATP levels contribute to apoptosis signaling, particularly in lymphocytes, by triggering the mitochondrial permeability transition (MPT). High intracellular dATP promotes the opening of the mitochondrial permeability transition pore, leading to loss of mitochondrial membrane potential and subsequent release of cytochrome c into the cytosol, which activates the apoptosome and caspase cascade to execute programmed cell death. This pathway is especially relevant in immune cells, where dATP accumulation from deoxyadenosine analogs or metabolic stress amplifies apoptotic responses, helping to eliminate damaged or unnecessary lymphocytes. dATP also influences control through dNTP pool sensing, particularly during . Low dATP concentrations signal nucleotide scarcity, activating the ATR kinase pathway (and to a lesser extent ) at the onset of , which halts progression to allow repair or dNTP replenishment and prevents replication fork stalling.30114-3) This sensing mechanism, conserved from Mec1 to mammalian ATR, ensures genomic stability by coordinating replication with nucleotide availability. In the pathway, dATP exerts feedback inhibition on (dNK), the rate-limiting enzyme that phosphorylates deoxyadenosine to . At high concentrations, dATP competitively binds to dNK, reducing its activity and preventing excessive dATP synthesis from salvaged nucleosides, thus maintaining in purine pools.61769-7/pdf) This regulation is vital in tissues with active salvage activity, such as rapidly dividing cells.

Clinical and Research Applications

Medical Significance

Deoxyadenosine triphosphate (dATP) plays a critical role in the pathogenesis of adenosine deaminase (ADA) deficiency, an autosomal recessive disorder that accounts for approximately 10-15% of severe combined immunodeficiency (SCID) cases, with an incidence of about 1 in 200,000 to 500,000 live births worldwide. In ADA deficiency, unmetabolized deoxyadenosine accumulates and is phosphorylated to dATP, which potently inhibits ribonucleotide reductase (RNR), leading to an imbalance in deoxyribonucleotide triphosphate (dNTP) pools. This disruption impairs DNA synthesis and repair, triggering apoptosis primarily in lymphocytes, resulting in profound T-cell, B-cell, and natural killer cell deficiencies characteristic of ADA-SCID. Clinical manifestations of ADA-SCID typically emerge within the first six months of life, including recurrent severe infections (e.g., and chronic ), , and progressive organ damage such as chronic lung disease. Additional features may involve skeletal abnormalities, , and neurological deficits in up to 80% of cases. Diagnosis is confirmed by measuring low ADA activity and elevated dATP levels in erythrocytes or lymphocytes, often alongside for ADA gene mutations. Without intervention, ADA-SCID is fatal within the first one to two years due to overwhelming infections. Therapeutic strategies for ADA-SCID target dATP accumulation and immune restoration. Enzyme replacement therapy with polyethylene glycol-conjugated ADA (PEG-ADA, e.g., Adagen) reduces toxic metabolites, including dATP, and improves immune function in more than 80% of treated patients, though it requires lifelong administration. A newer recombinant human PEG-ADA (elapegademase, e.g., Revcovi) provides similar benefits with weekly dosing and potentially better tolerability. from a matched donor offers curative potential with survival rates exceeding 90%, restoring ADA expression and normalizing dNTP levels. involves autologous CD34+ stem cells transduced with expressing ADA; Strimvelis (approved by the in 2016) uses a retroviral and achieves sustained immune reconstitution in most patients. As of 2025, lentiviral gene therapies have shown long-term efficacy, with 95% overall survival and immune protection in 59 of 62 treated children over 10+ years of follow-up, without serious complications. dATP analogs have therapeutic applications in other diseases. 2',3'-Dideoxyadenosine triphosphate (ddATP), the active metabolite of (ddI), competitively inhibits by acting as a chain terminator during viral , forming a of early antiretroviral therapy. Similarly, (3'-deoxyadenosine), which is metabolized to 3'-deoxyATP, induces in various cancer cells, including and , by activating pathways and disrupting /, with ongoing preclinical evaluation for antineoplastic use.

Uses in Molecular Biology

Deoxyadenosine triphosphate (dATP) serves as an essential deoxyribonucleoside triphosphate (dNTP) substrate in (PCR) for DNA amplification in applications. In standard , dATP is incorporated by DNA polymerases such as Taq to extend primers and synthesize new DNA strands complementary to the template, providing the adenine bases required for accurate replication. It is also used in variants like real-time quantitative (qPCR) and high-fidelity , where enzymes like Phusion or Q5 polymerases ensure minimal errors during amplification of complex templates. Typical reaction conditions include a final concentration of 200 μM for each dNTP, including dATP, to optimize yield and specificity while balancing cost and reagent stability. In DNA sequencing techniques, dATP and its analogs play critical roles in chain elongation and termination. For , the dideoxy analog ddATP acts as a chain terminator; when incorporated by in place of dATP, its lack of a 3'-OH group prevents further addition, generating fragments of varying lengths that reveal the sequence upon separation by . This method, developed in 1977, relies on a mixture of normal dNTPs (including dATP) and low concentrations of ddNTPs for controlled termination. In next-generation sequencing (NGS) by synthesis, reversible terminator analogs of dATP—modified with cleavable fluorescent groups at the 3'-OH—are sequentially incorporated by polymerases, imaged for base identification, and then unblocked to allow the next cycle, enabling high-throughput parallel sequencing of millions of fragments. dATP functions as a key in (cDNA) synthesis during reverse transcription PCR (RT-PCR), where reverse transcriptases like M-MuLV convert templates into stable cDNA for downstream analysis. Incorporated alongside other dNTPs, dATP ensures faithful representation of residues in the resulting double-stranded cDNA, which is then amplified via to detect low-abundance transcripts such as in studies. This process typically uses 200-500 μM dNTP concentrations to support efficient polymerization from RNA primers. For in vitro assays, dATP is employed to measure activity, where its incorporation rate into synthetic templates quantifies and fidelity under controlled conditions. Fluorescent or radioactive analogs of dATP, such as IR-dATP or ³²P-labeled variants, enable or autoradiographic detection of , facilitating studies of repair mechanisms and inhibitor screening without relying on radiolabeled endpoints. These assays often use nanomolar to micromolar dATP concentrations to mimic physiological substrate availability. In and , dATP acts as a precursor in synthetic DNA assembly methods like , where PCR-amplified fragments with overlapping ends are joined by chew-back, fill-in (requiring dNTPs including dATP), and in a single isothermal reaction. This enables scarless construction of plasmids or pathways from multiple inserts, with dATP supporting the 3' extension phase at concentrations around 200 μM in the master mix. Enzymatic gene synthesis further utilizes dATP in template-directed by engineered polymerases, assembling DNA sequences up to kilobases for applications in . Modified dATP analogs expand labeling capabilities in molecular biology. Azido-dATP, bearing an azide group at the N6 position or 2' sugar, is incorporated by polymerases or terminal transferases into DNA, enabling subsequent copper-catalyzed azide-alkyne cycloaddition (CuAAC) click chemistry for site-specific conjugation to fluorophores or affinity tags in imaging and pull-down assays. Similarly, biotin-dATP analogs, with a 11- or 14-atom linker to the biotin moiety, allow enzymatic incorporation into probes for streptavidin-based detection in hybridization or microarray experiments, providing high sensitivity without altering base-pairing. These modifications maintain near-native polymerase efficiency while facilitating multiplexed analysis.