Search Results (378)

A/T(U) and G/C nucleobase pair formation in DNA and RNA is crucial to numerous fundamental biological processes, including replication, transcription, and translation. The specificity of A/T(U) and G/C base pairing is used for the recognition of complementary sequences in medical and biotechnological applications, such as PCR, nucleic acid drugs, and CRISPR–Cas9-based gene editing. It is essential to understand and predict fidelity of biological reactions, avoiding off-target binding, in order to improve the accuracy and efficacy of applications. In particular, recognition mechanisms of complementary bases or whole sequences must be understood in detail. Despite the prevailing view that Watson–Crick hydrogen bonding is a primary mechanism for complementary base recognition, several experiments have shown that DNA polymerase does not require hydrogen bonding to select complementary bases. Other factors, such as the shape and geometric fitting of the bases and the base stacking, also appear to be crucially involved in the selection. E.g., artificial bases lacking the ability to form hydrogen bonds can still be recognized by DNA polymerase solely based on base-pair geometry. However, hydrogen bonding also contributes importantly to recognition. The accuracy of selecting a complementary nucleobase or sequence varies depending on reactions, suggesting the co-existence of multiple selection mechanisms. This review provides an overview of biological processes and applications involving base pairing and discusses the molecular mechanism underlying complementary base recognition. Full article

Recent findings demonstrate that concentrated sulfuric acid supports rich organic chemistry, including the stability of the canonical DNA bases adenine, thymine, guanine and cytosine. Yet, due to full protonation in concentrated sulfuric acid, these bases may not pair as effectively as they do in water. We are therefore motivated to study nucleic acid bases that pair via hydrophobic and van der Waals interactions instead of canonical hydrogen bonding. Here, we investigate the stability of 14 selected, commercially available alternative nucleobases in concentrated sulfuric acid to evaluate their potential for forming DNA-like polymers in this solvent. The reactivity of compounds 1–14 have not been previously investigated in concentrated sulfuric acid. We incubate the selected compounds in 98% and 81% w/w sulfuric acid and monitor their stability using ¹H and ¹³C NMR spectroscopy over 3 weeks at room temperature. In 98% w/w sulfuric acid, six bases—benzo[c][1,2,5]thiadiazole (1), 2,2′-bipyridine (2), 1,1′-biphenyl (3), 1-methoxy-3-methylbenzene (MMO2) (7) and 1-chloro-3-methoxybenzene (ClMO) (13), and 2,4-difluorotoluene (14)—remain soluble and stable with no detectable degradation. A few compounds show non-destructive reactivity, like sulfonation (compound 3) or H/D exchange (compounds 7, 13, 14). The other compounds react rapidly or are insoluble in 98% w/w sulfuric acid. In 81% w/w sulfuric acid, only compounds 1 and 2 remain stable and soluble, while other selected compounds are insoluble or unstable. Our findings identify a subset of alternative bases stable in concentrated sulfuric acid, advancing efforts towards the design of an example genetic-like polymer in this unusual solvent. Our work further highlights sulfuric acid’s potential for supporting complex organic chemistry, with implications for astrobiology, planetary science of Venus and synthetic biology. Full article

The protozoan pathogen Toxoplasma gondii is responsible for toxoplasmosis, a disease that can be deadly in immunocompromised patients and the developing fetus during pregnancy. Current treatments are widely considered to be suboptimal. We have recently reported that 5-fluoropyrimidines have highly promising anti-toxoplasmosis effects and are internalized by the parasite by a high-affinity uracil/uridine transporter, TgUUT1. Here, we attempt to identify the gene encoding this transport protein. The only nucleoside or nucleobase family identified in the T. gondii genome was the Equilibrative Nucleoside Transporter (ENT) family, with four members. Of these, TgAT1 is known to be purine-specific, and deletion of the TgENT2 and TgENT3 genes, either separately or jointly, did not affect uridine transport or sensitivity to 5-fluoropyrimidines. In contrast, depletion of TgENT1, an essential gene, resulted in a significant reduction in the uptake of both uracil and uridine but not of the amino acid tryptophan. Moreover, expression of TgENT1 in a Leishmania mexicana cell line with low endogenous uracil uptake rates significantly increased uracil uptake for these cells. We conclude that it is highly probable that TgENT1 encodes the T. gondii uracil/uridine transporter. On the basis of our previous results, we infer that TgENT1 likely also mediates the uptake of 5-fluoropyrimidines. Full article

The spontaneous emergence of macroscopic dissipative structures in systems driven by generalized chemical potentials is well established in non-equilibrium thermodynamics. Examples include atmospheric/oceanic currents, hurricanes and tornadoes, Rayleigh–Bénard convection cells and reaction–diffusion patterns. Less well recognized, however, are microscopic dissipative structures that form when the driving potential excites internal molecular degrees of freedom (electronic states and nuclear coordinates), typically via high-energy photons or coupling with ATP. Examples include dynamic nanoscale lipid rafts, kinesin or dynein motors along microtubules, and spatiotemporal Ca²⁺ signaling waves propagating through the cytoplasm. The thermodynamic dissipation theory of the origin of life asserts that the core biomolecules of all three domains of life originated as self-organized molecular dissipative structures—chromophores or pigments—that proliferated on the Archean ocean surface to absorb and dissipate the intense “soft” UV-C (205–280 nm) and UV-B (280–315 nm) solar flux into heat. Thermodynamic coupling to ancillary antenna and surface-anchoring molecules subsequently increased photon dissipation and enabled more complex dissipative processes, including photosynthesis, to dissipate lower-energy but higher-intensity UV-A and visible light. Further thermodynamic coupling to abiotic geophysical cycles (e.g., the water cycle, winds, and ocean currents) ultimately led to today’s biosphere, efficiently dissipating the incident solar spectrum well into the infrared. This paper reviews historical considerations of UV light in life’s origin and our proposal of UV-C molecular dissipative structuring of three classes of fundamental biomolecules: nucleobases, fatty acids, and pigments. Increases in structural complexity and assembly into larger complexes are shown to be driven by the thermodynamic imperative of enhancing solar photon dissipation. We conclude that thermodynamic selection of dissipative structures, rather than Darwinian natural selection, is the fundamental creative force in biology at all levels of hierarchy. Full article

Aldolases are powerful biocatalysts for the stereoselective formation of carbon–carbon bonds and are widely used in the synthesis of chiral intermediates for pharmaceutical applications. Among them, 2-deoxyribose-5-phosphate aldolase (DERA) has been extensively exploited for the preparation of the conserved side chain of statins. In this work, we report a novel chemoenzymatic approach for the synthesis of nucleobase-substituted lactol products as potential precursors of new statin analogues. A C49M variant of DERA from Pectobacterium atrosepticum (PaDERA C49M) was employed to catalyze sequential aldol additions using aldehyde-functionalized nucleobases as non-natural electrophilic substrates. The formation of nucleobase-containing lactols was confirmed, demonstrating for the first time the acceptance of nucleobase-derived aldehydes in DERA-catalyzed aldol reactions. This strategy provides access to structurally novel statin side-chain precursors and expands the synthetic potential of DERA toward the generation of new classes of bioactive compounds. Full article

DNAzymes are catalytically active single-stranded DNAs that fold into metal-ion-assisted architectures to mediate diverse reactions. Addressing the performance gap in biological settings, we establish a novel conceptual framework based on a continuous iteration workflow of selection, enhancement, and application. This paradigm integrates selection constraints, molecular engineering, and clinical context into a unified cycle. We summarize the evolution of SELEX toward application-driven selection incorporating functional/environmental constraints, deep-sequencing-enabled high-throughput activity readouts, droplet compartmentalization and structure- and computation-guided design. We further consolidate engineering strategies to improve stability, kinetics and controllability, including 2′-sugar modifications and XNA substitution, backbone and nucleobase functionalization, arm and secondary-structure engineering for switchable or split architectures and multivalent organization on nanocarriers or nucleic acid scaffolds to enhance local concentration, protection and targeted delivery. Finally, we survey applications in ultrasensitive biosensing and portable diagnostics, activatable and multimodal in vivo imaging, and therapies for cancer, inflammatory diseases and airway disorders, and outline translational priorities: data-driven design, next-generation delivery, standardized safety/PK-PD evaluation and scalable manufacturing, ultimately for clinical and point-of-care deployment. Full article

OGG1 and MUTYH are base excision repair (BER) DNA glycosylases (DGs) from the Helix–hairpin–Helix superfamily responsible for initiating and coordinating the repair of 8-oxo-7,8-dihydroguanine (OG), and its replication-derived mispair with adenine (OG:A), respectively. The DNA repair activities of these DGs are pivotal to safeguarding nuclear and mitochondrial genomes. Indeed, DG functional impairment is associated with numerous pathologies, including neurodegenerative diseases, metabolic syndromes, and cancer. The timely and precise localization and processing of oxidized nucleobases carried out by these DGs are modulated by a complex regulatory network at both transcriptional and posttranslational levels, as well as intricate protein–protein interaction networks. In the absence of regulation, inappropriate and imbalanced DG activity may trigger telomeric instability, changes in transcriptional profiles and cell death. This review focuses on summarizing key features of OGG1 and MUTYH function, with a special emphasis on structure, regulation, and novel emerging roles. Full article

Traditional prebiotic chemistry experiments often isolated single reactions under clean, controlled conditions, yet early Earth was chemically diverse and physically dynamic. Such primordial complexity likely imposed obstacles, including side reactions, low yields, and unstable intermediates, but it also generated opportunities, including redundant routes, parallel pathways, and environmental filters that could bias mixtures toward subsets of persistent and chemically productive compounds. This review examines how heterogeneous prebiotic settings could generate RNA precursors, including nucleobases, ribose, and phosphate-containing species, through multiple concurrent pathways. Although side reactions can sequester carbon in inert tars and reduce yields of specific targets, networked chemistry can also enhance robustness when different routes converge on shared intermediates, or when apparent byproducts reenter productive cycles. Environmental factors such as ultraviolet irradiation, mineral surfaces, wet-dry cycling, and thermal gradients can act as constraints that enrich certain products by differential stability, reactivity, and compartmentalization. In this context, the RNA world hypothesis remains compelling, as RNA can store heritable sequence information and catalyze reactions through sequence dependent folding, thereby linking heredity and chemistry within a single polymer. At the same time, the emergence of functional sequence information and of control architectures that couple sequence to reproducible function remains a central open problem, and it sets clear limits on what chemistry alone can explain. Rather than dismissing messy mixtures as irrelevant noise, it is more accurate to treat them as the native context in which concentration mechanisms, environmental cycling, and selective persistence could enable the accumulation and survival of RNA related molecules. Full article

Background/Objectives: Tyrosinemia type 1 (HT-1) is a treatable inherited disorder characterized by disrupted tyrosine metabolism, leading to severe liver, renal, and occasionally neurological dysfunction. Early diagnosis by newborn screening markedly reduces the risk of hepatocellular carcinoma (HCC), the most serious complication. A deeper understanding of HT-1 pathophysiology is necessary to prevent disease complications and improve diagnostic and therapeutic strategies. This study explored the untargeted serum metabolomic profiles of HT-1 patients. Methods: High-resolution untargeted metabolomics coupled with liquid chromatography was applied for serum analysis of 16 late-diagnosed Chilean HT-1 patients on nitisinone (NTBC) therapy and 16 age- and sex-matched controls. The statistically significant up- and down-regulated features were used for annotation and association with different metabolic pathways. Results: Untargeted metabolomics revealed 1066 features significantly changed in HT-1 patients. Increased metabolites included aromatic compounds, medium- and long-chain acyl-carnitines, bile acids (prevalently taurine-conjugated), indole-based compounds, modified nucleosides and nucleobases. Decreased metabolites were mainly related to lipid class, including lysophosphatidylcholines, lysophosphatidic acids, long-chain fatty acids, and acylglycerols. Conclusions: Untargeted metabolomics showed perturbation of tyrosine- and tryptophan-related pathways and described a novel HT-1 metabolomic pattern demonstrating net dysregulation of lipid and bile acid metabolism in NTBC-treated patients with delay diagnoses. Increased acylcarnitines, taurine-conjugated bile acids, modified nucleobases, and reduced lysophosphatidylcholines overlap with the metabolomic pattern previously reported in Wnt/β-catenin-associated HCC. Although direct mechanistic link cannot be established in this study, these alterations may reflect persistent disease-related metabolic adaptations and warrant further investigation to clarify their potential relevance with long-term complications. Full article

To develop a modifier based on diethanolamine, a corresponding phosphoramidite for automated solid-phase deoxyribonucleic acid synthesis was synthesized. The influence of this modifier on the thermal stability of the terminally modified nucleic acids showed a dependence on the neighboring nucleobases and could be attributed to the fraying of the DNA ends. The potential for modification with dioxazaborocanes was first investigated using a small molecule model, and the formation of the dioxazaborocane was confirmed both in solution and in the solid state. Such a modification could expand the scope of xenonucleic acids in the future and modulate the properties of nucleic acids in solution. The influence on the thermal stability of the modified nucleic acids was minimal. In the future, this modification will be extended to internal incorporation and the potential of dioxazaborocanes in the nucleic acid context will be further exploited. Full article

We demonstrate that gold nanoparticles (AuNPs) are capable of unwinding double-stranded (ds) DNA. Upon unwinding, the exposed nucleobases of the separated strands adsorb onto the nanoparticle surface, resulting in the coating of the particles. The unwinding process was characterized by Atomic Force Microscopy (AFM) and absorption spectroscopy. Our results show that AuNPs initially bind to single-stranded overhangs at the duplex termini, forming dsDNA–nanoparticle dumbbells. This binding event subsequently initiates the separation of the DNA strands. As the unwinding proceeds, the nanoparticles become progressively wrapped by the unwound DNA strands, which leads to a gradual reduction in the interparticle distance within the dumbbells. This process is driven by the strong affinity of nucleobases for the gold surface. The efficiency of DNA unwinding was found to depend strongly on both nanoparticle size and temperature. These findings provide new insights into DNA-nanoparticle interactions and may facilitate the rational design of DNA–AuNP hybrid nanostructures such as dumbbell-shaped conjugates for applications in DNA-based nanoelectronics, biosensing, and self-assembled nanomaterials. Full article

Since 1978, platinum-based drugs have benefited countless cancer patients and come to form the foundation of many cancer pharmacotherapies. These drugs induce apoptosis in cancer cells by forming cross-links between nucleobases in the DNA. Our previous studies have shown that these drugs can also interact with other similar compounds whose structures resemble nucleobases. Therefore, this study analyzed the interactions of Cisplatin, Carboplatin, and Oxaliplatin with Pyridine derivatives (Nicotinic acid, Nicotinamide, Isonicotinic acid, and Picolinic acid). These values were then compared with those for Guanine and Adenine coming from DNA using spectroscopic methods and computational chemistry (B3LYP/6-31G(d,p) and MN15/def2-TZVP methods). Theoretical studies suggest cytostatic affinity, not only for nucleobases but also for Pyridine derivatives. Experimental studies have confirmed these theoretical results. Full article

Protein and nucleic acid play central roles in biology and pharmaceuticals. Both share a similar architecture made of a backbone and side chains. Protein has a peptide backbone and various side chains, whereas nucleic acid has a phosphate backbone and aromatic side chains. However, they are significantly different in the chemical properties of the backbone and side chains. The protein backbone is uncharged, while nucleic acid backbone is negatively charged. The protein side chains comprise widely different chemical properties. On the other hand, the nucleic acid side chains comprise a uniform chemical property of aromatic bases. Such differences lead to fundamentally different folding, molecular interactions and co-solvent interactions, which are the focus of this review. In regular protein secondary structures, the peptide groups form polar hydrogen bonds, making the interior hydrophilic. The side chains of different chemical properties are exposed on the outside of the protein secondary structures and participate in molecular and co-solvent interactions. On the other hand, hydrophobic/aromatic nucleobase side chains are located inside the typical double helix or quadruplex structures. The charged phosphate groups of the nucleic acid backbone are located outside, participating in electrostatic interactions. The nucleobases are also involved in molecular interactions, when exposed in breaks, hairpins, kinks and loops. These structural differences between protein and nucleic acid confer different interactions with commonly used co-solvents, such as denaturants, organic solvents and polymers. Full article

For decades, 8-oxoguanine (8-oxoG) has been recognized as a pervasive and pro-mutagenic oxidative DNA lesion. In human cells, 8-oxoG is removed from DNA via the base excision repair pathway initiated by 8-oxoguanine–DNA glycosylase (OGG1). However, emerging evidence over the past twenty years suggests a more complex, regulatory role for this DNA modification. Here, we discuss findings that 8-oxoG, particularly when present in gene promoters, can act as a signal to modulate transcription, establishing an 8-oxoG/OGG1 axis in the inflammatory response. Proposed mechanisms include the generation of 8-oxoG during chromatin remodeling processes involving histone demethylases, the recruitment of transcription factors (NF-κB, HIF1α, Myc, SMAD, etc.) by OGG1, and the lesion’s enrichment in guanine-rich sequences prone to forming G-quadruplex structures. The pro-mutagenic nature of 8-oxoG and the lack of dedicated, functionally separate writer and reader proteins challenge its classification as a true epigenetic DNA mark, distinguishing it from canonical epigenetic nucleobases like 5-methylcytosine and 5-hydroxymethylcytosine. On the other hand, 8-oxoG is well suited for the role of a regulatory signal localized to DNA and involved in the cellular response to oxidative stress and the associated physiological stimuli. Full article

Nucleopeptides (NPs) are unnatural hybrid polymers designed by coupling nucleobases to the side chains of amino acid residues within peptides. In this study, we present the synthesis of an Fmoc-protected nucleobase amino acid (NBA) monomer (Fmoc-1,4-TzlNBA_A) with adenine attached to the side chain of L-homoazidoalanine (Aha) through a 1,4-linked-1,2,3-triazole. The coupling was accomplished by a Cu(I)-catalyzed azide–alkyne cycloaddition (CuAAC) of Fmoc-Aha and N9-propargyladenine. Subsequently, a homotrinucleopeptide (HalTzl_AAA) containing three 1,4-TzlNBA_A residues was synthesized, using different solid-phase peptide synthesis (SPPS) approaches, and its ability to recognize U-rich motifs of RNAs involved in the HIV replication cycle was studied using circular dichroism (CD) and fluorescence spectroscopy. CD curves confirmed the binding of HalTzl_AAA to U-rich motifs of the transactivation responsive element (TAR UUU RNA HIV-1) bulge and the anticodon stem–loop domain of human tRNALys3 (ASLLys3) by a decrease in the positive ellipticity band intensity around 265 nm during the complexation. 5′-(FAM(6))-labeled TAR UUU and hASLLys3 were used for fluorescence anisotropy binding studies. Fluorescence data revealed that HalTzl_AAA bound TAR’s UUU bulge with a moderate affinity (K_d ≈ 38 µM), whereas the ASLLys3 UUUU-containing loop sequence was recognized with 2.5 times lower affinity (with K_d ≈ 75 µM). Both the standard SPPS method and its variants, which involved the attachment of adenine to the L-Aha side chain using the click reaction during the synthesis on the resin or after the nucleopeptide cleavage, were characterized by a similar efficiency and yield. The CD and fluorescence results demonstrated that HalTzl_AAA recognized the U-rich sequences of the RNAs with moderate and varied affinities. It is likely that both the hydrogen bonds associated with the complementarity of the interacting sequences and the conformational aspects associated with the high conformational dynamics of U-rich motifs are important in the recognition process. The nucleopeptide represents a new class of RNA binders and may be a promising scaffold for the development of new antiviral drugs. Full article