A chloromethyl-triazole fluorescent chemosensor for O6-methylguanine DNA methyltransferase.

Fluorescent chemosensors offer a direct means of measuring enzyme activity for cancer diagnosis, predicting drug resistance, and aiding in the discovery of new anticancer drugs. O6-methylguanine DNA methyltransferase (MGMT) is a predictor of resistance towards anticancer alkylating agents such as temozolomide. Using the fluorescent molecular rotor, 9-(2-carboxy-2-cyanovinyl)julolidine (CCVJ), we synthesized, and evaluated a MGMT fluorescent chemosensor derived from a chloromethyl-triazole covalent inhibitor, AA-CW236, a non-pseudosubstrate of MGMT. Our fluorescence probe covalently labelled the MGMT active site C145, producing a 18-fold increase in fluorescence. Compared to previous fluorescent probes derived from a substrate-based inhibitor, our probe had improved binding and reaction rate. Overall, our chloromethyl triazole-based fluorescence MGMT probe is a promising tool for measuring MGMT activity to predict temozolomide resistance.

C5-Propynyl modified 2'-fluoroarabinonucleic acids form stable duplexes with RNA that are RNase H competent.

The clinical success of the antisense approach for the treatment of genetic disorders is indisputably the result of chemical modifications along the oligonucleotide (ON) scaffold, which impart desirable properties including high RNA affinity, nuclease stability and improved drug delivery. While effective, many modifications are not capable of eliciting an RNase H response limiting their application in antisense systems. To contribute to the structural design and inventory of nucleoside analogues with favorable antisense properties, herein we describe the synthesis of C5-propynyl-2'-fluoroarabinonucleic acids (FANAP). Incorporation of individual and multiple uridine (FaraUP) and cytidine (FaraCP) inserts into ONs revealed, both stabilized duplexes formed with RNA. In contrast, these modifications demonstrated a negligible (FaraUP) or reduced (FaraCP) effect on DNA binding. Moreover, modified ONs containing these analogues supported E. coli RNase H cleavage of RNA with an altered cleavage pattern observed relative to controls. Moreover, a 2'-O-methoxyethyl (2'-O-MOE) gapmer with a FANAP core was able to elicit RNA cleavage at an increased rate compared to C5-propynyl-arabinonucleic acids (ANAP). Enzymatic hydrolysis of these gapmers was assessed with nuclease S1 digestion and revealed greater stability of ANAP compared to FANAP. These results suggest C5-propynyl ANA/FANA modifications demonstrate promising potential for the design of therapeutic ONs.

Oligonucleotides Containing C5-Propynyl Modified Arabinonucleic Acids: Synthesis, Biophysical and Antisense Properties.

The introduction of chemical modifications on the nucleic acid scaffold has allowed for the progress of antisense oligonucleotides (ASOs) in the clinic for the treatment of a variety of disorders. In contribution to the repertoire of gene-silencing nucleic acid modifications, herein we report the synthesis and incorporation of C5-propynyl arabinouridine (araUP ) and arabinocytidine (araCP ) into mixed-base ASOs containing a pyrimidine core. Substitution of the core with araUP and araCP resulted in stabilization of the duplex formed with RNA but not with DNA. Similar results were obtained with ASOs bearing phosphorothioate linkages or methoxyethyl (MOE) wings in a gapmer design. All modified ASOs were compatible with E. coli RNase H mediated degradation of target RNA. Substitution of DNA for araUP and araCP in the central portion of a gapmer with MOE wings demonstrated improved nuclease resistance. These results suggest C5-modified arabinonucleic acids may serve as a potential chemical modification for therapeutic ASOs.

Preparation of a Convertible Spacer Containing a Disulfide Group for Versatile Functionalization of Oligonucleotides.

The protocols described in this article provide details regarding the synthesis and characterization of a disulfide containing linker phosphoramidite for terminal functionalization of synthetic oligonucleotides. The linker is first synthesized from 6-mercaptohexanol in two steps and is incorporated at the 5' end of short DNA oligonucleotides using automated solid-phase synthesis. The linker contains a terminal tosylate group which is post-synthetically displaced by altering the deprotection conditions to yield a variety of functional handles (N3 , NH2 , OMe, SH) or alternatively, the tosylate can be displaced directly with primary amines such as tert-butylamine. The linker system is also compatible with RNA oligonucleotides enabling the introduction of various functional handles (N3 , NH2 ). The protocol outlined in this procedure provides access to a versatile linker for the terminal functionalization of oligonucleotides containing a disulfide bond which may serve useful in the synthesis of reduction-responsive oligonucleotide conjugates. As a proof of concept, in this protocol the linker is used to modify a dT10 oligonucleotide and then conjugated by copper(I)-mediated azide-alkyne cycloaddition (CuAAC) to an alkyne-modified poly(ethylene glycol) which shows concentration dependent release of the oligonucleotide upon treatment with 1,4-dithiothreitol, a reducing agent. © 2023 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Preparation of disulfide linker phosphoramidite 3 Basic Protocol 2: Synthesis, functionalization, and characterization of DNA oligonucleotides containing disulfide linker phosphoramidite 3 Basic Protocol 3: Displacement of terminal tosylate functionalized DNA with primary aliphatic amines Basic Protocol 4: Synthesis of oligonucleotide-PEG conjugate Support Protocol: Preparation of PEG-alkyne.

Structural basis of 3'-end poly(A) RNA recognition by LARP1.

La-related proteins (LARPs) comprise a family of RNA-binding proteins involved in a wide range of posttranscriptional regulatory activities. LARPs share a unique tandem of two RNA-binding domains, La motif (LaM) and RNA recognition motif (RRM), together referred to as a La-module, but vary in member-specific regions. Prior structural studies of La-modules reveal they are pliable platforms for RNA recognition in diverse contexts. Here, we characterize the La-module of LARP1, which plays an important role in regulating synthesis of ribosomal proteins in response to mTOR signaling and mRNA stabilization. LARP1 has been well characterized functionally but no structural information exists for its La-module. We show that unlike other LARPs, the La-module in LARP1 does not contain an RRM domain. The LaM alone is sufficient for binding poly(A) RNA with submicromolar affinity and specificity. Multiple high-resolution crystal structures of the LARP1 LaM domain in complex with poly(A) show that it is highly specific for the RNA 3'-end, and identify LaM residues Q333, Y336 and F348 as the most critical for binding. Use of a quantitative mRNA stabilization assay and poly(A) tail-sequencing demonstrate functional relevance of LARP1 RNA binding in cells and provide novel insight into its poly(A) 3' protection activity.

Synthesis of a Convertible Linker Containing a Disulfide Group for Oligonucleotide Functionalization.

The synthesis and incorporation of a tosylated phosphoramidite linker containing a disulfide bond is described. Incorporation of the linker into short DNA and RNA oligomers proceeded efficiently using automated solid phase synthesis. Treatment of the support bound oligonucleotide followed by cleavage from the solid support provided a variety of common functional handles, expanding the strategies of bifunctional modification of synthetic oligonucleotides for conjugation applications.

Arabinonucleic acids containing C5-propynyl modifications form stable hybrid duplexes with RNA that are efficiently degraded by E. coli RNase H.

The promise of the antisense approach to treat a variety of diseases with oligonucleotides and solutions to challenges that have been encountered in their development is attributable to chemical modification of the nucleic acid scaffold. Herein, we describe preliminary data regarding the synthesis of a novel C5-propynyl-ß-d-arabinouridine (araUP) phosphoramidite and its incorporation into oligonucleotides. Substitution of araUP in dT18 results in minor stabilization of duplexes formed with RNA when modifications are placed consecutively and a uniformly modified araUP 18-mer increases stability by 34 °C relative to DNA. The modified oligomer exhibits improved nuclease and serum stability when compared to DNA and duplexes formed between RNA and araUP oligonucleotides are substrates for E. coli RNase H. These preliminary results merit further investigation into C5-propynyl modified arabino nucleic acids for potential therapeutic gene silencing applications.

Generation of oligonucleotide conjugates via one-pot diselenide-selenoester ligation-deselenization/alkylation.

A breadth of strategies are needed to efficiently modify oligonucleotides with peptides or lipids to capitalize on their therapeutic and diagnostic potential, including the modulation of in vivo chemical stability and for applications in cell-targeting and cell-permeability. The chemical linkages typically used in peptide oligonucleotide conjugates (POCs) have limitations in terms of stability and/or ease of synthesis. Herein, we report an efficient method for POC synthesis using a diselenide-selenoester ligation (DSL)-deselenization strategy that rapidly generates a stable amide linkage between the two biomolecules. This conjugation strategy is underpinned by a novel selenide phosphoramidite building block that can be incorporated into an oligonucleotide by solid-phase synthesis to generate diselenide dimer molecules. These can be rapidly ligated with peptide selenoesters and, following in situ deselenization, lead to the efficient generation of POCs. The diselenide within the oligonucleotide also serves as a flexible functionalisation handle that can be leveraged for fluorescent labelling, as well as for alkylation to generate micelles.

Beyond ribose and phosphate: Selected nucleic acid modifications for structure-function investigations and therapeutic applications.

Over the past 25 years, the acceleration of achievements in the development of oligonucleotide-based therapeutics has resulted in numerous new drugs making it to the market for the treatment of various diseases. Oligonucleotides with alterations to their scaffold, prepared with modified nucleosides and solid-phase synthesis, have yielded molecules with interesting biophysical properties that bind to their targets and are tolerated by the cellular machinery to elicit a therapeutic outcome. Structural techniques, such as crystallography, have provided insights to rationalize numerous properties including binding affinity, nuclease stability, and trends observed in the gene silencing. In this review, we discuss the chemistry, biophysical, and structural properties of a number of chemically modified oligonucleotides that have been explored for gene silencing.

Recent Advances of DNA Tetrahedra for Therapeutic Delivery and Biosensing.

The chemical and self-assembly properties of nucleic acids make them ideal for the construction of discrete structures and stimuli-responsive devices for a diverse array of applications. Amongst the various three-dimensional assemblies, DNA tetrahedra are of particular interest, as these structures have been shown to be readily taken up by the cell, by the process of caveolin-mediated endocytosis, without the need for transfection agents. Moreover, these structures can be readily modified with a diverse range of pendant groups to confer greater functionality. This minireview highlights recent advances related to applications of this interesting DNA structure including the delivery of therapeutic agents ranging from small molecules to oligonucleotides in addition to its use for sensing and imaging various species within the cell.

Dual-Location Dual-Acid/Glutathione-Degradable Cationic Micelleplexes through Hydrophobic Modification for Enhanced Gene Silencing.

Gene therapy holds great promise for the treatment of acquired genetic disorders such as cancer with reduced side effects compared to chemotherapy. For gene therapy to be successful, it is crucial to develop efficient and nontoxic gene carriers to overcome the poor in vivo stability and low cellular uptake of nucleic acid-based therapeutic agents. Here, we report a new and versatile approach exploring a combination of hydrophobic modifications and dual-stimuli-responsive degradation (SRD) for controlled gene delivery with amphiphilic block copolymer-based nanocarriers. The block copolymer, synthesized by atom transfer radical polymerization, is designed with an acid-labile acetal linkage at the block junction and a pendant disulfide group in the hydrophobic block. The incorporation of labile linkages enables both disulfide-core-cross-linking and dual-location dual-acid/reduction-responsive degradation (DL-DSRD). Furthermore, the disulfide linkages integrated as hydrophobic moieties facilitate the nucleic acids to condense into nanometer-sized micelleplexes through electrostatic interactions of pendant dimethylamino groups with the anionic phosphate groups of the nucleic acids. Our preliminary results demonstrate that the DL-DSRD approach through hydrophobic modification is a robust platform in the development of gene delivery systems with enhanced colloidal stability, reduced cytotoxicity, and improved gene transfection efficiency.

O6 -Alkylguanine DNA Alkyltransferase Mediated Disassembly of a DNA Tetrahedron.

Tetrahedron DNA structures were formed by the assembly of three-way junction (TWJ) oligonucleotides containing O6 -2'-deoxyguanosine-alkylene-O6 -2'-deoxyguanosine (butylene and heptylene linked) intrastrand cross-links (IaCLs) lacking a phosphodiester group between the 2'-deoxyribose residues. The DNA tetrahedra containing TWJs were shown to undergo an unhooking reaction by the human DNA repair protein O6 -alkylguanine DNA alkyltransferase (hAGT) resulting in structure disassembly. The unhooking reaction of hAGT towards the DNA tetrahedra was observed to be moderate to virtually complete depending on the protein equivalents. DNA tetrahedron structures have been explored as drug delivery platforms that release their payload in response to triggers, such as light, chemical agents or hybridization of release strands. The dismantling of DNA tetrahedron structures by a DNA repair protein contributes to the armamentarium of approaches for drug release employing DNA nanostructures.

Covalent capture of OGT's active site using engineered human-E. coli chimera and intrastrand DNA cross-links.

O 6-Alkylguanine DNA alkyltransferases (AGTs) are proteins found in most organisms whose role is to remove alkylation damage from the O6- and O4-positions of 2'-deoxyguanosine (dG) and thymidine (dT), respectively. Variations in active site residues between AGTs from different organisms leads to differences in repair proficiency: The human variant (hAGT) has a proclivity for removal of alkyl groups at the O6-position of guanine and the E. coli OGT protein has activity towards the O4-position of thymine. A chimeric protein (hOGT) that our laboratory has engineered with twenty of the active site residues mutated in hAGT to those found in OGT, exhibited activity towards a broader range of substrates relative to native OGT. Among the substrates that the hOGT protein was found to act upon was interstrand cross-linked DNA connected by an alkylene linkage at the O6-position of dG to the complementary strand. In the present study the activity of hOGT towards DNA containing alkylene intrastrand cross-links (IaCL) at the O6- and O4-positions respectively of dG and dT, which lack a phosphodiester linkage between the connected residues, was evaluated. The hOGT protein exhibited proficiency at removal of an alkylene linkage at the O6-atom of dG but the O4-position of dT was refractory to protein activity. The activity of the chimeric hOGT protein towards these IaCLs to prepare well defined DNA-protein cross-linked conjugates will enable mechanistic and high resolution structural studies to address the differences observed in the repair adeptness of O4-alkylated dT by the OGT protein relative to other AGT variants.

O4 -Alkylated-2-Deoxyuridine Repair by O6 -Alkylguanine DNA Alkyltransferase is Augmented by a C5-Fluorine Modification.

Oligonucleotides containing various adducts, including ethyl, benzyl, 4-hydroxybutyl and 7-hydroxyheptyl groups, at the O4 atom of 5-fluoro-O4 -alkyl-2'-deoxyuridine were prepared by solid-phase synthesis. UV thermal denaturation studies demonstrated that these modifications destabilised the duplex by approximately 10 °C, relative to the control containing 5-fluoro-2'-deoxyuridine. Circular dichroism spectroscopy revealed that these modified duplexes all adopted a B-form DNA structure. O6 -Alkylguanine DNA alkyltransferase (AGT) from humans (hAGT) was most efficient at repair of the 5-fluoro-O4 -benzyl-2'-deoxyuridine adduct, whereas the thymidine analogue was refractory to repair. The Escherichia coli AGT variant (OGT) was also efficient at removing O4 -ethyl and benzyl adducts of 5-fluoro-2-deoxyuridine. Computational assessment of N1-methyl analogues of the O4 -alkylated nucleobases revealed that the C5-fluorine modification had an influence on reducing the electron density of the O4 -Cα bond, relative to thymine (C5-methyl) and uracil (C5-hydrogen). These results reveal the positive influence of the C5-fluorine atom on the repair of larger O4 -alkyl adducts to expand knowledge of the range of substrates able to be repaired by AGT.

Altering Residue 134 Confers an Increased Substrate Range of Alkylated Nucleosides to the E. coli OGT Protein.

O6-Alkylguanine-DNA alkyltransferases (AGTs) are proteins responsible for the removal of mutagenic alkyl adducts at the O6-atom of guanine and O4-atom of thymine. In the current study we set out to understand the role of the Ser134 residue in the Escherichia coli AGT variant OGT on substrate discrimination. The S134P mutation in OGT increased the ability of the protein to repair both O6-adducts of guanine and O4-adducts of thymine. However, the S134P variant was unable, like wild-type OGT, to repair an interstrand cross-link (ICL) bridging two O6-atoms of guanine in a DNA duplex. When compared to the human AGT protein (hAGT), the S134P OGT variant displayed reduced activity towards O6-alkylation but a much broader substrate range for O4-alkylation damage reversal. The role of residue 134 in OGT is similar to its function in the human homolog, where Pro140 is crucial in conferring on hAGT the capability to repair large adducts at the O6-position of guanine. Finally, a method to generate a covalent conjugate between hAGT and a model nucleoside using a single-stranded oligonucleotide substrate is demonstrated.

AGT Activity Towards Intrastrand Crosslinked DNA is Modulated by the Alkylene Linker.

DNA oligomers containing dimethylene and trimethylene intrastrand crosslinks (IaCLs) between the O4 and O6 atoms of neighboring thymidine (T) and 2'-deoxyguanosine (dG) residues were prepared by solid-phase synthesis. UV thermal denaturation (Tm ) experiments revealed that these IaCLs had a destabilizing effect on the DNA duplex relative to the control. Circular dichroism spectroscopy suggested these IaCLs induced minimal structural distortions. Susceptibility to dealkylation by reaction with various O6 -alkylguanine DNA alkyltransferases (AGTs) from human and Escherichia coli was evaluated. It was revealed that only human AGT displayed activity towards the IaCL DNA, with reduced efficiency as the IaCL shortened (from four to two methylene linkages). Changing the site of attachment of the ethylene linkage at the 5'-end of the IaCL to the N3 atom of T had minimal influence on duplex stability and structure, and was refractory to AGT activity.

Influence of nucleotide modifications at the C2' position on the Hoogsteen base-paired parallel-stranded duplex of poly(A) RNA.

Polyadenylate (poly(A)) has the ability to form a parallel duplex with Hoogsteen adenine:adenine base pairs at low pH or in the presence of ammonium ions. In order to evaluate the potential of this structural motif for nucleic acid-based nanodevices, we characterized the effects on duplex stability of substitutions of the ribose sugar with 2'-deoxyribose, 2'-O-methyl-ribose, 2'-deoxy-2'-fluoro-ribose, arabinose and 2'-deoxy-2'-fluoro-arabinose. Deoxyribose substitutions destabilized the poly(A) duplex both at low pH and in the presence of ammonium ions: no duplex formation could be detected with poly(A) DNA oligomers. Other sugar C2' modifications gave a variety of effects. Arabinose and 2'-deoxy-2'-fluoro-arabinose nucleotides strongly destabilized poly(A) duplex formation. In contrast, 2'-O-methyl and 2'-deoxy-2'-fluoro-ribo modifications were stabilizing either at pH 4 or in the presence of ammonium ions. The differential effect suggests they could be used to design molecules selectively responsive to pH or ammonium ions. To understand the destabilization by deoxyribose, we determined the structures of poly(A) duplexes with a single DNA residue by nuclear magnetic resonance spectroscopy and X-ray crystallography. The structures revealed minor structural perturbations suggesting that the combination of sugar pucker propensity, hydrogen bonding, pKa shifts and changes in hydration determine duplex stability.

Structural basis of interstrand cross-link repair by O6-alkylguanine DNA alkyltransferase.

DNA interstrand cross-links (ICL) are among the most cytotoxic lesions found in biological systems. O6-Alkylguanine DNA alkyltransferases (AGTs) are capable of removing alkylation damage from the O6-atom of 2'-deoxyguanosine and the O4-atom of thymidine. Human AGT (hAGT) has demonstrated the ability to repair an interstrand cross-linked duplex where two O6-atoms of 2'-deoxyguanosine were tethered by a butylene (XLGG4) or heptylene (XLGG7) linkage. However, the analogous ICL between the O4-atoms of thymidine was found to evade repair. ICL duplexes connecting the O4-atoms of 2'-deoxyuridine by a butylene (XLUU4) or heptylene (XLUU7) linkage have been prepared to examine the influence of the C5-methyl group on AGT-mediated repair. Both XLUU4 and XLUU7 were refractory to repair by human and E. coli (OGT and Ada-C) AGTs with comparably low µM dissociation constants for 2 : 1 or 4 : 1 AGT/DNA stoichiometries. The solution structures of two heptylene linked DNA duplexes (CGAAAYTTTCG)2, XLUU7 (Y = dU) and XLGG7 (Y = dG), were solved and the global structures were virtually identical with a RMSD of 1.22 Å. The ICL was found to reside in the major groove for both duplexes. The linkage adopts an E conformation about the C4-O4 bond for XLUU7 whereas a Z conformation about the C6-O6 bond was observed for XLGG7. This E versus Z conformation may partially account for hAGTs discrimination towards the repair of these ICL, supported by the crystal structures of hAGT with various substrates which have been observed to adopt a Z conformation. In addition, a higher mobility at the ICL site for XLUU7 is observed relative to XLGG7 that may play a role in repair by hAGT. Taken together, these findings provide insights on the AGT-mediated repair of cytotoxic ICL in terms of its processing capability and substrate specificity.

O6-2'-Deoxyguanosine-butylene-O6-2'-deoxyguanosine DNA Interstrand Cross-Links Are Replication-Blocking and Mutagenic DNA Lesions.

DNA interstrand cross-links (ICLs) are cytotoxic DNA lesions derived from reactions of DNA with a number of anti-cancer reagents as well as endogenous bifunctional electrophiles. Deciphering the DNA repair mechanisms of ICLs is important for understanding the toxicity of DNA cross-linking agents and for developing effective chemotherapies. Previous research has focused on ICLs cross-linked with the N7 and N2 atoms of guanine as well as those formed at the N6 atom of adenine; however, little is known about the mutagenicity of O6-dG-derived ICLs. Although less abundant, O6-alkylated guanine DNA lesions are chemically stable and highly mutagenic. Here, O6-2'-deoxyguanosine-butylene-O6-2'-deoxyguanosine (O6-dG-C4-O6-dG) is designed as a chemically stable ICL, which can be induced by the action of bifunctional alkylating agents. We investigate the DNA replication-blocking and mutagenic properties of O6-dG-C4-O6-dG ICLs during an important step in ICL repair, translesion DNA synthesis (TLS). The model replicative DNA polymerase (pol) Sulfolobus solfataricus P2 DNA polymerase B1 (Dpo1) is able to incorporate a correct nucleotide opposite the cross-linked template guanine of ICLs with low efficiency and fidelity but cannot extend beyond the ICLs. Translesion synthesis by human pol κ is completely inhibited by O6-dG-C4-O6-dG ICLs. Moderate bypass activities are observed for human pol Î· and S. solfataricus P2 DNA polymerase IV (Dpo4). Among the pols tested, pol Î· exhibits the highest bypass activity; however, 70% of the bypass products are mutagenic containing substitutions or deletions. The increase in the size of unhooked repair intermediates elevates the frequency of deletion mutation. Lastly, the importance of pol Î· in O6-dG-derived ICL bypass is demonstrated using whole cell extracts of Xeroderma pigmentosum variant patient cells and those complemented with pol Î·. Together, this study provides the first set of biochemical evidence for the mutagenicity of O6-dG-derived ICLs.

Preparation of Intrastrand {G}O(6) -Alkylene-O(6) {G} Cross-Linked Oligonucleotides.

This unit describes the preparation O(6) -2'-deoxyguanosine-butylene-O(6) -2'-deoxyguanosine dimer phosphoramidites and precursors for incorporation of site-specific intrastrand cross-links (IaCL) into DNA oligonucleotides. Protected 2'-deoxyguanosine dimers are produced using the Mitsunobu reaction. IaCL DNA containing the intradimer phosphodiester are first chemically phosphorylated, followed by a ring-closing reaction using the condensing reagent 1-(2-mesitylenesulfonyl)-3-nitro-1H-1,2,4-triazole. Phosphoramidites are incorporated into oligonucleotides by solid-phase synthesis and standard deprotection and cleavage protocols are employed. This approach allows for the preparation of IaCL DNA substrates in amounts and purity amenable for biophysical characterization, and biochemical studies as substrates to investigate DNA repair and bypass pathways. © 2016 by John Wiley & Sons, Inc.