The folding of long DNA strands into designed nanostructures has evolved into an art. Being based on linear chains only, the resulting nanostructures cannot readily be transformed into covalently linked frameworks. Covalently linking strands in the context of folded DNA structures requires a robust method that avoids sterically demanding reagents or enzymes. Here we report chemical ligation of the 3′-amino termini of oligonucleotides and 5′-phosphorylated partner strands in templated reactions that produce phosphoramidate linkages. These reactions produce inter-nucleotide linkages that are isoelectronic and largely isosteric to phosphodiesters. Ligations were performed at three levels of complexity, including the extension of branched DNA hybrids and the ligation of six scaffold strands in a small origami.

Molecular storage solutions for incorporating small molecules in crystalline matrices are of interest in the context of structure elucidation, decontamination, and slow release of active ingredients. Here we report the syntheses of 1,3,5,7-tetrakis(2,4-dimethoxyphenyl)adamantane, 1,3,5,7-tetrakis(4-methoxyphenyl)adamantane, 1,3,5,7-tetrakis(4-methoxy-2-methylphenyl)adamantane, and 1,3,5,7-tetrakis(4-methoxy-2-ethylphenyl)adamantane, together with their X-ray crystal structures. All four compounds crystallize readily. Only the octaether shows an unusual level of (pseudo)polymorphism in its crystalline state, combined with the ability to include a number of different small molecules in its crystal lattices. A total of 20 different inclusion complexes with guest molecules as different as ethanol or trifluorobenzene were found. For nitromethane and benzene, schemes for uptake and release are presented.

Cofactors are critical for energy-consuming processes in the cell. Harnessing such processes for practical applications requires control over the concentration of cofactors. We have recently shown that DNA triplex motifs with a designed binding site can be used to capture and release nucleotides with low micromolar dissociation constants. In order to increase the storage capacity of such triplex motifs, we have explored the limits of ligand binding through designed cavities in the oligopurine tract. Oligonucleotides with up to six non-nucleotide bridges between purines were synthesized and their ability to bind ATP, cAMP or FAD was measured. Triplex motifs with several single-nucleotide binding sites were found to bind purines more tightly than triplexes with one large binding site. The optimized triplex consists of 59 residues and four C3-bridges. It can bind up to four equivalents of ligand with apparent K_d values of 52 µM for ATP, 9 µM for FAD, and 2 µM for cAMP. An immobilized version fuels bioluminescence via release of ATP at body temperature. These results show that motifs for high-density capture, storage and release of energy-rich biomolecules can be constructed from synthetic DNA.

Invited for the cover of this issue are Sven Vollmer and Clemens Richert of the University of Stuttgart. The cover image hints at the analogy between a honey comb, as a macroscopic storage device, and DNA triplexes with designed binding sites, as molecular storage motifs that can release ATP to fuel a bioluminescence reaction. Read the full text of the article at 10.1002/chem.201503220.

How the biochemical machinery evolved from simple precursors is an open question. Here we show that ribonucleotides and amino acids condense to peptidyl RNAs in the absence of enzymes under conditions established for genetic copying. Untemplated formation of RNA strands that can encode genetic information, formation of peptidyl chains linked to RNA, and formation of the cofactors NAD⁺, FAD, and ATP all occur under the same conditions. In the peptidyl RNAs, the peptide chains are phosphoramidate-linked to a ribonucleotide. Peptidyl RNAs with long peptide chains were selected from an initial pool when a lipophilic phase simulating the interior of membranes was offered, and free peptides were released upon acidification. Our results show that key molecules of genetics, catalysis, and metabolism can emerge under the same conditions, without a mineral surface, without an enzyme, and without the need for chemical pre-activation.

Template-directed incorporation of nucleotides at the terminus of a growing complementary strand is the basis of replication. For RNA, this process can occur in the absence of enzymes, if the ribonucleotides are first converted to an active species with a leaving group. Thus far, the activation required a separate chemical step, complicating prebiotically plausible scenarios. Here we show that a combination of a carbodiimide and an organocatalyst induces near-quantitative incorporation of any of the four ribonucleotides. Upon in situ activation, adenosine monophosphate was found to also form oligomers in aqueous solution. So, both de novo strand formation and sequence-specific copying can occur without an artificial synthetic step.

It is becoming increasingly clear that nature uses RNAs extensively for regulating vital functions of the cell, and short sequences are frequently used to suppress gene expression. However, controlling the concentration of small molecules intracellularly through designed RNA sequences that fold into ligand-binding structures is difficult. The development of “endless”, a triplex-based folding motif that can be expressed in mammalian cells and binds the second messenger 3′,5′-cyclic guanosine monophosphate (cGMP), is described. In vitro, DNA or RNA versions of endless show low micromolar to nanomolar dissociation constants for cGMP. To test its functionality in vivo, four endless RNA motifs arranged in tandem were co-expressed with a fluorescent cGMP sensor protein in murine vascular smooth muscle cells. Nitric oxide induced endogenous cGMP signals were suppressed in endless-expressing cells compared to cells expressing a control motif, which suggests that endless can act as a genetically encoded cGMP sink to modulate signal transduction in cells.

It is becoming increasingly clear that nature uses RNAs extensively for regulating vital functions of the cell, and short sequences are frequently used to suppress gene expression. However, controlling the concentration of small molecules intracellularly through designed RNA sequences that fold into ligand-binding structures is difficult. The development of “endless”, a triplex-based folding motif that can be expressed in mammalian cells and binds the second messenger 3′,5′-cyclic guanosine monophosphate (cGMP), is described. In vitro, DNA or RNA versions of endless show low micromolar to nanomolar dissociation constants for cGMP. To test its functionality in vivo, four endless RNA motifs arranged in tandem were co-expressed with a fluorescent cGMP sensor protein in murine vascular smooth muscle cells. Nitric oxide induced endogenous cGMP signals were suppressed in endless-expressing cells compared to cells expressing a control motif, which suggests that endless can act as a genetically encoded cGMP sink to modulate signal transduction in cells.

Binding RNA targets, such as microRNAs, with high fidelity is challenging, particularly when the nucleobases to be bound are located at the terminus of the duplex between probe and target. Recently, a peptidyl chain terminating in a quinolone, called ogOA, was shown to act as a cap that enhances affinity and fidelity for RNAs, stabilizing duplexes with Watson–Crick pairing at their termini. Here we report the three-dimensional structure of an intramolecular complex between a DNA strand featuring the ogOA cap and an RNA segment, solved by NMR and restrained torsion angle molecular dynamics. The quinolone stacks on the terminal base pair of the hybrid duplex, positioned by the peptidyl chain, whose prolinol residue induces a sharp bend between the 5′ terminus of the DNA chain and the glycine linked to the oxolinic acid residue. The structure explains why canonical base pairing is favored over hard-to-suppress mismatched base combinations, such as T:G and A:A, and helps to design improved high-fidelity probes for RNA.

Cofactors are pivotal compounds for the cell and many biotechnological processes. It is therefore interesting to ask how well cofactors can be bound by oligonucleotides designed not to convert but to store and release these biomolecules. Here we show that triplex-based DNA binding motifs can be used to bind nucleotides and cofactors, including NADH, FAD, SAM, acetyl CoA, and tetrahydrofolate (THF). Dissociation constants between 0.1 μM for SAM and 35 μM for THF were measured. A two-nucleotide gap still binds NADH. The selectivity for one ligand over the others can be changed by changing the sequence of the binding pocket. For example, a mismatch placed in one of the two triplets adjacent to the base-pairing site changes the selectivity, favoring the binding of FAD over that of ATP. Further, changing one of the two thymines of an A-binding motif to cytosine gives significant affinity for G, whereas changing the other does not. Immobilization of DNA motifs gives beads that store NADH. Exploratory experiments show that the beads release the cofactor upon warming to body temperature.

The discovery of small RNAs such as microRNAs (miRNAs), small interfering RNAs (siRNAs), or Piwi-associated RNAs (piRNAs) has led to new challenges in the selective detection of RNAs. Many noncoding RNAs act as post-translational regulators of gene expression and are involved in the regulation of cell proliferation or apoptosis, but are difficult to amplify, label, and detect. Standard microarray detection procedures involve pre-hybridization labeling or enzymatic 3′-labeling by polymerase-catalyzed extension. Dual labeling would improve the fidelity of detection, but no polymerases for 5′-extension are known. Here we report a novel labeling method for RNAs bearing natural 5′-phosphate groups, such as miRNAs, based on enzyme-free ligation of a biotin- or fluorophore-labeled oligonucleotide to the 5′ termini. The method uses in situ activation of the natural 5′-phosphate groups in these RNAs and was optimized to give near-quantitative conversion in solution. With use of biotin- or fluorophore-bearing labeling strands, different miRNA sequences were detected on microarrays with little background fluorescence. In combination with an established method of enzymatic on-chip labeling at the 3′ termini, highly selective detection of related miRNAs was achieved by dual recognition at both termini, even in the case of miRNAs differing in only one nucleotide.

Detecting short RNA strands with high fidelity at any of the bases of their sequence, including the termini, can be challenging, since fraying, wobbling, and refolding all compete with canonical base pairing. We performed a search for 5′-substituents of oligodeoxynucleotides that increase base pairing fidelity at the terminus of duplexes with RNA target strands. From a total of over 70 caps, differing in stacking moiety and linker, a phosphodiester-linked sequence of the residues of L-prolinol, glycine, and oxolinic acid, dubbed ogOA, was identified as a 5′-cap that stabilizes any of the four canonical base pairs, with ΔT_m values of up to +13.1 °C for an octamer. At the same time, the cap increases discrimination against any of the 12 possible terminal mismatches, including mismatches that are more stable than their perfectly matched counterparts in the control duplex, such as A:A. A probe with the cap also showed increased selectivity in the detection of two closely related microRNAs, let7c and let7a, with a ΔT_m value of 9.2 °C. Melting curves also yielded thermodynamic data that shed light on the uniformity of molecular recognition in the sequence space of DNA:DNA and DNA:RNA duplexes. Hybridization probes with fidelity-enhancing caps should find applications in the individual and parallel detection of biologically active RNA species.