A comparison of DNA and RNA quadruplex structures and stabilities.

Guanosine-rich sequences are prone to fold into four-stranded nucleic acid structures. Such quadruplex sequences have long been suspected to play important roles in regulatory processes within cells. Although DNA quadruplexes have been studied in great detail, four-stranded structures made up from RNA have received only minor attention, although it is known that RNA is able to form stable quadruplexes as well. Here, we compare quadruplex structures and stabilities of a variety of DNA and RNA sequences. We focus on well established DNA sequences and determine the topologies and stabilities of the corresponding RNA sequences by CD spectroscopy and CD thermal melting experiments. We find that the RNA sequences exclusively fold into the all-parallel conformation in contrast to the diverse topologies adopted by DNA quadruplexes. The thermal stabilities of the RNA structures rival those of the corresponding DNA sequences, often displaying enhanced stabilities compared to their DNA counterparts. Especially thermodynamically less stable sequences show a strong preference for potassium, with the RNA quadruplexes exhibiting much higher stabilities than the corresponding DNAs. The latter finding suggests that quadruplexes formed at critical positions in mRNAs might perturb gene expression to a larger extend than previously anticipated.

Artificial ribozyme switches containing natural riboswitch aptamer domains.

RNA Lego: The use of natural riboswitch aptamers in synthetic RNA switches (see picture) should broaden the scope of artificial RNA regulators dramatically. It is shown that thiamine pyrophosphate (TPP) aptamers can be used in engineered devices as very sensitive switches of gene expression in unmodified organisms. The approach demonstrates that intrinsic metabolites can be utilized as external effectors of cellular functions.

Redesigned tetrads with altered hydrogen bonding patterns enable programming of quadruplex topologies.

Guanosine analogs assemble to unusual nucleobase tetrads, restricting possible conformations of four-stranded DNAs.

Small molecule-triggered assembly of DNA nanoarchitectures.

The utilization of toehold-containing DNA strands allows for the assembly of complex nanostructures via kinetically driven hybridization reactions. Here, we have rendered this strategy ligand-dependent, resulting in small-molecule-inducible DNA nanoarchitectures.