Hans A. Heus

Macroscopic Hierarchical Surface Patterning of Porphyrin Trimers via Self-Assembly and Dewetting

The use of bottom-up approaches to construct patterned surfaces for technological applications is appealing, but to date is applicable to only relatively small areas (∼10 square micrometers). We constructed highly periodic patterns at macroscopic length scales, in the range of square millimeters, by combining self-assembly of disk-like porphyrin dyes with physical dewetting phenomena. The patterns consisted of equidistant 5-nanometer-wide lines spaced 0.5 to 1 micrometers apart, forming single porphyrin stacks containing millions of molecules, and were formed spontaneously upon drop-casting a solution of the molecules onto a mica surface. On glass, thicker lines are formed, which can be used to align liquid crystals in large domains of square millimeter size.

Enhanced transcription rates in membrane-free protocells formed by coacervation of cell lysate

Liquid–liquid phase transitions in complex mixtures of proteins and other molecules produce crowded compartments supporting in vitro transcription and translation. We developed a method based on picoliter water-in-oil droplets to induce coacervation in Escherichia coli cell lysate and follow gene expression under crowded and noncrowded conditions. Coacervation creates an artificial cell-like environment in which the rate of mRNA production is increased significantly. Fits to the measured transcription rates show a two orders of magnitude larger binding constant between DNA and T7 RNA polymerase, and five to six times larger rate constant for transcription in crowded environments, strikingly similar to in vivo rates. The effect of crowding on interactions and kinetics of the fundamental machinery of gene expression has a direct impact on our understanding of biochemical networks in vivo. Moreover, our results show the intrinsic potential of cellular components to facilitate macromolecular organization into membrane-free compartments by phase separation.

Solution structure of the pseudoknot of SRV-1 RNA, involved in ribosomal frameshifting

Abstract RNA pseudoknots play important roles in many biological processes. In the simian retrovirus type-1 (SRV-1) a pseudoknot together with a heptanucleotide slippery sequence are responsible for programmed ribosomal frameshifting, a translational recoding mechanism used to control expression of the Gag-Pol polyprotein from overlapping gag and pol open reading frames. Here we present the three-dimensional structure of the SRV-1 pseudoknot determined by NMR. The structure has a classical H-type fold and forms a triple helix by interactions between loop 2 and the minor groove of stem 1 involving base-base and base-sugar interactions and a ribose zipper motif, not identified in pseudoknots so far. Further stabilization is provided by a stack of five adenine bases and a uracil in loop 2, enforcing a cytidine to bulge. The two stems of the pseudoknot stack upon each other, demonstrating that a pseudoknot without an intercalated base at the junction can induce efficient frameshifting. Results of mutagenesis data are explained in context with the present three-dimensional structure. The two base-pairs at the junction of stem 1 and 2 have a helical twist of approximately 49°, allowing proper alignment and close approach of the three different strands at the junction. In addition to the overwound junction the structure is somewhat kinked between stem 1 and 2, assisting the single adenosine in spanning the major groove of stem 2. Geometrical models are presented that reveal the importance of the magnitude of the helical twist at the junction in determining the overall architecture of classical pseudoknots, in particular related to the opening of the minor groove of stem 1 and the orientation of stem 2, which determines the number of loop 1 nucleotides that span its major groove.

Nuclear magnetic resonance studies of the hammerhead ribozyme domain: Secondary structure formation and magnesium ion dependence☆

Proton nuclear magnetic resonance (n.m.r.) experiments were used to probe base-pair formation in several hammerhead RNA enzyme (ribozyme) domains. The hammerhead domains consist of a 34 nucleotide ribozyme bound to a complementary 13 nucleotide non-cleavable DNA substrate. Three hammerhead domains were studied that differ in the sequence and stability of one of the helices involved in recognition of the substrate by the ribozyme. The n.m.r. data show a 1:1 stoichiometry for the ribozyme-substrate complexes. The imino proton resonances in the hammerhead complexes were assigned by two-dimensional nuclear Overhauser effect experiments. These data confirm the presence of two of the three helical regions in the hammerhead domain, predicted from phylogenetic data; and are also consistent with the formation of the third helix. Since a divalent cation is required for efficient catalytic activity of the hammerhead domain, the magnesium ion dependence of the n.m.r. spectra was studied for two of the hammerhead complexes. One of the complexes showed very large spectral changes upon addition of magnesium ions. However, the complex that has the most C.G base-pairs in one of the recognition helices shows essentially no spectral (and therefore presumably structural) changes upon addition of magnesium. These data are consistent with a model where the magnesium binding site already exists in the magnesium-free complex, suggesting that the magnesium ion serves primarily a catalytic, and not a structural, role under the conditions used here.

New developments in structure determination of pseudoknots

Recently, several high‐resolution structures of RNA pseudoknots have become available. Here we review the progress in this area. The majority of the structures obtained belong to the classical or H‐type pseudoknot family. The most complicated pseudoknot structure elucidated so far is the Hepatitis Delta Virus ribozyme, which forms a nested double pseudoknot. In particular, the structure–function relationships of the H‐type pseudoknots involved in translational frameshifting have received much attention. All molecules considered show interesting new structural motifs.

Solution structure of a HNA–RNA hybrid

BACKGROUND Synthetic nucleic acid analogues with a conformationally restricted sugar-phosphate backbone are widely used in antisense strategies for biomedical and biochemical applications. The modified backbone protects the oligonucleotides against degradation within the living cell, which allows them to form stable duplexes with sequences in target mRNAs with the aim of arresting their translation. The biologically most active antisense oligonucleotides also trigger cleavage of the target RNA through activation of endogenous RNase H. Systematic studies of synthetic oligonucleotides have also been conducted to delineate the origin of the chirality of DNA and RNA that are both composed of D-nucleosides. RESULTS Hexitol nucleic acids (HNA) are the first example of oligonucleotides with a six-membered carbohydrate moiety that can bind strongly and selectively to complementary RNA oligomers. We present the first high resolution nuclear magnetic resonance structure of a HNA oligomer bound to a complementary RNA strand. The HNA-RNA complex forms an anti-parallel heteroduplex and adopts a helical conformation that belongs to the A-type family. Possibly, due to the rigidity of the rigid chair conformation of the six-membered ring both the HNA and RNA strand in the duplex are well defined. The observed absence of end-fraying effects also indicate a reduced conformational flexibility of the HNA-RNA duplex compared to canonical dsRNA or an RNA-DNA duplex. CONCLUSIONS The P-P distance across the minor groove, which is close to A-form, and the rigid conformation of the HNA-RNA complex, explain its resistance towards degradation by Rnase H. The A-form character of the HNA-RNA duplex and the reduced flexibility of the HNA strand is possibly responsible for the stereoselectivity of HNA templates in non-enzymatic replication of oligonucleotides, supporting the theory that nucleosides with six-membered rings could have existed at some stage in molecular evolution.

Heteronuclear scalar couplings in the bases and sugar rings of nucleic acids: Their determination and application in assignment and conformational analysis

The scalar coupling constants in uniformly isotope‐enriched [13C, 15N] nucleotide 5′‐monophosphates (5′‐NMPs) and in various non‐labelled cyclic nucleotides were investigated. These model compounds yielded an almost complete set of homonuclear and heteronuclear coupling constants in ribonucleotides, the knowledge of which is useful in designing novel heteronuclear NMR experiments and opens up new possibilities in the structure determination of larger nucleic acids. Three sets of heteronuclear coupling constants were obtained: (1) conformation‐independent 1H–13C, 1H–15N, 13C–15N, 13C–13C and 15N–15N coupling constants in the base, knowledge of which is essential in optimizing and designing new NMR experiments, which use the coherent transfer of magnetization via the J‐coupling network in the nucleic acid base and sugar; (2) 1H–13C coupling constants, 3JH1′C4/2 and 3JH1′C8/6, monitoring the glycosidic torsion angle χ, give important information on the rotamer distribution around the χ angle; a new parameterization of the Karplus equations is presented; and (3) conformation‐dependent one‐bond and multiple bond 1H–13C coupling constants in the ribose sugar. Conformationally rigid, cyclic, nucleotides were used to determine multiple bond 1H–13C coupling constants in pure N‐type and pure S‐type sugar rings. Equations were derived for the determination of the fraction S‐type sugar, pS, from the three‐bond JCH couplings 3JH3′C1′, 3JH2′C4′, 3JH1′C3′ and 3JH4′C2′. Their values for pure N‐ and S‐type sugar conformations were used to derive Karplus equations, which describe the dependence of these coupling constants on the phase angle, P.

Structure of the ribozyme substrate hairpin of Neurospora VS RNA: a close look at the cleavage site.

The cleavage site of the Neurospora VS RNA ribozyme is located in a separate hairpin domain containing a hexanucleotide internal loop with an A-C mismatch and two adjacent G-A mismatches. The solution structure of the internal loop and helix la of the ribozyme substrate hairpin has been determined by nuclear magnetic resonance (NMR) spectroscopy. The 2 nt in the internal loop, flanking the cleavage site, a guanine and adenine, are involved in two sheared G.A base pairs similar to the magnesium ion-binding site of the hammerhead ribozyme. Adjacent to the tandem G.A base pairs, the adenine and cytidine, which are important for cleavage, form a noncanonical wobble A+-C base pair. The dynamic properties of the internal loop and details of the high-resolution structure support the view that the hairpin structure represents a ground state, which has to undergo a conformational change prior to cleavage. Results of chemical modification and mutagenesis data of the Neurospora VS RNA ribozyme can be explained in context with the present three-dimensional structure.

The Hairpin Elements of Nucleic Acid Structure: DNA and RNA Folding

Hairpin molecules have attracted a great deal of interest for many years. On one hand, this is because of their role in cellular processes, the recognition between the codon on mRNA and the anti-codon loop of tRNA being the most outstanding example. On the other hand, the study of the folding in hairpin loops and the thermodynamic parameters governing hairpin formation has been considered as a basis for the description of the stereochemistry of folding in more complicated nucleic acid structures and for the prediction of the secondary structure and its stability in such molecules.

Fast production of homogeneous recombinant RNA—towards large-scale production of RNA

In the past decades, RNA molecules have emerged as important players in numerous cellular processes. To understand these processes at the molecular and atomic level, large amounts of homogeneous RNA are required for structural, biochemical and pharmacological investigations. Such RNAs are generally obtained from laborious and costly in vitro transcriptions or chemical synthesis. In 2007, a recombinant RNA technology has been described for the constitutive production of large amounts of recombinant RNA in Escherichia coli using a tRNA-scaffold approach. We demonstrate a general applicable extension to the described approach by introducing the following improvements: (i) enhanced transcription of large recombinant RNAs by T7 RNA polymerase (high transcription rates, versatile), (ii) efficient and facile excision of the RNA of interest from the tRNA-scaffold by dual cis-acting hammerhead ribozyme mediated cleavage and (iii) rapid purification of the RNA of interest employing anion-exchange chromatography or affinity chromatography followed by denaturing polyacrylamide gel electrophoresis. These improvements in the existing method pave the tRNA-scaffold approach further such that any (non-)structured product RNA of a defined length can cost-efficiently be obtained in (multi-)milligram quantities without in vitro enzymatic manipulations.