Michael P. Robertson

Simultaneous detection of diverse analytes with an aptazyme ligase array

Allosteric ribozymes (aptazymes) can transduce the noncovalent recognition of analytes into the catalytic generation of readily observable signals. Aptazymes are easily engineered, can detect diverse classes of biologically relevant molecules, and have high signal-to-noise ratios. These features make aptazymes useful candidates for incorporation into biosensor arrays. Allosteric ribozyme ligases that can recognize a variety of analytes ranging from small organics to proteins have been generated. Upon incorporation into an array format, multiple different aptazyme ligases were able to simultaneously detect their cognate analytes with high specificity. Analyte concentrations could be accurately measured into the nanomolar range. The fact that analytes induced the formation of new covalent bonds in aptazyme ligases (as opposed to noncovalent bonds in antibodies) potentiated stringent washing of the array, leading to improved signal-to-noise ratios and limits of detection.

In vitro selection of nucleoprotein enzymes

Natural nucleic acids frequently rely on proteins for stabilization or catalytic activity. In contrast, nucleic acids selected in vitro can catalyze a wide range of reactions even in the absence of proteins. To augment selected nucleic acids with protein functionalities, we have developed a technique for the selection of protein-dependent ribozyme ligases. After randomizing a previously selected ribozyme ligase, L1, we selected variants that required one of two protein cofactors, a tyrosyl transfer RNA (tRNA) synthetase (Cyt18) or hen egg white lysozyme. The resulting nucleoprotein enzymes were activated several thousand fold by their cognate protein effectors, and could specifically recognize the structures of the native proteins. Protein-dependent ribozymes can potentially be adapted to novel assays for detecting target proteins, and the selection methods generality may allow the high-throughput identification of ribozymes capable of recognizing a sizable fraction of a proteome.

The structural basis of ribozyme-catalyzed RNA assembly.

Life originated, according to the RNA World hypothesis, from self-replicating ribozymes that catalyzed ligation of RNA fragments. We have solved the 2.6 angstrom crystal structure of a ligase ribozyme that catalyzes regiospecific formation of a 5′ to 3′ phosphodiester bond between the 5′-triphosphate and the 3′-hydroxyl termini of two RNA fragments. Invariant residues form tertiary contacts that stabilize a flexible stem of the ribozyme at the ligation site, where an essential magnesium ion coordinates three phosphates. The structure of the active site permits us to suggest how transition-state stabilization and a general base may catalyze the ligation reaction required for prebiotic RNA assembly.

Concentration by evaporation and the prebiotic synthesis of cytosine.

The efficient prebiotic synthesis of cytosine from urea andcyanoacetaldehyde (CA) has recently been claimed to be invalidon the basis of possible side reactions of the starting materials and the inapplicability of prebiotic syntheses usingdrying beach conditions. We therefore have investigated the synthesis of cytosine and uracil from urea and cyanoacetaldehydeat 100 °C under dry-down conditions, and in solution at 4 °C and -20 °C. We find that cytosine isproduced from the low temperature experiments more efficientlythan calculated from the Arrhenius extrapolation from highertemperatures, i.e., 60-120 °C. In addition, we findthat CA dimer is as efficient as the monomer in cytosine synthesis. We also studied whether evaporating very dilutesolutions of nonvolatile organic compounds will concentrateaccording to theory. Solutions as dilute as 10-4 M concentrate from pure water approximately according to theory.Similar solutions in 0.5 M NaCl have less than theoreticalconcentrations due to absorption, but concentrations neardryness were very high.

Prebiotic synthesis of 5-substituted uracils: a bridge between the RNA world and the DNA-protein world

Under prebiotic conditions, formaldehyde adds to uracil at the C-5 position to produce 5-hydroxymethyluracil with favorable rates and equilibria. Hydroxymethyluracil adds a variety of nucleophiles, such as ammonia, glycine, guanidine, hydrogen sulfide, hydrogen cyanide, imidazole, indole, and phenol, to give 5-substituted uracils with the side chains of most of the 20 amino acids in proteins. These reactions are sufficiently robust that, if uracil had been present on the primitive Earth, then these substituted uracils would also have been present. The ribozymes of the RNA world would have included many of the functional groups found in proteins today, and their catalytic activities may have been considerably greater than presently assumed.

The Structure of a Rigorously Conserved RNA Element within the SARS Virus Genome

We have solved the three-dimensional crystal structure of the stem-loop II motif (s2m) RNA element of the SARS virus genome to 2.7-Å resolution. SARS and related coronaviruses and astroviruses all possess a motif at the 3′ end of their RNA genomes, called the s2m, whose pathogenic importance is inferred from its rigorous sequence conservation in an otherwise rapidly mutable RNA genome. We find that this extreme conservation is clearly explained by the requirement to form a highly structured RNA whose unique tertiary structure includes a sharp 90° kink of the helix axis and several novel longer-range tertiary interactions. The tertiary base interactions create a tunnel that runs perpendicular to the main helical axis whose interior is negatively charged and binds two magnesium ions. These unusual features likely form interaction surfaces with conserved host cell components or other reactive sites required for virus function. Based on its conservation in viral pathogen genomes and its absence in the human genome, we suggest that these unusual structural features in the s2m RNA element are attractive targets for the design of anti-viral therapeutic agents. Structural genomics has sought to deduce protein function based on three-dimensional homology. Here we have extended this approach to RNA by proposing potential functions for a rigorously conserved set of RNA tertiary structural interactions that occur within the SARS RNA genome itself. Based on tertiary structural comparisons, we propose the s2m RNA binds one or more proteins possessing an oligomer-binding-like fold, and we suggest a possible mechanism for SARS viral RNA hijacking of host protein synthesis, both based upon observed s2m RNA macromolecular mimicry of a relevant ribosomal RNA fold.

Prebiotic synthesis of diaminopyrimidine and thiocytosine

The reaction of guanidine hydrochloride with cyanoacetaldehyde gives high yields (40–85%) of 2,4-diaminopyrimidine under the concentrated conditions of a drying lagoon model of prebiotic synthesis, in contrast to the low yields previously obtained under more dilute conditions. The prebiotic source of cyanoacetaldehyde, cyanoacetylene, is produced from electric discharges under reducing conditions. The effect of pH and concentration of guanidine hydrochloride on the rate of synthesis and yield of diaminopyrimidine were investigated, as well as the hydrolysis of diaminopyrimidine to cytosine, isocytosine, and uracil. Thiourea also reacts with cyanoacetaldehyde to give 2-thiocytosine, but the pyrimidine yields are much lower than with guanidine hydrochloride or urea. Thiocytosine hydrolyzes to thiouracil and cytosine and then to uracil. This synthesis would have been a significant prebiotic source of 2-thiopyrimidines and 5-substituted derivatives of thiouracil, many of which occur in tRNA. The applicability of these results to the drying lagoon model of prebiotic synthesis was tested by dry-down experiments where dilute solutions of cyanoacetaldehyde, guanidine hydrochloride, and 0.5m NaCl were evaporated over varying periods of time. The yields of diaminopyrimidine varied from 1 to 7%. These results show that drying lagoons and beaches may have been major sites of prebiotic syntheses.

Optimization and optimality of a short ribozyme ligase that joins non-Watson–Crick base pairings

A small ribozyme ligase (L1) selected from a random sequence population appears to utilize non-Watson-Crick base pairs at its ligation junction. Mutational and selection analyses confirmed the presence of these base pairings. Randomization of the L1 core and selection of active ligases yielded highly active variants whose rates were on the order of 1 min(-1). Base-pairing covariations confirmed the general secondary structure of the ligase, and the most active ligases contained a novel pentuple sequence covariation. The optimized L1 ligases may be optimal within their sequence spaces, and minimal ligases that span less than 60 nt in length have been engineered based on these results.

A general method for phasing novel complex RNA crystal structures without heavy-atom derivatives

Using idealized known RNA secondary-structural fragments, it is demonstrated that it is possible to solve novel complex RNA structures without resort to heavy-atom phasing methods.

Combinatorial methods: aptamers and aptazymes

Combinatorial methods have been used to generate nucleic acid molecules with specific characteristics. Aptamers are nucleic acid binding species, and can be modified to directly transduce molecular recognition to optical signals. Aptazymes are allosteric or effector-activated ribyzymes. We have designed or selected aptazymes that are responsive to a variety of ligands. In particular, we have selected a ribozyme ligase that is activated 10,000-fold in the presence of an oligonucleotide effector, and have designed ligases that are up to 1,600-fold dependent on small molecule effectors. Even in those instances where designed constructs were initially unresponsive, we have been able to use selection to optimize their response characteristics.