In vitro selection and characterization of a highly efficient Zn(II)-dependent RNA-cleaving deoxyribozyme

A group of highly efficient Zn(II)-dependent RNA-cleaving deoxyribozymes has been obtained through in vitro selection. They share a common motif with the ‘8–17’ deoxyribozyme isolated under different conditions, including different design of the random pool and metal ion cofactor. We found that this commonly selected motif can efficiently cleave both RNA and DNA/RNA chimeric substrates. It can cleave any substrate containing rNG (where rN is any ribonucleotide base and G can be either ribo- or deoxyribo-G). The pH profile and reaction products of this deoxyribozyme are similar to those reported for hammerhead ribozyme. This deoxyribozyme has higher activity in the presence of transition metal ions compared to alkaline earth metal ions. At saturating concentrations of Zn²⁺, the cleavage rate is 1.35 min^–1 at pH 6.0; based on pH profile this rate is estimated to be at least ~30 times faster at pH 7.5, where most assays of Mg²⁺-dependent DNA and RNA enzymes are carried out. This work represents a comprehensive characterization of a nucleic acid-based endonuclease that prefers transition metal ions to alkaline earth metal ions. The results demonstrate that nucleic acid enzymes are capable of binding transition metal ions such as Zn²⁺ with high affinity, and the resulting enzymes are more efficient at RNA cleavage than most Mg²⁺-dependent nucleic acid enzymes under similar conditions.     

In vitro selection of a 5'-purine ribonucleotide transferase ribozyme

Here we report in vitro selection of a novel ribozyme that catalyzes the 5′-nucleotidyl transfer reaction forming the 2′–5′ phosphodiester bond. This ribozyme was retrieved as a sole sequence in the pool enriched for the 5′-triphosphate-dependent activities in incorporating ATP-γS. The originally selected ribozyme consisting of 109-nucleotide (nt) was miniaturized to 45-nt M4 ribozyme via a series of mutation studies, and based on this mini-ribozyme a trans-acting system was constructed. One of the most challenging tasks in our study was to determine the chemistry occurring at the 5′-ppp site. We utilized various analytical methods including MALDI-TOF analysis of the product generated by the trans-acting system and elucidated the chemistry to be 3′→5′ mononucleotide extension forming the 2′–5′ phosphodiester bond. Interestingly, M4 ribozyme promiscuously accepts a variety of purine nucleotides bearing 5′-mono-, di- and triphosphates as substrates. This remarkable ability of M4 ribozyme would lead us to the development of a new tool for the 5′-modification of RNAs with unique chemical groups.     

Calcium(II)-dependent catalytic activity of the Azoarcus ribozyme: testing the limits of resolution for in vitro selection

Group I intron ribozymes isolated from natural sources have a strict dependence on the divalent metal cations Mg(II) or Mn(II) for catalytic activity. However, mutant versions of the Tetrahymena ribozyme have been previously isolated in the laboratory that show demonstrable activity in 10 mM CaCl(2) as the only supplied salt. Here, we sought to discover similar variants of another group I intron that is likely more evolutionarily specialized. We used in vitro selection to isolate a Ca(II)-dependent variant of the naturally-occurring form of the Azoarcus ribozyme, which is half the size of the Tetrahymena ribozyme and possesses an extremely high G+C content of 71%. A mutation of G to A at position 118 was selected in multiple independent trials. Activity of the mutant is very poor in Ca(II) and can only be observed after RT-PCR, highlighting the power of in vitro selection to isolate molecules with rare and low-level activities. The mutation likely confers an alternate but rare folded conformation that permits accommodation of Ca(II) ions and catalysis. This work also serves to caution that although a selection may be successful, isolates may not be catalytically proficient enough to provide useful levels of activity.     

In vitro selection of a ligase ribozyme carrying alkylamino groups in the side chains

A novel ligase ribozyme was in vitro selected from a random-sequence RNA library including N(6)-aminohexyl-modified adenine residues in place of natural adenine residues. This ribozyme mediated the formation of a phosphodiester bond with a DNA oligonucleotide through condensation with a 5'-triphosphate moiety on the ribozyme. Among the clones isolated from this selection, one was shown to accelerate ligation about 250-fold compared to the original random-sequence RNA library. Almost no rate acceleration was observed when the N(6)-aminohexyl-groups on adenine residues were omitted. Furthermore, ligation was dependent on the presence of a template DNA oligonucleotide that bridged the two strands.     

In vivo characterization of A-192411: a novel fungicidal lipopeptide (II)

The ability of the novel antifungal cyclic hexalipopetide A-192411 to treat fungal infections in rodents is presented. Efficacy was demonstrated against Candida albicans as both prolonged survival of systemically infected mice and clearance of viable yeasts from kidneys. The efficacy of A-192411, administered intraperitoneally, was equivalent to amphotercin B at a 4-fold lower dose by weight in the systemic candidiasis models in mice, while the efficacy of A-192441 administered intravenously was equivalent to amphotercin B by weight in the Candida pyelonephritis model in rats. A-192411 also slightly prolonged the survival of immunocompromised mice infected systemically with Aspergillus fumigatus.     

Synthesis,characterization and antiglaucoma activity of a novel proton transfer compound and a mixed-ligand Zn(II) complex

A novel proton transfer compound, pyridin-2-ylmethanaminium 2,4-dichloro-5-sulfamoylbenzoate (1), and a mixed-ligand Zn(II) complex, bis(2,4-dichloro-5-sulfamoylbenzoate)(2-aminomethylpyridine)aquazinc(II) monohydrate (2), have been synthesized from the same free ligands, which are 2,4-dichloro-5-sulfamoylbenzoic acid (Hsba) and 2-aminomethylpyridine (amp). They have been characterized by elemental, spectral (¹H NMR, IR and UV–vis.) and thermal analyses. Additionally, magnetic measurement and single crystal X-ray diffraction technique were applied to compound 2. In the complex, Zn(II) ion exhibits a distorted octahedral configuration coordinated by O1 and O1ⁱ atoms of two mono dentante sba anions and N1, N2, N2ⁱ atoms of bidentante amp anion and a water molecule (O1w). The free ligands Hsba and amp, and the products 1 and 2, and acetazolamide (AAZ) as the control compound, were also evaluated for their in vitro inhibitor effects on human Carbonic Anhydrase isoenzymes (hCA I and hCA II) purified from erythrocyte cell by affinity chromatography for their hydratase and esterase activities. The IC₅₀ values of products 1 and 2 for hydratase activity are 0.26 and 0.13 μM for hCA I and 0.30 and 0.15 μM for hCA II, respectively. The IC₅₀ values of the same inhibitors for esterase activity are 0.32 and 0.045 μM for hCA I and 0.29 and 0.23 μM for hCA II, respectively. In relation to esterase activities, the inhibition equilibrium constants (K_i) were also determined and found 0.25 and 0.058 μM on hCA I and 0.22 and 0.24 μM on hCA II for 1 and 2, respectively. The comparison of the inhibition studies of newly synthesized compounds 1 and 2 to parent compounds Hsba and amp and to AAZ indicated that 1 and 2 have effective inhibitory activity on hCA I and II, and might be used potential inhibitors.     

In vitro selection and characterization of cellulose-binding DNA aptamers

Many nucleic acid enzymes and aptamers have modular architectures that allow them to retain their functions when combined with other nucleotide sequences. This modular function facilitates the engineering of RNAs and DNAs that have more complex functions. We sought to create new DNA aptamers that bind cellulose to provide a module for immobilizing DNAs. Cellulose has been used in a variety of applications ranging from coatings and films to pharmaceutical preparations, and therefore DNA aptamers that bind cellulose might enable new applications. We used in vitro selection to isolate aptamers from a pool of random-sequence DNAs and subjected two distinct clones to additional rounds of mutagenesis and selection. One aptamer (CELAPT 14) was chosen for sequence minimization and more detailed biochemical analysis. CELAPT 14 aptamer variants exhibit robust binding both to cellulose powder and paper. Also, an allosteric aptamer construct was engineered that exhibits ATP-mediated cellulose binding during paper chromatography.     

In vitro selection and characterization of a stable subdomain of phosphoribosylanthranilate isomerase

The (beta(alpha))8-barrel is the most common enzyme fold and it is capable of catalyzing an enormous diversity of reactions. It follows that this scaffold should be an ideal starting point for engineering novel enzymes by directed evolution. However, experiments to date have utilized in vivo screens or selections and the compatibility of (beta(alpha))8-barrels with in vitro selection methods remains largely untested. We have investigated plasmid display as a suitable in vitro format by engineering a variant of phosphoribosylanthranilate isomerase (PRAI) that carried the FLAG epitope in active-site-forming loop 6. Trial enrichments for binding of mAb M2 (a mAb to FLAG) demonstrated that FLAG-PRAI could be identified from a 10(6)-fold excess of a FLAG-negative competitor in three rounds of in vitro selection. These results suggest PRAI as a useful scaffold for epitope and peptide grafting experiments. Further, we constructed a FLAG-PRAI loop library of approximately 10(7) clones, in which the epitope residues most critical for binding mAb M2 were randomized. Four rounds of selection for antibody binding identified and enriched for a variant in which a single nucleotide insertion produced a truncated (beta(alpha))8-barrel consisting of (beta(alpha))1-5beta6. Biophysical characterization of this clone, trPRAI, demonstrated that it was selected because of a 21-fold increase in mAb M2 affinity compared with full-length FLAG-PRAI. Remarkably, this truncated barrel was found to be soluble, structured, thermostable and monomeric, implying that it represents a genuine subdomain of PRAI and providing further evidence that such subdomains have played an important role in the evolution of the (beta(alpha))8-barrel fold.     

Synthesis and characterization of the acetazolamide complexes of Co(II) and Zn(II)

The preparation and characterization of the complexes of Acetazolamide (Acm) with Co(II) and Zn(II) are described. The complexes are of the type M(Acm)₂(NH₃)₂. Monodentate or bidentate behaviour of Acm from the electronic properties and the IR spectral data is discussed. The probable structures of the complexes are proposed.     

In vitro selection and characterization of influenza A (A/N9) virus variants resistant to a novel neuraminidase inhibitor, A-315675

With the recent introduction of neuraminidase (NA) inhibitors into clinical practice for the treatment of influenza virus infections, considerable attention has been focused on the potential for resistance development and cross-resistance between different agents from this class. A-315675 is a novel influenza virus NA inhibitor that has potent enzyme activity and is highly active in cell culture against a variety of strains of influenza A and B viruses. To further assess the therapeutic potential of this compound, in vitro resistance studies have been conducted and a comparative assessment has been made relative to oseltamivir carboxylate. The development of viral resistance to A-315675 was studied by in vitro serial passage of influenza A/N9 virus strains grown in MDCK cells in the presence of increasing concentrations of A-315675. Parallel passaging experiments were conducted with oseltamivir carboxylate, the active form of a currently marketed oral agent for the treatment of influenza virus infections. Passage experiments with A-315675 identified a variant at passage 8 that was 60-fold less susceptible to the compound. Sequencing of the viral population identified an E119D mutation in the NA gene, but no mutations were observed in the hemagglutinin (HA) gene. However, by passage 10 (2.56 microM A-315675), two mutations (R233K, S339P) in the HA gene appeared in addition to the E119D mutation in the NA gene, resulting in a 310-fold-lower susceptibility to A-315675. Further passaging at higher drug concentrations had no effect on the generation of further NA or HA mutations (20.5 microM A-315675). This P15 virus displayed 355-fold-lower susceptibility to A-315675 and >175-fold-lower susceptibility to zanamivir than did wild-type virus, but it retained a high degree of susceptibility to oseltamivir carboxylate. By comparison, virus variants recovered from passaging against oseltamivir carboxylate (passage 14) harbored an E119V mutation and displayed a 6,000-fold-lower susceptibility to oseltamivir carboxylate and a 175-fold-lower susceptibility to zanamivir than did wild-type virus. Interestingly, this mutant still retained susceptibility to A-315675 (42-fold loss). This suggests that cross-resistance between A-315675- and oseltamivir carboxylate-selected variants in vitro is minimal.     

In vitro selection of second site revertants analysis of the hairpin ribozyme active site

We have used in vitro genetics to evaluate the function and interactions of the conserved base G8 in the hairpin ribozyme catalytic RNA. Second site revertant selection for a G8X mutant, where X is any of the other three natural nucleobases, yielded a family of second site suppressors of the G8U mutant, but not of G8C or G8A, indicating that only G and U can be tolerated at position 8 of the ribozyme. This result is consistent with recent observations that point to the functional importance of G8 N-1 in the chemistry of catalysis by this ribozyme reaction. Suppression of the G8U mutation was observed when changes were made directly across loop A from the mutated base at substrate position +2 or positions +2 and +3 in combination. The same changes made in the context of the natural G8 sequence resulted in a very large drop in activity. Thus, the G8U mutation results in a change in specificity of the ribozyme from 5'-N / GUC-3' to 5'-N / GCU-3'. The results presented imply that G8 interacts directly with U+2 during catalysis. We propose that this interaction favors the correct positioning of the catalytic determinants of G8. The implications for the folding of the ribozyme and the catalytic mechanism are discussed.     

Solution equilibrium characterization of insulin-mimetic Zn(II) complexes

Solution speciation (stoichiometry and stability constants) of the insulin mimetic Zn(II) complexes of several bidentate ligands with (O,O), (N,O) or (S,O) coordination modes have been determined by pH-metry at 25 degrees Celsius and I=0.2M (KCl). All ligands were found to coordinate in a bidentate way forming mono, bis and tris complexes, besides a mixed hydroxo bis complex ZnL(2)(OH) detected in the slightly basic pH range together with the tris complex. Relationships between the stability data, lipophilicity of the complexes and earlier biological data are evaluated. The validity of the linear free energy relationships (LFER) between the proton and Zn(II) complexes and also between the VO(IV) and Zn(II) complexes is tested.     

In vitro characterization of a novel polymeric-based pH-sensitive liposome system

This study demonstrates rapid and pH-sensitive release of a highly water-soluble fluorescent aqueous content marker, pyranine, from egg phosphatidylcholine liposomes following incorporation of N-isopropylacrylamide (NIPA) copolymers in liposomal membranes. The pH-sensitivity of this system correlates with the precipitation of the copolymers at acidic pH. In vitro release can be significantly improved by increasing the percentage of anchor in the copolymer and thus favoring its binding to the liposomal bilayer. In the case of liposomes containing a poly(ethylene glycol)-phospholipid conjugate, the insertion of the pH-sensitive copolymer in the liposomal membrane appears to be sterically inhibited. Dye release from these formulations at acidic pH can still be achieved by varying the anchor molar ratio and/or molecular mass of the polymers or by including the latter during the liposome preparation procedure. Removal of unbound polymer results in decreased leakage only when the copolymer is inserted by incubation with preformed liposomes, but can be overcome by preparing liposomes in the presence of polymer. Aqueous content and lipid mixing assays suggest contents release can occur without membrane fusion. The results of this study indicate that the addition of pH-sensitive copolymers of NIPA represents promising strategy for improving liposomal drug delivery.     

In vitro selection and characterization of Bcl-X(L)-binding proteins from a mix of tissue-specific mRNA display libraries

The covalent coupling of an mRNA to the protein that it encodes (mRNA display) provides a powerful tool for analysis of protein function in the post-genomic era. This coupling allows the selective enrichment of individual members from libraries of displayed proteins and the subsequent regeneration of an enriched library using the RNA moiety. Tissue-specific libraries from poly(A)(+) mRNA were prepared by priming first and second strand cDNA synthesis with oligonucleotides containing nine random 3' nucleotides, the fixed regions of which encoded the requisite sequences for formation of mRNA display constructs and a library-specific sequence tag. Starting with a pool of uniquely tagged libraries from different tissues, an iterative selection was performed for binding partners of the anti-apoptotic protein Bcl-X(L). After four rounds of selection, the pool was deconvoluted by polymerase chain reaction amplification with library-specific primers. Subsequent clonal sequence analysis revealed the selection of three members of the Bcl-2 family known to bind to Bcl-X(L). In addition, several proteins not previously demonstrated to interact with Bcl-X(L) were identified. The relative binding affinities of individual selected peptides were determined, as was their susceptibility to competition with a BH3 domain peptide. Based on these data, a putative BH3 domain was identified in most peptides.     

In vitro selection and characterization of DNA aptamers recognizing chloramphenicol

Chloramphenicol (Cam), although an effective antibiotic, has lost favour due to some fatal side effects. Thus there is an urgent need for rapid and sensitive methods to detect residues in food, feed and environment. We engineered DNA aptamers that recognize Cam as their target, by conducting in vitro selections. Aptamers are nucleic acid recognition elements that are highly specific and sensitive towards their targets and can be synthetically produced in an animal-friendly manner, making them ethical innovative alternatives to antibodies. None of the isolated aptamers in this study shared sequence homology or structural similarities with each other, indicating that specific Cam recognition could be achieved by various DNA sequences under the selection conditions used. Analyzing the binding affinities of the sequences, demonstrated that dissociation constants (K_d) in the extremely low micromolar range, which were lower than those previously reported for Cam-specific RNA aptamers, were achieved. The two best aptamers had G rich (>35%) nucleotide regions, an attribute distinguishing them from the rest and apparently responsible for their high selectivity and affinity (K_d ∼ 0.8 and 1 μM respectively). These aptamers open up possibilities to allow easy detection of Cam via aptamer-based biosensors.     

In vitro selection of a novel catalytic RNA: characterization of a sulfur alkylation reaction and interaction with a small peptide.

An in vitro RNA selection for catalytic activity was used to co-select for binding activity to a small peptide. 5'-phosphorothioate-modified RNA (GMPS-RNA) sequences were selected from a randomized pool of oligoribonucleotides for their ability to accelerate a halide substitution reaction with N-bromoacetyl-bradykinin (BrBK). One RNA selected shows a 2,420-fold increase in rate of reaction with BrBK relative to the starting pool. This reaction is specifically inhibited by free bradykinin (Ki 230 microM), indicating that interactions with bradykinin contribute to the rate enhancement. Inhibition of the reaction by the peptide requires both the amino- and carboxy-terminal arginine residues of the peptide for optimal inhibition activity. Reaction with N-bromoacetamide is not enhanced, indicating that the intrinsic reactivity of the 5' phosphorothioate is not increased in the selected RNA. Through 3'-end boundary analysis, much of the catalytic activity of the selected GMPS-RNA is shown to reside in a hairpin structure in the selected region of the molecule. This hairpin structure is also implicated in the recognition of the peptide substrate.     

Identification and characterization of a major Zn(II) resistance determinant of Mycobacterium smegmatis

A zinc ion-sensitive mutant of Mycobacterium smegmatis was isolated. The transposon insertion was located in zitA (MSMEG0750), a gene coding for a cation diffusion facilitator family protein. Zinc ions specifically induced expression of zitA. In silico analysis revealed that environmental and opportunistic pathogenic species contain higher numbers of cation diffusion facilitator genes than do obligate pathogens.     

Photoluminescent properties of novel design heteroleptic Zn(II) complexes

Three novel heteroleptic Zn(II) complexes containing 8‐hydroxy quinoline and various pyrazolone‐based derivatives were synthesized and their structures confirmed by ¹H–nuclear magnetic resonance, mass spectrometry, Fourier transform infra‐red spectroscopy, UV–vis analysis and element analysis. All three complexes showed good photoluminescence properties in the solid state and in solution in the maximum emission range from 475 to 490 nm with a quantum yield of 0.45 to 0.51. Absorption spectra revealed that the complexes possessed a maximum absorption range of 272–281 nm with a band gap of 2.59–2.68 eV. The highest occupied molecular orbital and lowest unoccupied molecular orbital of all the complexes were determine by cyclic voltammetry. All complexes displayed high thermal stability. These characteristics were assessed to find suitability for an alternative cheap light emitter for organic light‐emitting diodes.