Recent advances in the in vitro evolution of nucleic acids

Molecular evolution allows chemists and biologists to generate nucleic acids with tailor-made binding or catalytic activities. Recent examples of nucleic acid evolution in vitro provide insights into natural ribozyme evolution and also demonstrate potential applications of evolved DNA and RNA molecules. Efforts to expand the scope of nucleic acid evolution are also underway, including the development of novel methods for exploring nucleic acid sequence-space and the incorporation of non-natural chemical functionality into nucleic acid libraries.     

Modeling nucleic acids

Nucleic acids are an important class of biological macromolecules that carry out a variety of cellular roles. For many functions, naturally occurring DNA and RNA molecules need to fold into precise three-dimensional structures. Due to their self-assembling characteristics, nucleic acids have also been widely studied in the field of nanotechnology, and a diverse range of intricate three-dimensional nanostructures have been designed and synthesized. Different physical terms such as base-pairing and stacking interactions, tertiary contacts, electrostatic interactions and entropy all affect nucleic acid folding and structure. Here we review general computational approaches developed to model nucleic acid systems. We focus on four key areas of nucleic acid modeling: molecular representation, potential energy function, degrees of freedom and sampling algorithm. Appropriate choices in each of these key areas in nucleic acid modeling can effectively combine to aid interpretation of experimental data and facilitate prediction of nucleic acid structure.     

A simple nucleic acid alternative: aminopropyl nucleic acids (APNAs)

Aminopropyl nucleic acids are constitutionally simple nucleic acids alternatives with one chiral center per nucleotide and with the constitutional potential to hybridize with RNA. Both R and S isomers of the 3'-or 2'-aminopropyl nucleosides were incorporated either into DNA or likewise were used for fully modified sequences. The (R)-adenine analogue, yielding (S)-APNA, can be considered as a candidate for universal base pairing.     

Extracellular nucleic acids

Extracellular nucleic acids are found in different biological fluids in the organism and in the environment: DNA is a ubiquitous component of the organic matter pool in the soil and in all marine and freshwater habitats. Data from recent studies strongly suggest that extracellular DNA and RNA play important biological roles in microbial communities and in higher organisms. DNA is an important component of bacterial biofilms and is involved in horizontal gene transfer. In recent years, the circulating extracellular nucleic acids were shown to be associated with some diseases. Attempts are being made to develop noninvasive methods of early tumor diagnostics based on analysis of circulating DNA and RNA. Recent observations demonstrated the possibility of nucleic acids exchange between eukaryotic cells and extracellular space suggesting their participation in so far unidentified biological processes.     

Interaction of resveratrol and genistein with nucleic acids

Resveratrol (RES) and genistein (GEN) are the dietary natural products known to possess chemopreventive property and also the ability to repair DNA damage induced by mutagens/carcinogens. It is believed that the therapeutic activity of these compounds could be primarily due to their interaction with nucleic acids but detailed reports are not available. We here explore the interaction of these drugs with nucleic acids considering DNA and RNA as a potential therapeutic target. The interaction of RES and GEN has been analysed in buffered solution with DNA [saline sodium citrate (SSC)] and RNA [tris ethylene diammine tetra acetic acid (TE)] using UV-absorption and Fourier transform infrared (FTIR) spectroscopy. The UV analysis revealed lesser binding affinity with nucleic acids at lower concentration of RES (P/D = 5.00 and 10.00), while at higher drug concentration (P/D = 0.75, 1.00 and 2.50) hyperchromic effect with shift in the lambda(max) is noted for DNA and RNA. A major RES-nucleic acids complexes was observed through base pairs and phosphate backbone groups with K = 35.782 M(-1) and K = 34.25 M(-1) for DNARES and RNA-RES complexes respectively. At various concentrations of GEN (P/D = 0.25, 0.50, 0.75, 1.00 and 2.50) hyperchromicity with shift in the lambda(max) from 260-->263 nm and 260--> 270 nm is observed for DNA-GEN and RNA-GEN complexes respectively. The binding constant (from UV analysis) for GEN-nucleic acids complexes could not be obtained due to GEN absorbance overlap with that of nucleic acids at 260 nm. Nevertheless a detailed analysis with regard to the interaction of these drugs (RES/GEN) with DNA and RNA could feasibly be understood by FTIR.     

Iodo-Gen-mediated radioiodination of nucleic acids

Iodo-Gen (1,3,4,6-tetrachloro-3a,6a-diphenylglycoluril), widely used as an oxidizing agent for iodination of proteins, can also be used for iodination of nucleic acids. Optimal conditions were determined for efficient labeling of RNA and DNA with 125I. The proposed procedure for radioiodination of nucleic acids is more beneficial than the methods utilizing TlCl3 because of the milder reaction conditions, the simplicity and completeness of separation of reaction products from the oxidizing agents, and the absence of a toxic catalyst. Using the standard procedure for Iodo-Gen-mediated iodination a specific radioactivity of up to 1.3 X 10(9) dpm/micrograms RNA can be achieved. The proposed procedure is also suitable for radioiodination of DNA.     

Difference in conformational diversity between nucleic acids with a six-membered 'sugar' unit and natural 'furanose' nucleic acids

Natural nucleic acids duplexes formed by Watson-Crick base pairing fold into right-handed helices that are classified in two families of secondary structures, i.e. the A- and B-form. For a long time, these A and B allomorphic nucleic acids have been considered as the 'non plus ultra' of double-stranded nucleic acids geometries with the only exception of Z-DNA, a left-handed helix that can be adopted by some DNA sequences. The five-membered furanose ring in the sugar-phosphate backbone of DNA and RNA is the underlying cause of this restriction in conformational diversity. A collection of new Watson-Crick duplexes have joined the 'original' nucleic acid double helixes at the moment the furanose sugar was replaced by different types of six-membered ring systems. The increase in this structural and conformational diversity originates from the rigid chair conformation of a saturated six-membered ring that determines the orientation of the ring substituents with respect to each other. The original A- and B-form oligonucleotide duplexes have expanded into a whole family of new structures with the potential for selective cross-communication in a parallel or antiparallel orientation, opening up a new world for information storage and for molecular recognition-directed self-organization.     

Volumetric properties of nucleic acids

Volumetric studies can yield useful new information on a myriad of intra- and intermolecular interactions that stabilize nucleic acid structures. In particular, appropriately designed volumetric measurements can characterize the conformation-dependent hydration properties of nucleic acids as a function of solution conditions, including temperature, pressure, ionic strength, pH, and cosolvent concentration. We have started to accumulate a substantial database on volumetric properties of DNA and RNA, as well as on related low molecular weight model compounds. This database already has provided unique insights into the molecular origins of various nucleic acid recognition processes, including helix-to-coil and helix-to-helix conformational transitions, as well as drug-DNA interactions. In this article, we review recent progress in volumetric investigations of nucleic acids, emphasizing how these data can be used to gain insight into intra-and intermolecular interactions, including hydration properties. Throughout this review, we underscore the importance of volume and compressibility data for characterizing the hydration properties of nucleic acids and their constituents. We also describe how such volumetric data can be interpreted at the molecular level to yield a better understanding of the role that hydration can play in modulating the stability and recognition of nucleic acids.     

Making and breaking nucleic acids: two-Mg2+-ion catalysis and substrate specificity

DNA and a large proportion of RNA are antiparallel duplexes composed of an unvarying phosphosugar backbone surrounding uniformly stacked and highly similar base pairs. How do the myriad of enzymes (including ribozymes) that perform catalysis on nucleic acids achieve exquisite structure or sequence specificity? In all DNA and RNA polymerases and many nucleases and transposases, two Mg2+ ions are jointly coordinated by the nucleic acid substrate and catalytic residues of the enzyme. Based on the exquisite sensitivity of Mg2+ ions to the ligand geometry and electrostatic environment, we propose that two-metal-ion catalysis greatly enhances substrate recognition and catalytic specificity.     

Exogenous nucleic acids aggregate in non-P-body cytoplasmic granules when transfected into cultured cells

To modulate gene expression in research studies or in potential clinical therapies, transfection of exogenous nucleic acids including plasmid DNA and small interference RNA (siRNA) are generally performed. However, the cellular processing and the fate of these nucleic acids remain elusive. By investigating the cellular behavior of transfected nucleic acids using confocal imaging, here we show that when siRNA was co-transfected into cultured cells with other nucleic acids, including single-stranded RNA oligonucleotides, single and double-stranded DNA oligonucleotides, as well as long double-stranded plasmid DNA, they all aggregate in the same cytoplasmic granules. Interestingly, the amount of siRNA aggregating in granules was found not to correlate with the gene silencing activity, suggesting that assembly of cytoplasmic granules triggered by siRNA transfection may be separable from the siRNA silencing event. Our results argue against the claim that the siRNA-aggregating granules are the functional site of RNA interference (RNAi). Taken together, our studies suggest that, independent of their types or forms, extraneously transfected nucleic acids are processed through a common cytoplasmic pathway and trigger the formation of a new type of cytoplasmic granules “transfection granules”.     

Interaction of the putative anticancer alkaloid chelerythrine with nucleic acids: biophysical perspectives

Alkaloids represent an important group of molecules that have immense pharmacological potential. Benzophenanthridine alkaloids are one such class of alkaloids known for their myriad pharmacological activities that include potential anticancer activities. Chelerythrine is a premier member of the benzophenanthridine family of the isoquinoline group. This alkaloid is endowed with excellent medicinal properties and exhibits antibacterial, antimicrobial and anti-inflammatory properties. The molecular basis of its therapeutic activity is considered due to its nucleic acid binding capabilities. This review focuses on consolidating the current status on the nucleic acid binding properties of chelerythrine that is essential for the rational design and development of this alkaloid as a potential drug. This work reviews the interaction of chelerythrine with different natural and synthetic nucleic acids like double- and single-stranded DNAs, heat-denatured DNA, quadruplex DNA, double- and single-stranded RNA, tRNA and triplex and quadruplex RNA. The review emphasizes on the mode, specificity, conformational aspects and energetics of the binding that is particularly helpful for developing nucleic acid targeted therapeutics. The fundamental results discussed in this review will greatly benefit drug development for many diseases and serve as a database for the design of futuristic benzophenanthridine-based therapeutics.     

乳杆菌对数生长期培养基滤液核酸组分分析

目的通过对乳杆菌对数生长期培养基滤液中核酸组分的分析,阐明乳杆菌DM9811对数生长期培养基滤液中核酸的性质。方法应用核酸的分离、纯化及电泳分析技术。结果乳杆菌对数生长期培养基滤液中核酸组分为RNA,其片段大小为100 bp左右。乳杆菌对数生长期培养基滤液中核酸组分为RNA,为对数期产生且呈时间依赖关系。结论核酸组分不仅仅是遗传信息的载体,还可能作为有效的信息分子。     

Peptide nucleic acids: deoxyribonucleic acid mimics with a peptide backbone

This tutorial briefly describes a new class of synthetic biopolymer, which is referred to as peptide nucleic acid (PNA). In PNA, individual nucleobases are linked to an achiral neutral peptide backbone. PNA exhibits the hybridization characteristic (e.g., Watson—Crick duplex formation) of DNA. The achiral peptide backbone provides similar interbase distances as natural DNA, and adequate flexibility to permit base pair interactions with complementary RNA or DNA strands. Several potential applications of PNA oligomers in biotechnology are suggested. These include the use of PNAs as a probe for specific recognition of a DNA or RNA sequence selective, purification of nucleic acids via designed high affinity binding to PNA, screening for DNA mutations, and as possible therapeutic agents.     

Cellular nucleic acid binding protein binds G-rich single-stranded nucleic acids and may function as a nucleic acid chaperone

Cellular nucleic acid binding protein (CNBP) is a small single-stranded nucleic acid binding protein made of seven Zn knuckles and an Arg-Gly rich box. CNBP is strikingly conserved among vertebrates and was reported to play broad-spectrum functions in eukaryotic cells biology. Neither its biological function nor its mechanisms of action were elucidated yet. The main goal of this work was to gain further insights into the CNBP biochemical and molecular features. We studied Bufo arenarum CNBP (bCNBP) binding to single-stranded nucleic acid probes representing the main reported CNBP putative targets. We report that, although bCNBP is able to bind RNA and single-stranded DNA (ssDNA) probes in vitro, it binds RNA as a preformed dimer whereas both monomer and dimer are able to bind to ssDNA. A systematic analysis of variant probes shows that the preferred bCNBP targets contain unpaired guanosine-rich stretches. These data expand the knowledge about CNBP binding stoichiometry and begins to dissect the main features of CNBP nucleic acid targets. Besides, we show that bCNBP presents a highly disordered predicted structure and promotes the annealing and melting of nucleic acids in vitro. These features are typical of proteins that function as nucleic acid chaperones. Based on these data, we propose that CNBP may function as a nucleic acid chaperone through binding, remodeling, and stabilizing nucleic acids secondary structures. This novel CNBP biochemical activity broadens the field of study about its biological function and may be the basis to understand the diverse ways in which CNBP controls gene expression.     

In vitro preparation of amelogenin nanoparticles carrying nucleic acids

Amelogenin, a matrix protein involved in biomineralization of enamel, can self-assemble to form nanospheres in a pH-dependent manner. Nucleic acids (single-stranded, double-stranded, and plasmid DNA, as well as RNA) could be co-precipitated with amelogenin, demonstrating a strong binding of nucleic acids to amelogenin. The amounts of co-precipitated nucleic acids were analyzed and binding levels upto 90 μg DNA/mg amelogenin was achieved. The co-precipitation could also be carried out in a bacterial cell homogenate, and no bacterial proteins were found in the amelogenin aggregates, suggesting specificity for nucleic acid binding. Dynamic light scattering showed that amelogenin nanosphere structure is maintained upon DNA binding with an upto 2.6 nm increase in diameter. The reported binding of nucleic acids to amelogenin can be explored practically for nucleic acid separation.     

Perfectly complementary nucleic acid enzymes

The ability to maximize the use of available nucleic acid sequence space would have been crucial during the presumed RNA world and confers selective advantage in many contemporary organisms. One way to access sequence space at a higher density would be to make use of both strands of a duplex nucleic acid for the production of functional molecules. As a demonstration of this possibility, two pairs of nucleic acid enzymes were engineered to be perfect complements, each with the capacity to adopt a distinct structure and catalyze a particular chemical transformation. Both members of each pair of enzymes exhibited nearly the same level of activity as the canonical form of the corresponding catalytic motif. The ability to generate functional nucleic acids encoded by both strands of a duplex has implications for the evolution of catalytic nucleic acids and the prospects for realizing maximum functionality from a given genetic sequence. Present address (Scott T. Kuhns): CancerVax Corp., 9393 Towne Center Drive, San Diego, CA 92121, USA     

Fractionation with ethanol of nucleic acids from viroid-infected plants

A combination of high salt and low ethanol concentration allowed the fractionation of nucleic acids extracted from viroid-infected leaves. By adding 0.4-0.5 vol of ethanol to 1 vol of a solution in 2 M LiCl of nucleic acids (containing mainly DNA, 4S, 5S, 7S, and viroid RNAs), 85% of the DNA and 75% of the 4S RNA remained in solution, from where they could be recovered by increasing the ethanol concentration, whereas almost all 5S, 7S, and viroid RNAs precipitated. When this process was repeated three times a 95% elimination of the initial DNA and 4S RNA was achieved. The method can be of special interest in viroid purification considering that DNA and 4S RNA are the most abundant contaminants in the starting solution of nucleic acids. It is suggested that the highly ordered secondary structure of viroid RNA may be responsible for its particular behavior in the ethanol fractionation of nucleic acids.     

Watersoluble synthetic nucleic acid analogs--polyethyleneimine derivatives containing nucleic acid bases--conformation and interactionwith nucleic acids

Water soluble polyethyleneimine derivatives containing nucleic acid bases were found to interact with polynucleotides, DNA, RNA. The conformational change by formation of complex was observed by CD spectra and was discussed with the hypochromicity in UV spectra. The rates of interactions between nucleic acid bases in polymers were slow as shown by UV spectra, but the conformational changes of the polynucleotides were fast as shown by CD spectra. In the case of the uracil derivative (PEI-Hse-Ura), high value of CD spectra [theta] 2.80 = -8.0 x 10(-4) for the complex with DNA might be caused by psi type conformation of DNA.