Melting of DNA Oligomers: Dynamical Models and Comparison with Experimental Results

We compare experimental melting curves of short heterogeneous DNA oligomers with theoretical curves derived from statistical mechanics. Partition functions are computed with the one-dimensional Peyrard-Bishop (PB) Hamiltonian, already used in the study of the melting of long DNA chains. Working with short chains we take into account, in the computations, not only the breaking of the interstrand hydrogen bonds, but also the complete dissociation of the double helix into separate single strands. Since this dissociation equilibrium is of general relevance, independent of the particular microscopic model, we give some details of its treatment. We discuss how the non bonded three-dimensional interactions, not explicitly considered in the one-dimensional PB model, are taken into account through the treatment of the dissociation equilibrium. We also evaluate the relevance of the dissociation as a function of the chain length.     

A strategy for establishing accurate quantitation standards of oligonucleotides: quantitation of phosphorus of DNA phosphodiester bonds using inductively coupled plasma-optical emission spectroscopy

A novel approach for quantitation of DNA (oligonucleotides) with an unprecedented accuracy of approximately 1% is reported. Quantitation of DNA is commonly performed by measuring UV absorption or fluorescence from dyes intercalated into DNA. Both methods need accurate quantitation standards to yield more comparable results between laboratories. For establishing technically authentic standards for DNA quantitation, a new measurement approach carrying an inherent capability of absolute quantitation is demanded. The proposed approach is based on the stoichiometric existence of phosphorus (P) in DNA. The quantity of P from the phosphodiester backbone of a purified oligonucleotide was accurately determined using inductively coupled plasma-optical emission spectroscopy (ICP-OES) with yttrium internal standard via acid digestion. The number of moles of oligonucleotides was then calculated from that of P using the stoichiometry. The major issues regarding the validity of the suggested approach were (i) effective removal of extra P sources, (ii) quantitative recovery of P through the digestion process, and (iii) oligomeric purity of the target oligonucleotide. These issues were investigated experimentally using various analytical techniques such as matrix-assisted laser desorption/ionization-time of flight mass spectrometry (MALDI-TOF MS), capillary electrophoresis, electrical conductometry, UV spectrometry, and gravimetry. In conclusion, it is feasible to certify pure oligonucleotide reference materials with uncertainties less than 1% using the proposed approach.     

New approaches to targeting RNA with oligonucleotides: inhibition of group I intron self-splicing

RNA is one class of relatively unexplored drug targets. Since RNAs play a myriad of essential roles, it is likely that new drugs can be developed that target RNA. There are several factors that make targeting RNA particularly attractive. First, the amount of information about the roles of RNA in essential biological processes is currently being expanded. Second, sequence information about targetable RNA is pouring out of genome sequencing efforts at unprecedented levels. Third, designing and screening potential oligonucleotide therapeutics to target RNA is relatively simple. The use of oligonucleotides in cell culture, however, presents several challenges such as oligonucleotide uptake and stability, and selective targeting of genes of interest. Here, we review investigations aimed at targeting RNA with oligonucleotides that can circumvent several of these potential problems. The hallmark of the strategies discussed is the use of short oligonucleotides, which may have the advantage of higher cellular uptake and improved binding selectivity compared to longer oligonucleotides. These strategies have been applied to Group I introns from the mammalian pathogens Pneumocystis carinii and Candida albicans. Both are examples of fungal infections that are increasing in number and prevalence.     

Efficient strategies for the conjugation of oligonucleotides to antibodies enabling highly sensitive protein detection

Three methods for the conjugation of oligonucleotides to antibodies and the subsequent application of these conjugates to protein detection at attomole levels in immunoassays are described. The methods are based on chemical modification of both antibody and oligonucleotide. Aldehydes were introduced onto antibodies by modification of primary amines or oxidation of carbohydrate residues. Aldehyde- or hydrazine-modified oligonucleotides were prepared either during phosphoramidite synthesis or by post-synthesis derivatization. Conjugation between the modified oligonucleotide and antibody resulted in the formation of a hydrazone bond that proved to be stable over long periods of time under physiological conditions. The binding activity of each antibody-oligonucleotide conjugate was determined to be comparable to the corresponding unmodified antibody using a standard sandwich ELISA. Each oligonucleotide contained a unique DNA sequence flanked by universal primers at both ends and was assigned to a specific antibody. Highly sensitive immunoassays were performed by immobilizing analyte for each conjugate onto a solid support with cognate capture antibodies. Binding of the antibody-oligonucleotide conjugate to the immobilized analyte allowed for amplification of the attached DNA. Products of amplification were visualized using gel electrophoresis, thus denoting the presence of bound analyte. The preferred conjugation method was used to generate a set of antibody-oligonucleotide conjugates suitable for high-sensitivity protein detection.     

Zebrafish chaperone protein GP96 is required for otolith formation during ear development

Chaperone proteins are considered to be fairly ubiquitous proteins that promote the correct folding and assembly of multiple newly synthesized proteins. While performing an embryonic screen in zebrafish using morpholino phosphorodiamidate oligonucleotides (MPOs), we identified a role for an endoplasmic reticulum chaperone protein family member, zebrafish GP96. Knockdown of GP96 resulted in a specific otolith formation defect during early ear development. Otolith precursor particles did not adhere to the kinocilia of the tether cells in the GP96-MPO-injected embryos, aggregating instead into a single clump. Although otolith development was abnormal, the patterning of the ear and the differentiation of tether cells and macular sensory and support cells was not affected. We have isolated and sequenced the full open reading frame of zebrafish GP96 and characterized its expression pattern. GP96 is expressed both maternally and zygotically. GP96 RNA is localized within the floorplate, hatching gland, and in the cells of the otic placode and otic vesicle, consistent with the function of GP96 in ear development. We conclude that the GP96 chaperone protein is involved in the otolith formation during normal ear development. This is the first report of a specific function during organism development being attributed to a chaperone class molecule.     

Antisense inhibition of neuronal nicotinic receptors in the tobacco-feeding insect,Manduca sexta

Acetylcholine is the predominant excitatory transmitter in the insect central nervous system with many of its effects mediated by nicotinic acetylcholine receptors. These receptors are present at very high density and are structurally heterogeneous, although little is known about functional distinctions between them. An interesting system for examining these receptors is the larval stage of Manduca sexta, a nicotine-resistant tobacco-feeding insect. The nicotinic responses of cultured neurons were found to be blocked by mecamylamine and curare but highly resistant to alpha-bungarotoxin. The responses were also unaffected by the reducing agent dithiothreitol and the alkylating agent bromoacetylcholine suggesting that the alpha-subunit dicysteine agonist binding site is protected. To begin determining the functional roles of different subunits in these receptors, cultured neurons were treated with oligonucleotides based on the gene sequence of the alpha subunit, MARA1. Antisense DNA caused a significant downward shift in the amplitude distribution of nicotinic responses compared to sense or reverse antisense treatments. These treatments did not affect currents mediated by the application of GABA. The reduction in the nicotinic depolarization and inward currents did not affect the rate of current onset or recovery, suggesting that antisense MARA1 causes a partial block of all nicotinic responses in these neurons. These results demonstrate that receptor gene expression in insect neurons can be manipulated in a sequence-specific manner by antisense treatment and they provide evidence that MARA1 is important for normal nicotinic responses in Manduca.     

Binding of Nonnatural α,β-Oligocytidylates with DNA Duplexes

Binding of short fluorescently labeled AT-containing DNA duplexes with modified oligocytidylates is studied. The latter are modified to contain nonnatural -anomers along with natural -nucleotides; the nucleotide composition is selected according to the putative scheme of noncanonical triplex formation between duplex and oligomer bases. Nondenaturing gel electrophoresis is used to study the interaction of fluorescent duplexes with cytidyl oligomers and oligocytidylate self-association at low temperatures. A DNA duplex of random AT composition is shown to bind with an excess of the corresponding oligocytidylate in 0.1 M Tris-HCl in the presence of Mg²⁺. Binding is observed at neutral pH values, while more basic pH (8.0) prevents binding of the AT duplex and oligocytidylate. Unlike oligonucleotides of random composition, a regular dA₃₀:dT₃₀ duplex does not bind with the dC strand. It is also shown that an alternating self-complementary duplex d(AT)₁₆ and oligocytidylate d(CC)₁₅ do not form complexes, and poly-dC self-associates are formed instead. The effect of 2-O-methylation of the third strand on complex formation and self-association is also analyzed. The results suggest that a modified oligocytidylate binds with a random-composition duplex, albeit with lower efficiency.     

Molecular profiling of tyrosine kinases in normal and cancer cells

As the post-genome era is approaching, with vast amount of sequence information available and new technology developed, scientists are presented with opportunities to explore in simple analysis the structure and expression pattern of not just a single gene, but of an entire family of genes, if not the entire genome. The concept of molecular profiling or expression array has thus emerged. The need to simultaneously see all genes in the same family is obvious under the precept of the combinatorial process being an underlying principle of complex biological systems: no gene exists in isolation, for virtually every molecule participates in intermolecular interactions. The activation of receptor tyrosine kinases through homo or hetero-dimerization is the prototypic example. In this review, a tyrosine kinase profile technique and its application to studying the expression of tyrosine kinases and the identification of novel kinases will be discussed. This serves as an introduction to the several interesting papers published in this special kinase issue of theJournal of Biomedical Sciences, using this technique. A new simplified approach, kinase display, which is an extension of the profiling method and requires only restriction digestion and gel analysis will also be introduced.