Sequence requirements of oligonucleotide chiral selectors for the capillary electrophoresis resolution of low-affinity DNA binders.

We recently reported that a great variety of DNA oligonucleotides (ONs) used as chiral selectors in partial-filling capillary electrophoresis (CE) exhibited interesting enantioresolution properties toward low-affinity DNA binders. Herein, the sequence prerequisites of ONs for the CE enantioseparation process were studied. First, the chiral resolution properties of a series of homopolymeric sequences (Poly-dT) of different lengths (from 5 to 60-mer) were investigated. It was shown that the size increase-dependent random coil-like conformation of Poly-dT favorably acted on the apparent selectivity and resolution. The base-unpairing state constituted also an important factor in the chiral resolution ability of ONs as the switch from the single-stranded to double-stranded structure was responsible for a significant decrease in the analyte selectivity range. Finally, the chemical diversity enhanced the enantioresolution ability of single-stranded ONs. The present work could lay the foundation for the design of performant ON chiral selectors for the CE separation of weak DNA binder enantiomers.

Separation and identification of oligonucleotides by hydrophilic interaction liquid chromatography (HILIC)-inductively coupled plasma mass spectrometry (ICPMS).

A method for the separation and detection of oligonucleotides utilizing hydrophilic interaction liquid chromatography (HILIC) with inductively coupled plasma mass spectrometry (ICPMS) is described. Polythymidylic acids of various lengths (10, 15, 20 and 30 nucleotides) were separated under gradient HILIC conditions. Selective detection of oligonucleotides was possible through monitoring m/z 47, corresponding to (31)P(16)O(+), using ICPMS. Oxygen was used as a reaction gas in the collision/reaction cell to produce PO(+) by reacting with phosphorus in the gas phase, thereby effectively eliminating the interferences for phosphorus normally seen at m/z 31. Limits of detections (LODs) were determined to be 1.69 pmol, 1.21 pmol, 1.0 pmol and 0.55 pmol loaded on column for the 10, 15, 20 and 30 mer, respectively.

Histidine affinity chromatography of homo-oligonucleotides. Role of multiple interactions on retention.

The recent application of histidine-agarose affinity supports in plasmid purification takes advantage of the biorecognition of nucleic acid bases by the histidine ligand. This consideration prompted the need for better understanding the interactions involved in affinity chromatography of plasmid DNA with the histidine-agarose support. In this work, we used synthetic homo-deoxyoligonucleotides with different sizes (1-30 nucleotides long), to explore the effect of several conditions like hydrophobic character of the individual bases, presence of secondary structures, temperature, pH and salt concentration on the mechanism of retention of nucleic acids to histidine-agarose support. One of the most striking results shows that histidine interacts preferentially with guanine, and the presence of secondary structures on polyA and polyG oligonucleotides has a significant influence on retention. Otherwise, the temperature manipulation has not shown a direct influence on oligonucleotide retention, only inducing conformational changes on secondary structures. Overall, the results obtained provide valuable information for the future development and implementation of histidine and other amino acids as ligands in chromatography for the purification of plasmid DNA and other nucleic acids, by improving the knowledge of the interactions involved as well as of the parameters influencing the retention.

Identification of residues in the single-stranded DNA-binding site of the 8-kDa domain of rat DNA polymerase beta by UV cross-linking.

Rat DNA polymerase beta (beta-pol) is a 39-kDa monomeric protein, organized in two structurally and functionally distinct domains. The 8-kDa NH2-terminal domain binds single-stranded (ss) DNA, whereas the 31-kDa COOH-terminal domain does not. To facilitate studies on ssDNA binding structure-function relationships of beta-pol, we overexpressed the 8-kDa domain in Escherichia coli, and purified the recombinant protein to homogeneity. Single-stranded nucleic acid binding of the recombinant 8-kDa domain was found to be similar to that previously reported for the 8-kDa fragment prepared by proteolysis of intact beta-pol (Kumar, A., Widen, S. G., Williams, K. R., Kedar, P. Karpel, R. L., and Wilson, S. H. (1990b) J. Biol. Chem. 265, 2124-2131; Casas-Finet, J. R., Kumar, A., Morris, G., Wilson, S. H., and Karpel, R. L. (1991) J. Biol. Chem. 266, 19618-19625). Residues in or near the DNA-binding pocket of the recombinant 8-kDa domain were examined by photochemical cross-linking to [32P] p(dT)16. Cross-linking was localized to a tryptic fragment spanning residues 28 through 35 and a V8 protease fragment spanning residues 27 through 58. Sequence analysis of the various [32P]p(dT)16-labeled proteins indicated that Ser30 and His34 were modified by cross-linking to p(dT)16. Therefore, these residues of the ssDNA-binding domain of beta-pol appear to be in close contact with this nucleic acid probe.

Sequence recognition protein for the 17-base-pair A + T-rich tract in the replication origin of simian virus 40 DNA.

A DNA-binding protein has been identified that recognizes runs of deoxyadenines and/or deoxythymines (dA/dT sequences) and purified from a chromatographic fraction containing the multiprotein DNA polymerase alpha-primase complex of HeLa cells by successive steps of chromatography on oligo(dT)-cellulose and Q-Sepharose. Polyacrylamide gel electrophoresis of the purified dA/dT sequence-binding protein in the presence of NaDodSO4 showed a single protein band of 62 kDa. Nitrocellulose filter binding assays using homopolydeoxynucleotides indicated that the purified protein preferentially binds to dA/dT sequences in single-stranded or duplex DNAs. Gel mobility shift assays with a variety of DNAs showed that the purified protein specifically binds to a fragment of simian virus 40 DNA containing the minimal (core) origin for replication. The binding occurred in a protein-dependent manner and in the presence of a vast excess of competing DNAs lacking the simian virus replication origin. The origin binding was reduced, however, when DNA fragments from simian virus 40 deletion mutants containing deletions within the 17-base-pair A + T-rich tract in the core DNA replication origin were used in the assays. These results indicate that the dA/dT sequence-binding protein preferentially binds to the 17-base-pair A + T-rich tract and suggest a possible role for the protein in the initiation of DNA replication.

Kinetic investigation of unfolding and partial refolding of a crab satellite (dA-dT)n.

Crab (dA-dT)n was isolated from the testes of Cancer borealis by a procedure involving separation of DNA and segregation of the satellite fraction by Hg2+ binding/Cs2SO4 density gradient ultracentrifugation. The titration of crab (dA-dT)n samples at 10 degrees indicated a sharp absorbance change at pH 11.98 in agreement with the pHm value observed for synthetic poly(dA-dT) under identical conditions. The reversal of the titration, however, resulted only in about 50% recovery of the original absorbance (at 260 nm) in marked contrast to the complete reversibility of the synthetic material. pH-jump experiments were carried out for the purpose of characterizing the rates and mechanisms of conformational transitions brought about by changes in the solution environment. It was found that the disintegration of the putative native structure of crab (dA-dT)n starts with a very fast reaction (occurring within the 6-msec deadtime of the instrument and comprising 65% of the total absorbance change) and it is completed via a slower first-order reaction (k = 66 sec minus 1). It is postulated that the first process is due to the rapid untwisting of end regions and, perhaps, some short hairpin-like helical branches present on the macromolecules. The second reaction is believed to be the end-to-end type unwinding of the double-helical backbone of crab (dA-dT)n. In the presence of low concentration (3 mug/ml) of Hg2+ ions the overall rate of disintegration process decreased drastically. pH jumps from pH values above pHm to values below were used to study the rates of absorbance changes corresponding to the refolding of the strands of denatured crab (DA-dT)n. A concentration independent process consisting of two phases was observed. The first phase was a gradual nonexponential process spanning the first second of the reaction, and the other, a very slow first-order process characterized by the rate constant value of 0.053 sec minus 1. It is proposed that the first part of the process (involving about 24% of nucleotide residues) is an intramolecular formation of helical hairpins (frequently interrupted by mismatching bases) and the second part is a manifestation of some association of the extant unpaired bases during the folding of the branched structure. Refolded crab (dA-dT)n samples when subjected again to pH greater than pHm in the stopped-flow apparatus displayed not the disintegration pattern of the native crab (dA-dT)n but rather that of synthetic poly(dA-dT. The marked facility of crab (dA-dT)n macromolecules for rapid conformational transitions induced by slight changes in the solution environment might be relevant to the biological function of this DNA.