Viral aggregation: buffer effects in the aggregation of poliovirus and reovirus at low and high pH.

The effects of the buffer employed in maintaining a given pH value were tested on the aggregation of two viruses, poliovirus and reovirus. Poliovirus was found to aggregate at pH values of 6 and below, but not at pH 7 or above, except in borate buffer. Reovirus aggregated at pH 4 and below, but was found to aggregate only in acetate or tris(hydroxymethyl)aminomethane-citrate buffers at pH 5. Other buffers tested for aggregation of reovirus at pH 5 (succinate, citrate, and phosphate-citrate) induced little aggregation. No significant aggregation was found for reovirus at pH 6 and above. For both viruses, the most effective aggregation was induced by buffers having a substantial monovalently charged anionic component, such as acetate at pH 5 and 6 or citrate at pH 3. Cationic buffers at low pH, such as glycine, were generally weaker in aggregating ability than anionic buffers at the same pH. These results, when correlated with the isoelectric point of the viruses (poliovirus at pH 8.2; reovirus at pH 3.9) indicated that both viruses aggregated strongly when their overall charge was positive, but only under certain circumstances when their overall charge was negative. Although reovirus aggregated massively at its isoelectric point, poliovirus remained dispersed at its isoelectric point. The conclusion can be drawn that those pH and buffer conditions which induced aggregation of one virus do not necessarily induce it in another.     

Viral aggregation: buffer effects in the aggregation of poliovirus and reovirus at low and high pH.

The effects of the buffer employed in maintaining a given pH value were tested on the aggregation of two viruses, poliovirus and reovirus. Poliovirus was found to aggregate at pH values of 6 and below, but not at pH 7 or above, except in borate buffer. Reovirus aggregated at pH 4 and below, but was found to aggregate only in acetate or tris(hydroxymethyl)aminomethane-citrate buffers at pH 5. Other buffers tested for aggregation of reovirus at pH 5 (succinate, citrate, and phosphate-citrate) induced little aggregation. No significant aggregation was found for reovirus at pH 6 and above. For both viruses, the most effective aggregation was induced by buffers having a substantial monovalently charged anionic component, such as acetate at pH 5 and 6 or citrate at pH 3. Cationic buffers at low pH, such as glycine, were generally weaker in aggregating ability than anionic buffers at the same pH. These results, when correlated with the isoelectric point of the viruses (poliovirus at pH 8.2; reovirus at pH 3.9) indicated that both viruses aggregated strongly when their overall charge was positive, but only under certain circumstances when their overall charge was negative. Although reovirus aggregated massively at its isoelectric point, poliovirus remained dispersed at its isoelectric point. The conclusion can be drawn that those pH and buffer conditions which induced aggregation of one virus do not necessarily induce it in another.     

Low- and high-resolution mapping of DNA damage at specific sites

Measurement of DNA damage and repair at the nucleotide level in intact cells has provided compelling evidence for the molecular details of these events as they occur in intact organisms. Furthermore, these measurements give the most accurate picture of the rates of repair in different structural domains of DNA in chromatin. In this report, we describe two methods currently used in our laboratories to map DNA lesions at (or near) nucleotide resolution in yeast cells. The low-resolution method couples damage-specific strand breaks in DNA with indirect end-labeling to measure DNA lesions over a span of 1.5 to 2 kb of DNA sequence. The resolution of this method is limited by the resolution of DNA length measurements on alkaline agarose gels (about +/-20 bp on average). The high-resolution method uses streptavidin magnetic beads and special biotinylated oligonucleotides to facilitate end-labeling of DNA fragments specifically cleaved at damage sites. The latter method maps DNA damage sites at nucleotide resolution over a shorter distance (<500 bp), and is constrained to the length of DNA resolvable on DNA sequencing gels. These methods are used in tandem for answering questions regarding DNA damage and repair in different chromatin domains and states of gene expression.     

Oligonucleotides Quality Control Analysis in Free Solution by Capillary Electrophoresis at Acidic pH

Abstract

A new method for fast, automated and inexpensive oligonucleotides analysis by capillary electrophoresis at low pH is presented. This method does not need any sieving media to resolve a mixture of polynucleotides which are analysed in free solution and separated on the base of composition and not length. This technique has been used to test a large set of standard and modified oligonucleotides thus to be applied in oligos routine quality control.     

Sequence-specific labeling of superhelical DNA by triple helix formation and psoralen crosslinking.

Site-specific labeling of covalently closed circular DNA was achieved by using triple helix-forming oligonucleotides 10, 11 and 27 nt in length. The sequences consisted exclusively of pyrimidines (C and T) with a reactive psoralen at the 5'-end and a biotin at the 3'-end. The probes were directed to different target sites on the plasmids pUC18 (2686 bp), pUC18/4A (2799 bp) and pUC1 8/4A-H 1 (2530 bp). After triple helix formation at acid pH the oligonucleotides were photocrosslinked to the target DNAs via the psoralen moiety, endowing the covalent adduct with unconditional stability, e.g. under conditions unfavorable for preservation of the triplex, such as neutral pH. Complex formation was monitored after polyacrylamide gel electrophoresis by streptavidin-alkaline phosphatase (SAP)-induced chemiluminescence. The yield of triple helix increased with the molar ratio of oligonucleotide to target and the length of the probe sequence (27mer > 11mer). The covalent adduct DNA were visualized by scanning force microscopy (SFM) using avidin or streptavidin as protein tags for the biotin group on the oligonucleotide probes. We discuss the versatility of triple helix DNA complexes for studying the conformation of superhelical DNA.     

Quasi-isoelectric buffers for protein analysis in a fast alternative to conventional capillary zone electrophoresis

Two different approaches are here reported for obtaining ultra-narrow pI cuts from 2-pH unit wide carrier ampholyte ranges, as commercially available, for use as quasi-isoelectric buffers in capillary electrophoresis separations of proteins. One of them uses multicompartment electrolyzers endowed with isoelectric membranes (Immobiline technology); the other employs the Rotofor equipment. Although the first approach results in more precise pI cuts, the latter technique is much faster, easier to handle and permits the immediate collection of 20 fractions in a single run. This results in ultra-narrow, ca. 0.1-pH unit intervals, uniformly spaced apart along the original wider gradient utilized for the fractionation. It is here shown that such quasi-isoelectric buffers, especially those in the pH 8-9 interval, have the unique property of coating the silica wall, thus preventing interaction of the proteins with the silica surface, that would otherwise totally disrupt the separation. On the contrary, such a shielding is not obtained in control, non isoelectric buffers (such as phosphate), that give very poor separations in uncoated capillaries. It is hypothesized that such a unique shielding effect is due to the oligo-amino backbone of the carrier ampholytes, typically composed (in the Vesterberg's synthetic approach) of 4-6 nitrogens spaced apart by ethylene moieties. Although such oligoprotic buffers should bear, in the isoelectric state, just one positive and one negative charge, they might be transiently ionized upon contact with the silanols, thus inducing a cooperative binding to the silica wall.     

Use of polybuffer as carrier ampholytes in mixed-bed Immobiline gels for isoelectric focusing

In mixed-bed, carrier ampholyte-Immobiline gels, a primary, insolubilized pH gradient is admixed with a secondary, soluble pH gradient generated by amphoteric buffers. The latter are the standard carrier ampholytes (e.g. Ampholine, Pharmalyte, Biolyte, Servalyte), used in conventional isoelectric focusing, admixed to Immobiline gels in levels of approximately 0.5-1%. It is here shown that polybuffers 96 (covering the pH 6-9 range) and 74 (covering the pH 4-7 interval) used as eluents in chromatofocusing, can effectively substitute the standard carrier ampholytes with considerable savings (they are 1/16th as expensive as the latter chemicals).     

Characterization of polymeric buffers for operating membrane-trapped enzyme reactors in an electric field

A novel class of amphoteric, polymeric buffers, is described, consisting of grafting onto growing polyacrylamide chains weakly acidic and basic acrylamido-monomers (called Immobilines; protolytic groups as N-substituents on the nitrogen of the amido bond), for operating a membrane-immobilized enzyme reactor (MIER) in an electric field. With these soluble, polymeric buffers, it is possible to operate the membrane reactor at any optimum of pH activity, for any given enzyme, in the pH 3-10 scale. Such buffers, being amphoteric, are confined in the enzyme reaction chamber by the same isoelectric trapping mechanism. The best buffers were found to be those polymerized in presence of 9% neutral monomer (acrylamide) and containing 20 mM Immobiline as buffering ion. To decrease their viscosity in solution, the polymeric buffers are synthesized at high temperatures (70 degrees C) and in presence of a chain-transfer agent. The weight average molecular size in these conditions has been found to be ca. 200,000 Da. These buffers exhibited excellent performance in a variety of enzyme reactions in the MIER, such as in the case of penicillin G acylase and histidine decarboxylase and were found to greatly stabilize enzyme activity, permitting operation of the MIER over extended periods of time. As an example, in a penicillin G acylase reactor, >75% enzyme activity was maintained over a 10-d cycle of operation, while with conventional buffers more than 90% inactivation was experienced over the same period of time. This novel class of macromolecular, amphoteric buffers could also be exploited in other types of conventional bioreactors not based on an isoelectric trapping mechanism.     

Parallel multiplex thermodynamic analysis of coaxial base stacking in DNA duplexes by oligodeoxyribonucleotide microchips

Parallel thermodynamic analysis of the coaxial stacking effect of two bases localized in one strand of DNA duplexes has been performed. Oligonucleotides were immobilized in an array of three-dimensional polyacrylamide gel pads of microchips (MAGIChips‘). The stacking effect was studied for all combinations of two bases and assessed by measuring the increase in melting temperature and in the free energy of duplexes formed by 5mers stacked to microchip-immobilized 10mers. For any given interface, the effect was studied for perfectly paired bases, as well as terminal mismatches, single base overlaps, single and double gaps, and modified terminal bases. Thermodynamic parameters of contiguous stacking determined by using microchips closely correlated with data obtained in solution. The extension of immobilized oligonucleotides with 5,6-dihydroxyuridine, a urea derivative of deoxyribose, or by phosphate, decreased the stacking effect moderately, while extension with FITC or Texas Red virtually eliminated stacking. The extension of the immobilized oligonucleotides with either acridine or 5-nitroindole increased stacking to mispaired bases and in some GC-rich interfaces. The measurements of stacking parameters were performed in different melting buffers. Although melting temperatures of AT- and GC-rich oligonucleotides in 5 M tetramethylammonium chloride were equalized, the energy of stacking interaction was significantly diminished.     

Parallel self-associated structures formed by T,C-rich sequences at acidic pH

Oligonucleotides of nonregular heteropyrimidine sequences incorporating or not incorporating purine residues 5'-d(ACTCCCTTCTCCTCTCTA), 5'-d(ACTCCCTGGTCCTCTCTA), 5'-d(TCTCTCCTGGTCCCTCC), and 5'-d(TCTCTCCTCTTCCCTCC) can form self-associated parallel-stranded (ps) structures at pH 4-5.5. The ps structures were identified by studying at neutral and acidic pH UV melting transitions, FTIR spectra, and fluorescence of pyrene-labeled oligonucleotides as well as by chemical joining of 5'-phosphorylated oligonucleotides. A gel electrophoresis run for oligonucleotides 5'-d(TCTCTCCTCTTCCCTCC) and 5'-d(ACTCCCTTCTCCTCTCTA) has shown the formation of homoduplexes at low DNA strand concentrations. Ps structures are held by C-C(+) base pairs and have N- and S-types of sugar puckering as detected by FTIR spectroscopy in the millimolar concentration range. Guanine inserts as well as thymine and purine inserts into an oligomeric cytosine sequence make the formation of the tetraplex i-motif unfavorable. MvaI restriction endonuclease, which recognizes the CCT/AGG sequence in DNA, does not cleave parallel pseudosubstrates.     

Inversion of in situ synthesized oligonucleotides: improved reagents for hybridization and primer extension in DNA microarrays

Oligonucleotides synthesized in array format suffer from contamination by truncated species. We have developed a method to invert DNA molecules in situ after completed synthesis. Reactive functions at the 5'-ends of the oligonucleotides are permitted to react with functions on the support before the 3'-ends are released, in effect reversing the orientation of full-length oligonucleotides, while any 5'-truncated molecules are lost. This strategy serves both to purify in situ synthesized reagents and to reorient the oligonucleotides, causing them to expose free 3'-hydroxyls. In situ inverted oligonucleotides can be used in assays based on DNA polymerase-assisted extension of immobilized primers, and we demonstrate their utility in minisequencing and in pyrosequencing.     

Monitoring equilibria and kinetics of protein folding/unfolding reactions by capillary zone electrophoresis

A method is described here for studying conformational transitions of proteins due to denaturing agents: capillary zone electrophoresis (CZE) in acidic, isoelectric buffers. The sample is run in 50 mM isoelectric glutamic acid (pH = pI = 3.2) added with 1 mM oligoamine (tetraethylene pentamine) for quenching protein interaction to the capillary wall (final pH = 3.3). Muscle acylphosphatase (AcP), in this buffer, exhibited a free solution mobility of 2.63 x 10(-4) cm(2) V(-1) s(-1). By studying the unfolding kinetics, as a function of time of incubation in 7 M urea, it was possible to measure the rate constant of the unfolding reaction, estimated to be 0.00030+/-0.00006 s(-1). The same measurements, when repeated via spectroscopic monitoring of intrinsic fluorescence, gave a value of 0.00034+/-0.00002 s(-1), thus in excellent agreement with CZE data. By equilibrium unfolding CZE studies, it was possible to construct the typical sigmoidal transition of unfolding vs urea molarity: the midpoint of this transition, at which the folded and unfolded states should be equally populated, was estimated to be at 4.56 M urea. Similar experiments by fluorometric analysis gave a value of 4.60 M urea as midpoint of the unfolding curve.     

Production of a homogeneous Cl. botulinum type B neurotoxin

The method for obtaining the neurotoxin, or alpha-fraction of the toxin, of Cl. botulinum, type B, is described. In accordance with this method, the toxin was precipitated three times with hydrochloric acid in the isoelectric zone with subsequent extraction with phosphate (pH 6.8) and citrate-phosphate (pH 5.6) buffers, then fractionated in columns with DEAE cellulose (pH 5.6), DEAE Sephadex A-50 (pH 7.2) and Sephadex G-200 (pH 7.2). The homogeneous neurotoxin preparations with molecular weights ranging from 145,000 to 160,000 and having the isoelectric point at pH 5.5 and toxicity 5.0--10.0 x 10(7) Dlm per 1 mg protein were obtained.     

Mutagenesis directed by phosphotriester analogs of oligonucleotides

20-mer oligodeoxyribonucleotides d-ACGACGG (R') CCAG (R') TGATCCGTA, where R' = R' = H (20), F' = Et, R' = H (20-Et), or R' = R' = Et (20-Et2) were synthesized by modified triester method. Ethylated dinucleotide blocks were prepared by transesterification method from chlorophenyl derivatives. Structures of oligonucleotides were confirmed by Maxam - Gilbert method. Mutagenesis induced by oligonucleotides was studied on DNA of M13mpB phage. Oligonucleotides were not totally complementary to this DNA in the region of 4-11 codons of Z'-gene. They all were shown to direct the formation of the designed deletion mutants, phosphotriester analogues (20-Et) and (20-Et2) being more effective mutagens. The specificity of oligonucleotides: DNA binding and mutant DNA structure were shown by Sanger method.     

8-aza-7-deazaadenine and 7-deazaguanine: synthesis and properties of nucleosides and oligonucleotides with nucleobases linked at position-8

The 8-aza-7-deazaadenine (pyrazolo[3,4-d]pyrimidin-4-amine) N8-(2'-deoxyribonucleoside) (2) and the 7-deazaguanine (pyrrolo[3,4-d]pyrimidine-2-amin-(3H)-4-one) C8-(2'-deoxyribonucleoside) (4) were synthesized and incorporated in oligonucleotides employing phosphoramidite chemistry. Oligonucleotides carrying compound 2 are able to form base pairs with the four canonical DNA constituents without significant structural discrimination. The nucleoside 4 was obtained from the corresponding ribonucleoside by deoxygenation. Oligonucleotides containing compound 4 showed similar base pairing properties as those with 2'-deoxyisoguanosine.     

Evaluation of an effective sample prefractionation method for the proteome analysis of breast cancer tissue using narrow range two-dimensional gel electrophoresis

One method of improving the protein profiling of complex mammalian proteomes is the use of prefractionation followed by application of narrow pH range two dimensional (2-D) gels. The success of this strategy relies on sample solubilization; poor solubilization has been associated with missing protein fractions and diffuse, streaked, and/or trailing protein spots. In this study, I sought to optimize the solubilization of prefractionated human cancer cell samples using isoelectric focusing (IEF) rehydration buffers containing a variety of commercially available reducing agents, detergents, chaotropes, and carrier ampholytes. The solubilized proteins were resolved on 2-D gels and compared. Among five tested IEF rehydration buffers, those containing 3-[(3-cholamidopropyl)dimethylamino]-1-propane sulfonate (CHAPS) and dithiothreitol (DTT) provided superior resolution, while that containing Nonidet P-40 (NP-40) did not significantly affect protein resolution, and the tributyl phosphine (TBP)-containing buffer yielded consistently poor results. In addition, I found that buffers containing typically high urea and ampholyte levels generated sharper 2-D gels. Using these optimized conditions, I was able to apply 2-D gel analysis successfully to fractionated proteins from human breast cancer tissue MCF-7, across a pH range of 4-6.7.     

Predicting stability of DNA duplexes in solutions containing magnesium and monovalent cations

Accurate predictions of DNA stability in physiological and enzyme buffers are important for the design of many biological and biochemical assays. We therefore investigated the effects of magnesium, potassium, sodium, Tris ions, and deoxynucleoside triphosphates on melting profiles of duplex DNA oligomers and collected large melting data sets. An empirical correction function was developed that predicts melting temperatures, transition enthalpies, entropies, and free energies in buffers containing magnesium and monovalent cations. The new correction function significantly improves the accuracy of predictions and accounts for ion concentration, G-C base pair content, and length of the oligonucleotides. The competitive effects of potassium and magnesium ions were characterized. If the concentration ratio of [Mg (2+)] (0.5)/[Mon (+)] is less than 0.22 M (-1/2), monovalent ions (K (+), Na (+)) are dominant. Effects of magnesium ions dominate and determine duplex stability at higher ratios. Typical reaction conditions for PCR and DNA sequencing (1.5-5 mM magnesium and 20-100 mM monovalent cations) fall within this range. Conditions were identified where monovalent and divalent cations compete and their stability effects are more complex. When duplexes denature, some of the Mg (2+) ions associated with the DNA are released. The number of released magnesium ions per phosphate charge is sequence dependent and decreases surprisingly with increasing oligonucleotide length.     

The use of poly(2-acrylamido-2-methyl-1-propanesulfonic acid) polymers as spacers for isotachophoresis in sieving gel matrices

The electric field strength gradients generated in isotachophoresis (ITP) may be used for the separation of biomolecules. Poly(2-acrylamido-2-methyl-1-propanesulfonic acid) (polyAMPS) polymers of a uniform distribution of molecular mass were synthesized and used as novel spacers in ITP. Since these polymeric spacers are strongly acidic species, their ionic charges remain constant over a wide pH range, so that their ionic mobilities are governed solely by their molecular masses and not by the pH of the milieu. A modification of ITP known as telescope electrophoresis was used to separate a number of acidic dyes of varying ionic mobility, using polyAMPS polymers as spacers. The resolution obtained was superior to that obtained by polyacrylamide gel electrophoresis (PAGE), due to the focusing effect of the electric field strength gradient. Since these novel polymeric spacers are designed to operate within sieving medium, it was decided to test their suitability for the separation of DNA molecules. DNA molecules up to 1000 bp long were successfully resolved, with a similar resolution to that obtained with conventional PAGE.     

Chemical synthesis of oligonucleotides containing a free sulphydryl group and subsequent attachment of thiol specific probes.

Oligonucleotides containing a free sulphydryl group at their 5'-termini have been synthesised and further derivatised with thiol specific probes. The nucleotide sequence required is prepared using standard solid phase phosphoramidite techniques and an extra round of synthesis is then performed using the S-triphenylmethyl O-methoxymorpholinophosphite derivatives of 2-mercaptoethanol, 3-mercaptopropan (1) ol or 6-mercaptohexan (1) ol. After cleavage from the resin and removal of the phosphate and base protecting groups, this yields an oligonucleotide containing an S-triphenylmethyl group attached to the 5'-phosphate group via a two, three or six carbon chain. The triphenylmethyl group can be readily removed with silver nitrate to give the free thiol. With the three and six carbon chain oligonucleotides, this thiol can be used, at pH 8, for the attachment of thiol specific probes as illustrated by the reaction with fluorescent conjugates of iodoacetates and maleiimides. However, oligonucleotides containing a thiol attached to the 5'-phosphate group via a two carbon chain are unstable at pH 8 decomposing to the free 5'-phosphate and so are unsuitable for further derivatisation.     

Atypical sieving of open circular DNA during pulsed field agarose gel electrophoresis

Pulsed field agarose gel (PFG) electrophoresis, originally used to improve the resolution by length of linear DNA [Cantor et al. (1988) Annu. Rev. Biophys. Biophys. Chem. 17, 287-304], is found here to cause atypical sieving of 48.5-97.0-kb open circular DNA. Two procedures of PFG electrophoresis are used: rotating gel electrophoresis with rotation of 2 pi radians [2 pi RGE; Serwer, P., & Hayes, S.J. (1989) Appl. Theor. Electrophor. (in press)] and field inversion gel electrophoresis [FIGE; Carle, G.F., Frank, M., & Olson, M. V. (1986) Science 232, 65-68]. During 2 pi RGE at 6 V/cm, the electrophoretic mobility (mu) of 48.5-kb open circular DNA increases in magnitude as agarose percentage (A) increases from 0.4 to 1.5. The sieving revealed by this mu vs A relationship is highly atypical (possibly unique) for any particle. The extent of this atypical sieving increases as electrical potential gradient, DNA length, and pulse time increase. In some cases a maximum is observed in a plot of mu's magnitude vs A. The mu of open circular lambda DNA is smaller in magnitude than the mu of equally long linear lambda DNA. Atypical sieving has also been observed by use of FIGE. As pulse times used during FIGE decrease below those achievable by 2 pi RGE, the progressive loss of circular DNA's atypical sieving is accompanied by both a dramatic increase in mu's magnitude at the lower A values and a decrease in mu's magnitude at the higher A values. At the lower A values, open circular DNA sometimes migrates more rapidly than linear DNA of the same length.(ABSTRACT TRUNCATED AT 250 WORDS)