Nucleic acid hybridization using DNA covalently coupled to cellulose.

We describe a method for linking RNA and DNA covalently to finely divided cellulose through a diazotized aryl amine, which reacts primarily with guanine and uracil (thymine) residues of single strands. The high efficiency of coupling and high capacity of the cellulose for nucleic acid make possible a product with as much as 67 mug of nucleic acid per mg of cellulose. The product is especially suitable for hybridization experiments where very low backgrounds are important, and it is stable in 99% formamide at 80 degrees C so that hybridized nucleic acid can be recovered easily. Full length linear Simian Virus 40 (SV40) DNA, produced by cleavage of SV40(I) DNA with S1 nuclease, can be coupled to diazo cellulose with an efficiency of 80-90%, and is effective in hybridization experiments with SV40 DNA, complementary RNA synthesized in vitro from SV40(I) DNA with E. coli RNA polymerase, and the SV40-specific fraction of total RNA from SV40-infected and transformed cells. In these experiments an excess of cellulose-bound DNA was used, and the efficiency of hybridization was about 90% when ribonuclease treatment of the hybrids was omitted.     

Nucleic acid purification using microfabricated silicon structures

A microfluidic device has been designed, fabricated and tested for its ability to purify bacteriophage lambda DNA and bacterial chromosomal DNA, a necessary prerequisite for its incorporation into a biosensor. This device consists of a microfabricated channel in which silica-coated pillars were etched to increase the surface area within the channel by 300-600%, when the etch depth is varied from 20 to 50 microm. DNA was selectively bound to these pillars in the presence of the chaotropic salt guanidinium isothiocyanate, followed by washing with ethanol and elution with low-ionic strength buffer. Positive pressure was used to move solutions through the device, removing the need for centrifugation steps. The binding capacity for DNA in the device was approximately 82 ng/cm2 and on average, 10% of the bound DNA could be purified and recovered in the first 50 microl of elution buffer. Additionally, the device removed approximately 87% of the protein from a cell lysate. Nucleic acids recovered from the device were efficiently amplified by the polymerase chain reaction suggesting the utility of these components in an integrated, DNA amplification-based biosensor. The miniaturized format of this purification device, along with its excellent purification characteristics make it an ideal component for nucleic acid-based biosensors, especially those in which nucleic acid amplification is a critical step.     

Nucleic acid sequence analysis software for microcomputers

It is clear that a computer-aided data control system is required for even small laboratories generating nucleic acid data. While the molecular biologist at many universities and large research institutions has access to mainframe computers and nucleic acid sequence analysis software, many find it more convenient to perform sequence analysis on microcomputers that are typically located within the investigator's laboratory and totally dedicated to sequence storage and analysis, in essence giving the investigator more personal control of analysis activities than is sometimes possible with shared mini- or mainframe computers. New programs are being written and released at an increasing rate to perform increasingly more complex and specialized analyses using small computer-based systems. This trend will undoubtedly continue, fueled by the need to manage the ever increasing quantity of sequence data.     

Nucleic acid amplification strategies for DNA microarray-based pathogen detection

DNA microarray-based screening and diagnostic technologies have long promised comprehensive testing capabilities. However, the potential of these powerful tools has been limited by front-end target-specific nucleic acid amplification. Despite the sensitivity and specificity associated with PCR amplification, the inherent bias and limited throughput of this approach constrain the principal benefits of downstream microarray-based applications, especially for pathogen detection. To begin addressing alternative approaches, we investigated four front-end amplification strategies: random primed, isothermal Klenow fragment-based, phi29 DNA polymerase-based, and multiplex PCR. The utility of each amplification strategy was assessed by hybridizing amplicons to microarrays consisting of 70-mer oligonucleotide probes specific for enterohemorrhagic Escherichia coli O157:H7 and by quantitating their sensitivities for the detection of O157:H7 in laboratory and environmental samples. Although nearly identical levels of hybridization specificity were achieved for each method, multiplex PCR was at least 3 orders of magnitude more sensitive than any individual random amplification approach. However, the use of Klenow-plus-Klenow and phi29 polymerase-plus-Klenow tandem random amplification strategies provided better sensitivities than multiplex PCR. In addition, amplification biases among the five genetic loci tested were 2- to 20-fold for the random approaches, in contrast to >4 orders of magnitude for multiplex PCR. The same random amplification strategies were also able to detect all five diagnostic targets in a spiked environmental water sample that contained a 63-fold excess of contaminating DNA. The results presented here underscore the feasibility of using random amplification approaches and begin to systematically address the versatility of these approaches for unbiased pathogen detection from environmental sources.     

Nucleic acid-free mutation of prion strains

While prions share the ability to propagate strain information with nucleic acid based pathogens, it is unclear how they mutate and acquire fitness in the absence of this informational component. Because prion diseases occur as epidemics, understanding this mechanism is of paramount importance for implementing control strategies to limit their spread, and for evaluating their zoonotic potential. Here we review emerging evidence indicating how prion protein primary structures, in concert with PrP^Sc conformational compatibility, determine prion strain mutation.     

Nucleic acid enzymes

Since the discovery of the first natural ribozyme more than 20 years ago, it has become clear that nucleic acids are not only the static depository of genetic information, but also possess intriguing catalytic activity. The number of reactions catalyzed by engineered nucleic acid enzymes is growing continuously. The versatility of these catalysts supports the idea of an ancestral world based on RNA predating the emergence of proteins, and also drives many studies towards practical applications for nucleic acid enzymes.     

Nucleic acid amplification-free detection of DNA and RNA at ultralow concentration

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Nucleic acid content and nucleotide composition of DNA in leptospirae.

The contents of DNA and RNA were studied in 9 strains of leptospirae and the composition of nitrogen bases of DNA in 20 strains of pathogenic and saprophytic leptospirae. It has been found that leptospirae contain a high per cent ration of nucleic acids. According to the nucleotide composition, the family of Leptospira as a whole belongs to the AT-type. According to overall guanine and cytosine contents, the investigated strains of pathogenic leptospirae fall into 3 groups and differ from the seprophytic strains. With respect to the limited number of the investigated strains, the DNA nucleotide composition of leptospirae can be used as a supplementary biochemical criterion in the classification of leptospirae.     

Nucleic acid molecular switches

Natural and artificial ribozymes can catalyse a diverse range of chemical reactions. Through recent efforts in enzyme engineering, it has become possible to tailor the activity of ribozymes to respond allosterically to specific effector compounds. These allosteric ribozymes function as effector-dependent molecular switches that could find application as novel genetic-control elements, biosensor components or precision switches for use in nanotechnology.     

Nucleic acid constituent interactions

Hydrogen bonding contributes of the order of 5–15 kcal/mol base pair to the stability of the helix (electronic or intrinsic energy). This contribution is selective, i.e., there is a preferential stability of the Watson-Crick G-C pair relative to all other pairs. Stacking interactions contribute approximately of the same order as hydrogen bonding. Perhaps the most interesting aspect of the stacking interactions which emerges from the theoretical analysis is the fact that the stacking maxima are not necessarily at the angles the successive base pair plans assume in a regular double helix. Consequently some sequence dependent structure peculiarities may arise. That is, the double helix may have a fine structure contingent on the sequence of base pairs. Indeed such sequence dependent polymorphism has been reported in the recent literature and appears to influence the ability of aromatic drugs to intercalate into the helix. The solvent effect which is another factor of stability seems to decrease somewhat bonding scheme preferences. For example, in the model we used to estimate solvent effect, we find that the G-C pair formation is de-stabilized strongly in water, while the A-T pair formation is mildly enhanced. The continuum model of solvent effect leads to similar qualitative conclusions. Studies of backbone conformation indicate that only a limited range of conformational states are comparable with the helical configuration. Improved empirical methods are needed in order to successfully calculate backbone effects for relatively large segments of nucleic acids.     

Nucleic acid enzymes.

Last year provided new structural data, particularly for the group I intron and the Hepatitis delta ribozymes, that were essential for a better understanding of the RNA structure/function relationship. The role of metal ions in catalysis of ribozyme action still remains elusive, however. In vitro selection has continued to be a rich source for obtaining data on new nucleic acid enzyme activities.     

Nucleic acid hybridization of highly repeated DNA in extracts of single Drosophila.

We have developed and characterized a method for the rapid detection and quantitation of specific DNAs in partially purified extracts of single Drosophila. While the method should be applicable to a number of repetitious DNA sequences, we have used the polypyrimidine DNA sequences (TCTCT)n to develop this technique. Using hydroxyapatite chromatography, we were able to measure the amount of nucleic acid hybrid formed and to obtain a thermal elution profile of the hybrid formed in extracts of single flies. Under a variety of conditions, purified DNA and DNA in partially purified extracts gave essentially identical results. The procedure can be used to detect the presence of rare sequences, or to measure the relative abundance of a prevalent DNA species. 40 different wild type strains of Drosophila melanogaster were examined using this technique and all contain similar amounts of the same polypyrimidine/polypurine sequence. From a small scale screening of different laboratory stocks of D. melanogaster, a variant was found which formed more DNA-DNA hybrid with labelled polypyrimidine tracts than did wild type. The additional hybrid was distinguished by a lower thermal stability than the hybrid formed in wild type.     

Automated DNA mutation analysis by single-strand conformation polymorphism using capillary electrophoresis with laser-induced fluorescence detection

Automation is essential for rapid genetic-based mutation analysis in clinical laboratory to screen a large number of DNA samples. We propose in this report an automatic process using Beckman Coulter P/ACE™ capillary electrophoresis (CE) with laser-induced fluorescence (LIF) system to detect a single-point mutation in the codon 12 of human K-ras gene. Polymerase chain reaction (PCR) using a fluorescently labeled reverse primer and a plain forward primer to specifically amplify a selected 50 bp DNA fragment in human K-ras gene. The amplified DNA is placed on the sample tray of the CE system with a pre-programmed step for single-strand conformation polymorphism (SSCP) analysis. Sample injection and denaturation processes are performed online along with separation and real-time data analysis. The concept of automation for rapid DNA mutation analysis using CE-LIF system for SSCP is presented.     

Nucleic acid scanning-by-hybridization of enterohemorrhagic Escherichia coli isolates using oligodeoxynucleotide arrays.

Nucleic acid scanning by hybridization (NASBH) is a non-electrophoretic typing strategy that uses gridded oligonucleotides to reproducibly characterize arbitrarily amplified nucleic acid sequences. Membrane-bound arrays of terminally-degenerate oligonucleotides were hybridized to DNA amplification fingerprinting (DAF) products from enterohemorrhagic Escherichia coli O157:H7 isolates. Numerical and cluster analysis of 64 isolates, selected by DAF to represent a single dominant amplification type identified 14 hybridization types. Results show that NASBH is a powerful alternative for the identification of closely related bacteria, can be used successfully in epidemiological studies, and holds potential in general nucleic acid diagnostics.     

Nucleic acid reduction in yeast

Summary A method for reduction of nucleic acid levels in preparations of the yeastsSaccharomyces cerevisiae andKluyromyces fragilis by means of alkaline treatment has been developed. Under similar conditions (4.5% NH₄OH, 65° C, 30 min) a low nucleic acid content (less than 2%) was obtained for both strains. Higher losses of proteins and biomass were obtained withK. fragilis than withS. cerevisiae.