The use of modified primers to eliminate cycle sequencing artifacts.

Cycle sequencing is the workhorse of DNA sequencing projects, allowing the production of large amounts of product from relatively little template. This cycling regime, which is aimed at linear growth of the desired products, can also produce artifacts by exponential amplification of minor side-products. These artifacts can interfere with sequence determination. In an attempt to allow linear but prevent exponential growth of products, and thus eliminate artifacts, we have investigated the use of primers containing modified residues that cannot be replicated by DNA polymerase. Specifically, we have used primers containing 2'- O -methyl RNA residues or abasic residues. Oligomers consisting of six DNA residues and 20 2'- O -methyl RNA residues, with the DNA residues located at the 3'-end, primed as efficiently as DNA primers but would not support exponential amplification. Oligonucleotides containing fewer DNA residues were not used as efficiently as primers. DNA primers containing a single abasic site located six residues from the 3'-end also showed efficient priming ability without yielding exponential amplification products. Together these results demonstrate that certain types of modified primers can be used to eliminate artifacts in DNA sequencing. The technique should be particularly useful in protocols involving large numbers of cycles, such as direct sequencing of BAC and genomic DNA.

Filamentous phage IKe mRNAs conserve form and function despite divergence in regulatory elements.

As a means of determining whether there has been selection to conserve the basic pattern of filamentous phage mRNAs, the major mRNAs representing genes II to VIII have been defined for a phage distantly related to the Ff group specific for Escherichia coli hosts bearing F pili. Phage IKe has a genome with 55% identity with the Ff genome and infects E. coli strains bearing N pili. The results reveal a remarkably similar pattern of overlapping polycistronic mRNAs with a common 3' end and unique 5' ends. The IKe mRNAs, like the Ff phage mRNAs, represent a combination of primary transcripts and processed RNAs. However, examination of the sequences containing the RNA endpoint positions revealed that effectively the only highly conserved regulatory element is the rho-independent terminator that generates the common 3' end. Promoters and processing sites have not been maintained in identical positions, but frequently are placed so as to yield RNAs with similar coding function. By conserving the pattern of transcription and processing despite divergence in the regulatory elements and possibly the requirements for host, endoribonucleases, the results argue that the pattern is not simply fortuitous.

Functional analysis of filamentous phage f1 mRNA processing sites.

The abundant mRNAs used as templates for synthesis of filamentous phage f1 proteins are a combination of primary transcripts and 3' products of processing. The processing steps are mediated by host endoribonucleases. One of the enzymes implicated in f1 mRNA processing is RNase E, the only endonuclease thus far shown to have a global role in mRNA decay. By establishing the temperature-sensitive phenotypes of RNase E mutants and then inducing a transcription unit bearing cloned f1 processing sites, we show that RNase E is required for production of at least three of the processed RNAs. Using in vivo processing assays, we also test directly the regions implicated genetically in previous work to contain the processing sites. The sites function as discrete domains in a number of transcription units, show little influence of translation, but appear to have increased activity at the 5' terminus of an mRNA. From their functional properties, we suggest that the known processing sites from phage f1 that are dependent on RNase E may be representative of relatively late steps in rne-dependent cleavage pathways.

Binding of biotinylated DNA to streptavidin-coated polystyrene latex: effects of chain length and particle size.

The binding of 5'-end biotinylated DNA, ranging in size from 100 to 5000 base pairs, was studied using streptavidin-coated polystyrene latex particles with diameters between 0.944 and 0.090 micron. The experimental binding constants and forward rate constants of this solid-phase reaction were determined to be several orders of magnitude lower than values for the biotin-streptavidin interaction in solution as expected and were shown to depend on the size of both ligand and substrate. An observed inflection in the binding constant of the biotinylated DNA appeared around 1000 base pairs, possibly indicating different surface orientations of the macroligand above and below this critical size. This effect was more pronounced for the smaller latex particles used in this study and highlighted possible differences in the surface arrangement of streptavidin on the differently sized particles. Diffusion limitation to the binding reaction was found to be significant in all cases. In this present work, an exponential relationship was established between the experimental binding constant and the number of base pairs in the biotinylated DNA. This relationship possibly provides a means to predict capacity and binding speed in cases where adsorption, purification, and release of larger DNA chains are required.