Rapid identification of genomic interferon genes by sequencing on phage λ DNA templates

A family of U1 pseudogenes in Bombyx mori may be derived from an ancestral pseudogene

Seven EMBL-4 lambda clones containing U1 small nuclear RNA sequences were isolated from a Bombyx mori genomic library. Six of the seven represent unique sequences. The six unique U1 sequences exhibit fixed point 3'-end truncation. Five out of the six clones share immediate 3'-end flanking sequences while two share 5'-end flanking sequences. Fixed point 3'-end truncation and a hierarchy of shared to unique diagnostic mutations may suggest a family of U1 pseudogenes generated from a reverse-transcribed class II pseudogene in B. mori. An ancestral 'master' U1 pseudogene capable of RNA- and/or DNA-mediated transposition may give rise to generations of U1 pseudogenes that include the original pseudogene's flanking sequences. Identical 3'-end truncation in some of these U1 sequences can be explained by RNA self-priming due to intra-strand binding prior to reverse transcription.

Direct sequencing of bacteriophage T4 DNA with a thermostable DNA polymerase

We present a simple and convenient protocol for the direct sequencing of bacteriophage T4 genomic DNA. The method utilizes the thermostable DNA polymerase from Thermus aquaticus (Taq) and 32P-end-labeled oligodeoxyribonucleotide primers to produce extension products that allow the analysis of at least 200 nucleotides (nt) on a single sequencing gel. Single-nt changes in the template were easily detectable following an overnight exposure of the autoradiograms. Comparison of sequences from fully modified T4 DNA containing glucosylated hydroxymethyldeoxycytosine or from templates containing cytosine showed little difference in sequence clarity. These techniques considerably simplify the molecular analysis of T-even bacteriophages and should be compatible with automated sequencing methods which employ 5'-end-labeled primers.

Rapid identification of clones using the same degenerate oligonucleotide mixture for both screening and sequencing

A simple and rapid strategy for distinguishing between positively hybridizing colonies and false positive-hybridization signals is described. The isolation of a specific DNA sequence depends on the ability to distinguish between a clone that contains the correct sequence and a false hybridization-positive or background signal. This procedure utilizes the same oligonucleotide mixture both as a screening probe and as a sequencing primer. The mixture of oligonucleotides is used as a primer to obtain sequence information directly from double-stranded DNA. Conditions for sequencing with oligonucleotides having up to 64-fold degeneracy are described. Since the sequence information obtained is directly adjacent to the site of oligonucleotide:DNA hybridization, it is necessary to know only a minimal length of DNA or peptide sequence to both design oligonucleotide probes and confirm the authenticity of the hybridization positives. The advantages of the degenerate oligonucleotide sequencing method include the rapid, reliable identification of authentic versus false hybridization positives made directly without subcloning into single-stranded M13 phage, without sequencing large regions of DNA, or without synthesizing sequence-specific primers.