Abstract
Abstract A displacement synthesis procedure was used to construct symmetrical recombinant cDNAs. A double-stranded cDNA containing a hairpin loop was extended by the addition of a homopolymer to the 3′ end. This was followed by displacement, or “third strand” synthesis that was primed by an oligonucleotide hybridized to the homopolymer. Ideally, the product should be a DNA containing an inverted repeat with twofold rotational symmetry about nonsymmetrical sequences representing the hairpin loop in the original double-stranded cDNA. Duck globin cDNAs were synthesized by the displacement mode of construction and cloned in pBR322. An α-globin recombinant, pDGPα-2, was isolated and sequenced. This recombinant was found to have two 3′ half regions (mRNA sequence sense) inverted about a nonsymmetrical 5′ half region and an adjacent oligo(dGṡdC) homopolymer. The sequence arrangement indicates that the cDNA folded back on itself, forming a large loop, to prime synthesis of a second strand. We propose that the internal oligo(dGṡ dC) arose through dynamic shifts in cDNA intrastrand structure during the course of synthesis.
Published Version
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