Foldback DNA is defined by its rapid, concentration-independent renaturation, consistent with intramolecular base pairing of inverted repeat sequences. Foldback DNA, isolated from renatured mouse main band DNA by hydroxyapatite chromatography, is spread for electron microscopy by the formamide isodenaturing technique. A large fraction of the molecules can be recognized as intramolecular "hairpins"--structures in which complementary sequences on a single DNA strand form base-paired "stem" regions analogous to tRNA stems. The stem regions of the hairpins have a wide distribution of lengths, averaging about 1000 base pairs. About 60% of the stem regions terminate in single-stranded loops, ranging from 400 to many thousands of nucleotides in length, while 40% of the hairpins do not have discernible loops. There are about 40,000 hairpin-forming sequences in the main band portion of the mouse haploid genome. They appear to be either clustered in groups or confined to about one third of the DNA, rather than uniformly or randomly distributed. Another large fraction of the molecules seen in foldback DNA consists of linear structures, some of which are probably also hairpins. The electron microscopic results, along with simple theoretical considerations, make possible a better interpretation of our previous studies of the yield and S1 nuclease resistance of mouse foldback DNA.