Isolation of repeated and self-complementary sequences from E. coli DNA

Characterization of inverted repeated sequences in wheat nuclear DNA

The properties of inverted repeated sequences in wheat nuclear DNA have been studied by HAP(1) chromatography, nuclease S1 digestion and electron microscopy. Inverted repeated sequences comprise 1.7% of wheat genome. The HAP studies show that the amount of "foldback HAP bound DNA" depends on DNA length. Inverted repeats appear to be clustered with an average intercluster distance of 25 kb. It is estimated that there are approximately 3 x 10(6) inverted repeats per haploid wheat genome. The sequences around inverted repeats involve all families of repetition frequencies. Inverted repeats are observed as hairpins in electron microscopy. 20% of hairpins are terminated by a single-stranded spacer ranging from 0.3 to 1.5 kb in length. Duplex regions of the inverted repeats range from 0.1 to 0.45 kb with number average values of 0.24 kb and 0.18 kb for unlooped and looped hairpin respectively. Thermal denaturations and nuclease S1 digestions have revealed a length of about 100 bases for duplex regions. The methods used to study inverted repeated sequences are compared and discussed.

One strand equivalent of the Escherichia coli genome is transcribed: complexity and abundance classes of mRNA

DNA-RNA hybridization experiments show that essentially all of the genomic information is transcribed. High, intermediate, and rare abundance classes of messenger RNA (mRNA) are present, and their estimated complexities are equal to about 240, 1300, and 700 average-sized mRNA species, respectively. The high abundance mRNA species are present, an average, two to three copies per cell and constitute about 95 percent of the mRNA mass. Intermediate abundance mRNA species are present, on average, about once per 35 cells. The relative abundance and complexity of these mRNA classes correspond well with previous respective measurements on protein. Rare RNA species are thought to represent maximally repressed genes. Analysis of RNA synthesized in vitro by isolated nucleoids (chromosomes) suggests that sense and nonsense sequences are extensively interspersed on a given strand of the DNA.