DNA from two blue-green algae was isolated and characterized. The buoyant densities, thermal denaturation and re-naturation, thermal melting values, base compositions, sedi-mentation coefficients, and molecular weights were determined. Blue-green algal DNA renatured extensively and at a comparable rate to that of bacterial DNA. The similarities among the kinds of DNA from bacteria and blue-green algae were interpreted to reflect a close relationship. A popular hypothesis to explain the origin of chloroplasts is that they arose as the result of symbiosis between blue-green algae and eucaryotic cells. Indeed, Ris and Plaut (28) pointed out that the morphological appearance of DNA in blue-green algae cells seemed remarkably similar to the DNA observed in chloroplasts. Many other articles have appeared which support the endosymbiotic hypothesis (4, 9, 12, 23, 29, 34). Further evidence in support of the hypothesis would be information showing a considerable degree of relatedness in the physi-cochemical properties of blue-green algal DNA compared to the DNA of the chloroplast. Whereas extensive knowledge is available on the physicochemical properties of a variety of chloroplastic DNA (17, 19, 35, 38), information on blue-green algal DNA is very limited (2, 10, 14, 20). Thus, the purpose of this communication is to examine in detail the properties of DNA from two species of blue-green algae, so that more meaningful comparisons of these kinds of DNA could be made with chloroplastic DNA. As a further measure of the significance to be attached to relatedness in physicochemical properties, the blue-green algal and chloroplastic DNA were also compared to bacterial DNA. MATERIALS AND METHODS Axenic cultures of Anacystis niditlans (625 high temperature strain) and Lyngbya sp. (Indiana University Culture Collection No. 487) were grown at 25-30 C in 1-1 Erlenmeyer flasks containing 400 ml of liquid media (1) with constant supply of air. The cells were harvested by filtration and checked for absence of bacterial contamination before extracting DNA. The cells were homogenized and treated with lysozyme (6). DNA was extracted by the procedure of Marmur (24) using only one ethanol precipitation. At this stage the DNA was I Present address: treated with /8-amylase according to Ritossa and Spiegelman (30) and further purified with chloroform. DNA (15-20 ,ug/ml) in 0.15 M NaCl, 15 mM SSC2 was thermally denatured and renatured according to Marmur and Doty (25). Spontaneous or "snap back" renaturation was carried out by the procedure described by Dawid and Wolsten-holme (7). CsCl density gradient centrifugation was done according to Schildkraut et al. (32) in the Spinco Model E analytical ultra-centrifuge. Micrococcus lysodeikticus (p = 1.731 g/cm3) and E. coli (p = 1.710 g/cm') DNA species were used as markers. Alkaline CsCl was prepared by the method of Flamm et al. (11) by adding 100 jul 1 N NaOH to 3.3 ml of solution containing 10 to 30 ,ig of DNA in 10 mm tris-HCl buffer, pH 8.5. CsCl was then added to establish a proper initial den...
