TRANSFORMATION OF NONPOLAR FILAMENTS OF THE BLUE‐GREEN ALGA GLOEOTRICHIA ECHINULATA U. WISC. 1052 INTO DOUBLE HELICES 1 2

SUMMARY Normally straight filaments of Gloeotrichia echinulata U. Wisc. 1052 transform into double helices when a critical culture density has been attained. In inorganic Zehnder‐Gorham's medium No. 11, the alga initially is morphologically uniform and forms single, lightly curved, polar filaments. When a stage of close proximity of the filaments is reached, excessively long filaments are observed that are nonpolar. Some of these nonpolar filaments form helices. Two independent single helices may entwine to form a double helix. Double helices also form when both ends of an excessively long filament meet and start entwining until a loop is left at about the original middle of the filament. In another manner of double‐helix formation, a straight filament makes a hairpin bend at about its middle; then 2 helices form starting at the bend and they entwine into a double helix, leaving a loop at the location of the original bend. Under proper culture conditions, the structures of double helices show an amazing regularity. Once double‐helix formation has started, some strong force brings the process to completion. In a mature culture, helices disintegrate into apparently healthy, short pieces of filaments or single cells, while the straight or slightly curved polar filaments still persist. Helical transformation of nonpolar filaments does not appear to be a sign of nutritional or other stress but rather appears to serve a specific purpose. One might speculate that a genetic exchange between opposite cells takes place.