STUDIES ON THE MICROTUBULES IN HELIOZOA: II. The Effect of Low Temperature on These Structures in the Formation and Maintenance of the Axopodia

doi:10.1083/jcb.34.1.327

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ARTICLE

STUDIES ON THE MICROTUBULES IN HELIOZOA

: II. The Effect of Low Temperature on These Structures in the Formation and Maintenance of the Axopodia

Lewis G. Tilney ¹ and Keith R. Porter ¹

¹ From the Biological Laboratories, Harvard University, Cambridge, Massachusetts 02138

When specimens of Actinosphaerium nucleofilum are placed at4°C, the axopodia retract and the birefringent core (axoneme)of each axopodium disappears. In fixed specimens, it has beenshown that this structure consists of a highly patterned bundleof microtubules, each 220 A in diameter; during cold treatmentthese microtubules disappear and do not reform until the organismsare removed to room temperature. Within a few minutes afterreturning the specimens to room temperature, the axonemes reappearand the axopodia begin to reform reaching normal length 30–45min later. In thin sections of cells fixed during the earlystages of this recovery period, microtubules, organized in thepattern of the untreated specimens, are found in each reformingaxopodium. Reforming axopodia without birefringent axonemes(and thus without microtubules) are never encountered. Fromthese observations we conclude that the microtubules may beinstrumental not only in the maintenance of the axopodia butalso in their growth. Thus, if the microtubules are destroyed,the axopodia should retract and not reform until these tubularunits are reassembled. During the cold treatment short segmentsof a 340-A tubule appeared; when the organisms were removedfrom the cold, these tubular segments disappeared. It seemsprobable that they are one of the disintegration products ofthe microtubules. A model is presented of our interpretationof how a 220-A microtubule transforms into a 340-A tubule andwhat this means in terms of the substructure of the untreatedmicrotubules.

Submitted on January 20, 1967

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