Ref ID : 3355
Klaus Eisler; Electron Microscopical Obsevations on the Ciliate Furgasonia blochmanni Faure-Fremiet, 1967 Part II: Morphogenesis and Phylogenetic Conclusions. Europ.J.Protistol. 24(2):181-199, 1989
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The ultrastructural events during cortical morphogenesis of Furgasonia blochmanni are studied by TEM. The kinetosomal proliferation in the somatic cortex at the beginning of morphogenesis produces kinetosomal triads. All kinetosomes of these triads have the same fibrillar system as somatic monokinetids. Such somatic triads are also involved in the formation of the adoral membranelles of the opisthe. In the mature adoral membranelles the postciliary microtubules of the anterior and the middle kinetosomes of these triads as well as all kinetodesmal fibers are replaced by desmoses. Only the opisthe gets new adoral membranelles, since the parental adoral membranelles persist in the proter; however, the new paroal membrane of both the proter and the opisthe are newly formed as derivatives of the old paroral membrane. At the beginning at stomatogenesis the old paroral membrane divides into 2 parts of unequal length. The anterior part, which stays in the proter, splits longitudinally forming a new kinety 1' and the anlage of the new paroral membrane. In the adult cells the anterior kinetosomes of the paroral dyads (the right kinetosomes of the paroral membrane) are already orientated like somatic kinetosomes. Therefore, no rotation is necessary when these kinetosomes become part of the somatic monokinetids of kinety 1'. The posterior kinetosomes of the dyads of the anterior part of the paroral membrane (the anlage of a new paroral membrane of the proter) remain orientated perpendicularly to the longitudinal axis of the cell, an orientation which is necessary when these kinetosomes send postciliary microtubules towards for the forming cytopharyngeal basket. All kinetosomes of the posterior part of the former paroral membrane also become orientated such that triplet 9 points to the left towards the presumptive oral opening of the opisthe. During stomatogenesis both kinetosomes of the new paroral membranes are rotated by 90 degrees compared to the longitudinal axis of the cell and send postciliary microtubules towards the forming cytopharynx. In contrast to the adult cell, during stomatogenesis only the posterior kinetosomes of the paroral dyads are ciliated while the newly formed anterior kinetosomes are barren. At the end of stomatogenesis the cilia of the posterior kinetosomes are resorbed and new cilia grow at the anterior kinetosomes. During stomatogenesis all kinetosomes of the anlagen of the new paroral membranes possess postciliary microtubules, kinetodesmal fibers and in some cases transverse microtubules as well. Following stomatogenesis, the kinetodesmal fibers and transverse microtubules are resorbed, and the orientation of the anterior kinetosomes reverts from perpendicular to parallel to the paroral membrane axis. These data from F. blochmanni are compared with the ultrastructural data on morphogenesis from Paraurostyla, Tetrahymena and Coleps. Finally the phylongenetically significant characters obtained from studies on morphology and morphogenesis in F. blochmanni and other nassulid ciliates are discussed, and a "scheme of argumentation of phylogenetic systematics" is presented for the nassulids. It is concluded that F. blochmanni is correctly classified within the nassulid suborder Nassulina and that the Nassulida including F. blochmanni certainly are a monophyletic group within the subphylum Cyrtophora Small, 1976.