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Ultrastructure and motion analysis of permeabilized paramecium capable of motility and regulation of motility (1988)

Lieberman, Steven J. ; Hamasaki, Toshikazu ; Satir, Peter

New York, NY : Wiley-Blackwell

Cell Motility and the Cytoskeleton 9 (1988), S. 73-84

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ISSN: 0886-1544

Keywords: cilia ; metachronal waves ; electron microscopy ; calcium ; Life and Medical Sciences ; Cell & Developmental Biology

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Biology , Medicine

Notes: Structural and behavioral features of intact and permeabilized Paramecium tetraurelia have been defined as a basis for study of Ca2+ control of ciliary reversal. Motion analysis of living paramecia shows that all the cells in a population swim forward with gently curving spirals at speeds averaging 369 ± 19 μm/second. Ciliary reversal occurs in 10% of the cell population per second. Living paramecia, quick-fixed for scanning electron microscopy (SEM), show metachronal waves and an effective stroke obliquely toward the posterior end of the cell. Upon treatment with Triton X-100, swimming ceases and both scanning and transmission electron microscopy reveal cilia that uniformly project perpendicularly from the cell surface. Thin sections of these cells indicate that the ciliary, cell, and outer alveolar membranes are greatly disrupted or entirely missing and that the cytoplasm is also disrupted. These permeabilized paramecia can be reactivated and are capable of motility and regulation of motility. Motion analysis of cells reactivated with Mg2+ and ATP in low Ca2+ buffer (pCa7) shows that 71% swim forward in straight or curved paths at speeds averaging 221 ± 20 μm/second. When these cells are quick-fixed for SEM the metachronal wave patterns of living, forward swimming cells reappear. Motion analysis of permeabilized cells reactivated in high Ca2+ buffers (pCa 5.5) shows that 94% swim backward in tight spirals at a velocity averaging 156 ± 7 μm/second. SEM reveals a metachronal wave pattern with an effective stroke toward the anterior region. Although the permeabilized cells do not reverse spontaneously, the pCa response is preserved and the Ca2+ switch remains intact. The ciliary axonemes are largely exposed to the external environment. Therefore, the behavioral responses of these permeabilized cells depend on interaction of Ca2+ with molecules that remain bound to the axonemes throughout the extraction and reactivation procedures.

Additional Material: 6 Ill.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/cm.970090108

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Splitting the ciliary axoneme: Implications for a “Switch-Point” model of dynein arm activity in ciliary motion (1989)

Satir, Peter ; Matsuoka, Tatsuomi

New York, NY : Wiley-Blackwell

Cell Motility and the Cytoskeleton 14 (1989), S. 345-358

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ISSN: 0886-1544

Keywords: cell motility ; microtubules ; mussel gill ; ATPase ; electron microscopy ; Life and Medical Sciences ; Cell & Developmental Biology

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Biology , Medicine

Notes: In the presence of specific inhibitors of beat, 20 μM VO43- or pCa 4, mussel gill lateral (L) cilia can be arrested in two positions - “hands down” or “hands up” - at opposite ends of the stroke cycle. Cilia move to these positions by doublet microtubule sliding. Axonemes of arrested cilia, still tethered to the cell, are intact after demembranation and protease treatment. When reactivated by 4 mM ATP with inhibitors present, about 40% split apart. Splits are not random but occur preferentially between different specific doublets in the two opposite arrest positions. Several different related patterns of splitting are observed; for every pattern in “hands down” axonemes, there is a corresponding complementary split pattern in “hands up” axonemes. In some split patterns two doublets remain firmly attached to the central pair; these also differ depending on axonemal position. Although some of the patterns seen may be artifactual or difficult to explain, the complementary splitting patterns are predictable with simple assumptions by a “switch point” hypothesis of ciliary activity where, during each recovery stroke, doublets 6-8 have active dynein arms, while during each effective stroke, arms on doublets 1-4 become active, and arms 6-8 are turned off. Because of a difference between the patterns seen and the predictions, the status of the arms on doublet 9 is unresolved. The patterns also suggest that a spokecentral sheath attachment cycle may correlate with switching of arm activity during the generation of an asymmetric beat.

Additional Material: 8 Ill.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/cm.970140305

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