The sliding microtubule model of ciliary motility predicts that cumulative local displacement (Δl) of doublet microtubules relative to one another occurs only in bent regions of the axoneme. We have now tested this prediction by using the radial spokes which join the A subfiber of each doublet to the central sheath as markers of microtubule alignment to measure sliding displacements directly. Gill cilia from the mussel Elliptio complanatus have radial spokes lying in groups of three which repeat at 860 Å along the A subfiber. The spokes are aligned with the two rows of projections along each of the central microtubules that form the central sheath. The projections repeat at 143 Å and form a vernier with the radial spokes in the precise ratio of 6 projection repeats to 1 spoke group repeat. In straight regions of the axoneme, either proximal or distal to a bend, the relative position of spoke groups between any two doublets remains constant for the length of that region. However, in bent regions, the position of spoke groups changes systematically so that Δl (doublet 1 vs. 5) can be seen to accumulate at a maximum of 122 Å per successive 860-Å spoke repeat. Local contraction of microtubules is absent. In straight regions of the axoneme, the radial spokes lie in either of two basic configurations: (a) the parallel configuration where spokes 1–3 of each group are normal (90°) to subfiber A, and (b) the tilted spoke 3 configuration where spoke 3 forms an angle (θ) of 9–20°. Since considerable sliding of doublets relative to the central sheath (∼650 Å) has usually occurred in these regions, the spokes must be considered, functionally, as detached from the sheath projections. In bent regions of the axoneme, two additional spoke configurations occur where all three spokes of each group are tilted to a maximum of ± 33° from normal. Since the spoke angles do not lie on radii through the center of bend curvature, and Δl accumulates in the bend, the spokes must be considered as attached to the sheath when bending occurs. The observed radial spoke configurations strongly imply that there is a precise cycle of spoke detachment-reattachment to the central sheath which we conclude forms the main part of the mechanism converting active interdoublet sliding into local bending.
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1 October 1974
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October 01 1974
THE STRUCTURAL BASIS OF CILIARY BEND FORMATION : Radial Spoke Positional Changes Accompanying Microtubule Sliding
Fred D. Warner,
Fred D. Warner
From the Department of Biology, Biological Research Laboratories, Syracuse University, Syracuse, New York 13210, and the Department of Physiology-Anatomy, University of California, Berkeley, California 94720
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Peter Satir
Peter Satir
From the Department of Biology, Biological Research Laboratories, Syracuse University, Syracuse, New York 13210, and the Department of Physiology-Anatomy, University of California, Berkeley, California 94720
Search for other works by this author on:
Fred D. Warner
From the Department of Biology, Biological Research Laboratories, Syracuse University, Syracuse, New York 13210, and the Department of Physiology-Anatomy, University of California, Berkeley, California 94720
Peter Satir
From the Department of Biology, Biological Research Laboratories, Syracuse University, Syracuse, New York 13210, and the Department of Physiology-Anatomy, University of California, Berkeley, California 94720
Received:
December 14 1973
Revision Received:
May 22 1974
Online ISSN: 1540-8140
Print ISSN: 0021-9525
Copyright © 1974 by The Rockefeller University Press
1974
J Cell Biol (1974) 63 (1): 35–63.
Article history
Received:
December 14 1973
Revision Received:
May 22 1974
Citation
Fred D. Warner, Peter Satir; THE STRUCTURAL BASIS OF CILIARY BEND FORMATION : Radial Spoke Positional Changes Accompanying Microtubule Sliding . J Cell Biol 1 October 1974; 63 (1): 35–63. doi: https://doi.org/10.1083/jcb.63.1.35
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