Cytoskeletal Organization of Limulus Amebocytes Pre- and Post-Activation: Comparative Aspects

One of the major functions of circulating Limulus amebocytes is to effect blood coagulation upon receipt of appropriate signals. However, the hypothesis that Limulus amebocytes are fundamentally similar to vertebrate thrombocytes and platelets has not been tested sufficiently in previous studies of...

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Bibliographic Details
Published in:The Biological bulletin (Lancaster) 2004-08, Vol.207 (1), p.56-66
Main Authors: Conrad, Mara, Denobile, Joanna, Chaikhoutdinov, Irina, Escribano, Douglas, Lee, Kyeng-Gea, Cohen, William D.
Format: Article
Language:English
Subjects:
Actins
Actins - physiology
Animals
Biology
Blood cells
Blood Cells - cytology
Blood Cells - physiology
Blood Cells - ultrastructure
Blood clots
Blood Coagulation - physiology
Brackish
Cell Biology
Cell nucleus
Cell Size - physiology
Cells
Clotting
Comparative studies
Cytoskeleton
Erythrocytes
Fluorescence
Fluorescent Antibody Technique
Fluorescent Dyes
Horseshoe crabs
Horseshoe Crabs - cytology
Horseshoe Crabs - physiology
Invertebrates
Limulus
Marine
Membrane Glycoproteins
Microscopy, Electron
Microtubules
Microtubules - physiology
Physiological aspects
Platelets
Vertebrates
Xanthenes
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Summary:One of the major functions of circulating Limulus amebocytes is to effect blood coagulation upon receipt of appropriate signals. However, the hypothesis that Limulus amebocytes are fundamentally similar to vertebrate thrombocytes and platelets has not been tested sufficiently in previous studies of their cytoskeletal organization. Whereas the earlier data were derived from transmission electron microscopy (TEM) of thin sections of a limited number of cells, improved fluorescence labeling methods that retain cell morphology have now enabled us to survey F-actin and microtubule organization in intact individual amebocytes and in large amebocyte populations pre- and post-activation. Anti-tubulin immunofluorescence showed the marginal band (MB) of microtubules to be ellipsoidal in most unactivated cells, with essentially no other microtubules present. However, minor subpopulations of cells with discoidal or pointed shape, containing corresponding arrangements of microtubules suggestive of morphogenetic intermediates, were also observed. Texas-red phalloidin labeled an F-actin-rich cortex in unactivated amebocytes, accounting for MB and granule separation from the plasma membrane as visualized in TEM thin sections, and supporting earlier models for MB maintenance of flattened amebocyte morphology by pressure against a cortical layer. Shape transformation after activation by bacterial lipopolysaccharide was attributable principally to spiky and spreading F-actin in outer cell regions, with the MB changing to twisted, nuclei-associated forms and eventually becoming unrecognizable. These major pre- and post-activation cytoskeletal features resemble those of platelets and non-mammalian vertebrate thrombocytes, supporting recognition of the Limulus amebocyte as a representative evolutionary precursor of more specialized clotting cell types.
ISSN:0006-3185
1939-8697
DOI:10.2307/1543628