Marilyn L. Cayer

Structural features associated with movement and 'catch' of sea-urchin spines.

Spine catch ligaments of a sea urchin Arbacia punctulata were extended under constant load. Ligaments from an undisturbed animal may show any extension rate from zero (catch state) to rapid extension to failure. Replacing the preparation bath with CA(2)- and Mg(2+)-free sea water reversibly abolishes the catch state. The fine structure of the outermuscle layer and inner ligament cone associated with the spine base is described. The unstriated paramyosin muscles bear thin flanges and form compact interlocking rows. Subsurface cisternae are associated with the plasma membrane. The muscles are innervated by glia-free axons ending in bulbous terminals containing lucent synaptic vesicles. The ligament comprises cylindrical bundles of collagen fibrils: one or more minute muscle fibers (paramyosin) lie parallel with and closely adjoining each bundle. The mean diameter of these muscles is 0.3 micrometers and they occupy 2-3% of the ligaments cross-sectional area. Axons containing electron-opaque secretory droplets accompany the muscles between the collagen bundles: the cell bodies of these neurones generally lie on the outer surface of the ligament. When an urchin points a spine, the ligament on the side of the contracting spine muscle shortens but does not buckle. A function of the intraligamental muscles is to effect this non-buckled shortening. The catch mechanism (which reside entirely within the ligament) may be due either to the intraligamental muscles and/or to a locked polymer mechanism in which matrix molecules between collagen fibrils are reversibly cross-linked by divalent cations.

Actin-myosin interaction. Self-assembly into a bipolar “contractile unit”

The interaction of polymerizing actin with myosin filaments results in the formation of a complex wherein one myosin filament is complexed to six actin filaments. The closely associated actin filaments are parallel to the long axis of the myosin filament, and in cross-section are in an hexagonal array around the myosin filament. This structured complex (“contractile unit”) is bipolar in organization, demonstrable by decoration of the associated actin with heavy meromyosin. The herringbone pattern at each end of the complex points toward the center of the complex, similar to the in vivo situation in the sarcomere of striated muscle. Formation of the complex probably involves a unidirectional polymerization of the actin, and strongly suggests a “polarity specificity” of the actin-myosin interaction.

Observations on freeze-fractured membranes of a trypanosome.

Abstract Pure preparations of Trypanosoma brucei , free from plasma and cellular components were isolated from rat blood, and concentrated into loose pellets by low-speed centrifugation. Pellets were either processed for thin sectioning as a control for general morphology, or glycerol-treated after glutaraldehyde fixation for preparation of freeze-fracture replicas. Concentration of cells of 50,000–100,000/mm 2 of sectioned or fractured surface facilitated identification of fracture faces of the cell body, invaginated flagellar pocket and flagellum. Particle distribution and A and B faces of these regions of the cell are described. A collar of B face particles occurs around the neck of the flagellar pocket, possibly associated with a junction controlling ingress of ingested materials to coated vesicles formed along the membrane defining the pocket. A and B faces of the flagellum and adjoining surface of the cell body have shown that the only intra-membrane specialization corresponding to the miniature ‘maculae adherentes’ described previously in thin sections is probably an uninterrupted series of small clusters (3–6) of 80 A particles on the A face of the flagellar membrane. It is proposed that these arrays represent attachment points for strands linking the axoneme and paraxial rod to the flagellar surface, and are not directly concerned with the physical adhesion of the flagellum to the cell body surface—a linkage that appears to be established within the extracellular gap between these apposed surfaces of the cell. The potential use of freeze-etching in further study of the external antigens of the infective cell is discussed.

MECHANISM OF THE EXCITATION-CONTRACTION UNCOUPLING OF FROG SKELETAL MUSCLE BY FORMAMIDE

The contractility of guinea pig ileum and frog skeletal muscle is inhibited in solutions containing 0.4 to 2.5 M formamide (FMD). Contrary to mammalian vis ceral muscle, this blocking action is not reversed when frog muscles are transferred back to isotonic Ringers after FMD treatment. Under these conditions the water content of the skeletal muscles is markedly increased and electronmicrographs show a swellingof the transverse tubules. These changes are not observed when frog muscles are transferred to ethylene glycol solutions that are isosmotic with the FMD containing Ringers solution. In addition, over 50% of the contractility is recovered in these muscles. These observations provide direct evidence of the occurrence of an osmotic shock in frog muscles transferred from FMD solutions to isotonic Ringers. It is concluded that the resulting alterations in the triad structure and function are re sponsible for the irreversibility of the FMD uncoupling action in these muscles.

Organization of native and in vitro-reassembled myosin filaments from lobster tonic muscle

Tonic muscle of the crusher claw of the American lobster (Homarus americanus) was investigated with respect to sarcomeric organization and the capacity for self-assembly of extracted myosin for comparison with the same properties of rabbit muscle. Native myosin filaments in the lobster muscle are much longer than in rabbit skeletal fibers, and differ further in sarcomeric organization in showing an actin-to-myosin relationship in which two actin filaments are shared between adjacent myosins in a 12-membered orbital. The self-assembly of lobster myosin into filaments comparable in length and the fine structure to the natural filament was achieved in the presence of excess Mg2+, a condition not required for rabbit myosin self-assembly. Results of in situ and self-assembly studies indicate a difference in molecular organization between lobster and rabbit myosin filaments and of the inferred presence of regulatory factors in the formation of these ultrastructural elements. These studies represent the groundwork for an investigation of in vitro polymerization of actin in association with the synthetic lobster myosin filament.

Immunochemical studies of infectious mononucleosis—X. Characterization of a glycoprotein from horse erythrocytes which reacts with Paul-Bunnell antibody☆

A highly purified preparation of horse erythrocyte glycoprotein was prepared from an aqueous ethanolic extract of hemoglobin-free membranes. The subunit apparent mol. wt was 30,000. In aqueous solution the glycoprotein formed globular aggregates of 93 +/- 16 A diameter. The glycoprotein had a receptor for the Paul-Bunnell antibody of infectious mononucleosis which was associated with an O-glycosidically linked oligosaccharide and dependent on the presence of N-glycolylneuraminic acid. In addition the glycoprotein had a neuraminidase-sensitive receptor for human peripheral blood lymphocytes. Fifty per cent inhibition of the rosetting of sheep red cells by 4 x 10(5) lymphocytes was caused by 30 microgram of glycoprotein.