The structural elements responsible for contraction in the ciliateSpirostomum

Summary The surface of the contractile ciliateSpirostomum contains continuous spiral ciliated grooves traversing its length. Bundles of microtubules run parallel to the base of the grooves and appear to be part of a cohesive, semi-rigid cortex. Beneath this, a network of microfilament bundles occurs which is attached to the peristomal membranelle apparatus, also part of the cortex. The possible roles played by these structures during contraction of the organism were examined.During contraction, the entire cortex twists and the spiral arrangement of the grooves and microtubules decreases in pitch and increases in diameter. Simultaneously, the bundles of microfilaments change in distribution and appearance so as to suggest that they are undergoing an active shortening process. Based on these observations, two models for contraction are presented. In one, shortening of the animal arises from a smooth muscle-like contraction of the microfilament network whose attachment to the basal bodies of the membranellar cilia guarantees shortening and widening of the cortex and consequently the whole animal. In the second, a shortening (or sliding) of external microtubules relative to internal ones in the cortical microtubule bundles would result in an increase in diameter, a decrease in pitch, and a decrease in axial length of the bundles, resulting in contraction of the animal. The observations do not allow a choice between these alternatives to be made, and they may not, in fact, be mutually exclusive.     

Sea urchin egg cortical granule exocytosis is followed by a burst of membrane retrieval via uptake into coated vesicles

Using improved fixation procedures we have found that extensive endocytotic activity is turned on at fertilization in eggs of three species of sea urchins. Beginning after completion of cortical granule exocytosis and after exocytotic pits have completely smoothed over, the entire activated egg surface engages in a limited period of extensive removal of membrane via uptake into coated vesicles. This “burst phase” lasts about 3–5 min after which the number of invaginating coated vesicles decreases rapidly. At the end of this burst phase all the patches of cortical granule membranes have disappeared, and the egg surface is left uniformly covered by microvilli. For the remainder of the first cell cycle coated pits continue to form at a slower but steady rate. Endocytotic activity continues past the time of first cleavage. There is distinct overlap in onset and duration of the burst phase of endocytosis with the period of medium acidification during normal development. However, activation of eggs in choline sea water, which inhibits acid secretion, results in an endocytic burst whose timing and duration are similar to those in normal eggs. The endocytic burst is, therefore, independent of cytoplasmic alkalinization. These results suggest, in accord with the two-step model of egg activation (D. Epel, R. A. Steinhardt, and R. A. Humphreys, 1974; Dev. Biol.40, 245–255; D. Epel, 1978, Curr. Top. Dev. Biol.12, 185–246) that initiation of endocytosis is most likely a Ca²⁺-dependent event.     

Polymorphonuclear leukocyte migration through human amnion membrane

A new in vitro model has been developed for studying migration of human polymorphonuclear leukocytes (PMN) through living native cellular and matrix barriers. Human amnion membrane consists of a single layer of epithelium bound to a continuous basement membrane interfacing an avascular collagenous stroma. Living amnion was placed in plastic chambers with separate compartments on each side of the membrane. PMN were introduced on the epithelial side of the amnion, and a Millipore filter (Millipore Corp., Bedford, Mass.) was placed against the stromal side. In response to N-formylmethionyl-leucyl- phenylanlanine (FMLP) chemoattractant, PMN penetrated the full thickness of the amnion and were collected and counted on the filter. The rate of PMN traversal of the amnion was dependent on the concentration of FMLP (optimal at 10(-8)M) as well as the slope of the FMLP gradient across the amnion. The route of PMN migration was studied by transmission electron microscopy. PMN first attached to the epithelial surface, then infiltrated between intercellular junctions. PMN migrated around or through tight junction and hemidesmosome attachments. The PMN then penetrated the basement membrane and migrated through the dense collagenous stroma. The present amnion migration system has characteristics of the in vivo inflammatory state not described in any previous method for monitoring PMN migration in vitro. Prior methods have not used native epithelium, whole basement membrane, or collagenous stroma. PMN penetration of these barriers occurs in the normal inflammatory response and probably involves biochemical mechanisms not required for simple migration through the pores of an artificial filter. The amnion system can be useful for future biochemical and morphological studies of PMN penetration of these barriers and possible repair processes that may follow.     

Concanavalin A-stimulated Ca2+ uptake in rat splenocytes

Summary Commercially available concanavalin A binds Ca²⁺ with high apparent affinity. In order to dissociate concanavalin A stimulated Ca²⁺ uptake (defined as an increased association of ⁴⁵Ca²⁺ with cells) in rat splenocytes and Ca²⁺ binding to cell-bound concanavalin A, conditions were developed to remove more than 75% of the bound concanavalin A. Under these conditions concanavalin A treated cells showed a considerable increase in ⁴⁵Ca²⁺ uptake over control. The concanavalin A stimulated uptake of ⁴⁵Ca²⁺ occurred within minutes, and required concentrations of concanavalin A which promoted [³H]thymidine uptake into these cells. Succinyl concanavalin A was less potent in promoting Ca²⁺ uptake than concanavalin A. Sodium periodate inhibited Ca²⁺ uptake at concentrations which promoted ³H-thymidine incorporation into splenocytes.It is concluded that con canavalin A promotes Ca²⁺ uptake which is not due to binding of ⁴⁵Ca²⁺ to concanavalin A. Although the concanavalin A-promoted Ca²⁺ uptake occurs at lectin concentrations that cause lymphocyte proliferation as measured by ³H-thymidine incorporation, the role of Ca²⁺ in this event remains unclear.     

ULTRASTRUCTURE AND BIREFRINGENCE OF THE ISOLATED MITOTIC APPARATUS OF MARINE EGGS

Isolated mitotic apparatuses (MA) of clam and sea urchin eggs were investigated by polarizing and electron microscopy. Examination of fixed MA in oils of different refractive index revealed that at least 90% of the retardation of isolated MA is due to positive, form birefringence, the remaining retardation deriving from positive, intrinsic birefringence. Electron micrographs reveal the isolated MA to be composed of microtubules, ribosome-like particles, and a variety of vesicles. In the clam MA the number of vesicles and ribosome-like particles relative to the number of microtubules is much lower than in the sea urchin MA. In clam MA this allows form and intrinsic birefringence to be related directly to microtubules. The relation of birefringence to microtubules in isolated sea urchin MA is more complex since ribosome-like particles adhere to microtubules, are oriented by them, and are likely to contribute to the form birefringence of the isolated MA. However, comparison of values of retardation for clam and sea urchin MA, indicates that the major part of the birefringence in sea urchin MA is also due to microtubules. The interpretation of the structures giving rise to birefringence in the MA of the living cells is likely to be even more complex since masking substances, compression, or tension on the living MA may alter the magnitude or sign of the birefringence.