Regional differences in the lateral mobility of plasma membrane lipids in a molluscan embryo

Lateral mobility of plasma membrane proteins in dividing eggs of the loach (Misgurnus fossilis): Regional differences and changes during the cell cycle

Regional differences in lateral diffusion rates of fluorescence-labeled proteins have been studied in the plasma membrane of dividing eggs of the loach (Misgurnus fossilis) by fluorescence recovery after photobleaching (FRAP). Apparent animal-vegetal differences in fluorescence intensity, lateral diffusion coefficients, and fractions of mobile proteins have been found, with all these quantities being higher in the animal pole region than in the yolk region. Cyclic changes in protein diffusion coefficients and mobile fractions during the first few cell cycles have also been recorded. Soon after the end of a cleavage, the diffusion coefficient reaches its minimal value and increases rapidly before the next cleavage.

Lipid domains and lipid/protein interactions in biological membranes

In the fluid mosaic model of membranes, lipids are organized in the form of a bilayer supporting peripheral and integral proteins. This model considers the lipid bilayer as a two-dimensional fluid in which lipids and proteins are free to diffuse. As a direct consequence, both types of molecules would be expected to be randomly distributed within the membrane. In fact, evidences are accumulating to indicate the occurrence of both a transverse and lateral regionalization of membranes which can be described in terms of micro- and macrodomains, including the two leaflets of the lipid bilayer. The nature of the interactions responsible for the formation of domains, the way they develop and the time- and space-scale over which they exist represent today as many challenging problems in membranology. In this report, we will first consider some of the basic observations which point to the role of proteins in the transverse and lateral regionalization of membranes. Then, we will discuss some of the possible mechanisms which, in particular in terms of lipid/protein interactions, can explain lateral heterogenities in membranes and which have the merit of providing a thermodynamic support to the existence of lipid domains in membranes.

Cell lineage in molluscan development

Cell lineage specification in molluscs is brought about by two mechanism: the segregation of morphogenetic plasms and inductive cell interactions. The evidence for the existence of morphogenetic plasms is largely circumstantial, but in one species, Bithynia, such a plasm has been identified in the polar lobe that forms at first cleavage. Inductive cell interactions are thought to be a prerequisite for the development of a large number of tissues and organs. The most extensively studied example is the specification of the mesodermal stem cell in Lymnaea and Patella, which occurs between 5th and 6th cleavage through an interaction between one macromere and a large number of micromeres. Both segregation and induction are tuned to the animal-vegetal polarity of the egg, at least during early development. This polarity probably arises during oogenesis and is manifest in regional differentiations of the surface architecture of the egg, in the distribution of inner membrane particles in the plasma membrane, in membrane fluidity characteristics, in ionic conductance properties of the plasma membrane, etc. All these phenomena have in common that they represent properties of the egg surface, suggesting that the polarity of the egg is somehow imprinted into the plasma membrane and the cortex of the egg during oogenesis.

Cell lineage-specific inhibition of cytokinesis by concanavalin A in a molluscan embryo (Nassarius reticulatus, Gastropoda)

The effects of the lectin concanavalin A (Con A) on cleavage were studied in early embryos of the gastropodNassarius reticulatus. Progression of the first cleavage furrow is inhibited by incubating eggs before the first cleavage with 0.3-20 μg/ml Con A. Treatment with 1.0-20 μg/ml Con A during first cleavage causes regression of the cleavage furrow. Treatment with low concentrations (0.3-1.0 μg/ml) during the same period does not affect first cleavage. However, when further development of such eggs is followed, one finds that second cleavage is inhibited typically in only one of the two blastomeres of the 2-cell stage, i.e. the CD-blastomere. As a result, a 3-cell embryo is formed. At third cleavage of such embryos, the CD-blastomere forms either one double-sized micromere (1cd-micromere) or two normal-sized micromeres (1c and 1d) simultaneously. Sometimes micromere formation in the CD-blastomere is inhibited. Con A binding does not affect karyokinesis, nor does it affect the division asynchronies typical for normal development. On the basis of these and other results it is argued that binding of Con A to sites located at the vegetal pole of the egg is responsible for the cell lineage-specific inhibition of cleavage by Con A. This effect is most probably mediated by changes in the organization of the egg cortex.

Localized activity of Ca2+-stimulated ATPase and transcellular ionic currents during mesoderm induction in embryos ofLymnaea stagnalis (Mollusca)

InLymnaea stagnalis, mesoderm induction occurs at the 24-cell stage, when the apical tip of the macromere 3D establishes a close contact with a number of micromeres. Via its tip, the macromere 3D is supposed to receive an inductive signal from the micromeres, resulting in the determination of the mesodermal stem cell 4d at the next division. In view of the possibility that transcellular ionic currents might somehow be involved, either in the processes that bring about this particular configuration of blastomeres or in the induction process itself, we mapped the electric field around the embryo during the 24-cell stage, using a vibrating probe. We detected a reversal of the current direction as compared to the uncleaved egg, whilst the polarity of the field along the animal-vegetal axis was maintained. We also mapped the localization of Ca²⁺-stimulated AT-Pase, an enzyme that drives the Ca²⁺-efflux from the cell. We found that this enzyme is localized exclusively along the cytoplasmic face of the apical plasma membrane of macromere 3D, and that its presence is restricted to the period from 110 to 135 min after the fifth cleavage, when there is close contact between macormere 3D and the micromeres. Since the localization of the Ca²⁺-stimulated ATPase coincides both in time and space with the induction of the mesoderm-mother cell, we suggest that localized calcium fluxes may play a role in this induction process.

Polar localization of plasma membrane Ca2+/Mg2+ ATPase correlates with the pattern of steady ionic currents in eggs ofLymnaea stagnalis andBithynia tentaculata (Mollusca)

During extrusion of the first polar body in eggs ofLymnaea stagnalis andBithynia tentaculata a localized Ca²⁺ /Mg²⁺ ATPase activity was detected, using Ando's enzyme-cytochemical method for electron microscopy [Ando et al. (1981) Acta Histochem Cytochem 14:705-726]. The enzyme activity was distributed in a polar fashion, along the cytoplasmic face of the plasma membrane. In the eggs ofLymnaea it was found only in the vegetal hemisphere, whereas inBithynia eggs it was localized both in the vegetal hemisphere and at the animal pole. This pattern of enzyme activity corresponds to the polar pattern of transcellular ionic currents measured with the vibrating probe, which we showed to be partially carried or regulated by calcium [Zivkovic and Dohmen (1989) Biol Bull (Woods Hole) 176 (Suppl):103-109]. The characteristics of the ATPase were studied using a variety of approaches such as ion and substrate depletions and substitutions, addition of specific inhibitors of ATPase activity, treatment with EDTA/EGTA and electron energy-loss spectrometry. The results indicate that, inLymnaea, there are at least two enzymatic entities. The first one is a Ca²⁺ /Mg²⁺ ATPase localized along the membrane and in the cortex of the vegetal hemisphere. The second one is a Ca²⁺-stimulated ATPase (calcium pump of the plasma membrane) localized in a small region of the membrane at the vegetal pole. We speculate that in the eggs ofLymnaea andBithynia a functional relationship exists between the plasma-membrane-associated ATPase activity and the transcellular ionic currents measured in the same region.

Mechanisms of polar lobe formation in fertilized eggs of molluscs

Polar lobe formation in the marine mudsnail, Ilyanassa obsoleta, involves formation of a microtubule-, microfilament-dependent furrow that constricts at two rates, then stops and relaxes. Some artificial seawater mixtures allow relatively normal development, facilitate insertion of microelectrode tips, and prevent artifactual bleb formation during such punctures. Membrane events may affect formation of polar lobe constrictions: (1) Brief treatment with digitonin prevents constrictions, but not cytokinesis per se, and the suppression of constrictions is permanent. Tomatine (but not tomatidine) and filipin act similarly, although filipin often also stops cytokinesis as well. (2) Responses to digitonin, tomatine, and filipin occur with little change in membrane potential. (3) Adhesion to substrata in response to brief treatment at low pH prevents both constrictions and cytokinesis. (4) Adhesion to substrata via polylysine allows both constrictions and cytokinesis, but embryos are smaller in volume and develop abnormally. Formation of lobe constrictions may be sensitive to perturbations of the plasma membrane.

Effect of sodium dodecyl sulfate on polar lobe formation and function in Ilyanassa obsoleta embryos

Polar lobes, anucleate vegetal pole protrusions formed by Ilyanassa obsoleta embryos, serve as a mechanism for shunting morphogenetic determinants to one cell during the first two cleavages. Polar lobe material becomes segregated in the CD cell during first cleavage and in the D cell during second cleavage, resulting in a very unequal four-cell stage. Larval structures including external shell, foot, operculum, statocysts, and eyes develop only when polar lobe material is present. Treatment with the anionic detergent sodium dodecyl sulfate (SDS) before and during the first cleavage inhibited polar lobe formation and equalized cleavage, as the lobe material was distributed to two cells. No polar lobes formed during second clevage in SDS-equalized embryos, and the four-cell stage consisted of four equal cells with reduced cell contacts. SDS inrreversibly inhibited polar lobe formation without affecting cytokinesis. Although 27% of the larvae from SDS-equalized embryos had one or more lobe-dependent structures duplicated, morphogenesis was impaired: more than 40% of such larvae failed to form shell and/or statocysts. When cells were separated after equalized first cleavage and raised as pairs, the pairs of resulting larvae duplicated lobe-dependent structures with the same frequency as whole equalized embryos. Possible explanations for impaired morphogenesis in SDS-treated embryos are discussed.

Lipid lateral diffusion and membrane organization

It is shown that investigating the lateral motion of lipids in biological membranes can provide useful information on membrane lateral organization. After labeling membranes with extrinsic or intrinsic lipophilic fluorescent probes, fluorescence recovery after photobleaching experiments strongly suggests that specialized cells like spermatozoa, eggs and epithelia exhibit surface membrane regionalization or macrocompartmentation and that lateral microheterogeneities or lipid microdomains exist in the plasma membrane of many cellular systems.