Distribution of lectin binding sites in Xenopus laevis egg jelly.

Eggs from the anuran Xenopus laevis are surrounded by a thick jelly coat that is required during fertilization. The jelly coat contains three morphologically distinct layers, designated J1, J2, and J3. We examined the lectin binding properties of the individual jelly coat layers as a step in identifying jelly glycoproteins that may be essential in fertilization. The reactivity of 31 lectins with isolated jelly coat layers was examined with enzyme-linked lectin-assays (ELLAs). Using ELLA we found that most of the lectins tested showed some reactivity to all three jelly layers; however, two lectins showed jelly layer selectivity. The lectin Maackia amurensis (MAA) reacted only with J1 and J2, while the lectin Trichosanthes kirilowii (TKA) reacted only with J2 and J3. Some lectins were localized in the jelly coat using confocal microscopy, which revealed substantial heterogeneity in lectin binding site distribution among and within jelly coat layers. Wheat germ agglutinin (WGA) bound only to the outermost region of J3 and produced a thin, but very intense, band of fluorescence at the J1/J2 interface while the remainder of J2 stained lightly. The lectin MAA produced an intense fluorescence-staining pattern only at the J1/J2 interface. Several lectins were also tested for the ability to inhibit fertilization. WGA, MAA, and concanavalin A significantly inhibited fertilization and WGA was found to block fertilization by preventing sperm from penetrating the jelly. Using Western blotting, we identified high-molecular-weight components in J1 and J2 that may be important in fertilization.

Structural features of the abalone egg extracellular matrix and its role in gamete interaction during fertilization.

Abalone eggs are surrounded by a complex extracellular coat that contains three distinct elements: the jelly layer, the vitelline envelope, and the egg surface coat. In this study we used light and electron microscopy to describe these three elements in the red abalone (Haliotis rufescens) and ascribe function to each based on their interactions with sperm. The jelly coat is a spongy matrix that lies at the outermost margin of the egg and consists of variably sized fibers. Sperm pass through this layer with their acrosomes intact and then go on to bind to the vitelline envelope. The vitelline envelope is a multilamellar fibrous layer that appears to trigger the acrosome reaction after the sperm binding. Next, sperm release lysin from their acrosomal granules, a nonenzymatic protein that dissolves a hole in the vitelline envelope through which the sperm swims. Sperm then contact the egg surface coat, a network of uniformly sized filaments lying directly above the egg plasma membrane. This layer mediates attachment of sperm, via their acrosomal process, to the egg surface.

Ultrastructure of the proteoliaisin-ovoperoxidase complex and its spatial organization within the Strongylocentrotus purpuratus fertilization envelope.

Ovoperoxidase is a cortical granule-derived enzyme that hardens the sea urchin fertilization envelope by catalyzing the formation of dityrosine residues. Ovoperoxidase works in concert with a second protein, proteoliaisin, which anchors ovoperoxidase to the nascent fertilization envelope in a divalent cation-dependent manner. In this study, we examined the Ca(2+)-dependent interaction of proteoliaisin with ovoperoxidase in rotary-shadowed Pt replicas. Ovoperoxidase, a uniformly sized globular molecule, binds to a distal portion of rod-shaped proteoliaisin when low concentrations of Ca2+ are present. Higher Ca2+ concentrations lead to the formation of extended proteoliaisin strands that are decorated along their lengths with ovoperoxidase. Using immunogold labeling, we also examined the assimilation of these two proteins into the fertilization envelope in quick-frozen, deeply etched samples. Both proteins are abundant in the fertilization envelope as early as one minute after fertilization. Coincident with paracrystalline coating of the envelope, the labeling density is markedly reduced, suggesting that antigenic sites may be masked by the paracrystalline coat. This suggests that the ovoperoxidase-proteoliaisin complex resides within the central portion of the fertilization envelope, rather than in the paracrystalline coat.

Degradation of an extracellular matrix: sea urchin hatching enzyme removes cortical granule-derived proteins from the fertilization envelope.

The sea urchin fertilization envelope is an extracellular matrix assembled at fertilization to prevent polyspermy and protect the embryo during early development. During hatching, the embryo secretes a proteolytic hatching enzyme which dissolves the fertilization envelope, allowing a ciliated blastula to swim free. In this study we examined ultrastructural changes in the fertilization envelope during degradation of this matrix by hatching enzyme. The completed fertilization envelope is a trilaminar structure consisting of a dense, central layer of filaments sandwiched between surface coats of paracrystalline material. Hatching enzyme disassembles this matrix by degrading the paracrystalline layers and removing macromolecules from the central layer leaving behind a thin matrix of loosely woven fibers.

Evidence for the existence of two assembly domains within the sea urchin fertilization envelope.

The sea urchin fertilization envelope (FE) is a complex, macromolecular aggregate assembled by the addition of cortical granule secretions to the vitelline layer. The completed, trilaminar structure has a dense layer sandwiched between surface coats of paracrystalline material. Two cortical granule enzymes, ovoperoxidase and protease, and a cell surface transglutaminase are required for the assembly process. We have examined, by quick-freeze, deep-etch, rotary-shadow electron microscopy, the effects of inhibiting each of these enzymes upon FE assembly. These experiments reveal two domains within the FE, distinguishable by their enzymatic requirements for proper maturation. The first domain consists of the microvillar casts which require both protease and transglutaminase activities to obtain a normal paracrystalline coat. The second domain comprises the regions between casts and appears to mature by ovoperoxidase-mediated cross-linking of paracrystalline material to the envelope.

The fluorescent probe BCECF has a heterogeneous distribution in sea urchin eggs.

Sea urchin eggs were loaded with the pH-sensitive fluorescent probe BCECF. Homogenization of these eggs, followed by centrifugation, resulted in 25% of the total homogenate fluorescence remaining with the pellet. Fluorescence microscopy revealed brightly fluorescing punctate organelles whose fluorescence was not quenched by acidification. The excitation spectrum of intracellular BCECF was markedly red-shifted compared to probe calibrated in buffer. Model excitation spectra based on a two compartment model mimicked the intracellular BCECF spectrum, therefore, supporting the possibility that organelles in sea urchin eggs accumulate large amounts of BCECF in a relatively pH-insensitive form.