An ultrastructural study of mouse and rat embryo implantation sites was undertaken to determine whether the uterine luminal epithelial cells surrounding the blastocyst exhibited the morphologic characteristics of apoptotic or necrotic cell death. In both species the epithelial cells exhibited all of the characteristics of apoptosis, including surface blebbing, shrinkage and fragmentation of the cells, condensation of chromatin, and indentation and fragmentation of nuclei. Cytoplasmic organelles remained morphologically intact, and the cytoplasm maintained normal or increased staining density. Also, the epithelial cells and cell fragments were phagocytosed by the adjacent trophoblast cells. The epithelial cells did not exhibit the characteristics of necrotic cell death, such as swollen cells and mitochondria, damaged surface membranes, and disintegrated cytoplasmic organelles. We conclude that uterine epithelial cells surrounding mouse and rat embryos during implantation undergo apoptotic cell death leading to their phagocytosis by trophoblast cells.
Thin sections of rabbit granulosa, human SW-13 adrenal cortical adenocarcinoma, and mouse B-16 melanoma cells revealed an apparent single-layered basket of 4-to 7-nm filaments surrounding cytoplasmic gap junction vesicles . This interpretation was based upon apparent longitudinal, cross, and en face sections of structures surrounding the vesicle profiles in tissue treated with tannic acidglutaraldehyde . In granulosa cells incubated with the S-1 fragment of heavy meromyosin, arrowhead-decorated filaments were observed at the periphery of the gap junction vesicles, suggesting that these filaments contained actin . In addition, we found that small gap junctional blebs and vesicles at the cell surface were coated with short electron-dense bristles similar in appearance to the clathrincontaining coat of coated vesicles of nonjunctional membrane . The role of these and other cytoskeletal elements in the possible endocytosis of gap junction membrane is discussed .
The rat primary decidual zone (PDZ) is a transitory avascular region of transformed fibroblasts surrounding the implanting embryo. Studies using fluorescein-labeled tracers have shown that the PDZ is selectively permeable to macromolecules, permeability decreasing with increasing molecular weight. In the present study we investigated the morphologic basis of the permeability barrier. Horseradish peroxidase (HRP) or HRP-labeled immunoglobulin G (IgG-HRP) was administered i.v. to rats on Day 7 of pregnancy, and the animals were killed 30 min to 2 h later. The reaction product of HRP was the same density in uterine blood vessels as in the intercellular spaces of the endometrium and PDZ at 30 min and 1 h after administration. Two hours after administration, the reaction product of IgG-HRP was dense in uterine blood vessels, much less dense in the interstitial spaces of the endometrium, and was not detected in the PDZ. There was an abrupt change in the density of the IgG-HRP reaction product at the intercellular clefts between endothelial cells, where cellular junctions were observed in control tissue. This suggests that the passage of large macromolecules from blood to the implantation chamber is limited initially by cellular junctions between capillary endothelial cells. The exclusion of IgG-HRP from the PDZ indicates that an additional barrier(s) to macromolecules in this region. Lanthanum nitrate tracer was uniformly present throughout the intercellular spaces of the PDZ except at tight junctions between decidual cells. Freeze-fracture replicas of the PDZ showed tight junctions that varied from single strands to interconnected networks of strands oriented mainly parallel to the long axis of the PDZ. Some strands were discontinuous. The tight junctions between decidual cells appear to be functionally discontinuous because HRP readily penetrated the PDZ, but such junctions may retard larger macromolecules such as IgG-HRP. The biological significance of the permeability barrier of the PDZ is discussed.
Upon fertilization, the zebrafish egg undergoes marked physiological and structural changes, one of which involves blastodisc formation. Before fertilization, yolk globules are rounded and the endoplasm extends throughout the oocyte. During blastodisc formation, the yolk globules become angular and the endoplasm is restricted to streamers among the yolk globules. The streamers are oriented in an anterior-posterior axis of the egg. During blastodisc formation the cytoskeleton consists of an extensive array of filamentous structures of variable width in both the cortex as well as within elongate endoplasmic streamers. Although the filamentous components in the cortex and endoplasmic streamers probably include both microfilaments and microtubules, frequently they are somewhat wider than the usual dimensions, and possible reasons for this are suggested. From their arrangement in both the cortex and endoplasm, it seems likely that the components of the cytoskeleton (e.g., microfilaments and microtubules) may provide, through contraction, the major force responsible for the streaming of the endoplasm into the forming blastodisc. It is assumed that the surface tension of the vegetal hemisphere exceeds that of the animal hemisphere, thus forcing, through differential contraction, the endoplasm to flow in the direction of the forming blastodisc. No distinct barrier between the yolk and forming blastodisc was observed. The compressed condition of the larger and many-sided yolk globules could prevent their movement into the blastodisc. Scanning electron microscopy is limited in the resolution with which it can depict the cytoskeleton, but nonetheless it provides useful information about structural interrelationships.
The rat primary decidual zone (PDZ) is a transitory, avascular region of transformed fibroblasts surrounding the implanting embryo. Tracer studies have indicated that the PDZ is selectively permeable to macromolecules, permeability decreasing with increasing molecular weight of the tracer. To clarify the morphological basis of the permeability barrier, we have studied the ultrastructure of the PDZ with particular emphasis on the intercellular features and cellular junctions. The cells of the PDZ were large and tightly packed; their apposed membranes showed extensive interdigitations in some regions, but elsewhere they were relatively straight. Tight junctions, gap junctions, and desmosomelike junctions were observed between decidual cells. The tight junctions usually consisted of one or two points of membrane fusion, and they were oriented both parallel and perpendicular to the long axis of the PDZ. These junctions were frequently associated with gap junctions. Scattered pockets of dilated extracellular space between decidual cells contained collagen fibrils and an amorphous, dense material. These extracellular components were also sequestered by the decidual cells in deep invaginations of the cell surface that were continuous with the extracellular space. Decidual cells also exhibited flangelike processes that penetrated the basal laminae of the adjacent epithelium and capillary endothelium. Our present observations indicate that decidual cells are connected by tight junctions, and a previous study demonstrated that macromolecules up to 40 kDa readily cross the PDZ; hence, the tight junctions appear to be discontinuous. We suggest that the structures restricting the movement of large macromolecules (66 kDa and larger) across the PDZ from blood vessels to the embryo may include discontinuous tight junctions, membrane interdigitations, and amorphous intercellular material.
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