Freeze-fracture studies of annulate lamellae in zebrafish oocytes

Summary The zebrafish oocyte contains prominent stacks of annulate lamellae (AL) located primarily in a subcortical position of the ooplasm. Many lamellae comprising a stack eventually exhibit continuity with the rough-surfaced endoplasmic reticulum which is present in abundance in larger oocytes. Pore structure of both AL and nuclear envelope (NE) was studied and compared by use of freeze-fracture electron microscopy. In freeze-fracture replicas, the NE and AL pores were easily distinguished, and a variety of fracture planes with respect to the stacked AL were generated. The pore diameter of NE and AL is similar (100nm). The number of nuclear pores varied from an average of 40 pores/m² in early stage oocytes to nearly double this number in later stage oocytes. For AL, the center-to-center spacing (120–130 nm) and the number of pores per square micrometer (56–67) did not change markedly regardless of oocyte developmental stage examined. Hexagonal packing of AL pores is a common feature. The AL pores have an angular margin with octagonal symmetry suggested in some cases. The AL pore interior contains fibrillar and particulate components and, depending upon the fracture plane, may appear to be filled with a plug of material. Both P- and E-membrane fracture faces of AL have a relative scarcity of intramembranous particles. The non-porous membranes that extend from the AL, however, have a higher concentration of intramembranous particles.     

The annulate lamellae of salamander oocytes: Morphological and functional aspects

Summary The present study reports observations on the distribution, morphology and functional significance of annulate lamellae in the developing salamander oocyte. This organelle was found in the cytoplasm, both as individual elements and as a cluster made up of from two to approximately five lamellae organized into closely aligned stacks. Adjacent stacks of lamellae were found to be randomly oriented. Annulate lamellae are essentially identical in structure with the nuclear envelope. The terminations of lamellae were very frequently found to be expanded into sac-like structures. The outer surface of each sac is usually lined with ribosomes. The paired membranes in some of the lamellae exhibited dilations for varying distances from their terminal sacs. These dilated segments of the lamellae were also lined with ribosomes. The annulate lamellae were interpreted as being intermediate stages in the formation of rough-surfaced cisternae and would, therefore, represent structural precursors of a form of endoplasmic reticulum. This organelle may therefore represent a transient morphological response to a need for especially high concentrations of proteins.

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Zusammenfassung Die vorliegende Arbeit berichtet Beobachtungen über Verteilung, Morphologie und funktioneile Bedeutung von Annulate lamellae in der sich entwickelnden Oocyte von Salamandern. Diese Organellen wurden im Zytoplasma gefunden, sowohl als individuelle Elemente, als auch in Gruppen, die aus etwa zwei bis fünf nahe beieinanderliegenden Stapeln organisierten Lamellen bestehen. Aneinandergrenzende Stapel von Lamellen sind zufÄllig orientiert. Annulate lamellae sind in ihrer Feinstruktur im Wesentlichen mit der Kernmembran identisch. Die Enden von Lamellen waren sehr oft als sackförmige Strukturen ausgebildet. Die Äu\ere OberflÄche eines Sackes ist im allgemeinen mit Ribosomen besetzt. In einigen der Lamellen zeigten die gepaarten Membranen Ausweitungen über variierende Distanzen von ihren TerminalsÄcken. Diese ausgeweiteten Teilstücke der Lamellen waren ebenfalls mit Ribosomen besetzt. Die Beobachtungen werden dahin interpretiert, da\ die Annulate lamellae intermediÄre Stadien in der Bildung von granulÄren Zisternen sind und deshalb strukturelle VorlÄufer einer Form des endoplasmatischen Retikulums darstellen. Die Organelle mag deshalb eine vorübergehende morphologische Reaktion auf einen Bedarf von besonders hoher Proteinkonzentration darstellen.

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This investigation was supported by a Public Health Service research career program award (5-K3-HD-5356-07) from the National Institute of Child Health and Human Development.     

Annulate lamellae: comparison of antigenic epitopes of annulate lamellae membranes with the nuclear envelope

Laminin derived from the Engelbreth-Holm-Swarm (EHS) tumor and a lamininlike molecule synthesized by RN22 Schwannoma cells both stimulate rapid neurite outgrowth, consistent with a common neurite-promoting site. However, antilaminin antisera can only inhibit the activity of the EHS laminin. The blocking antibodies in such sera are directed against the terminal heparin-binding domain of the laminin long arm (Edgar, D., R. Timpl, and H. Thoenen. 1984. EMBO [Eur. Mol. Biol. Organ.] J. 3: 1463-1468). These epitopes are demonstrated by immunoblotting to be part of the A chain and to be absent in RN22 laminin, showing (through metabolic labeling) that the cells synthesized little if any 440-kD A chain. This indicates that the antibody inhibition was probably due to steric hindrance, a common neurite-promoting site, apparently not being antigenic in native molecules. Antibodies raised against a 25-kD proteolytic fragment derived from the long arm of laminin were then used as probes to identify other potential neurite-promoting structures. Although these antibodies do not cross-react with native laminin, they recognized the B chains of denatured EHS and RN22 molecules on immunoblots. The antibodies also bound to the large proteolytic fragment, derived from the long arm of laminin that contains the neurite-promoting site, thus inhibiting its activity. Taken together, these results point to the localization of normally nonantigenic, defined, B chain sequences within or close to the neurite-promoting site of laminin.     

An integral membrane protein from the nuclear pore complex is also present in the annulate lamellae: implications for annulate lamella formation

Annulate lamellae (AL) are cytoplasmic arrays of stacked membrane cisternae containing densely packed pore complexes which are similar in structure to the nuclear pore complexes (NPCs) and thus referred to as annulate lamella pore complexes (ALPCs). We have recently shown that the integral nuclear pore membrane protein POM121 tagged with green fluorescent protein was correctly targeted to the nuclear pores (H. S?derqvist et al., 1997, Eur. J. Biochem. 250, 808-813). Here we have investigated if POM121 fused to three tandem molecules of yellow fluorescent protein (YFP) (POM121-YFP(3)) also was able to distribute in the extensive and well-characterized AL of RC37 and BMGE cells. Transfected RC37 or BMGE cells displayed YFP fluorescence around the nuclear envelope, as well as in the cytoplasmic AL structures. The YFP fluorescence colocalized perfectly with immunostaining using antibodies specific for different NPC proteins. The AL of both transfected and untransfected BMGE cells resisted extractions with Tx-100 and 250 mM NaCl, but were completely solubilized at 450 mM NaCl. Loss of YFP fluorescence and immunostaining for other NPC proteins correlated under all extraction conditions tested, suggesting that overexpressed POM121-YFP(3) had become an integrated part both of the NPCs and of the ALPCs. Furthermore, we have generated a stable BHK cell line expressing POM121-YFP(3) located exclusively at the nuclear pores. Treatment with vinblastine sulfate, which induces formation of AL in a variety of cells, resulted in distribution of POM121-YFP(3) into cytoplasmic foci colocalizing with immunostaining for peripheral NPC proteins. Taken together, the results show that YFP-tagged POM121 is able to distribute in drug-induced or naturally occurring AL, suggesting that POM121 is a natural constituent of ALPCs. In COS cells, which normally lack or have very little AL, YFP-tagged POM121 distributed in the nuclear pores when expressed at low levels. However, at high expression levels the YFP fluorescence also distributed in a number of brightly fluorescing cytoplasmic dots or foci, which were not present in untransfected cells. This was also true for untagged POM121. The cytoplasmic foci varied in size from 0. 1 to 2 microm and were distinctly located in the immediate vicinity of ER cisternae (without colocalizing) and also contained other nuclear pore proteins, indicating that they may represent cytoplasmic AL. This idea is supported by time-lapse studies of postmitotic assembly of these structures. This raises the question of the role of POM121 in ALPC and NPC biogenesis.     

Ribosomal bodies and annulate lamellae in the oocytes of the lizardPodarcis sicula

Summary Ultrastructural studies suggest that, in the oocytes of the lizardPodarcis sicula, ribosomal bodies are structurally continuous with annulate lamellae during their organization and disaggregation. This observation may indicate the dynamic transformation of the cytomembranes of one structure into those of the other, and vice versa. Moreover, the presence of annulate lamellae has been detected for the first time in lizard oocytes. The hypothesis is advanced that ribosomal bodies and annulate lamellae, in spite of some different structural characteristics, may play a similar role during the oocyte growth.     

Structural organization and possible functional role of annulate lamellae containing cytoplasmic pores

This review is devoted to annulate lamellae, a specific compartment of endoplasmic reticulum that occurs, presumably, in actively growing and rapidly dividing cells (oocytes, embryonic and tumor cells). We summarized both earlier and recent data on the dustribution of annulate lamellae in various cell types, on their morphology, and the distribution of interaction with intracellular structures at various treatments. As the annulate lamellae contain cytoplasmic pore complexes, a special attention was paid to their relation with nuclear pores. Possible functions of the annulate lamellae in intracellular processes and, particularly, in nuclear envelope assembly, are discussed.     

The origin and fate of annulate lamellae in maturing sand dollar eggs

Electron micrograph evidence is presented that the nuclear envelope of the mature ovum of Dendraster excentricus is implicated in a proliferation of what appear as nuclear envelope replicas in the cytoplasm. The proliferation is associated with intranuclear vesicles which apparently coalesce to form comparatively simple replicas of the nuclear envelope closely applied to the inside of the nuclear envelope. The envelope itself may become disorganized at the time when fully formed annulate lamellae appear on the cytoplasmic side and parallel with it. The concept of interconvertibility of general cytoplasmic vesicles with most of the membrane systems of the cytoplasm is presented. The structure of the annuli in the annulate lamellae is shown to include small spheres or vesicles of variable size embedded in a dense matrix. Dense particles which are about 150 A in diameter are often found closely associated with annulate lamellae in the cytoplasm. Similar structures in other echinoderm eggs are basophilic. In this species, unlike other published examples, the association apparently takes place in the cytoplasm only after the lamellae have separated from the nucleus. If 150 A particles are synthesized by annulate lamellae, as their close physical relationship suggests, then in this species at least the necessary synthetic mechanisms and specificity must reside in the structure of annulate lamellae.     

Intranuclear and cytoplasmic annulate lamellae in the polyploid giant cells of the trophoblast

Intranuclear and cytoplasmic annulate lamellae in polyploid giant cells of the trophoblast have been studied in rat placenta on days 12--17 of development. The annulate lamellae are present in the cytoplasm within a limited time, being visible on day 12 only. These are arranged in bundles near the nucleus to be moving then to the cytoplasm. The end parts of annulate lamellae are broadened to make cisterns of rough endoplasmic reticulum. Unlike the cytoplasmic annulate lamellae, those found within the nucleus are seen in part of the nuclei investigated throughout the whole period examined to look as single structures (not gathered in bundles), they can be branching, separating closed spaces within the nucleus (making local swellings in the loci of branching; the latter having electron dense or transparent vesicles). Association with nuclear chromatin in some regions is a peculiar feature of the intranuclear annulate lamellae. This association is especially obvious at endoprophase in the cycle ofthe polytene nucleus during the somatic conjugation--chromonemes unite in a bundle and condense. Ultrastructural changes of the annulate lamellae is noted throughout the polytene nucleus cycle and during the cell differentiation. It is supposed that in the case of temporary labile chromosome polyteny in the nuclear cycle, which is characteristic of mammalian trophoblasts, annulate lamellae can well compare, in their function, with the synaptonemal complex--these prevent from too tight associations of homologues in the course of somatic conjugation of chromosomes.     

Formation and function of cytoplasmic annulate lamellae in the eggs ofPomatoceros triqueter L.

Summary During an ultrastructural study of the eggs of the serpulid wormPomatoceros triqueter L., annulate lamellae were frequently encountered in the cytoplasm. In particular, some observations indicated that they originate by successive outfoldings of the nuclear envelope. Consequently, annulate lamellae must consist of alternating layers of nuclear and cytoplasmic material, each layer being separated by part of the nuclear envelope. It was observed that there was a similarity between nuclear and inter-annulate lamellar material. Moreover tritiated thymidine was shown to be present in the stacks. It is inferred that this system might well function as an efficient means of transporting nuclear material into the cytoplasm. The authors wish to thank Messrs. P. C. Lloyd, P. Henley and D. Williams for technical assistance.     

On the occurrence and significance of annulate lamellae in gastrodermal cells of regenerating planarians.

Cytoplasmic annulate lamellae have been observed to occur only in a subset of the gastrodermal cell population of regenerating planarians. They have not been found in the gastrodermal cells of intact, non-injured worms, nor in any other somatic cell type. These observations plus the presence of numerous chromatoid bodies in the same cells are consistent with the hypothesis that these cells are altering their state of differentiation and are preparing for division. It is further suggested that these cells are the precursors to the definitive somatic stem cells, the beta cells.     

Differentiation and distribution of annulate lamellae in growing oocytes in the newt, Cynops pyrrhogaster

Stages of oocyte development in Cynops pyrrogaster are defined, and changes of annulate lamellae in their fine structure, number, sizes and locations during oogenesis are described. The results show that two different types of annulate lamellae occur during oogenesis. One type differentiates in or at the periphery of vesicle-rich cytoplasm at the early stages of vitellogenesis and increases in number and size. The maximum number of about 40 stacks per median section of oocyte is reached at the stage of complete differentiation of the animal and the vegetal hemispheres. In these growing oocytes, all the stacks show elongate appearances and tetragonal arrangements of annuli as common characteristics. A second type of stacks of annulate lamellae is added anew in full-grown oocytes, increasing the number of stacks per median section of the oocyte to about 90. The new stacks occur in close contact with electron-dense bodies in the cytoplasm and have a massive appearance and hexagonal array of annuli. It is suggested that they appear coincidentally with the onset of oocyte maturation. The possible significance of the observed results is discussed.     

Relationships between annulate lamellae and filament bundles in oocytes of the zebrafish,Brachydanio rerio

Summary Bundles of filaments have been observed in the vitellogenic oocyte of the zebrafish, Brachydanio rerio; and these filaments illustrate a close spatial and structural relationship to annulate lamellae. The filaments range from 6–8 nm in diameter, and the annulate lamellae may cap both rounded ends of the bundle as well as extend parallel to the surface of the filament bundles. The ends of the filaments can be observed to exhibit an apparent termination in close relation to pore margins of the annulate lamellae, the membrane of the interpore regions of the annulate lamellae, as well as many nearby polyribosomes. The possible functional significance of this unique relationship is discussed in reference to a recent hypothesis regarding the function of annulate lamellae.     

Fine structure of the pore-annulus complex in the nuclear envelope and annulate lamellae of germ cells

Summary Octagonal symmetry in the pore margin has been demonstratedin situ in annulate lamellae and the nuclear envelope of germ cells. The annular material is located to variable extent within the pore and also extends beyond the pore margin; in the latter case it may be continuous with extra-pore annular material of some adjacent pores. In thin sections of fixed material, the annular material of both the nuclear envelope and annulate lamellae appears to be composed of a matrix within which are embedded thin filaments and small granules, the disposition and interrelationship of which are described and discussed. The so-called intra-annular granule is described as consisting of a number of smaller units (similar to the granular component of the annular material) which become aggregated in the center of some pores in both the nuclear envelope and annulate lamellae. The possible significance of intra-annular granules is discussed in terms of binding and movement of macromolecules.This investigation was supported by research grants (HD-00699, GM-09229) and a Career Development Award from the National Institutes of Health, U. S. Public Health Service. The author acknowledges the skillful technical assistance of Mrs.Robert Decker.     

The relationship between nuclear envelope-derived annulate lamellae and the asymmetric division of primary spermatocytes in aphids

The structure of dividing primary spermatocytes of Amphorophora tuberculata (Aphididae, Hemiptera) as determined by electron microscopy and serial sectioning is described. The developmental stages examined extend from late prophase I to late telophase I. We looked for any asymmetric organization that could be causally linked to the differences in chromatin behaviour between the two daughter nuclei towards the end of meiosis I of this species. In late prophase I, evaginations of the nuclear envelope in the vicinity of two neigh-bouring centrosomes develop into closed cytoplasmic compartments with a dense content. The compartments open in prometaphase I and come to lie together with fragments of the nuclear envelope within the spindle area. Since nuclear pores are preserved in the membranes, intraspindle annulate lamellae have formed. These and material of presumed nuclear origin associated with them are asymmetrically distributed within the cell. Although dispersed at stages beyond prometaphase I, the material may be largely incorporated into one of the two daughter cells and thus be decisive for further development. Some annulate lamellae form a cap at the chromosome surface opposite to the neighbouring centrosomes in prometaphase I. These membranes may prevent interaction between spindle microtubules and chromosomes until a bipolar spindle forms in metaphase I. At this stage, both the banana-shaped autosomal bivalent and the X univalent occupy the equatorial plane. This is strange, because the X univalent has microtubular connections with one spindle pole and would be expected to migrate towards that pole. Possibly, the kinetochore of the X chromosome is inactive, and remains so in anaphase I, when the X univalent remains located between the two autosomal half-bivalents.M.F. Trendelenburg     

Multi-scale mechanical characterization of prostate cancer cell lines: Relevant biological markers to evaluate the cell metastatic potential

BackgroundConsidering the importance of cellular mechanics in the birth and evolution of cancer towards increasingly aggressive stages, we compared nano-mechanical properties of non-tumoral (WPMY-1) and highly aggressive metastatic (PC-3) prostate cell lines both on cell aggregates, single cells, and membrane lipids.MethodsCell aggregate rheological properties were analyzed during dynamic compression stress performed on a homemade rheometer. Single cell visco-elasticity measurements were performed by Atomic Force Microscopy using a cantilever with round tip on surface-attached cells. At a molecular level, the lateral diffusion coefficient of total extracted lipids deposited as a Langmuir monolayer on an air-water interface was measured by the FRAP technique.ResultsAt cellular pellet scale, and at single cell scale, PC-3 cells were less stiff, less viscous, and thus more prone to deformation than the WPMY-1 control. Interestingly, stress-relaxation curves indicated a two-step response, which we attributed to a differential response coming from two cell elements, successively stressed. Both responses are faster for PC-3 cells. At a molecular scale, the dynamics of the PC-3 lipid extracts are also faster than that of WPMY-1 lipid extracts.ConclusionsAs the evolution of cancer towards increasingly aggressive stages is accompanied by alterations both in membrane composition and in cytoskeleton dynamical properties, we attribute differences in viscoelasticity between PC-3 and WPMY-1 cells to modifications of both elements.General significanceA decrease in stiffness and a less viscous behavior may be one of the diverse mechanisms that cancer cells adopt to cope with the various physiological conditions that they encounter.