The ultrastructure of the nuclear periphery. The zonula nucleum limitans

The Quest for the Blueprint of the Nuclear Pore Complex

During my postdoc interview in June of 1998, I asked Günter why he was moving more towards the nucleus in his latest studies. He said, "Well Joe, that's where everything starts." By the end of the interview, I accepted the postdoc. He had a way of making everything sound so cool. Günter's progression was natural, since the endoplasmic reticulum and the nucleus are the only organelles that share the same membrane. The nuclear envelope extends into a double membrane system with nuclear pore complexes embedded in the pore membrane openings. Even while writing this review, I remember Günter stressing; it is the nuclear pore complex. Just saying nuclear pore doesn't encompass the full magnitude of its significance. The nuclear pore complex is one of the largest collection of proteins that fit together for an overall function: transport. This review will cover the Blobel lab contributions in the quest for the blueprint of the nuclear pore complex from isolation of the nuclear envelope and nuclear lamin to the ring structures.

Overexpression of the lamina proteins Lamin and Kugelkern induces specific ultrastructural alterations in the morphology of the nuclear envelope of intestinal stem cells and enterocytes

The nuclear envelope has a stereotypic morphology consisting of a flat double layer of the inner and outer nuclear membrane, with interspersed nuclear pores. Underlying and tightly linked to the inner nuclear membrane is the nuclear lamina, a proteinous layer of intermediate filament proteins and associated proteins. Physiological, experimental or pathological alterations in the constitution of the lamina lead to changes in nuclear morphology, such as blebs and lobulations. It has so far remained unclear whether the morphological changes depend on the differentiation state and the specific lamina protein. Here we analysed the ultrastructural morphology of the nuclear envelope in intestinal stem cells and differentiated enterocytes in adult Drosophila flies, in which the proteins Lam, Kugelkern or a farnesylated variant of LamC were overexpressed. Surprisingly, we detected distinct morphological features specific for the respective protein. Lam induced envelopes with multiple layers of membrane and lamina, surrounding the whole nucleus whereas farnesylated LamC induced the formation of a thick fibrillary lamina. In contrast, Kugelkern induced single-layered and double-layered intranuclear membrane structures, which are likely be derived from infoldings of the inner nuclear membrane or of the double layer of the envelope.

Organization of nuclear architecture during adipocyte differentiation

Obesity is a serious health problem worldwide since it is a major risk factor for chronic diseases such as type II diabetes. Obesity is the result of hyperplasia (associated with increased adipogenesis) and hypertrophy (associated with decreased adipogenesis) of the adipose tissue. Therefore, understanding the molecular mechanisms underlying the process of adipocyte differentiation is relevant to delineate new therapeutic strategies for treatment of obesity. As in all differentiation processes, temporal patterns of transcription are exquisitely controlled, allowing the acquisition and maintenance of the adipocyte phenotype. The genome is spatially organized; therefore decoding local features of the chromatin language alone does not suffice to understand how cell type-specific gene expression patterns are generated. Elucidating how nuclear architecture is built during the process of adipogenesis is thus an indispensable step to gain insight in how gene expression is regulated to achieve the adipocyte phenotype. Here we will summarize the recent advances in our understanding of the organization of nuclear architecture as progenitor cells differentiate in adipocytes, and the questions that still remained to be answered.

Significance of 1B and 2B domains in modulating elastic properties of lamin A

Nuclear lamins are type V intermediate filament proteins which form an elastic meshwork underlying the inner nuclear membrane. Lamins directly contribute to maintain the nuclear shape and elasticity. More than 400 mutations have been reported in lamin A that are involved in diseases known as laminopathies. These mutations are scattered mainly in the lamin rod domain along with some in its C-terminal domain. The contribution of the rod domain towards the elasticity of lamin A molecule was hitherto unknown. Here, we have elucidated the significance of the 1B and 2B domains of the rod in modulating the elastic behavior of lamin A by single-molecule force spectroscopy. In addition, we have also studied the network forming capacity of these domains and their corresponding viscoelastic behavior. We have shown that the 1B domain has the ability to form a lamin-like network and resists larger deformation. However at the single-molecular level, both the domains have comparable mechanical properties. The self-assembly of the 1B domain contributes to the elasticity of the lamin A network.

Adipogenesis is under surveillance of Hsp90 and the high molecular weight Immunophilin FKBP51

Adipose tissue plays a central role in the control of energy balance as well as in the maintenance of metabolic homeostasis. It was not until recently that the first evidences of the role of heat shock protein (Hsp) 90 and high molecular weight immunophilin FKBP51 have been described in the process of adipocyte differentiation. Recent reports describe their role in the regulation of PPARγ, a key transcription factor in the control of adipogenesis and the maintenance of the adipocyte phenotype. In addition, novel roles have been uncovered for FKBP51 in the organization of the architecture of the nucleus through its participation in the reorganization of the nuclear lamina. Therefore, the aim of this review is to integrate and discuss the recent advances in the field, with special emphasis on the roles of Hsp90 and FKBP51 in the process of adipocyte differentiation.

Evolution of the lamin protein family: what introns can tell

Lamins are the major components of the nuclear lamina, a filamentous layer found at the interphase between chromatin and the inner nuclear membrane. The lamina supports the nuclear envelope and provides anchorage sites for chromatin. Lamins and their associated proteins are required for most nuclear activities, mitosis, and for linking the nucleoskeleton to the network of cytoskeletal filaments. Mutations in lamins and their associated proteins give rise to a wide range of diseases, collectively called laminopathies. This review focuses on the evolution of the lamin protein family. Evolution from basal metazoans to man will be described on the basis of protein sequence comparisons and analyses of their gene structure. Lamins are the founding members of the family of intermediate filament proteins. How genes encoding cytoplasmic IF proteins could have arisen from the archetypal lamin gene progenitor, can be inferred from a comparison of the respective gene structures. The lamin/IF protein family seems to be restricted to the metazoans. In general, invertebrate genomes harbor only a single lamin gene encoding a B-type lamin. The archetypal lamin gene structure found in basal metazoans is conserved up to the vertebrate lineage. The completely different structure of lamin genes in Caenorhabditis and Drosophila are exceptions rather than the rule within their systematic groups. However, variation in the length of the coiled-coil forming central domain might be more common than previously anticipated. The increase in the number of lamin genes in vertebrates can be explained by two rounds of genome duplication. The origin of lamin A by exon shuffling might explain the processing of prelamin A to the mature non-isoprenylated form of lamin A. By alternative splicing the number of vertebrate lamin proteins has increased even further. Lamin C, an alternative splice form of the LMNA gene, is restricted to mammals. Amphibians and mammals express germline-specific lamins that differ in their protein structure from that of somatic lamins. Evidence is provided that there exist lamin-like proteins outside the metazoan lineage.

Epigenetic alterations in muscular disorders

Epigenetic mechanisms, acting via chromatin organization, fix in time and space different transcriptional programs and contribute to the quality, stability, and heritability of cell-specific transcription programs. In the last years, great advances have been made in our understanding of mechanisms by which this occurs in normal subjects. However, only a small part of the complete picture has been revealed. Abnormal gene expression patterns are often implicated in the development of different diseases, and thus epigenetic studies from patients promise to fill an important lack of knowledge, deciphering aberrant molecular mechanisms at the basis of pathogenesis and diseases progression. The identification of epigenetic modifications that could be used as targets for therapeutic interventions could be particularly timely in the light of pharmacologically reversion of pathological perturbations, avoiding changes in DNA sequences. Here I discuss the available information on epigenetic mechanisms that, altered in neuromuscular disorders, could contribute to the progression of the disease.

Introducing intermediate filaments: from discovery to disease

It took more than 100 years before it was established that the proteins that form intermediate filaments (IFs) comprise a unified protein family, the members of which are ubiquitous in virtually all differentiated cells and present both in the cytoplasm and in the nucleus. However, during the past 2 decades, knowledge regarding the functions of these structures has been expanding rapidly. Many disease-related roles of IFs have been revealed. In some cases, the molecular mechanisms underlying these diseases reflect disturbances in the functions traditionally assigned to IFs, i.e., maintenance of structural and mechanical integrity of cells and tissues. However, many disease conditions seem to link to the nonmechanical functions of IFs, many of which have been defined only in the past few years.

Filaments made from A- and B-type lamins differ in structure and organization

Lamins are intermediate filament proteins and the major component of the nuclear lamina. Current views of the lamina are based on the remarkably regular arrangement of lamin LIII in amphibian oocyte nuclei. We have re-examined the LIII lamina and propose a new interpretation of its organization. Rather than consisting of two perpendicular arrays of parallel filaments, we suggest that the oocyte lamina consists of parallel filaments that are interconnected in register to give the impression of a second set of perpendicular filaments. We have also used the oocyte system to investigate the organization of somatic lamins. Currently, it is not feasible to examine the organization of somatic lamins in situ because of their tight association with chromatin. It is also difficult to assemble vertebrate lamin filaments in vitro. Therefore, we have used the oocyte system, where exogenously expressed somatic B-type and A-type lamins assemble into filaments. Expression of B-type lamins induces the formation of intranuclear membranes that are covered by single filament layers. LIII filaments appear identical to the endogenous lamina, whereas lamin B2 assembles into filaments that are organized less precisely. Lamin A induces sheets of thicker filaments on the endogenous lamina and significantly increases the rigidity of the nuclear envelope.

Nuclear lamins: major factors in the structural organization and function of the nucleus and chromatin

Over the past few years it has become evident that the intermediate filament proteins, the types A and B nuclear lamins, not only provide a structural framework for the nucleus, but are also essential for many aspects of normal nuclear function. Insights into lamin-related functions have been derived from studies of the remarkably large number of disease-causing mutations in the human lamin A gene. This review provides an up-to-date overview of the functions of nuclear lamins, emphasizing their roles in epigenetics, chromatin organization, DNA replication, transcription, and DNA repair. In addition, we discuss recent evidence supporting the importance of lamins in viral infections.

The dynamic properties and possible functions of nuclear lamins

The nuclear lamins are thought to form a thin fibrous layer called the nuclear lamina, underlying the inner nuclear envelope membrane. In this review, we summarize data on the dynamic properties of nuclear lamins during the cell cycle and during development. We discuss the implications of dynamics for lamin functions. The lamins may be involved in DNA replication, chromatin organization, differentiation, nuclear structural support, and nuclear envelope reassembly. Emphasis is placed on recent data that indicate that the lamina, contrary to previous views, is not a static structure. For example, the lamins form nucleoplasmic foci, distinct from the peripheral lamina, which vary in their patterns of distribution as well as their composition in a cell cycle-dependent manner. During the S phase, these foci colocalize with chromatin and sites of DNA replication. At other points during the cell cycle, they may represent sites of lamin post-translation processing that take place prior to incorporation into the lamina. Secondary modifications of the lamins such as isoprenylation and phosphorylation are involved in the regulation of the dynamic properties and the assembly of lamins. In addition, a number of lamin-associated proteins have been recently identified and these are described along with their potential functions.

Patterns of nuclear lamins in diverse animal and plant cells and in germ cells as revealed by immunofluorescence microscopy with polyclonal and monoclonal antibodies

Polyclonal and monoclonal antibodies against rat liver nuclear lamins have been used to evaluate the immunological cross-reactivity of lamins with a given antibody in a variety of animal and plant cells. The results indicated that lamins of all vertebrate cells but not invertebrate cells share at least one antigenic determinant, resulting in immunological cross-reaction with polyclonal antisera to lamina from rat liver. The range of cross-reaction with monoclonal antibody to rat lamins includes all mammalian cells tested but we observed no reaction with other vertebrate and invertebrate cells. Thus, by means of immunological cross-reaction a less stringently conserved pattern is observed for lamins than, for example, cytoskeletal proteins. We have also investigated the fate of the nuclear lamins during meiosis in testes and ovaries of the mouse. Lamins are absent from male meiotic cells and during oogenesis in meiotic prophases.

The disappearance of the nuclear lamina during spermatogenesis: an electron microscopic and immunofluorescence study

The nuclear lamina is a proteinaceous layer lying directly beneath the inner nuclear membrane in somatic cells. Here we demonstrate by indirect immunofluorescence and electron microscopy that the lamina is completely absent from the nuclei of spermatocytes and spermatids of the chicken. The absence of a lamina in these cells can also be demonstrated in isolated nuclei lacking the two nuclear membranes. Implications of this finding for possible functions of the nuclear lamina are discussed.

Formation of multinuclear cells induced by dimethyl sulfoxide: inhibition of cytokinesis and occurrence of novel nuclear division in Dictyostelium cells

Our previous studies showed that 10 percent dimethyl sulfoxide (DMSO) induces the formation of actin microfilament bundles in the cell nucleus together with the dislocation of cortical microfilaments from the plasma membrane. The present study investigated the effects of DMSO on diverse activities mediated by cellular microfilaments as the second step toward assessing potential differences between nuclear and cytoplasmic actins of dictyostelium mucoroides. DMSO was found to reversibly inhibit cell-to- glass as well as cell-to-cell adhesion, cell locomotion, and cell multiplication, whereas cytoplasmic streaming and phagocytosis were not obviously inhibited. Also, 5 percent DMSO inhibited cytokinesis but did not totally inhibit cell growth thus leading to the development of giant cells more than 10 times larger than normal cells. Transmission electron microscopy using serial thin sections showed the occurrence of multinucleation in the DMSO- induced giant cells. After the removal of DMSO, the giant multinuclear cells underwent multiple cytoplasmic cleavage producing normal-sized mononuclear cells. The nuclear division in the DMSO-induced giant cells was unique in that no spindle microtubules were formed, and vesicles appeared inside the nucleus forming a transverse partition of the nuclear envelope. The presence of actin filaments in those nuclei was demonstrated by a binding study with skeletal muscle myosin subfragment-1, and their possible involvement in this mode of nuclear division is discussed.

Ultrastructure of benign cartilaginous tumors of intraosseous origin

The ultrastructure of chondroblastoma, chondromyxoid fibroma, and enchondroma is described. In chondroblastoma the tumor cells often show nuclear indentations and a thick nuclear fibrous lamina, and have features indicative of poorly differentiated cartilaginous cells. Chondroblastoma is a tumor thought to arise from immature chondrocytes related to the epiphyseal cartilage. In chondromyxoid fibroma the cells are pleomorphic with irregular cell processes and scalloping of the cell membrane. The nuclei are also often indented and demonstrate the presence of a thick nuclear fibrous lamina. The matrix consists of proteoglycan granules and fine fibrils. The large bizarre atypical cells often seen in this tumor, except for their size, do not differ from the typical cells. Chondromyxoid fibroma arises from cells related to the epiphyseal cartilage and demonstrates moderate degrees of cartilaginous differentiation. The close relationship between chondromyxoid fibroma and chondroblastoma is emphasized. The nuclear irregularities and the presence of a thick fibrous lamina are features shared by these two lesions. The tumor cells of enchondroma have features of well differentiated cartilage, and the pericellular matrix tends to be sparse around most cells. In addition to proteoglycan granules and fine fibrils, the matrix contains many dense membrane bound bodies. Numerous tumor cells undergoing necrosis are noted. Studies comparing enchondroma and well differentiated chondrosarcoma show no morphologic differences and both tumors have similar features. The application of electron microscopy does not provide pathognomonic features to distinguish between these lesions. However, it helps to correlate the ultrastructural findings with light microscopy.

Nuclear surface complex as observed with the high resolution scanning electron microscope. Visualization of the membrane surfaces of the neclear envelope and the nuclear cortex from Xenopus laevis oocytes

The nuclear envelope and associated structures from Xenopus laevis oocytes (stage VI) have been examined with the high resolution scanning electron microscope (SEM). The features of the inner and outer surfaces of the nuclear surface complex were revealed by manual isolation , whereas the membranes facing the perinuclear space (the space between the inner and outer nuclear membranes) were observed by fracturing the nuclear envelope in this plane and splaying the corresponding regions apart. Pore complexes were observed on all four membrane surfaces of this double-membraned structure. The densely packed pore complexes (55/micron2) are often clustered into triplets with shared walls (outer diameter = 90 nm; inner diameter = 25 nm; wall thickness = aproximately 30 nm), and project aproximately 20 nm above each membrane except where they are flush with the innermost surface. The pore complex appears to be an aggregate of four 30-nm subunits. The nuclear cortex, a fibrous layer (300 nm thickness) associated with the inner surface of the nuclear envelope, has been revealed by rapid fixation. This cortical layer is interrupted by funnel-shaped intranuclear channels (120-640 nm diam) which narrow towards the pore complexes. Chains of particles, arranged in spirals, are inserted into these intranuclear channels. The fibers associated with the innermost face of the nuclear envelope can be extraced with 0.6 MKI to reveal the pore complexes. A model of the nuclear surface complex, compiled from the visualization of all the membrane faces and the nuclear cortex, demonstrates relations between the intranuclear channels (3.2/micron2) and the numerous pore complexes, and the possibility of their role in nucleocytoplasmic interactions.

The nuclear fibrous lamina in human cells: studies on its appearance and distribution

The nuclear fibrous lamina, a structure of unknown function, is situated at the nuclear periphery directly apposed to the inner nuclear membrane. Although it has been well described in invertebrate and many non-human vertebrate cells, its occurrence in human tissue has not been emphasized. This survey of a large variety of human cells has documented the lamina to be present, although of varying thickness, in a large number of cell types. It is consistently thickest in mesenchymal or mesenchymally derived cells and its appearance and thickness is not correlated with pathologic alterations.

A modified procedure for the isolation of a pore complex-lamina fraction from rat liver nuclei

A modified procedure for the isolation of a nuclear pore complex-lamina fraction from rat liver nuclei is described. Evidence is provided that the isolated lamina, a 150-A thick, proteinaceous structure, apposes the inner nuclear envelope membrane, connecting nuclear pore complexes and surrounding the entire nucleus.

Experimental disintegration of the nuclear envelope. Evidence for pore-connecting fibrils

The disintegration of the nuclear envelope has been examined in nuclei and nuclear envelopes isolated from amphibian oocytes from amphibian oocytes and rat liver tissue, using different electron microscope techniques (ultrathin sections and negatively or positively stained spread preparations). Various treatments were studied, including disruption by surface tension forces, very low salt concentrations, and nonionic detergents such as Triton C-100 and Nonidet P-40. The highest local stability of the cylinders of nonmembranous pore complex material is emphasized. As progressive disintegration occurred in the membrane regions, a network of fibrils became apparent which interconnects the pore complexes and is distinguished from the pore complex-associated about 15-20 nm thick, located at the level of the inner nuclear membrane, which is recognized in thin sections to bridge the interpore distances. With all disintegraiton treatments a somewhat higher susceptibility of the outer nuclear membrane is notable, but a selective removal does not take place. Final stages of disintegration are generally characterized by the absence of identifiable, membrane-like structures. Analysis of detergent-treated nuclei and nuclear membrane fractions shows almost complete absence of lipid components but retention bo significant amount of glycoproteins with a typical endomembrane-type carbohydrate pattern. Various alternative interpretations of these observations are discussed. From the present observations and those of Aaronson and Blobel (1,2), we favor the notion that threadlike intrinsic membrane components are stabilized by their attachment to the pore complexes, and perhaps also to peripheral nuclear structures,and constitute a detergent-resistant, interpore skeleton meshwork.

Microsurgical lumbosacral ganglionectomy, anatomic rationale, and surgical results

Recent anatomic and physiologic work suggests that there may be substantial numbers of unmyelinated sensory axons in the ventral roots. The cell bodies of origin for these unmyelinated axons would presumably be located in the dorsal ganglion. We have performed 18 microsurgical lumbosacral ganglionectomies over the past two years for chronic lumbosacral pain syndromes. In spite of preoperative nerve block trials, good results were obtained in only 10 of 18 patients. Four patients obtained some pain relief, and four patients no pain relief whatsoever. Microganglionectomy in the lumbosacral area is probably easier technically than the more traditional intradural rhizotomy, but may not yield any better results.

[The ultrastructure of fibrous and histiocytic skin tumors (dermatofibroma, dermatofibrosarcoma protuberans, fibroxanthoma, and histiocytoma) (author's transl)]

A report on the ultrastructure of the following skin tumors: dermatofibroma (7 cases), histiocytoma (4 cases), dermatofibrosarcoma protuberans (1 case), and fibroxanthoma (1 case). Because of their different ultrastructural characteristics a division into two groups is possible: one group of tumors would include dermatofibroma, dermatofibrosarcoma protuberans, and fibroxanthoma, where the formation of fibers is extensive and fibroblasts are suggested for its histogenesis. These types of tumor differ from histiocytoma, the cellular character of which is determined by a very pronounced phagocytosis and storage of lipid and hemosiderin; a histogenesis from histiocytes is probable. The nuclei of dermatofibroma and histiocytoma show a simple surfacedevelopment, whereas the nuclei of dermatofibrosarcoma protuberans and fibroxanthoma show multisegmented nuclei ("labyrinth nuclei"). In the case of dermatofibrosarcoma protuberans this kind of nuclear segmentation seems to be a morphologic correlate of its semimalignancy. Based on ultrastructural analysis a classification of these fiber-producing tumors into "fibrous histiocytomas" is not justified.

Amoeba proteus: the nuclear periphery

This study extends previous work on the nuclear envelope and associated structures. It illustrates that the cylindrical structures of the honeycomb lattice are not attached to the nuclear envelope, although generally perpendicular and closely apposed to it, and that there is a complex arrangement of fibrillar material between the cylinders of the lattice. The relationship of nuclear helices to these structures is described and the possible mode of their transfer from nucleus to cytoplasm is discussed.

Isolation of nuclear pore complexes in association with a lamina

Nuclear pore complexes have been isolated in association with a 150 A thick lamina by detergent and salt fractionation of nuclear envelopes from rat liver. The pore complexes exhibit characteristic morphology and appear to be attached in a highly specific orientation to the lamina, which extends over relatively large areas. The pore complex-lamina fraction is composed of three major and several minor polypeptides with little or no DNA, RNA, or phospholipid. It is suggested that the association of the pore complexes and the lamina reflects the structural arrangement of the nuclear periphery in vivo.

On the attachment of the nuclear pore complex

Electron microscope examination of isolated rat liver nuclei after treatment with the detergent Triton X-100 revealed the complete removal of both the inner and outer membranes of the nuclear envelope. The envelope-denuded nuclei did not show any change in either shape or internal ultrastructure. Most strikingly, the nuclear pore complexes, which in untreated nuclei appear to be integral components of the nuclear envelope, were retained in their characteristic location at the distal ends of the channels leading through the peripheral heterochromatin. Determination of the chemical composition of detergent-treated nuclei showed that over 95% of the nuclear phospholipid was solubilized, thus corroborating the morphological absence of nuclear membranes. Furthermore, detergent treatment also solubilized approximately 10% of the nuclear protein. Analysis of the solubilized protein by polyacrylamide gel electrophoresis in the presence of SDS indicated that these proteins belong to a few specific classes which presumably represent the major polypeptides of the nuclear membranes. The total absence of the nuclear envelope on both morphological and biochemical grounds supports the idea that the nuclear pore complex does not require the membranes either for attachment to the nucleus or for maintenance of its own structural integrity.

Die Ei- und Embryonalentwicklung vonCorydendrium parasiticum mit besonderer Berücksichtigung der Oocyten-Feinstruktur während der Vitellogenese

1. Die Ei- und Embryonalentwicklung des HydroidenCorydendrium parasiticum (L.) wurde unter besonderer Berücksichtigung der feinstrukturellen Veränderungen der Oocyten während der Vitellogenese untersucht.

2.Corydendrium bildet als Stockform Monopodien mit Endpolypen und subterminaler Knospung. Das Perisarc beziehungsweise Periderm der Kolonie wird durch mit Toluidinblau metachromatisch anfärbbare Tröpfchen des Ektoderms gebildet; sie zeigen eine parakristalline Binnenstruktur und entsprechen den unter dem Lichtmikroskop sichtbaren, stark acidophilen Grana. In die Grundsubstanz der Mittellamelle sind Fibrillen mit periodischer Anordnung von Untereinheiten eingelagert. Perforationen in der Mittellamelle sind ein Ergebnis durchtretender Zellausläufer, die vermutlich eine Funktion beim Nahrungsaustausch besitzen.

3. Die Eizellen entstehen diffus in der Keimzone unterhalb eines Hydranthen. Ektodermale I-Zellen wandern nachweislich durch die Mittellamelle und differenzieren sich im Entoderm zu Keimzellen. Nur in diesem sind Prophase-Stadien der Meiose zu finden. Mit Berechtigung kann jedoch, trotz unterschiedlicher Herkunft der I-Zellen in der Frühentwicklung, von einer ektodermalen Abstammung der Hydroiden-Keimzellen gesprochen werden.

4. Die Eizellen wandern während der Wachstumsphase auf der Mittellamelle zur Gonophoren-Bildungszone. Die Gonophoren sind Hydranthen-Knospen homolog und vermutlich phyletisch umgewandelte Hydranthen. Frühzeitig in eine Knospenausstülpung einwandernde Oocyten legen deren Entwicklung zum Gonophor fest oder werden durch dessen morphologisch noch nicht sichtbares Blastem angelockt. Die Oocyten werden im Gonophor durch dessen Wachstum passiv mitgenommen und von einem allseitig geschlossenen Follikel-Epithel umgeben. Nach der Endphase ihres Wachstums vollziehen sie im Gonophor ihre beiden Reifeteilungen, wobei sie vorher ihr Follikel-Epithel durchbrochen haben. Die Befruchtung erfolgt entweder im Gonophor noch während des Auskriechens oder kurz danach an dessen Spitze im Freien.

5. Die feinstrukturellen Veränderungen während der Vitellogenese werden entsprechend den Entwicklungsstadien der Eizelle beschrieben. Komplexdotter, Lipidtropfen und Glykogen stehen am Ende der Vitellogenese. Zur Bildung des mengenmäßig überwiegenden Reservematerials der befruchtungsfähigen Eizelle, des Komplexdotters, werden zahlreiche Zwischenstufen geformt. Von besonderem Interesse sind dabei die Cytosomen, die auf Grund ihrer engen Beziehung zum granulären endoplasmatischen Retikulum und wegen ihrer parakristallinen Innenstruktur den „microbodies“ der Leber und Niere ähneln. In dem aus vier unterscheidbaren Komponenten bestehenden Komplexdotter sind vergleichbare parakristalline Strukturen nachweisbar, die den histochemisch im Dotter anderer Tierarten schon nachgewiesenen Enzymen entsprechen könnten. Neben einem Versuch, den Ablauf der Vitellogenese zu rekonstruieren, wird auf den Bau der Kernmembran und des Nucleolus näher eingegangen.

6. Die Furchung beginnt schon während des Ausstoßens der Eier aus dem Gonophor, an das sich diese unter Abscheidung einer Embryonalhülle festkleben. Die Furchung ist total und äqual. Die Kreuzstellung der vier ersten Blastomeren ist die Folge ihrer Verschiebbarkeit gegeneinander. Eine Furchungshöhle tritt nicht auf. Die Keimblätterbildung erfolgt als Morula-Delamination. I-Zellen und Cnidoblasten werden im prospektiven Entoderm gebildet und wandern frühzeitig in das durch eine besondere Rindenzone gekennzeichnete Ektoderm. Eine polare Differenzierung tritt erst kurz vor dem Ausschlüpfen der Planula hervor.

7. Die Planulae behalten bis zu ihrer Umwandlung in Primärpolypen ein solides Entoderm, wie es einem Sterrogastrula-Stadium entspricht. Schon nach einem Tag können sie metamorphosieren. Der bis zu 12 Tagen verzögerte Beginn der Metamorphose in Laborversuchen beruht wahrscheinlich auf der Abwesenheit bestimmter Bakterien.

Fine structural alterations of interphase nuclei of lymphocytes stimulated to grwoth activity in vitro

This report describes fine structural changes of interphase nuclei of human peripheral blood lymphocytes stimulated to growth by short-term culture with phytohemagglutinin. Chromatin is found highly labile, its changes accompanying the sequential increases of RNA and DNA synthesis which are known to occur in lymphocyte cultures. In "resting" lymphocytes, abundant condensed chromatin appears as a network of large and small aggregates. Early in the response to phytohemagglutinin, small aggregates disappear during increase of diffuse chromatin regions. Small aggregates soon reappear, probably resulting from disaggregation of large masses of condensed chromatin. Loosened and highly dispersed forms then appear prior to the formation of prophase chromosomes. The loosened state is found by radioautography to be most active in DNA synthesis. Small nucleoli of resting lymphocytes have concentric agranular, fibrillar, and granular zones with small amounts of intranucleolar chromatin. Enlarging interphase nucleoli change chiefly (1) by increase in amount of intranucleolar chromatin and alteration of its state of aggregation and (2) by increase in granular components in close association with fibrillar components.