Identification of the laminar-inducing factor: Wnt-signal from the anterior rim induces correct laminar formation of the neural retina in vitro

To study the molecular mechanism that controls the laminar organization of the retina, we utilized reaggregation cultures of dissociated retinal cells prepared from chicken embryos. These cells cannot generate laminated structures by themselves and, instead, form rosettes within the reaggregates. However, the dissociated cells can organize into a correctly laminated structure when cultured in the presence of a putative laminar inducing factor coming from particular tissue or cells, but its molecular identity of this factor has long remained elusive. In this study, we found that the anterior rim of the retina sends a signal to rearrange the rosette-forming cells into a neuroepithelial structure characteristic of the undifferentiated retinal layer. This activity of the anterior rim was mimicked by Wnt-2b expressed in this tissue, and was neutralized by a soluble form of Frizzled, which works as a Wnt antagonist. Furthermore, the neuroepithelial structure induced by Wnt-2b subsequently developed into correctly laminated retinal layers. These observations suggest that the anterior rim functions as a layer-organizing center in the retina, by producing Wnt-2b.     

解离的小鼠牙胚上皮细胞在重聚发育过程仍维持牙齿发育基因的表达

为了解牙胚细胞解离重聚过程的细胞形态和分子机制,将小鼠帽状期牙胚解离细胞重聚,移植到小鼠肾囊膜下培养,组织切片,HE染色,观察再生牙齿的形态发生过程,并用原位杂交的方法进一步检测了与牙上皮发育密切相关的基因在再生牙上皮中的表达情况。结果发现,解离重聚的牙胚细胞在牙齿器官的再生过程重现了正常牙齿的形态发生过程;解离的牙上皮细胞在重聚和再生过程中保持Fgf8、Noggin和Shh等牙上皮发育基因表达。以上结果表明,即便是被解离形成分散状态的牙上皮细胞,在与牙胚间充质细胞重新聚合后,仍保持牙向分化的潜能。该结果为理解牙齿再生的机理提供新的实验数据,对利用干细胞进行牙齿再生的研究有重要的提示意义。     

Difference between dorsal and ventral iris in lens producing potency in normal lens regeneration is maintained after dissociation and reaggregation of cells from the adult newt, Cynops pyrrhogaster

In Wolffian lens regeneration, lentectomized newt eye can produce a new lens from the dorsal marginal iris, but the ventral iris has never shown such capabilities. To investigate the difference of lens regenerating potency between dorsal and ventral iris epithelium at the cellular level, a transplantation system using cell reaggregates was developed. Two methods were devised for preparing the reaggregates from pigmented iris epithelial cells. One was rotating cells in an agar-coated multiplate on a gyratory shaker and the other was incubating cells in a microcentrifuge tube after slight centrifugation. Reaggregates made of dorsal iris cells that had been completely dissociated into single cells were phenotypically transformed into a lens when placed in the pupillary region of the lentectomized host eye. None of the ventral reaggregates produced a lens. Even dorsal reaggregates could not transdifferentiate into lens when they were placed away from the pupil. The produced lenses from the reaggregates were morphologically and immunohistochemically identified. To obtain evidence whether produced lenses really originated from singly dissociated cells, we labeled dissociated cells with a fluorescent dye (PKH26) before reaggregate formation and then traced it in the produced lens.     

The role of polarity in the development of the hydrozoan planula larva

Summary These experiments were done in order to define the role that polarity plays during embryogenesis in hydrozoans.Parts of hydrozoan embryos isolated at different developmental stages from early cleavage to postgastrula will regulate to form normal planulae. During this process, the original anterior-posterior axis of the part is conserved. In normal embryos the posterior pole of the anterior-posterior axis is congruent with the site where the polar bodies are given off and with the site where the first cleavage is initiated. By centrifuging fertilized eggs, it is possible to create embryos in which the first cleavage initiation site does not correspond to the site where the polar bodies are given off. In these embryos the posterior pole of the anterior-posterior axis corresponds to the first cleavage initiation site. When parts of these embryos are isolated at different stages they also regulate to form normal planulae. The axial properties of these planulae are determined by the site of first cleavage initiation.The interactions between regions of the embryo with different axial properties were studied by grafting together parts in such a way as to create embryos with abnormal axial arrangements. Following gastrulation interactions take place between the grafted parts leading to the formation of normal planulae with a new set of axial properties.Blastula stage embryos can be dissociated into single cells and the cells can be reaggregated. These reaggregates form normal planulae. Polarity can be entrained in the reaggregates by grafting a small piece of tissue from any part of an intact blastula to the reaggregate. These cells organize the formation of an axis of symmetry with an appropriate orientation with respect to the graft.     

Dissociation and reaggregation of cells of Chrysaora quinquecirrha (Cnidaria, Scyphozoa)

Cells of scyphistomae, strobilae, and ephyrae were dissociated with trypsin and reaggregated. Clumping was inhibited in low Ca++ and by puromycin, but not by collagenase or sugars. Reaggregates from the oral end of the polyp developed tentacles and mouths first and basal structures later, whereas the opposite sequence occurred with cells from the lower gastric region. Nile-blue-stained cells from hypostome or peduncle did not form specific structures in the reconstructed polyp, but were distributed throughout the animal. Ephyra cell aggregates showed little morphogenesis, whereas cells from presumptive ephyra tissue gave rise to structures with tentacles and multiple oral openings. Mixed reaggregates containing equal proportions of polyp and ephyra cells formed irregular structures with transparent outer layer and opaque inner cell mass, suggesting stage-specific sorting.     

In vitro peptidergic neurons from the adult locust pars intercerebralis: Morphological and immunocytological studies

Primary cell cultures were prepared from a major neurosecretory center of the adult locust brain, the pars intercerebralis, in order to characterize neurosecretory cells growingin vitro. Individual pars intercerebralis could be removed free of surrounding tissue and dissociated by mechanical treatment. Mature neurosecretory neurons of different sizes regenerate new neurites during the initial three daysin vitro in serum-free medium. They show a tendency to sprout one primary neurite from which fine processes develop. By means of electron microscopy, we observed the integrity of the cellular organelles, indicating that cultured neurons are healthy, and we were able to distinguish three types of neurosecretory neurons on the basis of the ultrastructural aspects of the neurosecretory material. These three types have the same ultrastructural characteristics asin situ neuroparsin, ovary maturing parsin and locust insulin related peptide neurons. Immunogold labelling at the electron microscopic level, using the two available specific antibodies, anti-neuroparsin and anti-ovary maturing parsin, confirms the morphological characterization of neuroparsin and ovary maturing parsin cells. These results show for the first time that cultured locust neurosecretory neurons behave like thosein vivo, in terms of their ultrastructure and immunocytochemistry. Moreover, the presence of recently-formed neurosecretory material both in the Golgi zone of the perikaryon and in the neuronal processes indicates that cultured neurons have functional capacity since they are able to synthesizede novo and to transport the neurosecretory material along the neurite. Thus our well-characterized culture system provides a suitable invitro model to investigate the secretory mechanism of locust neurosecretory neurons.     

Analysis of pattern formation during embryonic development of Hydractinia echinata

Summary Patterning processes during embryonic development of Hydractinia echinata were analysed for alterations in morphology and physiology as well as for changes at the cellular level by means of treatment with proportioning altering factor (PAF). PAF is an endogenous factor known to change body proportions and to stimulate nerve cell differentiation in hydroids (Plickert 1987, 1989). Applied during early embryogenesis, this factor interferes with the proper establishment of polarity in the embryo. Instead of normal shaped planulae with one single anterior and one single posterior end, larvae with multiple termini develop. Preferentially, supernumerary posterior ends, which give rise to polyp head structures during metamorphosis, form while anterior ends are reduced. The formation of such polycaudal larvae coincide with an increase in the number of interstitial cells and their derivatives at the expense of epithelial cells. Treatment of further advanced embryonic stages causes an increase in length, presumably due to the general stimulation of cell proliferation observed in such embryos. Also, the spatial arrangement of cells (i.e. cells in proliferation and RFamide (Arg-Phe-amide immunopositive nerve cells) is altered by PAF. Larvae that develop from treated embryos display altered physiological properties and are remarkably different from normal planulae with respect to their morphogenetic potential: (1) Larvae lose their capacity to regenerate missing anterior parts; isolated posterior larva fragments form regenerates of a bicaudal phenotype. (2) In accordance with the frequently observed reduction of anterior structures, the capacity to respond to metamorphosis-inducing stimuli decreases. (3) The morphogenetic potential to form basal polyp parts is found to be reduced. In contrast, the potential to form head structures during metamorphosis increases, since primary polyps with supernumerary hypostomes and tentacles metamorphose from treated animals.     

Regeneration in Hydrozoa: distal versus proximal transformation in Hydractinia

Summary Polyps of mature colonies of Hydractinia echinata obey the rule of distal transformation by regenerating heads but not stolons. However, this rule is not valid for young polyps as these regenerate stolons from proximal cut ends. Also, small cell aggregates and even small fragments excised from full-grown polyps are capable of stolon formation. Aggregates produced from dissociated cells undergo either distal or proximal transformation depending on their size, speed of head regeneration in the donor used for dissociation and the positional derivation of the cells. The latent capability of stolon formation is released under conditions that cause loss of morphogens and depletion of their sources. However, internal regulative processes can also lead to gradual proximal transformation: regenerating segments of polyps sometimes form heads at both ends and the distal pattern is duplicated. Subsequently, all sets of proximal structures, including stolons, are intercalated. In contrast to distal transformation, proximal transformation is a process the velocity of which declines with the age and size of the cell community.     

An ultrastructural study of adhesive junctions in reaggregates of unincubated chick embryos.

Cell suspensions obtained by the dissociation of unincubated chick embryo blastoderms were allowed to reaggregate on a gyratory shaker for 24-48 hours. The reaggregates which form during this period consist of an inner phase of tightly packed cohesive cells surrounded by an external phase of loosely packed cells. This sorted out arrangement achieves its definitive form between 24 and 48 hours of rotation culture. It was determined that the external phase consists of primitive ectoderm and that the internal phase consists of primitive endoderm. Both 24- and 48-hour reaggregates were examined in the electron microscope and observations were directed to areas of close membrane apposition between cells. In 48-hour reaggregates, primitive endoderm cells were joined by many specialized junctions (desmosomes). The formation of desmosomes in reaggregates of dissociated unincubated chick embryo cells was correlated with the sorting out process.     

Differences in growth of neurons from normal and regenerated teleost spinal cord in vitro

Summary Explants and dissociated cells from normal adult spinal cord and regenerating cord of the teleostApteronotus albifrons were grown in vitro for periods of 8 to 12 wk. During this time the neurons showed extensive neurite outgrowth. Neurite outgrowth from tissue explants and dissociated cells of regenerated spinal cord starts sooner and is more profuse than that from normal (unregenerated) cord. Neurite outgrowth is maximized by using adhesive substrata and a high density of explants or dissociated cells. Inasmuch asApteronotus does regenerate its spinal cord naturally after injury, whereas mammals do not, this culture system will be useful to study factors that control (permit) regeneration of spinal neurons in this adult vertebrate.     

Development of a new coulter counter system: Measurement of the volume,internal conductivity,and dielectric breakdown voltage of a single guard cell protoplast ofVicia faba

Summary Two intracellular microelectrodes were used to study electrotonic interaction between cultured embryonic (16- to 20-day-old) chick myocardial cells reaggregated into small spheresin vitro. Under different culture conditions, reaggregates with two types of functional membrane properties were produced: (i) highly differentiated reaggregates, and (ii) reverted reaggregates. In the highly differentiated state, the cells had high stable resting potentials and produced rapidly-rising tetrodotoxin (TTX)-sensitive action potentials in response to electric field stimulation. In the reverted state, the cells exhibited slowrising spontaneous action potentials having prominent pacemaker potentials and TTX-insensitive upstrokes. These states resemble electrophysiological properties of the highly differentiated (18 daysin ovo) and less fully differentiated (3 daysin ovo) intact embryonic chick heart, respectively. Both types of reaggregates had similar ultrastructural appearance, with many elongated cells and intercalated disc-like structures; gap-like junctions were not seen. The highly differentiated cells had input resistances of about 5 M, and exhibited only little electrotonic interaction in response to intracellular current injection either when the cells were at rest or during the action potential plateau. Intracellular stimulation produced propagating action potentials which triggered contraction of the entire reaggregate. Large hyperpolarizing current pulses applied during the action potential plateau caused premature repolarization which also propagated to the other impaled cell. In the reverted reaggregates, electrotonic interaction was weak or absent in about 52% of the impaled cell pairs, moderate in 30%, and strong in 18% (encountered only at interelectrode distances of less than 100 m). The difference in degree of electrotonic interaction may be due to the state of differentiation with respect to the membrane electrical properties.     

Selection of tomato tissue cultures able to grow on ribose as the sole carbon source

When tomato (Lycopersicon esculentum Mill.) callus or cell cultures were placed on media containing ribose as the sole carbon source, the tissues turned dark brown and ceased growth. However, after approximately 60 days bright green tissue able to grow on ribose emerged from 3 % of the brown necrotic callus tissue pieces plated. The selected tissue was highly organized, consisting of leafy primordia and associated meristematic tissues, sustained growth on ribose, and demonstrated the capacity to regenerate whole plants for at least 3 years. Cultures able to grow on ribose could not be selected from liquid suspension cultured tomato cells or from callus which had been mechanically macerated into cell aggregates containing less than approximately 100 cells. Plants regenerated from ribose adapted cultures were abnormal, having shortened internodes and thicker greener leaves. Regenerated plants were both male and female sterile.Abbreviations BAP N⁶-benzylaminopurine - CFM callusforming medium - IAA indole acetic acid - SDM shoot determination medium - RCM ribose containing medium     

Maintenance of determination by cells of imaginal discs ofDrosophila after dissociation and culture in vivo

Summary Wild type cells of imaginal wing discs or embryos were dissociated and mixed in different proportions with cells of genetically marked wing and/or leg discs. These latter were X-irradiated to such an extent that their rate of proliferation was drastically lowered. They served as a feeding layer in which the interspersed wild type cells could be cultured. The reaggregates were allowed to grow in vivo, and fragments of them were tested for recovery of imaginal structures formed by wild-type cells.The experimental conditions for maximal dilution and maximal recovery of wildtype cells were first analysed. Under these conditions the progeny of cells deriving from different fragments of mature wing discs are capable of forming large territories of cuticle. These consisted preferentially of structures located in the region from which their ancestral cells were derived. The proliferating cells remained confined to either the anterior or the posterior wing compartments, but were apparently able to transgress the dorsalventral compartment border. Cells with qualities for distinct imaginal discs and possibly regions could also be recovered from dissociated embryos of 7 h age. The efficiency with which imaginal structures could be recovered as well at the types or qualities of these structures did not depend on the histotype of the feeding layer.     

Microbiology in the 1990s: reflections about open questions and trends

The optimal conditions for protoplast formation ofCandida apicola were by using an enzyme fromArthrobacter sp. in combination with 2-mercaptoethanol. The kinetic data support the two-layered structure model of cell wall for this yeast but the structure of the cell wall depended on the age of cells and culture conditions. To regenerate the protoplasts, the type of osmotic stabilizer was important: sorbitol gave 16 to 30% regeneration. Electron microscopy revealed the presence of vesicles in the sections of protoplasts and whole cells ofCandida apicola grown in production medium and producing glycolipids. In sections of whole cells, vesicle-like structures are located in the periplasmic space and in protoplasts they can either be attached to, or released from, the cell surface. These vesicles are thought to be involved in the transport of the surface-active glycolipids and in the protection of the cell against denaturing effects.     

Regulated lens regeneration from isolated pigmented epithelial cells of newt iris in culture in response to FGF2/4

When a lens is removed from the newt eye, a new lens is regenerated from the pigmented epithelial cells of the dorsal iris, whereas the ventral iris never shows such an ability. It is important to clarify the nature of signaling molecules which act directly on the iris cells to accomplish lens regeneration from the iris and also to gain insight into the mechanism of dorso-ventral difference of the regeneration potential. To examine the effects of exogenous factors, we established an in vitro culture of reaggregates made from dissociated pigmented epithelial cells of dorsal or ventral halves of newt iris. Foci of depigmented cells appeared within the cell reaggregates, regardless of their origins, when the cell reaggregates were cultured with FGF2 or FGF4. In contrast, only the depigmented cells in the dorsal iris cell reaggregates underwent extensive proliferation and developed a lens with the synthesis of lens-specific crystallins, recapitulating the normal lens regeneration. On the other hand, neither FGF8, FGF10, EGF, VEGF, nor IGF promoted lens development from iris cell reaggregates. Consistent with the FGF-specific action, FGFR-specific inhibitor SU5402 suppressed the lens development from the cultured cell reaggregates. These results demonstrated that FGF2 or FGF4 is essential for the in vitro lens regeneration from the pigmented cells of the dorsal iris. In addition, these findings indicated that unequal competence in the dorsal and ventral iris to FGF2/4 contributes to the difference in lens forming ability between them.     

IN VITRO AGGREGATION OF MIXED EMBRYONIC KIDNEY AND NERVE CELLS : Influence on Macromolecular Synthesis

The possible role of nerve on growth of embryonic parenchymal organs such as kidney was explored by measuring macromolecular synthesis (DNA, RNA, and protein and three enzymes) in aggregates of mixed suspensions of cells from dissociated chick embryo kidney and nerve tissue. One and one-half to threefold increments in net synthesis of the three different types of macromolecules were observed in the mixed aggregates of kidney and nerve cells as compared with those of single organs or mixtures of kidney with nonneural cells. The addition of nerve-growth factor (NGF) did not significantly affect the results. Increased incorporation of label was paralleled by increases in chemically measured DNA and protein, suggesting an increase in growth in the mixed kidney-nerve aggregates compared with those of single tissues. Measurements of survival rate did not indicate increased cell stability in the mixed aggregates. The activities of three enzymes, acid phosphatase, alkaline phosphatase, and lactic dehydrogenase, were also enhanced two to four times in cultures of kidney plus nerve cells. Morphologic studies indicated a high degree of reorganization of tubular structures within the reaggregates of kidney cells alone or in those mixed with nerve. In addition, radioautographs of thymidine-³H-labeled cells in the aggregates showed a high level of DNA synthesis in the reformed tubular cells. Electron micrographs revealed the presence of large numbers of nerve fibers containing microtubules in the mixed cell aggregates. The data suggest a significant role for nerve in the growth processes of embryonic parenchymal organs.     

A study of cell interactions involved in Pleurodeles waltlii epidermal differentiation

Summary A polyclonal antibody (SP-2) has been produced, which recognizes antigens expressed in epidermal cells of Pleurodeles waltlii embryos. The antigens appear first at the end of gastrulation in the external surface of the embryo and are selectively expressed in ectodermally derived epidermal structures. Ectodermal commitment was investigated using cell cultures and blastocoel graft experiments. The four animal blastomeres of the 8-cell stage as well as the animal cap explants of the early gastrula stage cultured in vitro differentiate into epidermis, and SP-2 antigens are expressed. The expression of SP-2-defined antigens is inhibited both in vivo and in vitro by the inductive interaction of chordomesoderm. Once dissociated, ectodermal cells do not react with SP-2. Conversely, the aggregation of ectodermal cells may restore the expression of SP-2 antigens. Transplantation of animal cap explants or isolated ectodermal cells into the blastocoel of a host embryo at the early gastrula stage shows that only cells integrated into the epidermis express the marker antigens. When vegetal cells were dissociated from donor embryos before the mid-blastula stage and implanted into the blastocoel of host embryos at the early gastrula stage, their progeny were found in all germ layers, cells that were found in the host epidermis were stained with SP-2, whereas those contributing to mesoderm and endoderm were not. Thus the acquisition of cell polarity in epidermal differentiation and the organization of cells into epithelial structures are essential for SP-2-defined antigen expression.     

Electron-microscopic studies on reaggregate cultures of vascular smooth muscle cells from normotensive and spontaneously hypertensive rats

Summary Vascular smooth muscle cells were taken from the aortae of the WKY (normotensive) and SHR (spontaneously hypertensive) strains of rat by enzymatic dispersion and put into reaggregate culture. Initially the cells became individual spheroids having average diameters of 10 m and surfaces that were either rough or smooth. The cells were far more complex than they appeared on their surfaces; after one day in culture, there was considerable internal variation in these cells. All the cells, whether WKY or SHR, lost the bulk of their cytoplasmic contents (including myofilaments, many mitochondria, and vesicular structures) in the early stages of culture and eventually became flattened. After 14 days in culture, these modified cells collected to form reaggregates that were commonly roughly spherical and several hundred m in diameter. These reaggregates consisted of peripheral regions made up of several layers of flattened cells overlying cores formed by glia-like networks of cells similar in cytological appearance to the cells at the periphery. The meshes formed in this way contained cellular debris derived from dead cells or extrusion of cellular contents. It appears that SHR cells are quicker to form reaggregates than are WKY cells. Yet the SHR cells retained a rounded conformation after five days, whereas the WKY cells were more flattened and formed a more discrete aggregate at this stage of culture. However, by the fourteenth day of culture, differences between the two cell strains were not so pronounced, as far as could be judged by observations made with scanning and transmission electron microscopy. Both WKY and SHR cells at 14 days appeared highly secretory, possessing large Golgi systems as well as numerous ER cisternae and mitochondria. SHR cells produced greater amounts of connective tissue at all stages of culture than did WKY cells, indicating that a similar difference may contribute to the hypertension which develops naturally in situ in SHR animals.     

Compartments and distal outgrowth in theDrosophila imaginal wing disc

Summary Peripheral tissue of the imaginal wing disc gives rise to the proximal mesothoracic structures of the adult. Pieces of peripheral tissue, which have no regenerative capacity when cultured as intact fragments, are capable of distal outgrowth (regeneration) after dissociation and reaggregation. This ability depends on the region of the disc periphery from which the fragment is taken. Extensive distal outgrowth occurs in reaggreages of a fragment containing equal proportions of tissue from anterior and posterior developmental compartments. The extent of outgrowth decreases as the proportion of posterior tissue is reduced, so that a fragment containing only anterior tissue shows no regeneration after dissociation. Limited distal outgrowth occurs in reaggregates of a wholly posterior fragment, but the regenerative capacity is increased greatly when a small amount of anterior tissue is included. It is concluded that distal outgrowth in the wing disc requires an interaction between cells of the anterior and posterior compartments.     

Brain reaggregate cultures: Biochemical evidence for myelin membrane synthesis

Myelin membrane synthesis was studied using mechanically dissociated fetal rodent CNS which formed spherical reaggregates while being maintained in rotating culture flasks. These reaggregate cultures exhibited myelinogenesis in vitro after precisely the same period of time needed for myelin synthesis to commence in vivo. The myelin membrane related enzymes, 2′,3′ cyclic nucleotide phosphohydrolase (CNP) and cerebroside sulfotransferase (CST), appear similar in their specific activities and follow the same developmental patterns that these enzymes exhibit in vivo. In addition, phosphorylation of myelin basic protein occurs by the third week in vitro which agrees with previously published in vivo studies. These experiments indicate that this nerve-cell culture system may be an appropriate model for studying the biological regulation of myelinogenesis as well as a variety of other nervous-system functions.