The influence of tissue polarity on nematocyte migration in Hydra attenuata

Influences underlying the direction of nematocyte migration in hydra were studied. Nematocytes arise by interstitial cell differentiation in the body column, and then up to 80% migrate into the ectodermal epithelial cells of the tentacles. The migration of these cells, which is clearly apically directed, may be due either to a chemotactic attraction into the hypostome and tentacles, or to a property inherent in the tissue of the body column, such as the regeneration polarity. To distinguish between these two possibilities, the rates of accumulation of ³H-proline-labeled desmoneme and stenotele nematocytes in unlabeled heads (hypostome and tentacles) grafted either basally or apically to the labeled body column were compared. Basally grafted heads, if left in place for an appropriate length of time, reversed the regeneration polarity of the tissue. In all experiments the direction of desmoneme migration was correlated with the direction (apical or basal) of the regeneration polarity of the tissue. Further, the kinetics of polarity reversal were modified by varying the grafting procedure or the environmental conditions. In every case the kinetics of reversal of desmoneme migration also paralleled the kinetics of reversal of tissue polarity. The results suggest that the direction of desmoneme migration is influenced by the regeneration polarity of the tissue. Stenotele migration was largely unaffected by tissue polarity, but behaved as though chemotactically attracted to the head.     

Cell sorting during the regeneration of Hydra from reaggregated cells.

The role of cell sorting in the reorganization of Hydra cell reaggregates was studied. We quantitatively labeled ectodermal and endodermal cells by incubating whole animals in fluorescent beads or by injecting the beads into the gastric cavity. Beads were stably incorporated into the cells by phagocytosis. Our data show that dramatic cell sorting processes drive the formation of ectoderm and endoderm within the first 12 hr of reaggregation. After the ectoderm is established, no further rearrangement could be observed. We also tested the ability of cells to sort out with respect to their original position in Hydra by dissociating labeled apical and basal pieces of Hydra and measuring the clumping of labeled cells during reorganization. There was no increase in the clumping of cells during reorganization indicating that cell sorting is not involved in the formation of early activation centers. There was also no preferential incorporation of apically derived (presumptive head) tissue into tentacles that subsequently formed, indicating that after dissociation into single cells there is no predisposition of erstwhile presumptive head tissue to form heads.     

Plasticity in the nervous system of adult hydra. II. Conversion of ganglion cells of the body column into epidermal sensory cells of the hypostome

Due to the tissue dynamics of hydra, every neuron is constantly changing its location within the animal. At the same time specific subsets of neurons defined by morphological or immunological criteria maintain their particular spatial distributions, suggesting that neurons switch their phenotype as they change their location. A position-dependent switch in neuropeptide expression has been demonstrated. The possibility that ganglion cells of the body column are converted into epidermal sensory cells of the head was examined using a monoclonal antibody, TS33, whose binding is restricted to a subset of epidermal sensory cells of the hypostome, the apical end of the head. When animals devoid of interstitial cells, which are the nerve cell precursors, were decapitated and allowed to regenerate, they formed TS33+ epidermal sensory cells. As this latter cell type is not found in the body column, and the interstitial cell-free animals contained only epithelial cells and ganglion cells in the part of the ectoderm that formed the head during regeneration, the TS33+ epidermal sensory cells most likely arose from the TS33- ganglion cells. The observation of epidermal sensory cells labeled with both TS33 and TS26, a monoclonal antibody that binds to ganglion cells, in regenerating and normal heads provides further support. The double-labeled cells are probably in transition from a ganglion cell to an epidermal sensory cell. These results provide a second example of position-dependent changes in neuron phenotype, and suggest that the differentiated state of a neuron in hydra is only metastable with regard to phenotype.     

Role of interstitial cell migration in generating position-dependent patterns of nerve cell differentiation in Hydra

The role of interstitial cell migration in the formation of newly differentiated nerve cells was examined during head regeneration in Hydra magnipapillata. When distal tissue was removed from the body of a wild-type strain (105), nerve cell differentiation occurred at a rapid rate during the first 48 hr of regeneration, slowing after this point. Rapid nerve cell differentiation was due primarily to migration of interstitial cells, some of which appeared to be nerve cell precursors, into the regenerating head. The migration decreased considerably after the first 48 hr of regeneration. In reg-16, a mutant strain deficient in head regeneration, no migration of interstitial cells and hence no new nerve cell differentiation were observed in the regenerating tip. However, the interstitial cells of reg-16 were observed to migrate into regenerating tissue of strain 105. These observations suggest that the migration of nerve cell precursors plays an important role when the new nerve net is being established during head regeneration.     

Oriented migration of interstitial cells and nematocytes inHydra attenuata

Summary The migratory properties of hydra cells within the tissue were studied. The extent and direction of cell migration were examined in budding, non-budding, and regenerating animals. Nematocytes and a small number of single big interstitial cells (the multipotent interstitial cells) actively migrate preferentially in an apical direction. Basal migration of these cells occurs only when a bud is present and, in which case, the cells migrate into the developing bud. The regeneration of the hypostome and tentacles does not affect cell migration in either direction, except for apical migration of stenotele nematocytes, which was markedly reduced.This research was supported by National Science Foundation Grant (GB 29284), National Institute of Health Grant (HD 08086-01), and N.I.H. Public Health Service Training Grant (HD 00347).     

Commitment of hydra interstitial cells to nerve cell differentiation occurs by late S-phase

Nerve cells in hydra differentiate from the interstitial cell, a multipotent stem cell. Decapitation elicits a sharp increase in the fraction of the interstitial cells committed to nerve cell differentiation in the tissue which forms the new head. To investigate when during the cell cycle nerve cell commitment can be stimulated, hydra were pulse-labeled with [³H]thymidine at times from 18 hr before to 15 hr following decapitation; the resulting cohorts of labeled interstitial cells were in the various phases of the cell cycle at the time of decapitation. Increased commitment to nerve cell differentiation within a single cell cycle (≈24 hr) was observed in those cohorts which were at least 6 hr before the end of S-phase (12 hr) at the time of decapitation. The lag time required for decapitation to produce an effective stimulus for nerve cell differentiation was measured by transplanting the stem cells from the regenerating tissue to a neutral environment. Following decapitation, 3 to 6 hr were required for increased nerve cell commitment to be stable to such transplantation. These results suggest that interstitial cells must be stimulated by late S-phase to become committed to undergo nerve cell differentiation following the subsequent mitosis. However, when head regeneration was reversed by grafting a new head onto the regenerating surface, nerve cell differentiation by such committed stem cells was greatly reduced. This indicates that an appropriate tissue environment is required for committed interstitial cells to complete the nerve cell differentiation pathway.     

Patterning of the head in hydra as visualized by a monoclonal antibody: III. The dynamics of head regeneration

The dynamics of the early patterning processes leading to the regeneration of a head in tissue excised from the body column of Hydra oligactis were examined by using a monoclonal antibody, CP8. This antibody displays position-specific binding, labeling the head ectodermal epithelial cells. During regeneration of a head, antibody labeling is present well before morphological signs of the head, at a time correlated with the determination of the tissue (Javois et al., Dev. Biol., 117:607-618, '86). By quantifying antibody labeling during regeneration of three different pieces of tissue excised from the body column, it was found that the dynamics of the early patterning processes as visualized by CP8 labeling varied. The pattern of labeling observed as well as the spread of labeled tissue suggested that the amount and geometry of apical tissue in the regenerate played a critical role in the patterning processes. Contrary to the labeling pattern observed in heads which formed during bud development or which regenerated following decapitation (Javois et al., '86), not all the CP8+ tissue was confined to the head structures in these regenerates. Several alternative explanations for this surprising result are presented. The usefulness of these data in refining pattern formation models by more explicitly constraining their parameters is discussed.     

Transplantation stimulates interstitial cell migration in hydra

Migration of interstitial cells and nerve cell precursors was analyzed in Hydra magnipapillata and Hydra vulgaris (formerly Hydra attenuata). Axial grafts were made between [3H]thymidine-labeled donor and unlabeled host tissue. Migration of labeled cells into the unlabeled half was followed for 4 days. The results indicate that the rate of migration was initially high and then slowed on Days 2-4. Regrafting fresh donor tissue on Days 2-4 maintained high levels of migration. Thus, migration appears to be stimulated by the grafting procedure itself.     

Growth regulation of the interstitial cell population in hydra : I. Evidence for global control by nerve cells in the head

The interstitial cells of hydra form a multipotent stem cell system, producing terminally differentiated nerve cells and nematocytes during asexual growth. Under well-fed conditions the interstitial cell population doubles in size every 4 days. We have investigated the possible role of nerve cells in regulating this behavior. Nerve cells are normally found in highest concentrations in the head region of hydra, while interstitial cells are primarily located in the body column. Our experimental approach was to construct, by grafting, animals in which the density of nerve cells varied in (1) the head region, or (2) the body column. The growth of the interstitial cell population was then measured in these hydra. The results indicate that differences in head nerve cell density are closely correlated with how fast the interstitial cell population increases in size. Variations in the level of either nerve cells or interstitial cells in the body column showed no such correlation. These findings suggest the existence of a signaling mechanism in the head region. This signal, which is a function of the density of head nerve cells, emanates from the head tissue and exerts global control on the growth of the interstitial cell population in the body column.     

Patterning in hydra cell aggregates without the sorting of cells from different axial origins.

Aggregates of Hydra cells were studied to find out how the primary centers that form new heads are generated in a system of cells in which the original pattern has been destroyed. Since cells that originate near the heads (apical cells) temporarily maintain a high level of head activation potential during aggregate formation and may contribute to pattern formation, their distribution in the aggregates was investigated. The mutual distances between labeled epithelial cells were followed by vitally staining apical cells with DAPI. The distribution was random during early regeneration stages (3, 6, 24 hr). These results show that epithelial cells originating from apical regions do not sort. That is, dynamic cell movement to generate rudiments of new heads is not necessary for head formation in aggregates. A possible explanation of the mechanism is discussed.     

Characterization of the head organizer in hydra

A central process in the maintenance of axial patterning in the adult hydra is the head activation gradient, i.e. the potential to form a secondary axis, which is maximal in the head and is graded down the body column. Earlier evidence suggested that this gradient was based on a single parameter. Using transplantation experiments, we provide evidence that the hypostome, the apical part of the head, has the characteristics of an organizer in that it has the capacity to induce host tissue to form most of the second axis. By contrast, tissue of the body column has a self-organizing capacity, but not an inductive capacity. That the inductive capacity is confined to the hypostome is supported by experiments involving a hypostome-contact graft. The hypostome, but not the body column, transmits a signal(s) leading to the formation of a second axis. In addition, variations of the transplantation grafts and hypostome-contact grafts provide evidence for several characteristics of the organizer. The inductive capacity of the head and the self-organizing capacity of the body column are based on different pathways. Head inhibition, yya signal produced in the head and transmitted to the body column to prevent head formation, represses the effect of the inducing signal by interfering with formation of the hypostome/organizer. These results indicate that the organizer characteristics of the hypostome of an adult hydra are similar to those of the organizer region of vertebrate embryos. They also indicate that the Gierer-Meinhardt model provides a reasonable framework for the mechanisms that underlie the organizer and its activities. In addition, the results suggest that a region of an embryo or adult with the characteristics of an organizer arose early in metazoan evolution.     

Cytoplasmic dynein and dynactin as likely candidates for microtubule-dependent apical targeting of pancreatic zymogen granules.

The critical role of microtubules in vectorial delivery of post-Golgi carrier vesicles to the apical cell surface has been established for various polarized epithelial cell types. In the present study we used secretory granules of the rat and chicken pancreas, termed zymogen granules, as model system for apically bound post-Golgi carrier vesicles that underlie the regulated exocytotic pathway. We found that targeting of zymogen granules to the apical cell surface requires an intact microtubule system which contains its colchicine-resistant organizing center and, thus, the microtubular minus ends close to the apical membrane domain. Purified zymogen granules and their membranes were found to be associated with cytoplasmic dynein intermediate and heavy chain and to contain the major components of the dynein activator complex, dynactin, i.e. p150Glued, p62, p50, Arp1, and beta-actin. Kinesin heavy chain and the kinesin receptor, 160 kD kinectin, were not detected as components of zymogen granules. Immunofluorescence staining showed a zymogen granule-like distribution for dynein and dynactin (p150Glued, p62, p50, Arpl) in the apical cytoplasm, whereas kinesin and kinectin were largely concentrated in the basal half of the cells in a pattern similar to the distribution of calreticulin, a component of the endoplasmic reticulum. Secretory granules of non-polarized chromaffin cells of the bovine adrenal medulla, that are assumed to underlie microtubular plus end targeting from the Golgi apparatus to the cell periphery, were not found to be associated with dynein or dynactin. To our knowledge, this is the first demonstration of major components of the dynein-dynactin complex associated with the membrane of a biochemically and functionally well-defined organelle which is considered to underlie a vectorial minus end-driven microtubular transport critically involved in precise delivery of digestive enzymes to the apically located acinar lumen.     

Mechanisms of apical protein sorting in polarized thyroid epithelial cells.

The process leading to thyroid hormone synthesis is vectorial and depends upon the polarized organization of the thyrocytes into the follicular unit. Thyrocyte membrane proteins are delivered to two distinct domains of the plasma membrane using apical (AP) and basolateral (BL) sorting signals. A recent hypothesis for AP sorting proposes that apically destined proteins cluster with glycosphingolipids (GSLs) and cholesterol, into microdomains (or rafts) of the Golgi membrane from which AP vesicles originate. In MDCK cells the human neurotrophin receptor, p75hNTR, is delivered to the AP surface through a sorting signal, rich in O-glycosylated sugars, identified in its ectodomain. We have investigated whether this signal is functional in the thyroid-derived FRT cell line and whether p75hNTR clusters into lipid rafts to be sorted to the AP membrane. We found that p75hNTR is apically delivered via a direct pathway and does not associate with rafts during its transport to the surface of FRT cells. Therefore, although the same signal could be recognized by different cell types thyroid cells may possess a tissue-specific sorting machinery.     

In the multiheaded strain (mh-1) of Hydra magnipapillata the ectodermal epithelial cells are responsible for the formation of additional heads and the endodermal epithelial cells for the reduced ability to regenerate a foot

Hydra consist of three self-renewing cell lineages: the ectodermal epithelial, endodermal epithelial and interstitial cell lineages. The role of these cell lineages in head formation and foot regeneration in Hydra magnipapillata was studied by comparing the multiheaded strain mh-1 with the wild-type. Adult polyps of this strain show a reduced ability to regenerate a foot in the apical body half several days before additional heads are formed there. Cell lineage chimeras were produced, and it was found that in mh-1, the ectodermal epithelial cell lineage is responsible for the formation of additional heads, whereas the endodermal epithelial cell lineage and, to a lesser extent, the derivatives of the interstitial cell lineage, are responsible for the reduced ability of foot regeneration.     

WGA-binding, mucin glycoproteins protect the apical cell surface of mouse uterine epithelial cells.

Expression of apical cell surface proteins and glycoproteins was examined in polarized primary cultures of mouse uterine epithelial cells (UEC). Lectin-gold cytochemistry revealed that wheat germ agglutinin (WGA) bound specifically to the components of the apical glycocalyx as well as intracellular vesicles. Double labeling with the pH sensitive dye 3-(2,4-dinitroanilino)-3'amino-N-methyldipropylamine (DAMP) demonstrated the acidic nature of the WGA-staining intracellular vesicles. The enzymatic and chemical sensitivities of the WGA binding sites on the apical cell surface were monitored both by WGA-gold staining as well as by 125I-WGA binding assays. In thin sections, a large fraction of these sites were removed by pronase; however, application of a wide variety of proteases, glycosidases, or chemical treatments to the apical surface of intact UEC failed to reduce WGA binding. In no case did treatments designed to remove sialic acids reduce 125I-WGA binding more than 12%. In contrast, endo-beta-galactosidase as well as a combination of beta-galactosidase with beta-hexosaminidase succeeded in removing 28% and 77% of these sites, respectively. These studies suggested that the majority of the apically disposed WGA binding sites involved N-acetylglucosamine residues rather than sialic acids and included lactosaminoglycans. Many of the proteins detected at the apical cell surface by lactoperoxidase-catalyzed radioiodination were WGA-binding glycoproteins. A major class of these glycoproteins displayed Mr > 200 kDa by SDS-PAGE and was heavily labeled metabolically by 3H-glucosamine or by vectorial labeling at the apical cell surface with galactosyl transferase and UDP-3H-galactose. Analyses of the 3H-labeled oligosaccharides labeled by either procedure indicated that a large fraction of the apically disposed WGA-binding oligosaccharides consisted of neutral, O-linked mucin-type structures with median MW of approximately 1,500. Oligosaccharides in this fraction were partially (15%) sensitive to endo-beta-galactosidase digestion and bound to Datura stramonium agglutinin (68%), demonstrating the presence of lactosaminoglycan sequences. UEC were an extremely effective barrier to attachment or invasion by either a highly invasive melanoma cell line, B16-BL6, or implantation-competent mouse blastocysts. In contrast, neither uterine stromal cells nor a non-polarizing UEC cell line, RL95, prevented B16-BL6 attachment.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differentiation of the interstitial cell line in hydrozoan planulae

Repopulation of epithelial (colchicine-treated) planular tissue by interstitial cells, nematoblasts/nematocytes, and ganglionic cells was examined via grafting. Seventy-two-hour epithelial planular head pieces were grafted to 72-hour control labelled planular tail pieces, left in contact for 24 h, separated, and the head pieces were analyzed for interstitial cells and their derivatives. The reciprocal experiment of grafting 72-hour epithelial planular tails to 72-hour control labelled planular heads was also done and the tail pieces were examined. Repopulated planular head pieces contained interstitial cells, ganglionic cells and a reforming neural plexus but few nematoblasts/nematocytes. Reconstituted planular tail pieces contained interstitial cells and nematoblasts/nematocytes but no ganglionic cells. Results possibly suggest that the migrating interstitial cell population of 72-hour planulae is rich in committed precursors.     

Cellular behavior in the anteroposterior axis of the regenerating forelimb of the axolotl, Ambystoma mexicanum

Cellular behavior along the anteroposterior axis of the regenerating axolotl forelimb was studied by use of triploid (3N) tissue grafted into diploid (2N) hosts and three-dimensional computer reconstructions. Asymmetrical upper forelimbs were surgically constructed with one half (anterior or posterior) 3N and the other half 2N. Limbs were amputated immediately after grafting or were permitted to heal for 5 or 30 days prior to amputation. When regenerates had attained the stage of digital outgrowth, the limbs were harvested and sectioned in the transverse axis for histological analysis. When all limbs bearing anterior grafts were considered as a group, 77% of the 3N mesodermal cells were observed in the anterior side of the regenerates and 23% were located in the posterior side of the regenerates. When all limbs bearing posterior grafts were considered as a group, 76% of the 3N mesodermal cells were found in the posterior side of the regenerate and 24% had crossed into the anterior side. Healing times of 0, 5, or 30 days prior to amputation had no effect on the experimental outcome. Three-dimensional computer reconstructions revealed that most 3N cells of mesodermal origin underwent short-distance migration from anterior to posterior or from posterior to anterior and intermixed with diploid mesodermal cells near the midpoint of the regenerated anteroposterior axis. Some 3N cells were observed at greater distances from the graft-host interface. By contrast, labeled epidermal cells from both anterior and posterior grafts exhibited long-distance migration across all surfaces of regenerated limbs. Details of a computer-assisted reconstructive method for studying the three-dimensional distribution of labeled cells in tissues are presented.     

Fgfr-Ras-MAPK signaling is required for apical constriction via apical positioning of Rho-associated kinase during mechanosensory organ formation

Many morphogenetic movements during development require the formation of transient intermediates called rosettes. Within rosettes, cells are polarized with apical ends constricted towards the rosette center and nuclei basally displaced. Whereas the polarity and cytoskeletal machinery establishing these structures has been extensively studied, the extracellular cues and intracellular signaling cascades that promote their formation are not well understood. We examined how extracellular Fibroblast growth factor (Fgf) signals regulate rosette formation in the zebrafish posterior lateral line primordium (pLLp), a group of ～100 cells that migrates along the trunk during embryonic development to form the lateral line mechanosensory system. During migration, the pLLp deposits rosettes from the trailing edge, while cells are polarized and incorporated into nascent rosettes in the leading region. Fgf signaling was previously shown to be crucial for rosette formation in the pLLp. We demonstrate that activation of Fgf receptor (Fgfr) induces intracellular Ras-MAPK, which is required for apical constriction and rosette formation in the pLLp. Inhibiting Fgfr-Ras-MAPK leads to loss of apically localized Rho-associated kinase (Rock) 2a, which results in failed actomyosin cytoskeleton activation. Using mosaic analyses, we show that a cell-autonomous Ras-MAPK signal is required for apical constriction and Rock2a localization. We propose a model whereby activated Fgfr signals through Ras-MAPK to induce apical localization of Rock2a in a cell-autonomous manner, activating the actomyosin network to promote apical constriction and rosette formation in the pLLp. This mechanism presents a novel cellular strategy for driving cell shape changes.     

Head regeneration inHydra is initiated release of head activator and inhibitor

Summary Hydra regenerating heads release at least two substances into the surrounding medium: one stimulates and one inhibits head formation. The inhibitor is released mainly during the first hour after cutting, the activator is released more slowly with a maximum in the second hour and with substantial release still during the following six hours. The release of both substances seems to be specific for head regeneration: it is not found in animals regenerating feet. The sequential release of these substances leads to the early changes observed at the cellular level during head regeneration inhydra: the inhibitor produces a decrease, the activator an increase in the mitotic activity of interstitial and epithelial cells, if assayed on intact animals. Head regeneration is blocked, if the release of the head activator is prevented. It is therefore suggested that these substances are necessary to initiate head regeneration inhydra.