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.     

Gland cells arise by differentiation from interstitial cells in Hydra attenuata

The origin of the gland cells in asexually reproducing adult hydra is unclear. There is evidence suggesting that the gland cells are a self-renewing population as well as contrary evidence suggesting that they must arise from another cell type. We have reexamined the question and found the latter to be the case. Analysis of ectoderm/endoderm chimeras in which the ectoderm was labeled with [3H]thymidine indicates a precursor for gland cells in the ectoderm which migrates into the endoderm. Analysis of grafts between labeled lower halves and unlabeled upper halves of animals indicates the migratory precursor is either a large or a small interstitial cell. Measurement of the cell cycle times of the gland cells and the epithelial cells provided further support. The cell cycle time of the gland cells appears to be longer than that of the epithelial cells of the endoderm throughout the animal. This means that in the steady-state growth condition of hydra tissue, the gland cells cannot maintain their population size simply by cell division. These results and other data suggest the following dynamics for the gland cell population. Gland cells arise by differentiation from large interstitial cells, undergo a limited number of cell divisions, and then become postmitotic.     

Action of foot activator on growth and differentiation of cells in hydra

Foot activator is a small peptide found in hydra and specifically activates foot formation. I present a method for the further purification of foot activator by high-pressure liquid chromatography. The morphogenetically active fractions were assayed for their effect at the cellular level. Foot activator acts as a mitogen by pushing epithelial and interstitial cells, which are arrested in G2, into mitosis. In the presence of foot activator, epithelial stem cells are stimulated to differentiate into foot mucus cells, and interstitial nerve precursor cells differentiate into mature nerve cells. The interaction of foot activator with head activator in the development of hydra is discussed.     

A quantitative method for maceration of hydra tissue

Summary A method is described for the maceration (dissociation) of hydra tissue into single cells. The cells have characteristic morphology such that all basic types — epithelial, gland, mucous, interstitial, nematoblast, and nerve — can be distinguished. Criteria are given for identifying each cell type by phase contrast microscopy. It is shown that maceration quantitatively recovers cells from hydra tissue.     

Genetic analysis of developmental mechanisms in hydra. XVIII. Mechanism for elimination of the interstitial cell lineage in the mutant strain Sf-1

The interstitial cell lineage in mutant strain sf-1 of hydra is temperature sensitive and is lost rapidly from tissue when the animal is cultured at a restrictive temperature of 23 degrees C or higher. The mechanism responsible for this cell elimination process was investigated. Sf-1 polyps were treated at a restrictive temperature of 27 degrees C for varying lengths of time, their tissues were macerated, and the resultant dissociated cells were examined for evidence of phagocytosis after Feulgen staining. It was found that large phagocytic vacuoles were present in the cytoplasm of some epithelial cells. These vacuoles contained partially degraded cells, whose nuclei had highly-condensed and intensely Feulgen-positive chromatin granules. This indicated that, as in colchicine-treated (Campbell, 1976) or starved (Bosch and David, 1984) wild-type hydra, the epithelial cells in strain sf-1 engulfed and disintegrated other cells in the phagocytic vacuoles. The incidence of phagocytosis was higher in sf-1 tissue maintained at elevated temperature than in sf-1 tissue maintained at normal temperature. However, the observed incidence was relatively low (maximally 0.14 phagocytosed cells per epithelial cell) and appeared to be too low to account for the very rapid interstitial cell loss occurring in this strain. We concluded that elimination of the interstitial cell lineage at a restrictive temperature in strain sf-1 takes place in part by phagocytosis and in part by other yet-unidentified mechanisms (cf., Marcum et al., 1980).     

The extracellular matrix of hydra is a porous sheet and contains type IV collagen

Hydra, as an early diploblastic metazoan, has a well-defined extracellular matrix (ECM) called mesoglea. It is organized in a tri-laminar pattern with one centrally located interstitial matrix that contains type I collagen and two sub-epithelial zones that resemble a basal lamina containing laminin and possibly type IV collagen. This study used monoclonal antibodies to the three hydra mesoglea components (type I, type IV collagens and laminin) and immunofluorescent staining to visualize hydra mesoglea structure and the relationship between these mesoglea components. In addition, hydra mesoglea was isolated free of cells and studied with immunofluorescence and scanning electron microscopy (SEM). Our results show that type IV collagen co-localizes with laminin in the basal lamina whereas type I collagen forms a grid pattern of fibers in the interstitial matrix. The isolated mesoglea can maintain its structural stability without epithelial cell attachment. Hydra mesoglea is porous with multiple trans-mesoglea pores ranging from 0.5 to 1 μm in diameter and about six pores per 100 μm² in density. We think these trans-mesoglea pores provide a structural base for epithelial cells on both sides to form multiple trans-mesoglea cell–cell contacts. Based on these findings, we propose a new model of hydra mesoglea structure.     

Growth regulation of the interstitial cell population in hydra. II. A new mechanism for the homeostatic recovery of reduced interstitial cell populations

The interstitial cells of hydra comprise a stem cell population, producing at least two classes of terminally differentiated cell types, nerve cells and nematocytes. Exposure to hydroxyurea (HU) results in selective depletion of interstitial cells from the tissue. The surviving cells subsequently recovered to normal levels, and the mechanisms involved in this repopulation were examined. Hydra were treated for varying times with HU such that interstitial cell numbers were reduced to 7 or 35% of normal. Subsequent growth of the epithelial and interstitial cell populations in these animals was monitored. The results indicate that the growth rates of these two cell types were only slightly different from untreated controls during the 4 weeks after HU exposure, implying that repopulation should not have occurred. However, recovery of the interstitial cell population was observed. Further analysis revealed that the interstitial cells in HU animals, unlike normal hydra, were not uniformly distributed in the body column, and were especially reduced in the budding region. In normal animals a constant fraction of the interstitial and epithelial cells are lost into buds. However, as a consequence of this nonuniform distribution a smaller fraction of the interstitial cells are displaced into HU buds, thereby retaining a higher proportion in the adult tissue. Calculations indicate that this mechanism of increased retention is of sufficient magnitude to account for 40-60% of the observed recovery after HU treatment.     

Cnidarian and bilaterian promoters can direct GFP expression in transfected hydra

Complete sexual development is not easily amenable to experimentation in hydra. Therefore, the analysis of gene function and gene regulation requires the introduction of exogenous DNA in a large number of cells of the hydra polyps and the significant expression of reporter constructs in these cells. We present here the procedure whereby we coupled DNA injection into the gastric cavity to electroporation of the whole animal in order to efficiently transfect hydra polyps. We could detect GFP fluorescence in both endodermal and ectodermal cell layers of live animals and in epithelial as well as interstitial cell types of dissociated hydra. In addition, we could confirm GFP protein expression by showing colocalisation between GFP fluorescence and anti-GFP immunofluorescence. Finally, when a FLAG epitope was inserted in-frame with the GFP coding sequence, GFP fluorescence also colocalised with anti-FLAG immunofluorescence. This GFP expression in hydra cells was directed by various promoters, either homologous, like the hydra homeobox cnox-2 gene promoter, or heterologous, like the two nematode ribosomal protein S5 and L28 gene promoters, and the chicken beta-actin gene promoter. This strategy provides new tools for dissecting developmental molecular mechanisms in hydra; more specifically, the genetic regulations that take place in endodermal cells at the time budding or regeneration is initiated.     

Role of the cellular environment in interstitial stem cell proliferation in Hydra

Summary The role of the cellular environment on hydra stem cell proliferation and differentiation was investigated by introduction of interstitial cells into host tissue of defined cellular composition. In epithelial tissue lacking all non-epithelial cells the interstitial cell population did not grow but differentiated into nerve cells and nematocytes. In host tissue with progressively increased numbers of nerve cells growth of the interstitial cell population was positively correlated to the nerve cell density. In agreement with previous observations (Bode et al. 1976), growth of the interstitial cell population was also found to be negatively correlated to the level of interstitial cells present. The strong correlation between the growth of the interstitial cell population and the presence of interstitial cells and nerve cells implies that interstitial cell proliferation is controlled by a feedback signal from interstitial cells and their derivatives. Our results suggest that the cellular environment of interstitial cells provides cues which are instrumental in stem cell decision making. Offprint requests to: T.C.G. Bosch     

A SEM analysis of DMSO treated hydra polyps

Summary— Scanning electron microscopy revealed that exposure of hydra polyps to DMSO at concentrations used for permeabilizing tissue results in striking changes in epithelial cell morphology. Epithelial cells from treated polyps rounded up in shape and formed numerous large blebs at the cell surface. Along the borders of epithelial cells numerous small projections became detectable. The DMSO-induced changes at the cell surface corresponded to drastic changes in the intracellular organization. No evidence could be found for DMSO induced opening of cell junctions and/or opening of the interstitial space. The results demonstrate that DMSO affects the morphology and intracellular organization of hydra epithelial cells. Thus, caution is necessary in interpreting cell behavior in DMSO treated tissue.     

Cell lineages in Hydra: isolation and characterization of an interstitial stem cell restricted to egg production in Hydra oligactis

In an attempt to isolate unipotent stem cells (progenitors to the nerve cells, nematocytes, gland cells, and gametes) from Hydra oligactis females, animals were treated with a drug (hydroxyurea, HU) that preferentially lowers or eliminates the interstitial stem cells, leaving the epithelial tissue intact. In this epithelial environment, interstitial cells remaining after treatment will proliferate and differentiate, permitting a long-term analysis of their developmental capabilities. Following treatment of females with HU, animals were isolated that contained interstitial cells that gave rise to eggs only. Two clones of animals containing these cells were propagated for several years and the growth and differentiation behavior of the interstitial cells examined in their asexually produced offspring. During this time, the cells displayed an extensive proliferative capacity (classifying them as stem cells) and remained restricted to egg differentiation. It is proposed that both the sperm- and the egg-restricted stem cells arise from a multipotent stem cell, which also gives rise to the somatic cells (see above), and that, in hydra, sex is ultimately determined by interactions between cells of the two germ cell lineages.     

Epithelial morphogenesis in hydra requires de novo expression of extracellular matrix components and matrix metalloproteinases

As a member of the phylum Cnidaria, the body wall of hydra is organized as an epithelium bilayer (ectoderm and endoderm) with an intervening extracellular matrix (ECM). Previous studies have established the general molecular structure of hydra ECM and indicate that it is organized as two subepithelial zones that contain basement membrane components such as laminin and a central fibrous zone that contains interstitial matrix components such as a unique type I fibrillar collagen. Because of its simple structure and high regenerative capacity, hydra has been used as a developmental model to study cell-ECM interaction during epithelial morphogenesis. The current study extends previous studies by focusing on the relationship of ECM biogenesis to epithelial morphogenesis in hydra, as monitored during head regeneration or after simple incision of the epithelium. Histological studies indicated that decapitation or incision of the body column resulted in an immediate retraction of the ECM at the wound site followed by a re-fusion of the bilayer within 1 hour. After changes in the morphology of epithelial cells at the regenerating pole, initiation of de novo biogenesis of an ECM began within hours while full reformation of the mature matrix required approximately 2 days. These processes were monitored using probes to three matrix or matrix-associated components: basement membrane-associated hydra laminin beta1 chain (HLM-beta1), interstitial matrix-associated hydra fibrillar collagen (Hcol-I) and hydra matrix metalloproteinase (HMMP). While upregulation of mRNA for both HLM-beta1 and Hcol-I occurred by 3 hours, expression of the former was restricted to the endoderm and expression of the latter was restricted to the ectoderm. Upregulation of HMMP mRNA was also associated with the endoderm and its expression paralleled that for HLM-beta1. As monitored by immunofluorescence, HLM-beta1 protein first appeared in each of the two subepithelial zones (basal lamina) at about 7 hours, while Hcol-I protein was first observed in the central fibrous zone (interstitial matrix) between 15 and 24 hours. The same temporal and spatial expression pattern for these matrix and matrix-associated components was observed during incision of the body column, thus indicating that these processes are a common feature of the epithelium in hydra. The correlation of loss of the ECM, cell shape changes and subsequent de novo biogenesis of matrix and matrix-associated components were all functionally coupled by antisense experiments in which translation of HLM-beta1 and HMMP was blocked and head regeneration was reversibly inhibited. In addition, inhibition of translation of HLM-beta1 caused an inhibition in the appearance of Hcol-I into the ECM, thus suggesting that binding of HLM-beta1 to the basal plasma membrane of ectodermal cells signaled the subsequent discharge of Hcol-I from this cell layer into the newly forming matrix. Given the early divergence of hydra, these studies point to the fundamental importance of cell-ECM interactions during epithelial morphogenesis.     

Action of the head activator as a growth hormone in hydra.

At the cellular level the head activator from hydra acts as a mitogen or growth hormone. It shortens cell cycle times by stimulating cells arrested in the G2 period to go through mitosis. This is true for continuously proliferating cell types like epithelial cells, gland cells, and interstitial cells, and for differentiating interstitial cells including those undergoing a last mitosis before differentiating into nerves or nematocytes.     

Interstitial cell migration in Hydra attenuata. I. Quantitative description of cell movements

The interstitial cell system of hydra contains multipotent stem cells which can form at least two classes of differentiated cell types, nerves and nematocytes. The amount of nerve and nematocyte production varies in an axially dependent pattern along the body column. Some interstitial cells can migrate, which makes it conceivable that this observed pattern of differentiation is not the result of regionally specified stem cell commitment, but rather arises by the selective movement of predetermined cells to the correct site prior to expression. To assess this latter possibility quantitative information on the dynamics of interstitial cell migration was obtained. Epithelial hydra were grafted to normal animals in order to measure (1) the number of cells migrating per day, (2) the location of these cells within the host tissue, and (3) the axial directionality of this movement. Tissue properties such as axial position and the density of cells within the interstitial spaces of the host were also tested for their possible influence on migration. Results indicate that there is a considerable traffic of migrating interstitial cells and this movement has many of the characteristics necessary to generate the position-dependent pattern of nerve differentiation.     

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.     

Non-budding Hydra: Form Regulation and Bud Induction

Form regulation and bud induction were studied in a non-buddingstrain of Chlorohydra viridissima. Regeneration at a cut surfacein a column piece with an existing hydranth was observed andfound to be dependent on the column length Another aspect ofform regulation, formation and control of supernumerary tentacles,was investigated by grafting. Supernumerary tentacle formationin long polyps can be suppressed by implants of hypostomal orsubhypostomal tissue. Non-budding hydra can be induced to bud by implanting smallpieces of normal tissue into their columns. The cellular basisof this process was investigated by means of grafting, radioautography,and histological methods. No differences in the proportionsor appearances of the cell types were observed between non-buddingand normal animals. However, induced buds have higher proportionsof interstitial cells and their derivatives (nerves and nematoblasts)than do normal buds. Many of these interstitial cells and derivativesoriginate from cells in the grafted implant. Normal tissue fromwhich interstitial cells have been previously removed will notinduce buds in non-budding hydra. The non-budding syndrome is probably related to a deficiencyin interstitial cell differentiation. If nerve cells are involvedin bud initiation and form regulation, these results suggestinterstitial cells of non-budding hydra are unable to transforminto sufficiently active and/or numerous nerve cells to controlthose processes.     

Evidence for Cell Surface Extracellular Matrix Binding Proteins in Hydra vulgaris

The present study was designed to identify and functionally characterize potential cell surface extracellular matrix binding proteins in Hydra vulgaris. Using [³H]-laminin as a probe, radioreceptor analysis of a dissociated mixed hydra cell preparation indicated that the average number of laminin binding sites per cell was about 10,000 with a dissociation constant of 1.49 nM. These binding sites could be displaced with unlabelled laminin in a dose-dependent manner and with high concentrations (500 nM) of unlabelled fibronectin. No displacement with type-IV collagen and type-I collagen was observed. Immunoscreerting studies with a battery of antibodies raised to mammalian extracellular matrix (ECM) binding proteins indicated potential cell surface binding sites for the anti-β₁ integrin monoclonal antibody, mAb JG22. Cell adhesion studies indicated that mAb JG22 blocked binding of hydra cells to laminin, but did not affect their binding to fibronectin, type-IV collagen, or type-I collagen. Light and electron microscopic immunocytochemical studies indicated that mAb JG22 localized to the basal plasma membrane of ectodermal and endodermal epithelial cells. Immunoprecipitation studies identified two major bands with masses of about 196 kDa and 150 kDa under reducing conditions, and two bands with masses of >200 kDa under non-reducing conditions. Functional studies indicated that mAb JG22 could reversibly block morphogenesis of hydra cell aggregates, and could block in vivo interstitial cell migration in hydra grafts. These observations indicate that hydra has cell surface binding sites for ECM components which are functionally important during development of this simple Cnidarian     

Immunocytochemical evidence for an NMDA1 receptor subunit in dissociated cells of<Emphasis Type="Italic"> Hydra vulgaris</Emphasis>

We have previously reported immunocytochemical, biochemical, behavioral, and electrophysiological evidence for glutamatergic transmission through (±)--amino-3-hydroxy-5-methyl-isoxazole-4-propionic acid (AMPA)/kainate receptors in hydra. We now report specific localization of the N-Methyl-D-aspartic acid receptor subunit 1 (NMDAR1) in epithelial, nerve, nematocytes, and interstitial cells of hydra. Macerates of tentacle/hypostome pieces of Hydra vulgaris were prepared on agar-coated slides, fixed with buffered formaldehyde/glutaraldehyde, and fluorescently labeled with monoclonal antibodies against mammalian NMDAR1. Negative controls omitted primary antibody. Digital images were recorded and analyzed. Specific localized and intense labeling was found in ectodermal battery cells, other epithelial cells, nematocytes, interstitial cells, and sensory and ganglionic nerve cells, and in battery cells was associated with enclosed nematocytes and neurons. The labeling of myonemes was more diffuse and less intense. In nerve and sensory cells, punctate labeling was prominent on cell bodies. These results are consistent with our earlier evidence for glutamatergic neurotransmission and kainate/NMDA regulation of stenotele discharge. They support other behavioral and biochemical evidence for a D-serine-sensitive, strychnine-insensitive, glycine receptor in hydra and suggest that the glutamatergic AMPA/kainate-NMDA system is an early evolved, phylogenetically old, behavioral control mechanism.     

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.     

Genetic analysis of developmental mechanisms in hydra: XIV. Identification of the cell lineages responsible for the altered developmental gradients in a mutant strain,reg-16

The developmental gradients of six chimeric strains of hydra produced from a normal strain (105) and a regeneration-deficient strain (reg-16) were analyzed. The reg-16 mutant has been shown to have a lower gradient of head-activation potential and a higher gradient of head-inhibition potential than the normal 105 strain. The chimeric animals consisted of different combinations of the three self-renewing cell lineages found in hydra (the ectodermal and endodermal epithelial cell lineages and the interstitial cell lineage) from each of the parental origins. To identify the cell lineages responsible for the abnormal gradients in reg-16, the head-activation and head-inhibition potentials of these cell lineage chimeras were assayed by lateral transplantation of tissue. The results obtained have provided evidence which indicates that the defect responsible for the low head-activation potential in reg-16 resides in its ectodermal and endodermal epithelial cell lineages, whereas the defect responsible for its high head-inhibition potential resides in its endodermal epithelial and interstitial cell lineages. The cellular localization of these defects is not identical but very similar to the cellular localization of the regenerative defects in reg-16. This finding is consistent with and supports the view that the abnormalities of the developmental gradients are correlated to the reduced head regenerative capacity in reg-16.