Growth regulation of the interstitial cell population in hydra. III. Interstitial cell density does not control stem cell proliferation

The interstitial cells of hydra contain a stem cell population which produces several classes of differentiated cell types. A model has been proposed which governs the growth rate of the interstitial cell population. This model, based on the density of interstitial cells in the tissue, makes specific predictions about the relationships among this density, the proportion of stem cells in the interstitial cell population, the growth rate of the interstitial cell population, and the amount of nematocyte differentiation. Hydroxyurea treatments were used to experimentally reduce interstitial cell numbers, and the validity of these expected correlations was tested. The results demonstrate that the predictions of the interstitial cell density model were not upheld. Furthermore, the findings suggest that the interstitial cells are a heterogeneous population, containing some cells which are no longer stem cells but which do retain a limited capacity for proliferation. In the following paper (S. Heimfeld and H.R. Bode, 1986, Dev. Biol. 115, 59-68) we have proposed an alternative mechanism to explain the observed correlations, which incorporates this heterogeneity into amplification divisions of interstitial cells already committed to differentiation.     

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.     

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     

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.     

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.     

Distribution of interstitial stem cells in Hydra

The distribution of interstitial stem cells along the Hydra body column was determined using a simplified cloning assay. The assay measures stem cells as clone-forming units (CFU) in aggregates of nitrogen mustard inactivated Hydra tissue. The concentration of stem cells in the gastric region was uniform at about 0.02 CFU/epithelial cell. In both the hypostome and basal disk the concentration was 20-fold lower. A decrease in the ratio of stem cells to committed nerve and nematocyte precursors was correlated with the decrease in stem cell concentration in both hypostome and basal disk. The ratio of stem cells to committed precursors is a sensitive indicator of the rate of self-renewal in the stem cell population. From the ratio it can be estimated that <10% of stem cells self-renew in the hypostome and basal disk compared to 60% in the gastric region. Thus, the results provide an explanation for the observed depletion of stem cells in these regions. The results also suggest that differentiation and self-renewal compete for the same stem cell population.     

Regulation of interstitial cell differentiation in Hydra attenuata. I. Homeostatic control of interstitial cell population size.

Mechanisms regulating the population size of the multipotent interstitial cell (i-cell) in Hydra attenuata were investigated. Treatment of animals with 3 cycles of a regime of 24 h in 10-2 M hydroxyurea (HU) alternated with 12 h in culture medium selectively killed 95-99% of the i-cells, but had little effect on the epithelial cells. The i-cell population recovered to the normal i-cell:epithelial cell ratio of I:I within 35 days. Continuous labelling experiments with [3H]thymidine indicate that the recovery of the i-cell population is not due to a change in the length of the cell cycle of either the epithelial cells or the interstitial cells. In control animals 60% of the i-cell population undergo division daily while 40% undergo differentiation. Quantification of the cell types of HU-treated animals indicates that a greater fraction of the i-cells were dividing and fewer differentiating into nematocytes during the first 2 weeks of the recovery after HU treatment. Therefore, the mechanism for recovery involves a shift of the 60:40 division:differentiation ratio of i-cells towards a higher fraction in division until the normal population size of the i-cells is regained. This homeostatic mechanism represents one of the influences affecting i-cell differentiation.     

Putative intermediates in the nerve cell differentiation pathway in hydra have properties of multipotent stem cells

We have investigated the properties of nerve cell precursors in hydra by analyzing the differentiation and proliferation capacity of interstitial cells in the peduncle of Hydra oligactis, which is a region of active nerve cell differentiation. Our results indicate that about 50% of the interstitial cells in the peduncle can grow rapidly and also give rise to nematocyte precursors when transplanted into a gastric environment. If these cells were committed nerve cell precursors, one would not expect them to differentiate into nematocytes nor to proliferate apparently without limit. Therefore we conclude that cycling interstitial cells in peduncles are not intermediates in the nerve cell differentiation pathway but are stem cells. The remaining interstitial cells in the peduncle are in G1 and have the properties of committed nerve cell precursors (Holstein and David, 1986). Thus, the interstitial cell population in the peduncle contains both stem cells and noncycling nerve precursors. The presence of stem cells in this region makes it likely that these cells are the immediate targets of signals which give rise to nerve cells.     

Migration of multipotent interstitial stem cells in Hydra

Stem cells in Hydra represent one of the phylogenetically most ancient stem cell systems and, therefore, provide information for reconstructing the early history of stem cell control mechanisms. Hydra's interstitial stem cells are multipotent and differentiate into both somatic cell types and germ line cells. Although it is well accepted that cells of the interstitial cell lineage are migratory, the in vivo migratory potential of multipotent interstitial stem cells has never been explored. Combining in vivo tracing of genetically labeled interstitial stem cells and tissue transplantation, we show that in contrast to precursor cells, multipotent interstitial stem cells are stationary. Only when exposed to tissue depleted of the interstitial cell lineage, interstitial stem cells start to migrate and to repopulate emptied stem cell niches. We conclude that multipotent interstitial stem cells in Hydra are static and that microenvironmental cues including signals derived from the interstitial cell lineage or from niche cells can trigger a shift in collective stem cell behavior to start migration.     

Germ cells in Hydra oligactis males. II. Evidence for a subpopulation of interstitial stem cells whose differentiation is limited to sperm production

Animals containing germline-restricted interstitial cells were obtained by treating males from a clone of Hydra oligactis with hydroxyurea (HU) to lower the interstitial population to 1 or 2 cells per animal. A 3-day HU treatment produced animals whose interstitial cells did not form somatic cells, but did produce sperm. The isolation of these cells in HU-treated animals has lead us to propose that the interstitial cell population may contain subpopulations which possess different growth dynamics and developmental potentials. Through asexual propagation, we have cloned several animals containing only sperm precursor interstitial cells and have examined the growth and differentiation behavior of these cells in offspring propagated over a 2-year period. Evidence has been obtained which demonstrates (1) the extensive self-renewal capacity of the sperm precursor interstitial cells, and (2) the restricted differentiation capacity of these interstitial stem cells. Factors which affect cells entering and traversing the spermatogenic pathway are also presented.     

Homeostatic recovery of interstitial cell populations in Hydra.

The growth of interstitial cell populations in Hydra magnipapillata was examined following transplantation of small numbers of interstitial cells into "epithelial animals" which lacked all cell types in the interstitial cell lineage. The distribution pattern of transplanted interstitial cells during the growth phase was examined by staining whole animals with toluidine blue and cell numbers were determined by maceration. The following results were obtained: (1) Transplanted interstitial cells formed a contiguous patch which spread distoproximally but not circumferentially. (2) The displacement of interstitial cells from parents to buds was a random process; buds incorporated interstitial cells only when they were formed in the vicinity of the patch. (3) Interstitial cells increased exponentially in number with a doubling time of 1.8 days for at least 10 days after transplantation, which is faster than the normal doubling time of 2.8 days. (4) The self-renewal probability at low interstitial cell levels was estimated to be 0.72, which was higher than the normal value of 0.64. This increase was attained by lowering the fraction of nematocyte differentiation. These results indicate that the homeostatic recovery of interstitial cell populations is attained by increasing the self-renewal probability rather than by preferential retention of interstitial cells in parent animals at the expense of buds (Heimfeld, 1985).     

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.     

Cell cycle length, cell size, and proliferation rate in hydra stem cells

We have analyzed the cell cycle parameters of interstitial cells in Hydra oligactis. Three subpopulations of cells with short, medium, and long cell cycles were identified. Short-cycle cells are stem cells; medium-cycle cells are precursors to nematocyte differentiation; long-cycle cells are precursors to gamete differentiation. We have also determined the effect of different cell densities on the population doubling time, cell cycle length, and cell size of interstitial cells. Our results indicate that decreasing the interstitial cell density from 0.35 to 0.1 interstitial cells/epithelial cell (1) shortens the population doubling time from 4 to 1.8 days, (2) increases the [3H]thymidine labeling index from 0.5 to 0.75 and shifts the nuclear DNA distribution from G2 to S phase cells, and (3) decreases the length of G2 in stem cells from 6 to 3 hr. The shortened cell cycle is correlated with a significant decrease in the size of interstitial stem cells. Coincident with the shortened cell cycle and increased growth rate there is an increase in stem cell self-renewal and a decrease in stem cell differentiation.     

The cardiac valve interstitial cell

Cardiac valve interstitial cells (ICs) are a heterogeneous and dynamic population of specific cell types that have many unique characteristics. They are responsible for maintaining the extracellular scaffold that provides the mechanical characteristics vital for sustaining the unique dynamic behaviour of the valve. A number of cellular phenotypes can be distinguished: some are sparsely arranged throughout the valve leaflets, whilst others are arranged in thin bundles. These cells express molecular markers similar to those of skeletal, cardiac and smooth muscle cells (SMCs) and in particular, many ICs express smooth muscle (SM) alpha-actin, a marker of myofibroblasts. In this respect, these cells exhibit a profile unlike skin fibroblasts, which may allude to their role in valve function.     

Cloned interstitial stem cells grow as contiguous patches in hydra

The migration of interstitial cells was analyzed during the growth of stem cell clones in vivo. The spatial distribution of cloned cells was analyzed at a time by which extensive migration of interstitial cells could have occurred. All interstitial cell clones were found to form large contiguous patches of cells. The results indicate that there is little migration of large interstitial cells in undisturbed tissue during normal growth. This finding is surprising since numerous grafting experiments have shown extensive migration of these cells. The implications of finding nonrandomly distributed stem cells are discussed.     

Characterization of interstitial stem cells in hydra by cloning.

A procedure has been developed for cloning interstitial stem cells from hydra. Clones are prepared by introducing small numbers of viable cells into aggregates of nitrogen mustard-inactivated host tissue. Clones derived from added stem cells are identified after 1–2 weeks of growth by staining with toluidine blue. The incidence of clones increases with increasing input of viable cells according to one-hit Poisson statistics, indicating that clones arise from single cells. After correction for cell losses in the procedure, about 1.2% of the input cells are found to form clones. This compares with estimates from in vivo experiments of about 4% stem cells in whole hydra [David, C. N., and Gierer, A. (1974). Cell cycle kinetics and development of Hydra attenuata. III. Nerve and nematocyte differentiation. J. Cell Sci.16, 359–375.]Differentiation of nematocytes and nerve cells in clones was analyzed by labeling precursors with [³H]thymidine and scoring labeled nerves and nematocytes 2 days later. Nine clones examined in this way contained both differentiated nerve cells and nematocytes, demonstrating that the interstitial stem cell is multipotent. This result suggests that the observed localization of nerve and nematocyte differentiation in whole hydra probably occurs at the level of stemcell determination. The observation that differentiated cells occur very early in clone development suggests that a stem cell's decision to proliferate or differentiate is regulated by shortrange feedback signals which are already saturated in young clones.     

Epidermal cell proliferation. II. A comprehensive mathematical model of cell proliferation and migration in the basal layer predicts some unusual properties of epidermal stem cells

The clustering of 3HTdR labelled cells in the epidermal basal layer and their changes with time have been modelled mathematically and cannot be adequately fitted by an earlier model of the cell kinetic organisation of the skin. A more refined model analysis was performed based on Monte Carlo computer simulations of cell layers which take cell division, cell aging and lateral as well as vertical cell migration into account. A large variety of hypothetical scenarios was tested to see if each could provide a fit to the clustering data. The analysis provides further support for the concept of a cell kinetic heterogeneity with a stem-transit-postmitotic differentiation scheme. In the best overall model scheme three transit divisions are predicted but unlike in the earlier model it is now postulated that postmitotic cells can be produced at all stages in the lineage rather than only at the end of the amplification scheme. Most important, the model predicts that stem cells and most of the transit cells differ in the way they process 3HTdR label. Grain dilution is an important mechanism to explain the fate of some labelled cells in the tissue, but on its own it can only consistently explain the data if the stem cells have a very low labelling index (LI less than or equal to 1%) which implies a very short biologically unreasonable S-phase. If a higher LI (longer S-phase) is assumed for the stem-cells other mechanisms must be predicted to explain the lack of large clusters and the increase in time of the singles. The selective segregation of chromosomes at mitosis is one such mechanism. However, on its own a large number of cells would have to behave in this way (i.e. both stem and T1 cells). If combined with other assumptions such as some grain dilution this selective segregation may be restricted only to stem cells. In addition the model allows cell production and migration rates to be estimated and the analysis can be related to the EPU-concept. Indeed the model itself would tend to automatically generate an EPU like structure. The model quantitatively reproduces LI, PLM, CL and clustering data.     

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.     

Competing tumor cell migration mechanisms caused by interstitial fluid flow

In the seminal work by Swartz and collaborators (Shields et al., 2007) it was discovered that autologously secreted or activated (ECM-bound) chemokine forms local pericellular diffusion gradients skewed by fluid convection, and the cells subsequently chemotact up the flow-directed gradient. However, in (Polacheck et al., 2011) Kamm and collaborators found that there is a competing downstream and upstream migration transport mechanism. Their study showed that both mechanisms are present at the same time and the relative strength of these two stimuli governs the directional bias in migration for a cell population and is a function of cell density, interstitial flow rate, and CCR7 receptor availability. The main objective of this work is to give a possible explanation of these two different concurrent cell migration mechanisms by means of a theoretical model. Relying on multiphase modelling, separate momentum balance equations are formulated, respectively, for the cell phase and the interstitial fluid (IF) phase. In order to represent proteolytic activity and autologous chemotaxis a non-moving ECM component is included, as well as proteases secreted by the cancer cells and chemokine that can be released from ECM. The cell and IF momentum balance equations include cell-ECM and fluid-ECM resistance force terms (i.e., classical Darcy’s equation terms), but also a cell-fluid interaction term that can account for a more indirect effect that fluid-generated stress may have on cancer cells. We illustrate how the cancer cells can work through this term and effectively avoid being pushed in the flow direction, and even create upstream migration by controlling its magnitude and sign. We think of this as the mathematical interpretation of the experimental observation by Kamm and collaborators that the fluid generated matrix adhesion tension on the upstream side of cells activates integrin adhesion complexes, resulting in activation of focal adhesion (FA) proteins. The model predicts that generally the strength of the upstream migration mechanism is sensitive to the cell volume fraction: a lower density of cells is subject to a weaker upstream migration effect; a higher density of cancer cells can more effectively generate upstream migration. This behavior is a result of the nonlinear coupling between cell-ECM, fluid-ECM, and cell-fluid interaction terms that naturally are involved in the mathematical expression for the net cell velocity.     

Germ cells in Hydra oligactis males. I. Isolation of a subpopulation of interstitial cells that is developmentally restricted to sperm production

Single clones of interstitial cells were generated and analyzed to determine if one interstitial cell has the capacity to differentiate both somatic and germ cells. Such clones were produced by using hydroxyurea to selectively eliminate interstitial cells from normal Hydra oligactis males. The number of animals devoid of interstitial cells within the population was determined by staining whole animals with toluidine blue which renders the interstitial cells visible. The number of animals containing single clones of interstitial cells was then estimated using single hit Poisson statistics. In treatments which rendered 60-80% of the population devoid of interstitial cells, the majority of the animals containing interstitial cells lost the ability to produce somatic cells, including nerves and nematocytes, but retained the capacity to produce sperm. This result strongly suggests the presence of a separate germ line in hydra.