Injury-induced activation of the MAPK/CREB pathway triggers apoptosis-induced compensatory proliferation in hydra head regeneration

After bisection, Hydra polyps regenerate their head from the lower half thanks to a head-organizer activity that is rapidly established at the tip. Head regeneration is also highly plastic as both the wild-type and the epithelial Hydra (that lack the interstitial cell lineage) can regenerate their head. In the wild-type context, we previously showed that after mid-gastric bisection, a large subset of the interstitial cells undergo apoptosis, inducing compensatory proliferation of the surrounding progenitors. This asymmetric process is necessary and sufficient to launch head regeneration. The apoptotic cells transiently release Wnt3, which promotes the formation of a proliferative zone by activating the beta-catenin pathway in the adjacent cycling cells. However the injury-induced signaling that triggers apoptosis is unknown. We previously reported an asymmetric immediate activation of the mitogen-activated protein kinase/ribosomal S6 kinase/cAMP response element binding protein (MAPK/RSK/CREB) pathway in head-regenerating tips after mid-gastric bisection. We show here that pharmacological inhibition of the MAPK/ERK pathway or RNAi knockdown of the RSK, CREB, CREB binding protein (CBP) genes prevents apoptosis, compensatory proliferation and blocks head regeneration. As the activation of the MAPK pathway upon injury plays an essential role in regenerating bilaterian species, these results suggest that the MAPK-dependent activation of apoptosis-induced compensatory proliferation represents an evolutionary-conserved mechanism to launch a regenerative process.     

Cell type complexity in the basal metazoan Hydra is maintained by both stem cell based mechanisms and transdifferentiation

Understanding the mechanisms controlling the stability of the differentiated cell state is a fundamental problem in biology. To characterize the critical regulatory events that control stem cell behavior and cell plasticity in vivo in an organism at the base of animal evolution, we have generated transgenic Hydra lines [Wittlieb, J., Khalturin, K., Lohmann, J., Anton-Erxleben, F., Bosch, T.C.G., 2006. Transgenic Hydra allow in vivo tracking of individual stem cells during morphogenesis. Proc. Natl. Acad. Sci. U. S. A. 103, 6208-6211] which express eGFP in one of the differentiated cell types. Here we present a novel line which expresses eGFP specifically in zymogen gland cells. These cells are derivatives of the interstitial stem cell lineage and have previously been found to express two Dickkopf related genes [Augustin, R., Franke, A., Khalturin, K., Kiko, R., Siebert, S. Hemmrich, G., Bosch, T.C.G., 2006. Dickkopf related genes are components of the positional value gradient in Hydra. Dev. Biol. 296 (1), 62-70]. In the present study we have generated transgenic Hydra in which eGFP expression is under control of the promoter of one of them, HyDkk1/2/4 C. Transgenic Hydra recapitulate faithfully the previously described graded activation of HyDkk1/2/4 C expression along the body column, indicating that the promoter contains all elements essential for spatial and temporal control mechanisms. By in vivo monitoring of eGFP+ gland cells, we provide direct evidence for continuous transdifferentiation of zymogen cells into granular mucous cells in the head region. We also show that in this tissue a subpopulation of mucous gland cells directly derives from interstitial stem cells. These findings indicate that both stem cell-based mechanisms and transdifferentiation are involved in normal development and maintenance of cell type complexity in Hydra. The results demonstrate a remarkable plasticity in the differentiation capacity of cells in an organism which diverged before the origin of bilaterian animals.     

Differentiation pathways of ectodermal epithelial cells in hydra

The differentiation pathways of ectodermal epithelial cells in hydra were investigated. We found that under steady state conditions the ectodermal epithelial cells of the foot, the foot mucous cells, and the ectodermal epithelial cells of the tentacles, the battery cells, differentiate from gastric ectodermal ephithelial stem cells. From stem cell to the terminally differentiated state, a single cell cycle is required. The cells undergo a final round of DNA replication, double their genome to 4 n and become arrested in the G2-phase of the cell cycle. The ectodermal ephithelial cells of the hypostome, which like the tentacle cells are part of the head structure, can also arise from gastric ectodermal epithelial stem cells, but do so only during head regeneration and budding. They differentiate from stem cell to hypostomal cell in a single cell cycle, but in contrast to foot mucous and battery cells they remain capable of cell proliferation. Due to this self-renewal potential, they do not require recruitment from the gastric stem-cell pool in steady-state animals.     

Bromodeoxyuridine specifically labels the regenerative stem cells of planarians

The singular regenerative abilities of planarians require a population of stem cells known as neoblasts. In response to wounding, or during the course of cell turnover, neoblasts are signaled to divide and/or differentiate, thereby replacing lost cell types. The study of these pluripotent stem cells and their role in planarian regeneration has been severely hampered by the reported inability of planarians to incorporate exogenous DNA precursors; thus, very little is known about the mechanisms that control proliferation and differentiation of this stem cell population within the planarian. Here we show that planarians are, in fact, capable of incorporating the thymidine analogue bromodeoxyuridine (BrdU), allowing neoblasts to be labeled specifically during the S phase of the cell cycle. We have used BrdU labeling to study the distribution of neoblasts in the intact animal, as well as to directly demonstrate the migration and differentiation of neoblasts. We have examined the proposal that a subset of neoblasts is arrested in the G2 phase of the cell cycle by double-labeling with BrdU and a mitosis-specific marker; we find that the median length of G2 (approximately 6 h) is sufficient to account for the initial mitotic burst observed after feeding or amputation. Continuous BrdU-labeling experiments also suggest that there is not a large, slow-cycling population of neoblasts in the intact animal. The ability to label specifically the regenerative stem cells, combined with the recently described use of double-stranded RNA to inhibit gene expression in the planarian, should serve to reignite interest in the flatworm as an experimental model for studying the problems of metazoan regeneration and the control of stem cell proliferation.     

Involvement of nitric oxide in the head regeneration of Hydra vulgaris

Recent data have shown that a functional NO-cGMP signalling system plays an important role during development and seems to be operative early during the differentiation of embryonic stem cells. The intriguing possibility exists that this role can be evolutionarily conserved between vertebrates and invertebrates. In this paper, we have analyzed the effect of NO-cGMP pathway on the regeneration process in Hydra vulgaris, the most primitive invertebrate possessing a nervous system. Our results indicate that NO production increased during Hydra regeneration. The NOS inhibitor L-NAME reduced the regenerative process and the same effect was obtained by treatment with either the specific guanylate cyclase inhibitor ODQ or the protein kinase G (PKG) inhibitor KT-5823. In contrast, the regeneration process was increased by treating decapitated Hydra with the NO donor NOC-18. Furthermore, we found that cell proliferation was also increased by treating decapitated Hydra with the NO donor NOC-18 and reduced by treatment with the NOS inhibitor L-NAME. Our results strongly suggest that the NO-cGMP-PKG pathway is involved in the control of the proliferative-differentiative patterns of developing and regenerating structures in cnidarians as well as bilaterians.     

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.     

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.     

GNL3 is an evolutionarily conserved stem cell gene influencing cell proliferation,animal growth and regeneration in the hydrozoan Hydractinia

Nucleostemin (NS) is a vertebrate gene preferentially expressed in stem and cancer cells, which acts to regulate cell cycle progression, genome stability and ribosome biogenesis. NS and its paralogous gene, GNL3-like (GNL3L), arose in the vertebrate clade after a duplication event from their orthologous gene, G protein Nucleolar 3 (GNL3). Research on invertebrate GNL3, however, has been limited. To gain a greater understanding of the evolution and functions of the GNL3 gene, we have performed studies in the hydrozoan cnidarian Hydractinia symbiolongicarpus, a colonial hydroid that continuously generates pluripotent stem cells throughout its life cycle and presents impressive regenerative abilities. We show that Hydractinia GNL3 is expressed in stem and germline cells. The knockdown of GNL3 reduces the number of mitotic and S-phase cells in Hydractinia larvae of different ages. Genome editing of Hydractinia GNL3 via CRISPR/Cas9 resulted in colonies with reduced growth rates, polyps with impaired regeneration capabilities, gonadal morphological defects, and low sperm motility. Collectively, our study shows that GNL3 is an evolutionarily conserved stem cell and germline gene involved in cell proliferation, animal growth, regeneration and sexual reproduction in Hydractinia, and sheds new light into the evolution of GNL3 and of stem cell systems.     

Cell plasticity in homeostasis and regeneration

Over the past decades, genetic analyses performed in vertebrate and invertebrate organisms deciphered numerous cellular and molecular mechanisms deployed during sexual development and identified genetic circuitries largely shared among bilaterians. In contrast, the functional analysis of the mechanisms that support regenerative processes in species randomly scattered among the animal kingdom, were limited by the lack of genetic tools. Consequently, unifying principles explaining how stress and injury can lead to the reactivation of a complete developmental program with restoration of original shape and function remained beyond reach of understanding. Recent data on cell plasticity suggest that beside the classical developmental approach, the analysis of homeostasis and asexual reproduction in adult organisms provides novel entry points to dissect the regenerative potential of a given species, a given organ or a given tissue. As a clue, both tissue homeostasis and regeneration dynamics rely on the availability of stem cells and/or on the plasticity of differentiated cells to replenish the missing structure. The freshwater Hydra polyp provides us with a unique model system to study the intricate relationships between the mechanisms that regulate the maintenance of homeostasis, even in extreme conditions (starvation and overfeeding) and the reactivation of developmental programs after bisection or during budding. Interestingly head regeneration in Hydra can follow several routes according to the level of amputation, suggesting that indeed the homeostatic background dramatically influences the route taken to bridge injury and regeneration. Mol. Reprod. Dev. 77:837–855, 2010. © 2010 Wiley‐Liss, Inc.     

Stem cells of Hydra magnipapillata can differentiate into somatic cells and germ line cells

We investigated whether all stem cells of Hydra can differentiate both somatic cells and gametes or if a separate germ line exists in these phylogenetically old organisms. The differentiation potential of single stem cells was analyzed by applying a statistical cloning procedure. All stem cell clones were found to differentiate somatic cells. No clone was found to contain stem cells which do not differentiate. Most of the clones could be induced to form gametes. No clone was found that produced gametes only. The results indicate that stem cells are multipotent in the sense that individual stem cells can differentiate into somatic cells as well as germ line cells.     

Cell cycle analysis during retinoic acid induced differentiation of a human embryonal carcinoma-derived cell line

Several subclones of the human embryonal carcinoma (EC) cell line Tera-2 can be induced to differentiate in monolayer culture by retinoic acid (RA) to a flattened cell type with reduced growth rate. Using a method based on the transition probability model, we have analysed changes in cell cycle kinetics of Tera-2 cells during the differentiation process. Growth inhibition was shown to occur without a lag period and to be partly due to an increase in the duration of the S-phase, but with a relatively greater contribution from an increase in the duration of G1-phase. Since the fraction of the cell population in the G1-phase then doubled, cells accumulated in this part of the cycle. In contrast, the reduced proliferation rate of two murine EC cell lines, PC13 and P19, treated with RA occurs after a lag period of about two cell cycles and is mainly attributable to an increase in the duration of the S-phase. The results illustrate a differential response of human and murine EC cells to growth regulation by RA and again emphasize that although the stem cells of murine teratocarcinomas may provide a useful model, they are not identical to their human counterparts.     

Depletion of HOXA5 inhibits the osteogenic differentiation and proliferation potential of stem cells from the apical papilla

Mesenchymal stem cells (MSCs) are a prospective cell source for tissue regeneration due to their self‐renewal abilities and potential to differentiate into different cell lineages, but the molecular mechanisms of the directed differentiation and proliferation are still unknown. Recently, multiple studies have indicated the crucial role of HOX genes in MSC differentiation and proliferation. However, the role of HOXA5 in MSCs remains unknown. Here, we investigated HOXA5 function in stem cells from the apical papilla (SCAPs). After HOXA5 depletion, the results showed a significant decrease in ALP activity and a weakened mineralization ability of SCAPs. The real‐time RT‐PCR results showed prominently lessened expression of OPN and BSP. The CCK8 and CFSE results displayed inhibited proliferation of SCAPs, and flow cytometry assays revealed arrested cell cycle progression at the S phase. Furthermore, we found that depletion of HOXA5 upregulated p16^INK4A and p18^INK4C and downregulated the Cyclin A. Our research demonstrated that depletion of HOXA5 inhibited osteogenic differentiation and repressed cell proliferation by arresting cell cycle progression at the S phase via p16^INK4A, p18^INK4C, and Cyclin A in SCAPs, indicating that HOXA5 has a significant role in maintaining the proliferation and differentiation potential of dental‐tissue‐derived MSCs.     

Control of cell differentiation during proliferation. I. Monocytic differentiation of HL-60 promyelocytes

The cell proliferation relating an uncommitted precursor cell to a differentiated terminal cell has been quantitated. HL-60 promyelocytes, a bipotent precursor cell capable of differentiating along either the myeloid or monocytic pathway, were induced by a human lymphocyte-conditioned medium (CM) to differentiate into macrophage-like cells. The promyelocytes had a generation time of approx. 42 h. Most promyelocytes which differentiated became macrophage-like cells after only one cell division. Some, a minority, underwent more than one division. The time between induction of differentiation and expression of differentiated characteristics could thus be very short. Labelled S-phase promyelocytes could differentiate after traversing S. G2 and undergoing mitosis. Some, approx. 21%, required a subsequent complete cell cycle before differentiating. The data suggest a model in which cells must undergo a S-phase-specific differentiation control event in the presence of CM in order to differentiate in the subsequent G1 phase. This model proposes that a discrete time in S phase exists when cells are susceptible to exogenous regulation directing them to yield differentiated daughter cells.     

Cell proliferation dynamics and morphological differentiation during regeneration in Dorvillea bermudensis (Polychaeta, Dorvilleidae)

Although some species of Annelida have an enormous capacity to regenerate, it is not yet known whether reestablishment of lost body parts is performed by stem cells, depends on preceding dedifferentiation of somatic cells, or is a combination of both. In order to clarify how, in the case of epimorphic regeneration, the blastemas are formed, we applied the thymidine analog 5'-bromo-2'-deoxyuridine (BrdU) in the dorvilleid polychaete Dorvillea bermudensis to identify cells in the S-phase of the cell cycle. Regeneration pulse-chase experiments were carried out to determine onset and dynamics of the proliferation process, and BrdU pulse-chase experiments were undertaken to follow cell fate. We found irregularly distributed S-phase cells throughout the body of adult specimens. Subsequent to amputation, these cells do not migrate from the amputee towards the wound site, where proliferation activity was documented no earlier than 16 h after fragmentation. In the initial phase, the proliferation rate at the anterior end exceeds the rate at the posterior end. Observance of identity could be demonstrated for the ectoderm and can be assumed for the two other germ layers. The anterior blastema transforms into the head, while the posterior forms the pygidium and persists as a proliferation zone; four or numerous segments are formed by intercalation between the former anterior or posterior blastema and the amputee.     

Hydra, a niche for cell and developmental plasticity

The silencing of genes whose expression is restricted to specific cell types and/or specific regeneration stages opens avenues to decipher the molecular control of the cellular plasticity underlying head regeneration in hydra. In this review, we highlight recent studies that identified genes involved in the immediate cytoprotective function played by gland cells after amputation; the early dedifferentiation of digestive cells into blastema-like cells during head regeneration, and the early late proliferation of neuronal progenitors required for head patterning. Hence, developmental plasticity in hydra relies on spatially restricted and timely orchestrated cellular modifications, where the functions played by stem cells remain to be characterized.     

Synthesis of alpha-fetoprotein (AFP) and cell proliferation in regenerating livers of NMRI mice after partial hepatectomy. An immunohistochemical and autoradiographic study with 3H-thymidine

To get more information concerning the relation between cell proliferation and the synthesis of alpha-fetoprotein (AFP), liver regeneration and AFP production was followed simultaneously in short intervals in NMRI mice after two-thirds hepatectomy using autoradiographic and immunohistochemical methods. The results indicate that AFP synthesis is not linked closely to cell proliferation in the sense that each proliferating hepatocyte synthesizes AFP during a definite phase of the cell cycle. However, AFP production, as measured by the index of anti-AFP positive hepatocytes, occurs in a very small population of parenchymal cells when the bulk of the hepatocytes has just passed the S-phase and is considered to be in the G2-, M or early G1-phase of the cell cycle when the cells are still in an undifferentiate state.