Action of the head activator on the determination of interstitial cells in hydra.

In addition to its role as a growth hormone (preceding paper), at the cellular level the head activator functions as one of the substances which control the determination of uncommitted stem cells in hydra. In the presence of head activator the determination of interstitial stem cells to nerve cells is stimulated, the determination of interstitial cells to nematocytes is inhibited. The determination of interstitial cells to nerves occurs shortly before or in the very early S period of interstitial cells.     

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.     

Characterisation of two types of head activator receptor on hydra cells

A head activator (HA) analogue is described which even at high concentrations does not lose its biological activity. By cross-linking two HA molecules over a C8 spacer, the conformation was sufficiently altered, such that self-inactivation of HA by dimerisation was prevented. In addition, the introduction of a tyrosine instead of phenylalanine in one of the two HA molecules allowed radioactive labelling with iodine. This HA bipeptide was used to investigate the effect of HA at different concentrations and as ligand for HA receptor characterisation. We found that low concentrations (0.1-10 pM) sufficed to stimulate interstitial cell mitosis, and that higher concentrations (10-1000 pM) were required for the determination of interstitial cells to nerve cells. Binding of the radioactive HA ligand to living hydra and to purified membrane fractions was saturable and specific. Binding was compatible with HA analogues with a stable monomeric conformation, but less well with dimerising HA and HA analogues. Scatchard and kinetic analyses revealed the presence of at least two types of binding site in the membrane fraction, one with a 'lower' affinity (Kd = 10(-9) M) and one with a 100-fold higher affinity (Kd = 10(-11) M). Autoradiography showed that interstitial cells were differentially labelled, suggesting that the number or types of HA receptors may vary depending on cell cycle status. A mutant of hydra with a multiheaded morphology contained 6-20-times more HA receptors per mg protein than other hydra species or mutants.     

Head activator and head inhibitor are signals for nerve cell differentiation in hydra

Head activator and head inhibitor control nerve cell differentiation in hydra. Head activator acts as a stimulatory signal on nerve cell differentiation by forcing nerve cell precursors, which are arrested before final differentiation, to develop into mature nerve cells. Head inhibitor acts antagonistically by keeping the cells in their arrested state, before mitosis and terminal differentiation. This and other evidence suggest that the arrest of the nerve cell precursors occurs in the G₂-phase of their cell cycle. Nerve cell differentiation can also be induced by wounding the animal. This is a consequence of an initial disinhibition caused by diffusion of head inhibitor out of the tissue and the subsequent release of head activator which then stimulates nerve cell differentiation.     

Actions of head activator and head inhibitor during regeneration in hydra

Abstract. Head regeneration in hydra is initiated by an extensive release of head inhibitor and head activator from tissue close to the cut surface. Release of both substances is less extensive after removal of the foot. Incubation of regenerating animals in medium with head inhibitor blocks not only regeneration of a new head but also release of head activator and head inhibitor. No effect was found of the head activator on the release of both substances. Release of head-specific substances is thus controlled by the inhibitor alone. Cellular determination in a head-specific direction and the production of new sources for head factors requires head activator.     

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.     

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.     

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.     

Collagen and the proliferation and differentiation of rat ventral prostate epithelial cells

The purpose of this study was to determine if a cause-and-effect relationship exists between androgen-induced changes in collagen and epithelial cell proliferation and/or differentiation in rat ventral prostate. Analyses of the temporal relationship between dihydrotestosterone (DHT)-induced changes in the synthesis and levels of collagen in the regressed ventral prostates of adult castrates demonstrated that, during the first 7 days of restoration of prostatic growth, androgen increased the synthesis as well as the degradation of collagen. Cis-hydroxyproline (CHP) treatment (2-200 mg/kg) during the first 7 days of androgen-stimulated prostatic growth, combined with maintenance of animals on a proline-free diet, produced a dose-dependent reduction in prostate weight and DNA content to a maximum of 50%. The epithelium was characterized by numerous disorganized layers of irregularly shaped and tightly packed cells, many of which had no contact with the basal lamina. There was a loss of epithelial lamina lucida and the development of a ragged lamina densa. Cis-hydroxyproline effects were reversible in that, following cessation of CHP treatment, the perturbed morphology, DNA content, and organ weight returned to the range of DHT-treated controls. Collagenous components seem to be important in supporting the normal androgen-dependent proliferation and differentiation of prostatic epithelial cells.     

Production and characterization of monoclonal antibodies recognizing head activator in precursor form and immunocytochemical localization of head activator precursor and head activator peptide in the neural cell line NH15-CA2 and in hydra

A synthetic gene for the hydra neuropeptide head activator (HA) was used to produce large amounts of an HA bacterial fusion protein. From this protein an HA-containing fragment was cleaved out, attached in high copy number to carrier proteins, and used as an immunogen to produce monoclonal antibodies able to recognize head activator in precursor form. Using such antibodies and others with different specificities for HA epitopes in combination with different fixation procedures, we detected HA immunoreactivity in three locations in the HA-rich neural cell line NH15-CA2. A precursor-like HA immunoreactivity was present in the cytoplasm of cells and detected, independent of fixation procedure, by monoclonal antibodies characterized as HA-precursor-specific. With antibodies specific for the HA peptide, two immunoreactivities could be distinguished, one within cells and one at the outer cell membrane. HA was detected within differentiated cells with long processes when crosslinkers such as carbodiimide or glutaraldehyde were applied together with agents like methanol. HA peptide bound to target cells was restricted to small round cells with an undifferentiated morphology, especially to those in the process of cell division. In hydra HA precursor immunoreactivity was localized in interstitial cells and in developing nerve cells. HA peptide immunoreactivity was present in nerve cells, but was more concentrated on and in target cells such as interstitial cells and epithelial cells. In tissue sections immunoreactive cells were especially abundant in regions of high HA content such as hypostome, subhypostomal region, and the future head region of developing buds.     

Effect of neurotrophins on differentiation, calcification and proliferation in cultures of human pulp cells

Neurotrophins (NTs) are expressed during tooth development. However, little is known about a role of NTs in differentiation of pulp cells into mineralizing cells. In this study, mRNA expressions of hard tissue-related proteins, calcification and proliferation are examined in cultures of human pulp (HP) cells. Nerve growth factor (NGF), brain derived neurotrophic factor (BDNF), neurotrophin (NT)-3 and NT-4/5 increased the mRNA levels of dentin sialophsphoprotein, alkaline phosphatase, osteopontin, type I collagen and bone morphogenetic protein-2 and mineral deposition in cultures of HP cells. The increased levels and manners varied, depending on the concentrations of NTs and hard-tissue related protein tested. On the other hand, only NGF significantly stimulated DNA synthesis in cultures of HP cells. These findings suggest that NTs characteristically regulate hard-tissue related protein expression, calcification and proliferation in pulp cells. NTs may accelerate pulp cell differentiation.     

Regulation of proliferation and differentiation of respiratory tract epithelial cells by TGF beta

In this paper we examined the effects of transforming growth factor beta (TGF beta) on the proliferation and differentiation of rabbit tracheal epithelial cells in primary culture. Treatment of these cells with TGF beta inhibits cell proliferation in a time- and dose-dependent manner; concentrations as low as 1 pM are able to inhibit cell growth. Concomitantly, TGF beta causes cells to accumulate in the G0/G1 phase of the cell cycle and a sharp reduction in the ability of the cells to form colonies after subculture at clonal density. These results indicate that TGF beta induces terminal cell division in these cells. The inhibition of cell growth is accompanied by changes in cell morphology and a stimulation of the formation of cross-linked envelopes. TGF beta enhances the levels of transglutaminase activity and cholesterol sulfate, two markers of squamous differentiation. Our results indicate that TGF beta induces terminal squamous cell differentiation in rabbit tracheal epithelial cells. Retinoic acid (RA) does not affect the commitment to terminal cell division induced by TGF beta, but inhibits the expression of the squamous phenotype. Growth of normal human bronchial epithelial cells was affected by TGF beta in a way similar to that of rabbit tracheal epithelial cells. Several carcinoma cell lines tested were quite resistant to TGF beta, whereas growth of one carcinoma cell line was stimulated by TGF beta. These results indicate that a modified response to TGF beta could be one mechanism involved in the aberrant growth control of malignant cells.     

Novel function of keratins 5 and 14 in proliferation and differentiation of stratified epithelial cells

Keratins are cytoplasmic intermediate filament proteins preferentially expressed by epithelial tissues in a site-specific and differentiation-dependent manner. The complex network of keratin filaments in stratified epithelia is tightly regulated during squamous cell differentiation. Keratin 14 (K14) is expressed in mitotically active basal layer cells, along with its partner keratin 5 (K5), and their expression is down-regulated as cells differentiate. Apart from the cytoprotective functions of K14, very little is known about K14 regulatory functions, since the K14 knockout mice show postnatal lethality. In this study, K14 expression was inhibited using RNA interference in cell lines derived from stratified epithelia to study the K14 functions in epithelial homeostasis. The K14 knockdown clones demonstrated substantial decreases in the levels of the K14 partner K5. These cells showed reduction in cell proliferation and delay in cell cycle progression, along with decreased phosphorylated Akt levels. K14 knockdown cells also exhibited enhanced levels of activated Notch1, involucrin, and K1. In addition, K14 knockdown AW13516 cells showed significant reduction in tumorigenicity. Our results suggest that K5 and K14 may have a role in maintenance of cell proliferation potential in the basal layer of stratified epithelia, modulating phosphatidylinositol 3-kinase/Akt-mediated cell proliferation and/or Notch1-dependent cell differentiation.