Further characterization of the PW peptide family that inhibits neuron differentiation in <Emphasis Type="Italic">Hydra</Emphasis>

From an evolutionary point of view, Hydra has one of the most primitive nervous systems among metazoans. Two different groups of peptides that affect neuron differentiation were identified in a systematic screening of peptide signaling molecules in Hydra. Within the first group of peptides, a neuropeptide, Hym-355, was previously shown to positively regulate neuron differentiation. The second group of peptides encompasses the PW family of peptides that negatively regulate neuron differentiation. In this study, we identified the gene encoding PW peptide preprohormone. Moreover, we made the antibody that specifically recognizes LPW. In situ hybridization and immunohistochemical analyses showed that the PW peptides and the gene encoding them were expressed in ectodermal epithelial cells throughout the body except for the basal disk. The PW peptides are produced by epithelial cells and are therefore termed “epitheliopeptides.” Together with Hym-355, the PW family peptides mediate communication between neurons and epithelial cells and thereby maintain a specific density of neurons in Hydra. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Toshio Takahashi, Osamu Koizumi equally contributed to this study.     

Identification of a vasopressin-like immunoreactive substance in hydra

Vasopressin (VP)-like immunoreactivity has long been known in the hydra nervous system, but has not yet been structurally identified. In this study, using HPLC fractionation and an immunological assay, we have purified two peptides, FPQSFLPRGamide and SFLPRGamide, from Hydra magnipapillata. Both the peptides shared the same C-terminal structure, -PRGamide, with Arg-VP. The nonapeptide proved to be Hym-355, a peptide that stimulates neuronal differentiation in hydra. Detailed evaluation by competitive enzyme-linked immunosorbent assay (ELISA) and double immunostaining using anti-VP and anti-Hym-355 antibodies enabled us to conclude that the two peptides account for a major part of the VP-like immunoreactivity in hydra nerve cells.     

Enhancement of foot formation in Hydra by a novel epitheliopeptide, Hym-323

During the course of a systematic screening of peptide signaling molecules in Hydra magnipapillata, a novel peptide, Hym-323, which enhances foot regeneration was identified. The peptide is 16 amino acids long, and is encoded in the precursor protein as a single copy. Northern blot analysis, in situ hybridization analysis and immunohistochemistry showed that it was expressed in both ectodermal and endodermal epithelial cells throughout the body, except for the basal disk and the head region. The peptide enhanced foot regeneration by acting on epithelial cells. Lateral transplantation experiments indicated that the foot activation potential was increased in the peptide-treated tissue. These results suggest that Hym-323 is a peptide involved in a foot-patterning process in Hydra.     

A new case of neuropeptide coexpression (RGamide and LWamides) in Hydra,found by whole-mount,two-color double-labeling in situ hybridization

The freshwater polyp Hydra has a primitive nervous system that expresses at least six different neuropeptide genes: (1) three genes, coding for the preprohormones-A, -B, and -C that each gives rise to a variety of peptides with the C-terminal sequence Arg-Phe-NH(2) (the Hydra-RFamides); (2) one gene, coding for a preprohormone that gives rise to five peptides with the C-terminal sequence Leu-Trp-NH(2) (the Hydra-LWamides); (3) one gene, coding for a preprohormone that produces a peptide with the C-terminal sequence Lys-Val-NH(2) (Hydra-KVamide, also called Hym-176); and (4) one gene, coding for a preprohormone that gives rise to a peptide with the C-terminal sequence Arg-Gly NH(2) (Hydra-RGamide, also called Hym-355). In a previous paper, we described that a population of neurons in the peduncle (a region just above the foot) of Hydra coexpresses the preprohormone-A and KVamide genes, whereas neurons in the other regions only express either the preprohormone-A, -B, -C, LWamide, or the KVamide genes. Here, we investigated the RGamide gene expression, using whole-mount, two-color double-labeling in situ hybridization, and found that neurons in the basal disk (foot), gastric region, hypostome (a region around the mouth), and tentacles coexpress this gene together with the LWamide gene. A small population of neurons in the hypostome and upper gastric region expresses only the LWamide gene. No coexpression of the RGamide gene with any of the other neuropeptide genes was observed. This is the second example of coexpression of two neuropeptide genes in cnidarians. It demonstrates that many neurons in the primitive nervous systems of cnidarians use combinations ("cocktails") of neuropeptides for their signaling. It also shows that Hydra has at least seven neurochemically different populations of neurons.     

Polyps, peptides and patterning

Peptides serve as important signalling molecules in development and differentiation in the simple metazoan Hydra. A systematic approach (The Hydra Peptide Project) has revealed that Hydra contains several hundreds of peptide signalling molecules, some of which are neuropeptides and others emanate from epithelial cells. These peptides control biological processes as diverse as muscle contraction, neuron differentiation, and the positional value gradient. Signal peptides cause changes in cell behaviour by controlling target genes such as matrix metalloproteases. The abundance of peptides in Hydra raises the question of whether, in early metazoan evolution, cell-cell communication was based mainly on these small molecules rather than on the growth-factor-like cytokines that control differentiation and development in higher animals.     

Identification of a new member of the GLWamide peptide family: physiological activity and cellular localization in cnidarian polyps

KPNAYKGKLPIGLWamide, a novel member of the GLWamide peptide family, was isolated from Hydra magnipapillata. The purification was monitored with a bioassay: contraction of the retractor muscle of a sea anemone, Anthopleura fuscoviridis. The new peptide, termed Hym-370, is longer than the other GLWamides previously isolated from H. magnipapillata and another sea anemone, A. elegantissima. The amino acid sequence of Hym-370 is six residues longer at its N-terminal than a putative sequence previously deduced from the cDNA encoding the precursor protein. The new longer isoform, like the shorter GLWamides, evoked concentration-dependent muscle contractions in both H. magnipapillata and A. fuscoviridis. In contrast, Hym-248, one of the shorter GLWamide peptides, specifically induced contraction of the endodermal muscles in H. magnipapillata. This is the first case in which a member of the hydra GLWamide family (Hym-GLWamides) has exhibited an activity not shared by the others. Polyclonal antibodies were raised to the common C-terminal tripeptide GLWamide and were used in immunohistochemistry to localize the GLWamides in the tissue of two species of hydra, H. magnipapillata and H. oligactis, and one species of sea anemone, A. fuscoviridis. In each case, nerve cells were specifically labeled. These results suggest that the GLWamides are ubiquitous among cnidarians and are involved in regulating the excitability of specific muscles.     

Regionalized nervous system in Hydra and the mechanism of its development

The last common ancestor of Bilateria and Cnidaria is considered to develop a nervous system over 500 million years ago. Despite the long course of evolution, many of the neuron-related genes, which are active in Bilateria, are also found in the cnidarian Hydra. Thus, Hydra is a good model to study the putative primitive nervous system in the last common ancestor that had the great potential to evolve to a more advanced one. Regionalization of the nervous system is one of the advanced features of bilaterian nervous system. Although a regionalized nervous system is already known to be present in Hydra, its developmental mechanisms are poorly understood. In this study we show how it is formed and maintained, focusing on the neuropeptide Hym-176 gene and its paralogs. First, we demonstrate that four axially localized neuron subsets that express different combination of the neuropeptide Hym-176 gene and its paralogs cover almost an entire body, forming a regionalized nervous system in Hydra. Second, we show that positional information governed by the Wnt signaling pathway plays a key role in determining the regional specificity of the neuron subsets as is the case in bilaterians. Finally, we demonstrated two basic mechanisms, regionally restricted new differentiation and phenotypic conversion, both of which are in part conserved in bilaterians, are involved in maintaining boundaries between the neuron subsets. Therefore, this study is the first comprehensive analysis of the anatomy and developmental regulation of the divergently evolved and axially regionalized peptidergic nervous system in Hydra, implicating an ancestral origin of neural regionalization.     

Hydra Peptide Project 1993–2007

A systematic screening of peptide signaling molecules (<5000 da) in Hydra magnipapillata (the Hydra Peptide Project) was launched in 1993 and at least the first phase of the project ended in 2007. From the project a number of interesting suggestions and results have been obtained. First, a simple metazoan-like Hydra appears to contain a few hundred peptide signaling molecules: half of them neuropeptides and the rest epitheliopeptides that are produced by epithelial cells. Second, epitheliopeptides were identified for the first time in Hydra . Some exhibit morphogen-like activities, which accord with the notion that epithelial cells are primarily responsible for patterning in Hydra . A family of epitheliopeptides was involved in regulating neuron differentiation possibly through neuron–epithelial cell interaction. Third, many novel neuropeptides were identified. Most of them act directly on muscle cells inducing contraction or relaxation. Some were involved in cell differentiation and morphogenesis. During the course of this study, a number of important technical innovations (e.g. genetic manipulations in transgenic Hydra , high-throughput purification techniques, etc.) and expressed sequence tag (EST) and genome databases were introduced in Hydra research. They have already helped to identify and characterize novel peptides and will contribute even more to the Hydra Peptide Project in the near future.     

Subcellular localization of the epitheliopeptide, Hym-301, in hydra

Peptides, as signaling molecules, play a number of roles in cell activities. An epitheliopeptide, Hym-301, has been described as a peptide involved in morphogenesis in hydra. However, little is known about the intracellular location of the peptide or its specific functions. To investigate the mechanism of morphogenesis that involves peptidic molecules, we have examined the intracellular localization of Hym-301 in hydra by using immunohistochemical and immunogold electron-microscopic analyses. We have found that the pattern of distribution of mature peptide is slightly different from that of its mRNA, and that the peptide is stored in vesicles located adjacent to the cell membrane. We have also found that the peptide is released both extracellularly and internally to the cytoplasm of the cells. Based upon these observations, we have constructed a possible model mechanism of homeostatic regulation of the distribution of the Hym-301 peptide in a dynamic tissue context.     

Hym-301, a novel peptide, regulates the number of tentacles formed in hydra

Hym-301 is a peptide that was discovered as part of a project aimed at isolating novel peptides from hydra. We have isolated and characterized the gene Hym-301, which encodes this peptide. In an adult, the gene is expressed in the ectoderm of the tentacle zone and hypostome, but not in the tentacles. It is also expressed in the developing head during bud formation and head regeneration. Treatment of regenerating heads with the peptide resulted in an increase in the number of tentacles formed, while treatment with Hym-301 dsRNA resulted in a reduction of tentacles formed as the head developed during bud formation or head regeneration. The expression patterns plus these manipulations indicate the gene has a role in tentacle formation. Furthermore, treatment of epithelial animals indicates the gene directly affects the epithelial cells that form the tentacles. Raising the head activation gradient, a morphogenetic gradient that controls axial patterning in hydra, throughout the body column results in extending the range of Hym-301 expression down the body column. This indicates the range of expression of the gene appears to be controlled by this gradient. Thus, Hym-301 is involved in axial patterning in hydra, and specifically in the regulation of the number of tentacles formed.     

Neuron differentiation in hydra involves dividing intermediates

The neuron differentiation pathway in hydra is usually assumed to be the following. A multipotent stem cell among the large interstitial cells becomes committed to neuron differentiation and divides. The two daughter cells, which are postmitotic small interstitial cells, subsequently differentiate into neurons. Herein the neuron pathway of the lower peduncle of Hydra oligactis was examined in some detail. In this region a substantial amount of neuron differentiation takes place, but very few large interstitial cells are present. It was found that small interstitial cells, which are capable of dividing, differentiate into neurons. The minimum time required to traverse the pathway from S phase of the last proliferating intermediate to a neuron is 18 hr. Thus, the neuron differentiation pathway in the lower peduncle involves dividing intermediates and is therefore more complex than usually assumed. Evidence for dividing small interstitial cells in the head, where the highest rate of neuron differentiation occurs, suggests that this more complex pathway may be common to all regions of the animal. A consequence of this finding is that the body of evidence concerning the commitment of multipotent stem cells to neurons and the control of this commitment requires reinterpretation.     

Components, structure, biogenesis and function of the Hydra extracellular matrix in regeneration, pattern formation and cell differentiation

The body wall of Hydra is organized as an epithelial bilayer (ectoderm and endoderm) with an intervening extracellular matrix (ECM), termed mesoglea by early biologists. Morphological studies have determined that Hydra ECM is composed of two basal lamina layers positioned at the base of each epithelial layer with an intervening interstitial matrix. Molecular and biochemical analyses of Hydra ECM have established that it contains components similar to those seen in more complicated vertebrate species. These components include such macromolecules as laminin, type IV collagen, and various fibrillar collagens. These components are synthesized in a complicated manner involving cross-talk between the epithelial bilayer. Any perturbation to ECM biogenesis leads to a blockage in Hydra morphogenesis. Blockage in ECM/cell interactions in the adult polyp also leads to problems in epithelial transdifferentiation processes. In terms of biophysical parameters, Hydra ECM is highly flexible; a property that facilitates continuous movements along the organism's longitudinal and radial axis. This is in contrast to the more rigid matrices often found in vertebrates. The flexible nature of Hydra ECM can in part now be explained by the unique structure of the organism's type IV collagen and fibrillar collagens. This review will focus on Hydra ECM in regard to: 1) its general structure, 2) its molecular composition, 3) the biophysical basis for the flexible nature of Hydra's ECM, 4) the relationship of the biogenesis of Hydra ECM to regeneration of body form, and 5) the functional role of Hydra ECM during pattern formation and cell differentiation.     

Neuropeptides trigger oocyte maturation and subsequent spawning in the hydrozoan jellyfish Cytaeis uchidae

Oocyte maturation and subsequent spawning in hydrozoan jellyfish are generally triggered by light‐dark cycles. To examine if the initiation of the maturation process after light stimulus is mediated by neurotransmitters, neuropeptides isolated originally from Hydra magnipapillata were applied to sexually mature female medusae of the hydrozoan jellyfish Cytaeis uchidae. Among the Hydra neuropeptides tested, Hym‐53 (NPYPGLW‐NH₂), as well as a nonphysiological peptide, CGLWamide (CGLW‐NH₂), were most effective in inducing oocyte maturation and spawning. Hym‐355 (FPQSFLPRG‐NH₂) also triggered these events, but the stimulatory effect was weaker. Since Hym‐53‐OH (NPYPGLW) and Hym‐355‐OH (FPQSFLPRG) had no effect, amidation at the C‐terminus may be critical for the stimulatory activities of the peptides. Exposure to Hym‐53 for 2 min was sufficient to trigger of oocyte maturation, and the spawned eggs were able to be fertilized and to develop normally. Transmission electron microscopy confirmed that bundles of axon‐like structures that contain dense‐core synaptic vesicles and microtubules are present in the ovarian ectodermal epithelium overlying the oocytes. In addition, immunohistological analyses revealed that some of the neurons in the ectodermal epithelium are GLWamide‐ and PRGamide‐positive. These results suggest that a neuropeptide signal transduction pathway is involved in mediating the induction of oocyte maturation and spawning in this jellyfish. Mol. Reprod. Dev. 80: 223–232, 2013. © 2013 Wiley Periodicals, Inc.     

Interstitial stem cells in Hydra: multipotency and decision-making

Interstitial stem cells in Hydra constitute a population of multipotent cells, which continuously give rise to differentiated products during the growth and budding of Hydra polyps. They also give rise to germ cells in animals undergoing sexual differentiation. Cloning experiments have shown that interstitial stem cells are multipotent. In vivo tracing of stem cell lineages has revealed that stem cells divide symmetrically to yield two stem cells or asymmetrically to yield one stem cell daughter and one daughter cell which initiates nerve or nematocyte differentiation. Following commitment, some nerve cell precursors migrate from the body column into the head or foot region, thus giving rise to the high density of nerve cells observed in these regions. Stem cell proliferation is regulated by changes in the self-renewal probability and is controlled by stem cell density. Nerve cell commitment is controlled by several peptides including the Head Activator. Factors affecting nematocyte commitment are not known, but wnt and notch signaling are both required for differentiation of committed precursors.