The role of polyp-stolon junctions in the redox signaling of colonial hydroids

An encrusting colonial hydroid can be regarded as a network of polyps or ‘mouths’ connected by tube-like stolons. The success of the colony crucially depends on putting these mouths where the available food is. Feeding-related perturbations may provide important signals in this regard. After feeding, polyps contract regularly, dispersing food throughout the colony via the gastrovascular fluid. Mitochondrion-rich epitheliomuscular cells concentrated near polyp-stolon junctions likely drive these contractions. Putatively, the redox state of these cells may influence colony-level form. For instance, the metabolic demand associated with feeding-related contractions results in mitochondria that have relatively oxidized electron carriers and produce lesser amounts of reactive oxygen species (ROS). ROS or other redox-sensitive molecules emitted from polyp-stolon junctions into the gastrovascular fluid may provide stolons with signals influencing elongation, branching, and regression. Treatments of colonies with anti-oxidants cause peripheral stolon tips to rapidly regress. This regression appears to be an active process involving a flux of locally produced peroxides and cell and tissue death. At the same time, polyps and stolon tips in the center of treated colonies remain healthy. ‘Sheet-like’ growth of short, branched stolons ensues. Signals that inhibit the outward growth of stolons may lead by default to the concentrated growth of stolons and polyps in food-rich areas. ROS may mediate signaling mechanisms involving nitric oxide, programmed cell death, a variety of redox-regulated proteins, or all of these.     

Multicellular redox regulation in an early-evolving animal treated with glutathione

Redox signaling has emerged as a unifying theme in many seemingly disparate disciplines. Such signaling has been widely studied in bacteria and eukaryotic organelles and is often mediated by reactive oxygen species (ROS). In this context, reduced glutathione (GSH) acts as an important intracellular antioxidant, diminishing ROS and potentially affecting redox signaling. Complementing this cell-level perspective, colonial hydroids can be a useful model for understanding organism-level redox signaling. These simple, early-evolving animals consist of feeding polyps connected by tubelike stolons. Colonies treated exogenously with GSH or reduced glutathione ethyl ester (GEE) were expected to show a morphological change to sheetlike growth typical of low levels of ROS. Contrary to expectations, diminished stolon branching and polyp initiation was observed. Such runnerlike growth is associated with higher levels of ROS, and surprisingly, such higher levels were found in GSH- and GEE-treated colonies. Further investigations show that GSH triggered a feeding response in hydroid polyps, increasing oxygen uptake but at the same time relaxing mitochondrion-rich contractile regions at the base of polyps. Diminished gastrovascular flow and increased emissions of mitochondrial ROS also correlated with the observed runnerlike growth. In contrast to cell-level, "bottom-up" views of redox signaling, here the phenotype may arise from a "top-down" interaction of mitochondrion-rich regions and organism-level physiology. Such multicellular redox regulation may commonly occur in other animals as well.     

Quantitative measures of gastrovascular flow in octocorals and hydroids: toward a comparative biology of transport systems in cnidarians

Using microscopy, the gastrovascular systems of four hydroids (Eirene viridula, Cordylophora lacustris, Hydractinia symbiolongicarpus, and Podocoryna carnea) and two distantly related alcyonacean octocorals (Acrossota amboinensis and Sarcothelia sp.) were examined and compared within a phylogenetic framework. Despite a range of stolon widths (means 53–160 μm), the hydroid species exhibited similar patterns of gastrovascular flow: sequentially bidirectional flow in the stolons, driven by myoepithelial contractions emanating from the center of the colony. Unlike the hydroids, the gastrovascular system of A. amboinensis (mean stolon widths for 5 colonies, 0.57–1.21 mm) exhibited simultaneously bidirectional flow with incomplete, medial baffles (width 4–20 μm) separating the flow. Baffles visualized with transmission electron microscopy consisted of endoderm, mesoglea, and occasionally another layer of tissue. Mean flow rates of the gastrovascular fluid for seven stolons ranged from 125 to 275 μm s^?1, with maximum rates of 225–700 μm s^?1. In Sarcothelia sp., stolons were of comparable width (means for 13 colonies 0.55–1.4 mm) to those of A. amboinensis. These stolons, however, were divided by several partitions (width 8–25 μm), both complete and incomplete, which were spaced every 100.5±5.1 μm (mean±SE; range 27.1–283.7 μm) and appeared structurally similar to baffles. In lanes defined by these partitions, ciliary motion was visible in image sequences, and flow was unidirectional. Within a single stolon, flow moved in different directions in different lanes and changed direction by moving from lane to lane via occasional spaces between the partitions. Mean flow rates for 30 stolons ranged from 75 to 475 μm s^?1, with maximum rates of 85–775 μm s^?1. For both octocorals, flow rates of the gastrovascular fluid were not correlated with the width of the stolon lumen. While octocoral gastrovascular systems probably exhibit differences based on phylogenetic affinities, in all species studied thus far, gastrovascular flow is entirely driven by cilia, in contrast to the hydroid taxa.     

Circulation of fluids in the gastrovascular system of a stoloniferan octocoral

Cilia-based transport systems characterize sponges and placozoans. Cilia are employed in cnidarian gastrovascular systems as well, but typically function in concert with muscular contractions. Previous reports suggest that anthozoans may be an exception to this pattern, utilizing only cilia in their gastrovascular systems. With an inverted microscope and digital image analysis, we used stoloniferan octocoral colonies growing on microscope cover glass to quantitatively describe the movement of fluids in this system for the first time. Flow in stolons (diameter ≈300 μm) is simultaneously bidirectional, with average velocities of 100-200 μm/s in each direction. Velocities are maximal immediately adjacent to the stolon wall and decrease to a minimum in the center of the stolon. Flow velocity is unaffected by stolonal contractions, suggesting that muscular peristalsis is not a factor in propelling the flow. Stolon intersections (diameter ≈500 μm) occur below polyps and serve as traffic roundabouts with unidirectional, circular flow. Such cilia-driven transport may be the plesiomorphic state for the gastrovascular system of cnidarians.     

Structure and signaling in polyps of a colonial hydroid

Abstract. After feeding, polyps of colonial hydroids contract regularly, dispersing food throughout the colony via the gastrovascular fluid. Such contractions may trigger signaling pathways that allow colonies to grow in an adaptive manner, i.e., to initiate development of more polyps in food‐rich areas and to suppress polyp development in food‐poor areas. In this context, we investigated the structure and potential signaling of the junction between polyps and stolons in colonies of the hydroid Podocoryna carnea. Using transmission electron microscopy, we found that the density of mitochondrion‐rich epitheliomuscular cells was low in polyp and stolon tissues except at or near the polyp‐stolon junction, where many of these mitochondrion‐rich cells occur in ectodermal tissue. In vivo fluorescence microscopy suggests that these mitochondria are a principal source of the metabolic signals of the colony. Both native fluorescence of NAD(P)H and fluorescence from peroxides (visualized with H₂DCFDA) co‐localize to this region of the polyp. Rhodamine 123 fluorescence suggests that both these metabolic signals emanate from mitochondria. To test whether such metabolic signals may be involved in colony pattern formation, inbred lines of P. carnea were used. Colonies of a runner‐like inbred line grow with widely spaced polyps and long stolonal connections, much like wild‐type colonies in a food‐poor environment. Colonies of a sheet‐like inbred line grow with closely spaced polyps and short stolonal connections, similar to wild‐type colonies in a food‐rich environment. Polyp‐stolon junctions in runner‐like and sheet‐like colonies were imaged for the fluorescence of H₂DCFDA. Densitometric analysis of this signal indicates that the mitochondria in epitheliomuscular cells of runner‐like polyps emit greater amounts of peroxides. Because peroxides and other reactive oxygen species are frequently intermediaries in metabolic signaling pathways, we suspect that such signaling may indeed occur at polyp‐stolon junctions, affecting colony pattern formation in these inbred lines and possibly in hydroid colonies in general.     

Differential metabolism of sodium azide in maize callus and germinating embryos

Sodium azide is a potent mutagen of maize (Zea mays L.) kernels that may have potential as a point mutagen for inducing biochemical mutations in maize tissue cultures. Azide mutagenicity was evaluated in friable, embryogenic maize callus and a nonregenerable maize suspension culture by determining the number of resistant variant cell lines able to grow on media containing inhibitory concentrations of lysine plus threonine (LT). The number of LT-resistant variants selected from either culture type did not increase in response to azide treatment. In addition, there was no increase in somatic mutations in more than 100 plants regenerated from azide treated LT-resistant lines. The levels of mutagenic metabolite of azide (presumably azidoalanine), were determined by bioassay in the two azide-treated maize callus types and compared to levels of mutagenic metabolite in embryos isolated from azide-treated kernels. The two types of maize tissue cultures and isolated embryos contained similar levels of mutagenic metabolite 4 h after azide treatment indicating similar uptake and conversion of azide to mutagenic metabolite in the three tissues. Mutagenic metabolite in azide-treated embryos did not significantly decrease after 40 h. However, mutagenic metabolite levels in both azide-treated tissue cultures decreased to near background levels within 20 h providing evidence for rapid metabolism of the azide mutagenic metabolite. The lack of evidence for azide mutagenicity in maize callus and its known potent mutagenicity in kernels appears to be associated with specific differences in azide metabolism between callus tissues and kernel embryos.     

Physiological and metabolic aspects of experimental heterochrony in colonial hydroids

Hydractiniid hydroids display a range of morphological variation from sheet-like to runner-like forms, thus exemplifying the patterns of heterochrony found in many colonial animals. Experimental studies of clonal replicates of a Podocoryne carnea colony demonstrate a relationship between these heterochronic traits and physiological and metabolic factors. While colonies exposed to dilute solutions of 2, 4-dinitrophenol (an uncoupler of oxidative phosphorylation) for 4 hours per day show a strong dose-response relationship between within-colony gastrovascular flow rate and the timing of morphological development, colonies exposed for 20 hours per day fail to show this relationship. Spectrofluorometric measures of redox state suggest that the degree of “loose-coupling” of oxidative phosphorylation is proportional to the exposure time. Thus colonies exposed for 20 hours have significantly diminished ATP production relative to colonies exposed for 4 hours. Two underlying factors may be responsible for the breakdown of the dose-response relationship between flow rate and development: (1) colonies exposed to a high dose of uncoupler for 20 hours per day allocate a larger-than-normal share of their total energy budget into maintaining the minimal flow rate required physiologically, and (2) colonies' redox state has a direct effect on the timing of morphological development. The latter effect is particularly intriguing, given the extensive literature relating “metabolic activity” to development. In general, these results suggest a relationship between energy allocation, metabolism, and development in these hydroids, and these interrelationships may be central to the evolutionary process of heterochrony.     

Variation in growth and competitive ability between sexually and clonally produced hydroids

In controlled laboratory experiments, colonies of Podocoryna carnea typically overgrow and kill colonies of Hydractinia symbiolongicarpus. Generally, these experiments have used colonies grown from tissue explants (clonal replicates) surgically removed from mature colonies taken from natural populations. In contrast, experiments involving interspecific bouts between small, sexually produced colonies reveal that both the characteristics and outcomes of competition differ from previous studies. During competition between small sexually produced colonies, H. symbiolongicarpus exhibits directional growth toward P. carnea and produces nematocyte-rich hyperplastic stolons more readily than P. carnea does. Nevertheless, P. carnea can still overcome H. symbiolongicarpus if it initially grows away from the contact zone and subsequently flanks H. symbiolongicarpus. Overall, sexually produced colonies of H. symbiolongicarpus destroyed their P. carnea counterparts in more than 35% of competitive bouts, whereas P. carnea dominated their H. symbiolongicarpus counterparts in all similar encounters between clonally produced colonies. In natural populations, competition between small sexually produced colonies of H. symbiolongicarpus may predominate, and these results support the hypothesis that this species is adapted to competition early in colony development. More generally, studies of competition between sexually produced colonies should complement similar studies of clonally produced colonies.     

Multicellular redox regulation: integrating organismal biology and redox chemistry

Early in the 20th century, Charles Manning Child attributed organismal gradients in metabolism to interactions among groups of cells. Metabolic gradients are now firmly grounded in redox chemistry, yet modern work on metabolic signaling has consistently focused on the cellular level. Multicellular redox regulation, however, may occur when redox state is determined by the behavior of a group of cells. For instance, typically an abundance of substrate will shift the redox state of mitochondria in the direction of reduction, leading to increased reactive oxygen species (ROS). These ROS, in turn, may modify the conformation and activity of proteins involved in signaling pathways, resulting in phenotypic changes. In contrast, if substrate triggers the contractions of a muscular structure comprising mitochondrion-rich cells, the resulting metabolic demand may shift the redox state in the direction of oxidation, with a corresponding decrease of ROS and different phenotypic effects. Indeed, colonial hydroids exemplify this process. Parallel examples may occur whenever mitochondria are concentrated in cells of structures that can respond to environmental perturbations with increased metabolic demand. In these circumstances, predicting the direction of metabolic signaling may require an understanding of events at the organismal level.     

Evidence that azide occupies the chloride binding site near the manganese cluster in photosystem II

The effect of adding azide to photosystem II (PS II) membrane samples (BBY preparation), with or without chloride, has been investigated using continuous wave (CW) and pulsed EPR spectroscopy. In the BBY samples with 25 mM chloride, we observed that the inhibition induced by azide is partly recovered by the addition of bicarbonate. Electron spin-echo envelope modulation (ESEEM) was used to search for spin transitions of 15N nuclei magnetically coupled to the S2 state Mn cluster (multiline EPR signal form) in 15N (single terminal label) azide-treated samples with negative results. However, an 15N ESEEM peak was observed in parallel chloride-depleted PS II samples when the 15N-labeled azide is added. However, this peak is absent in chloride-depleted samples incubated in buffer containing both chloride and [15N]azide. Thus these results demonstrate an azide binding site in the immediate vicinity of the Mn cluster, and since this site appears to be competitive with chloride, these results provide further evidence that chloride is bound proximal to the Mn cluster as well. Discussion on the possible interplay between azide, chloride, and bicarbonate is provided.     

Metabolic impairment induces oxidative stress, compromises inflammatory responses, and inactivates a key mitochondrial enzyme in microglia

Microglial activation, oxidative stress, and dysfunctions in mitochondria, including the reduction of cytochrome oxidase activity, have been implicated in neurodegeneration. The current experiments tested the effects of reducing cytochrome oxidase activity on the ability of microglia to respond to inflammatory insults. Inhibition of cytochrome oxidase by azide reduced oxygen consumption and increased reactive oxygen species (ROS) production but did not affect cell viability. Azide also attenuated microglial activation, as measured by nitric oxide (NO.) production in response to lipopolysaccharide (LPS). It is surprising that the inhibition of cytochrome oxidase also diminished the activity of the alpha-ketoglutarate dehydrogenase complex (KGDHC), a Krebs cycle enzyme. This reduction was exaggerated when the azide-treated microglia were also treated with LPS. The combination of the azide-stimulated ROS and LPS-induced NO. would likely cause peroxynitrite formation in microglia. Thus, the possibility that KGDHC was inactivated by peroxynitrite was tested. Peroxynitrite inhibited the activity of isolated KGDHC, nitrated tyrosine residues of all three KGDHC subunits, and reduced immunoreactivity to antibodies against two KGDHC components. Thus, our data suggest that inhibition of the mitochondrial respiratory chain diminishes aerobic energy metabolism, interferes with microglial inflammatory responses, and compromises mitochondrial function, including KGDHC activity, which is vulnerable to NO. and peroxynitrite that result from microglial activation. Thus, activation of metabolically compromised microglia can further diminish their oxidative capacity, creating a deleterious spiral that may contribute to neurodegeneration.     

Intraspecific competition in a reef coral: effects on growth and reproduction

Summary Growth rates and reproduction of a branching coral (Stylophora pistillata) were compared in the presence and in the absence of intraspecific competition. Field experiments demonstrated a significant decline in the growth rate of competing colonies compared to noncompeting control colonies; the growth rate slowed in all of the interacting individuals, irrespective of their place in the hierarchy of the intraspecific dominance or of their color morph. In case of immediate killing of the subordinate, the dominant colony grew at a normal rate. In addition to the marked decrease in the growth rate of interacting colonies, the typical symmetry shape of these colonies was changed to an abnormal growth form. The number of female gonads per polyp was significantly reduced in colonies competing intraspecifically, and the typical synchrony in reproduction among different branches of a given colony was changed and desynchronized. Again, these results did not correlate with the hierarchy of dominance. We conclude that intraspecific competition in reef corals involves great investment of energy. The ecological significance and the different pathways of this competition are discussed.     

Nutrient Distribution and Absorption in the Colonial Hydroid Podocoryna carnea Is Sequentially Diffusive and Directional

The distribution and absorption of ingested protein was characterized within a colony of Podocoryna carnea when a single polyp was fed. Observations were conducted at multiple spatial and temporal scales at three different stages of colony ontogeny with an artificial food item containing Texas Red conjugated albumin. Food pellets were digested and all tracer absorbed by digestive cells within the first 2–3 hours post-feeding. The preponderance of the label was located in the fed polyp and in a transport-induced diffusion pattern surrounding the fed polyp. After 6 hours post-feeding particulates re-appeared in the gastrovascular system and their absorption increased the area over which the nutrients were distributed, albeit still in a pattern that was centered on the fed polyp. At later intervals, tracer became concentrated in some stolon tips, but not in others, despite the proximity of these stolons either to the fed polyp or to adjacent stolons receiving nutrients. Distribution and absorption of nutrients is sequentially diffusive and directional.     

Redox control and the evolution of multicellularity

Redox chemistry, involving the transfer of electrons and hydrogen atoms, is central to energy conversion in respiration; in addition, control of gene expression by redox state commonly occurs in bacteria, allowing a rapid response to environmental changes, such as altered food supply. Colonial metazoans often encrust surfaces over which the food supply varies in time or space; hence, in these organisms redox control of the development of feeding structures and gastrovascular connections could be similarly adaptive, allowing colonies to adjust the timing of development and spacing of structures in response to a variable food supply and other environmental factors. Experimental perturbations of redox state in colonial hydroids support this notion of adaptive redox control, and redox signaling in metazoans may have evolved in this ecological context. At the same time, redox signaling has important consequences for the evolutionary transition from unicellular to multicellular organisms. Unlike protein or peptide signaling, redox signaling acting in concert with programmed cell death may automatically inflict a cost on those cells that "defect," that is, selfishly favor their own replication rate over that of the multicellular group. In this way, redox signaling may have allowed multicellular individuality to evolve and more easily be maintained.     

Mitochondria as integrators of information in an early-evolving animal: insights from a triterpenoid metabolite

Mitochondria have the capacity to integrate environmental signals and, in animals with active stem cell populations, trigger responses in terms of growth and growth form. Colonial hydroids, which consists of feeding polyps connected by tube-like stolons, were treated with avicis, triterpenoid electrophiles whose anti-cancer properties in human cells are mediated in part by mitochondria. In treated hydroids, both oxygen uptake and mitochondrial reactive oxygen species were diminished relative to controls, similar to that observed in human cells exposed to avicins. While untreated colonies exhibit more stolon branches and connections in the centre of the colony than at the periphery, treated colonies exhibit the opposite: fewer stolon branches in the centre of the colony than at the periphery. The resulting growth form suggest an inversion of the normal pattern of colony development mediated by mitochondrial and redox-related perturbations. An as-yet-uncharacterized gradient within the colony may determine the ultimate phenotypic effects of avicin perturbation.     

The Selective Myosin II Inhibitor Blebbistatin Reversibly Eliminates Gastrovascular Flow and Stolon Tip Pulsations in the Colonial Hydroid Podocoryna carnea

Blebbistatin reversibly disrupted both stolon tip pulsations and gastrovascular flow in the colonial hydroid Podocoryna carnea. Epithelial longitudinal muscles of polyps were unaffected by blebbistatin, as polyps contracted when challenged with a pulse of KCl. Latrunculin B, which sequesters G actin preventing F actin assembly, caused stolons to retract, exposing focal adhesions where the tip epithelial cells adhere to the substratum. These results are consistent with earlier suggestions that non-muscle myosin II provides the motive force for stolon tip pulsations and further suggest that tip oscillations are functionally coupled to hydrorhizal axial muscle contraction.     

The morphogenetic potentials of endometrial and ovarian tumor cells when cultured on soft agar]

Morphofunctional peculiarities of tumor cells from 15 endometrial adenocarcinomas and 2 ovarian tumors have been investigated at the ultrastructural level. These cells could develop two types of colonies in soft agar: those with histotypical differentiation (numerous microvilli, well developed tight junctions, desmosomes, secretory granules), and those without it (absence of epithelial features, ability of tumor cells to produce filamentous extracellular matrix and striated collagen fibrils which are characteristic of fibroblastic cells). The addition of progesterone and tamoxifen to cell cultures resulted in rising the level of cell differentiation in the colonies. The fact that endometrial and ovarian cancer cells can express the properties specific of connective tissue cells may suggest a multipotention of the Mullerian epithelium derivatives to shed light on the histogenesis of the mixed Mullerian tumors of uterus.     

Mutagenesis of Saccharomyces cerevisiae by sodium azide activated in barley.

Concentrated dialysate of the extract prepared from barley seeds treated with sodium azide increased up to 100--200 times the frequency of forward mutations to cycloheximide resistance in the excision-deficient UV-sensitive heploid strain rad2-5 of Saccharomyces cerevisiae, when applied to growing cells in complete medium at pH 4.2. Only a slight increase of mutation frequency (less than 4 times) was found in the haploid RAD+ strain treated in the same way as well as in haploid RAD+ and rad2-5 strains treated directly by sodium azide. In contrast with the barley-activated sodium azide, UV irradiation was more effective in the induction of cycloheximide resistance in the RAD+ strain than in the RAD2-5 mutant. The dialysate from azide-treated barley seeds, applied at both pH 4.2 and pH 9, also significantly increased the frequency of locus-specific suppressor mutations to isoleucine independence and -- to a lesser extent -- reversions and/or gene conversions in the trp5 locus in growing cells of the diploid strain D7. The dialysate was also mutagenic in resting cells of strains D7 and rad2-5 but with lower effectiveness.     

In vivo time-lapse imaging of synaptic takeover associated with naturally occurring synapse elimination

During development, competition between axons causes permanent removal of synaptic connections, but the dynamics have not been directly observed. Using transgenic mice that express two spectral variants of fluorescent proteins in motor axons, we imaged competing axons at developing neuromuscular junctions in vivo. Typically, one axon withdrew progressively from postsynaptic sites and the competing axon extended axonal processes to occupy those sites. In rare instances when the remaining axon did not reoccupy a site, the postsynaptic receptors rapidly disappeared. Interestingly, the progress and outcome of competition was unpredictable. Moreover, the relative areas occupied by the competitors shifted in favor of one axon and then the other. These results show synaptic competition is not always monotonic and that one axon's contraction in synaptic area is associated with another axon's expansion.     

Intracellular calcium waves in bone cell networks under single cell nanoindentation

In this study, bone cells were successfully cultured into a micropatterned network with dimensions close to that of in vivo osteocyte networks using microcontact printing and self-assembled monolyers (SAMs). The optimal geometric parameters for the formation of these networks were determined in terms of circle diameters and line widths. Bone cells patterned in these networks were also able to form gap junctions with each other, shown by immunofluorescent staining for the gap junction protein connexin 43, as well as the transfer of gap-junction permeable calcein-AM dye. We have demonstrated for the first time, that the intracellular calcium response of a single bone cell indented in this bone cell network, can be transmitted to neighboring bone cells through multiple calcium waves. Furthermore, the propagation of these calcium waves was diminished with increased cell separation distance. Thus, this study provides new experimental data that support the idea of osteocyte network memory of mechanical loading similar to memory in neural networks.