Competition for space among sessile marine invertebrates: changes in HSP70 expression in two Pacific cnidarians

The evolution of the irreversible transition from a free-swimming state to an immobile sessile state in aquatic invertebrates modelled in a chemostat

To better understand the environmental factors and ecological processes underlying the evolution of the irreversible transition from a free-swimming state to an immobile sessile state as seen in many aquatic invertebrates, we study the adaptive dynamics of the settling rate of a hypothetical microorganism onto the wall of a chemostat. The two states, floating or settled, differ in their nutrient ingestion, reproduction and death rate. We consider three different settling mechanisms involving competition for space on the wall: (i) purely exploitative competition where free-swimming individuals settle in vacant space only, (ii) mixed exploitative and interference competition where individuals attempt to settle in any place but fail and die if the space is already occupied, and (iii) mixed exploitative and interference competition, but now settling in occupied space is successful and the former occupant dies. In the simplified environment of the chemostat, the input concentration of nutrients and the dilution rate of the tank are the main environmental control variables. Using the theory of adaptive dynamics, we find that the settling mechanisms and environmental control variables have qualitatively different effects on the evolution of the settling rate in terms of the direction of evolution as well as on species diversity. In the case of purely exploitative competition a small change in the settings of the environmental control variables can lead to an abrupt reversal of the direction of evolution, while in the case of mixed exploitative and interference competition the effect is gradual. For all three settling mechanisms, periodic fluctuations in the nutrient input open the possibility of evolutionary branching leading to the long-term coexistence of an intermediate and an infinitely high settling rates (in the case of low-frequency fluctuations), and an intermediate and a zero settling rates (in the case of high-frequency fluctuations).

Bio-effect-monitoring of long-term thermal wastes on the oyster, Crassostrea gigas, using heat shock proteins

We bio-monitored the stress of oyster, Crassostrea gigas, for possible long term effects of thermal waste from a power plant. The expression level of its heat shock proteins (HSPs) was measured by real time-reverse transcript PCR along with their density and growth in the field. Oyster size varied in a distance dependent pattern. Physics modeling for evaluation of spreading of the thermal effluent revealed that station A is affected by the thermal effluents abundance, and the size of C. gigas showed a negative relationship with distance to the power plant. The abundance and size of C. gigas were smallest at station A, which was closest to the thermal effluent outlet. The kinetics of changes in the hsp70 and hsp90 mRNA levels in the mantle of C. gigas were also investigated. Regardless of the higher expression level of hsp70 mRNA than hsp90, both hsp70 and hsp90 mRNA levels were significantly higher at station A. The expression levels decreased inversely with distance from the thermal effluent outlet, with expression of hsp70 mRNA at station A being approximately 7-fold higher than at station B and 15-fold higher than at station C. Similarly, expression of hsp90 mRNA at station A was approximately 14-fold higher than at station B and 22-fold higher than at station C. The present findings provide new insights on biological correlation among the growth of individuals and population size and the molecular index in C. gigas following thermal effects.

Chemical Ecology of Wave-Swept Shores: the Primacy of Contact Cues in Predation by Whelks

Wave-swept shores are valuable for developing and testing key ecological principles. A synthesis of research is nonetheless missing a critical component: the chemosensory basis for behavioral interactions that determine population- and community-wide attributes. Chemical signaling environments on wave-swept shores, given their intense, turbulent mixing and complex topographies, would be difficult or impossible to simulate in a laboratory setting. For this reason, appropriately scaled field studies are needed to advance understanding of chemical stimuli and their biotic effects. Here, we performed a field investigation to establish the relative roles of dissolved and contact cues in predation by whelks (Acanthinucella spirata) on barnacles (Balanus glandula), their preferred prey. Experiments tested responses of whelks to seawater drawn above dense prey patches (10,240-12,180 barnacles m^-2) and also over adjacent sand flats (no prey present). There was no evidence of waterborne stimuli associated with prey, even when sea states were nearly tranquil. Field trials also tested faux prey, which were constructed from cleaned barnacle shells and flavored gels. Prospective contact cues were presented to whelks at concentrations typical of epidermal tissue and cuticle in live, intact barnacles. These compounds were highly effective inducers of attack behavior and feeding. Selective enzyme degradations showed that the bioactive material was proteinaceous. Moreover, whelks did not distinguish faux barnacles with a single, purified glycoprotein (named "MULTIFUNCin") from live counterparts. Combined field results thus demonstrate the importance of contact cues, and indicate little, if any, effect of waterborne cues on predation by whelks under native conditions. Our findings underscore the need for appropriately scaled field experiments, and highlight surface chemistry as a critical factor that drives trophic interactions on rocky, wave-swept shores.

Hsp60 expression profiles in the reef-building coral Seriatopora caliendrum subjected to heat and cold shock regimes

Climate changes have increased the intensity/frequency of extreme thermal events, which represent serious threats to the health of reef-building corals. Since the vulnerability of corals exposed to thermal stresses are related to their ability to regulate Heat shock proteins (Hsps), we have analyzed together the time related expression profiles of the mitochondrial Hsp60 and the associated changes in tissue pigmentation in Seriatopora caliendrum subjected to 48 h of heat and cold treatments characterized by moderate (±2 °C) and severe (±6 °C) shocks. For the first time, an Hsp60 response was observed in a scleractinian coral exposed to cold stresses. Furthermore, the Hsp60 modulations and the changes in the tissue coloration were found to be specific for each treatment. A strong down-regulation at the end of the treatments was observed following both the severe shocks, but only the severe heat stress led to bleaching in concert with the lowest levels of Hsp60, suggesting that a severe heat shock can be more deleterious than an exposure to a severe cold temperature. On the contrary, a moderate cold stress seems to be more harmful than a moderate temperature increase, which could allow coral acclimation. Our results can provide a potential framework for understanding the physiological tolerance of corals under possible future climate changes.

Significance of investigating allelopathic interactions of marine organisms in the discovery and development of cytotoxic compounds

Marine sessile organisms often inhabit rocky substrata, which are crowded by other sessile organisms. They acquire living space via growth interactions and/or by allelopathy. They are known to secrete toxic compounds having multiple roles. These compounds have been explored for their possible applications in cancer chemotherapy, because of their ability to kill rapidly dividing cells of competitor organisms. As compared to the therapeutic applications of these compounds, their possible ecological role in competition for space has received little attention. To select the potential candidate organisms for the isolation of lead cytotoxic molecules, it is important to understand their chemical ecology with special emphasis on their allelopathic interactions with their competitors. Knowledge of the ecological role of allelopathic compounds will contribute significantly to an understanding of their natural variability and help us to plan effective and sustainable wild harvests to obtain novel cytotoxic chemicals. This review highlights the significance of studying allelopathic interactions of marine invertebrates in the discovery of cytotoxic compounds, by selecting sponge as a model organism.

Molecular cloning and expression of two heat-shock protein genes (HSC70/HSP70) from Prenant's schizothoracin (Schizothorax prenanti)

Through the RT-PCR and rapid amplification of cDNA ends, two complementary deoxyribonucleic acid (cDNA) clones encoding heat-shock cognate 70 (HSC70, designated Sp-HSC70) and inducible heat-shock protein 70 (HSP70, designated Sp-HSP70) were isolated from the liver of Prenant's schizothoracin (Schizothorax prenanti). The cDNAs were 2344- and 2292-bp in length and contained 1950- and 1932-bp open reading frames, encoded proteins of 649 and 643 amino acids, respectively. Amino acid sequence analysis indicated that both Sp-HSC70 and Sp-HSP70 contained three signature sequences of HSP70 family, two partial overlapping bipartite nuclear localization signal sequences (an ATP-binding site motif, a bipartite nuclear targeting signal), and a cytoplasmic characteristic motif EEVD. Homology analysis revealed that Sp-HSC70 and Sp-HSP70 shared 77.5% identity and Sp-HSC70 shared more than 81.1% identity with the known HSC70s of other vertebrates, while Sp-HSP70 shared more than 77.5 % identity with the known HSP70s of other vertebrates. Fluorescent real-time quantitative RT-PCR showed that Sp-HSC70 and Sp-HSP70 mRNAs were found in all tested tissues, including blood, brain, heart, liver, spleen, head kidney, white muscle, skin, gonad, hypophysis, red muscle, and gill. The Sp-HSC70 and Sp-HSP70 mRNA expression level in blood and head kidney displayed a significant increase in vibrio-challenged group with the bacterium Aeromonas hydrophila at 24 h post-infection compared to a control group. Temporally, there was a clear time-dependent expression pattern of Sp-HSC70 or Sp-HSP70 gene after bacterial challenge, and the expression of Sp-HSC70 and Sp-HSP70 mRNAs reached a maximum level at 12 and 6 h post-challenge, respectively. Both returned to control level after 7 × 24 h. The results suggest that Sp-HSC70 and Sp-HSP70 genes may play important roles in mediating the immune responses of A. hydrophila-related diseases in the Prenant's schizothoracin.

Effects of titanium dioxide (TiO2 ) nanoparticles on caribbean reef-building coral (Montastraea faveolata)

Increased use of manufactured titanium dioxide nanoparticles (nano-TiO2 ) is causing a rise in their concentration in the aquatic environment, including coral reef ecosystems. Caribbean mountainous star coral (Montastraea faveolata) has frequently been used as a model species to study gene expression during stress and bleaching events. Specimens of M. faveolata were collected in Panama and exposed for 17 d to nano-TiO2 suspensions (0.1 mg L(-1) and 10 mg L(-1) ). Exposure to nano-TiO2 caused significant zooxanthellae expulsion in all the colonies, without mortality. Induction of the gene for heat-shock protein 70 (HSP70) was observed during an early stage of exposure (day 2), indicating acute stress. However, there was no statistical difference in HSP70 expression on day 7 or 17, indicating possible coral acclimation and recovery from stress. No other genes were significantly upregulated. Inductively coupled plasma mass spectrometry analysis revealed that nano-TiO2 was predominantly trapped and stored within the posterior layer of the coral fragment (burrowing sponges, bacterial and fungal mats). The bioconcentration factor in the posterior layer was close to 600 after exposure to 10 mg L(-1) of nano-TiO2 for 17 d. The transient increase in HSP70, expulsion of zooxanthellae, and bioaccumulation of nano-TiO2 in the microflora of the coral colony indicate the potential of such exposure to induce stress and possibly contribute to an overall decrease in coral populations.

The repertoire of chemical defense genes in the coral Acropora digitifera genome

Scleractinian corals are of fundamental ecological significance in tropical and sub-tropical shallow water. This ecological success is attributed to their ability of formation of obligate endosymbioses with dinoflagellates of the genus Symbiodinium. Nevertheless, approximately one-third of reef-building coral species are critically endangered and the remainder are under threat from the effects of climate change and local impacts. Molecular and cellular mechanisms involved in stress responses and the establishment and collapse of the symbiosis are therefore an urgent subject of research. Metazoans possess large numbers of genes that participate in response to environmental stressors, and chemical defense genes included P450 and other oxidases, various conjugating enzymes, ATP-dependent efflux transporters, oxidative detoxification proteins, as well as transcription factors that regulate these genes. Here we searched those genes in recently decoded the coral Acropora digitifera genome. We found that this genome contains a set of chemical defense genes in numbers comparable with other cnidarians and metazoans and that there are some lineagespecific gene family expansions in the coral genome. These provide information for future research into molecular mechanisms involved in coral stress responses.

Up-regulation of Hsp60 in response to skeleton eroding band disease but not by algal overgrowth in the scleractinian coral Acropora muricata

Heat shock proteins are biomarkers commonly used to determine the effects of abiotic stresses on the physiology of reef building corals. In this study the effectiveness of the Hsp60 as indicator of biotic stresses in the scleractinian coral Acropora muricata was analyzed, considering the whole holobiont. We focused on two biological interactions recognized to be important contributors to coral reef degradation such as a coral disease, the Skeleton eroding band (SEB) caused by the protozoan Halofolliculina corallasia and the algal overgrowth. In the lagoon of Magoodhoo Island (Maldives) fragments of living tissue of A. muricata exposed to these biotic factors were sampled and proteins subjected to Western analysis. The two different biological interactions trigger diverse responses on Hsp60 level. No detectable effect on Hsp60 modulation appeared in colonies subjected to algal overgrowth. On the contrary, corals displayed a robust up-regulation of Hsp60 in the fragments sampled just above the SEB dark band, where the level of Hsp60 was almost twice compared to the control colonies, indicating that the aggressive behavior of the protozoan causes cellular damage also in coral portions neighboring and along the advancing front of the infection. Portions of coral sampled distant to the SEB band showed a Hsp60 level comparable to that observed in healthy colonies. We propose Hsp60 expression as a promising tool to evaluate physiological stress caused by SEB disease in reef corals.

The biology and ecology of black corals (Cnidaria: Anthozoa: Hexacorallia: Antipatharia)

Antipatharians, commonly known as black corals, are treasured by many cultures for medicinal purposes and to produce jewellery. Despite their economic and cultural importance, very little is known about the basic biology and ecology of black corals because most species inhabit deeper-water environments (>50m) which are logistically challenging to study. There has been a recent increase of studies focusing on antipatharians; however, these have not yet been comprehensively reviewed. This literature review seeks to summarize the available information on the biology and ecology of antipatharians. Although black corals occur throughout all oceans and from subtidal to abyssal depths, they are particularly common in tropical and subtropical regions at depths below 50m. Antipatharians are generally found in areas with hard substrates, low-light and strong currents. Under favourable conditions, some black coral species form dense aggregations to the point of becoming ecologically dominant. Zooplankton appears to be the major component of the diet of black corals, which feed as suspension feeders and use mucus and nematocysts to capture their prey. Previously categorized as azooxanthellate corals, recent research has revealed that many antipatharians appear capable of harbouring symbionts, but unlike other corals, dinoflagellates of the genus Symbiodinium are generally not important to the nutrition of black corals. Antipatharians reproduce through both sexual and asexual processes. In general, polyps and colonies are gonochoric, with fertilization and larval development likely occurring externally; however, to date antipatharian larvae have only been observed for a single species. Antipatharians are generally slow-growing and long-lived organisms with maximum longevities ranging from decades to millennia. Black corals are more abundant with depth, a pattern which has been hypothesized to avoid competition with obligate photosynthetic fauna. Additionally, antipatharians may compete for space by using sweeper tentacles and secondary metabolites. With the exception of a few predators such as gastropods and green sea turtles, antipatharians appear to be little impacted by predation. Like other corals, antipatharians can be habitat engineers of importance to a myriad of associated organisms including arthropods, annelids, echinoderms, mollusks, sponges and cnidarians, several of which are adapted to live exclusively on black corals. Given that most black coral species inhabit remote environments, our understanding of these organisms will depend on our ability to effectively sample and study them. Future collections, particularly in deeper waters (>50m), will be needed to determine whether antipatharian species have limited biogeographical distributions or whether this has simply been an artefact of low sampling efforts away from population centres and taxonomic uncertainties within this group. Additionally, biological and ecological studies require increased sample sizes because most information is currently derived from the examination of only a handful of specimens.

2-DE proteomic analysis of HSP70 in mollusc Chamelea gallina

Bidimensional electrophoresis (2-DE) protocols were adapted on Chamelea gallina digestive glands studies by the analysis of Heat Shock Proteins (HSP) compared with monodimensional electrophoresis (1-DE) results. Because polycyclic aromatic hydrocarbons (PAH) act on HSPs, C. gallina specimens were exposed to 0.5 mg/L of benzo[a]pyrene (B[a]P) for 24 h, 7 and 12 days. Immunoblotting after 1-DE showed a single band of 70 kDa significantly induced after 7 days of B[a]P exposure. After 2-DE, eight major high-resolved spots between 17 and 98 kDa were revealed. Three spots fell within the range of 62-98 kDa and of 5-6 pI, parameters which could include HSP70. Two spots of 77 and 72 kDa, obtained after 2-DE immunoblotting, could correspond to constitutive HSC70 and to inducible HSP70 forms respectively. Changes observed in inducible and in constitutive forms might be related to an adaptation to stress and to a normal protein synthesis capability, respectively. Employment of 2-DE and relationship between HSP70 and HSC70 may be useful to clarify their role in molluscs subjected to stress events.

Cloning and expression of heat shock protein 70 gene in the haemocytes of pearl oyster (Pinctada fucata, Gould 1850) responding to bacterial challenge

The cDNA of pearl oyster Pinctada fucata Hsp70 (designated PFHsp70) was cloned by EST and rapid amplification of cDNA ends (RACE) techniques. The full length of PFHsp70 cDNA was 2376 bp, consisting of a 5'-terminal untranslated region (UTR) of 89 bp, a 3' terminal UTR of 328 bp, and an open reading frame (ORF) of 1959 bp encoding a polypeptide of 652 amino acids with a theoretical molecular weight of 71.42 kDa and an estimated isoelectric point of 5.18. BLAST analysis revealed that the PFHsp70 gene shared high similarity with other Hsp70 genes. PFHsp70 contained all the three classical Hsp70 family signatures. The results indicated that the PFHsp70 was a member of the heat shock protein 70 family. Fluorescent real-time quantitative RT-PCR was used to examine the expression of PFHsp70 gene in haemocytes of P. fucata after the challenge of bacteria Vibrio alginolyticus. There was a clear time-dependent expression pattern of PFHsp70 after bacterial challenge, and the mRNA expression reached a maximum level at 4 h post-challenge, which returned to control level after 32 h. The up-regulated mRNA expression of PFHsp70 in P. fucata after bacterial challenge indicates that the Hsp70 gene is inducible and involved in immune response.

Environmental sensing and response genes in cnidaria: the chemical defensome in the sea anemone Nematostella vectensis

The starlet sea anemone Nematostella vectensis has been recently established as a new model system for the study of the evolution of developmental processes, as cnidaria occupy a key evolutionary position at the base of the bilateria. Cnidaria play important roles in estuarine and reef communities, but are exposed to many environmental stressors. Here, I describe the genetic components of a "chemical defensome" in the genome of N. vectensis and review cnidarian molecular toxicology. Gene families that defend against chemical stressors and the transcription factors that regulate these genes have been termed a chemical defensome and include the cytochromes P450 and other oxidases, various conjugating enyzymes, the ATP-dependent efflux transporters, oxidative detoxification proteins, as well as various transcription factors. These genes account for about 1% (266/27,200) of the predicted genes in the sea anemone genome, similar to the proportion observed in tunicates and humans, but lower than that observed in sea urchins. While there are comparable numbers of stress-response genes, the stress sensor genes appear to be reduced in N. vectensis relative to many model protostomes and deuterostomes. Cnidarian toxicology is understudied, especially given the important ecological roles of many cnidarian species. New genomic resources should stimulate the study of chemical stress sensing and response mechanisms in cnidaria and allow us to further illuminate the evolution of chemical defense gene networks.

Genomic survey of candidate stress-response genes in the estuarine anemone Nematostella vectensis

Salt marshes are challenging habitats due to natural variability in key environmental parameters including temperature, salinity, ultraviolet light, oxygen, sulfides, and reactive oxygen species. Compounding this natural variation, salt marshes are often heavily impacted by anthropogenic insults including eutrophication, toxic contamination, and coastal development that alter tidal and freshwater inputs. Commensurate with this environmental variability, estuarine animals generally exhibit broader physiological tolerances than freshwater, marine, or terrestrial species. One factor that determines an organism's physiological tolerance is its ability to upregulate "stress-response genes" in reaction to particular stressors. Comparative studies on diverse organisms have identified a number of evolutionarily conserved genes involved in responding to abiotic and biotic stressors. We used homology-based scans to survey the sequenced genome of Nematostella vectensis, the starlet sea anemone, an estuarine specialist, to identify genes involved in the response to three kinds of insult-physiochemical insults, pathogens, and injury. Many components of the stress-response networks identified in triploblastic animals have clear orthologs in the sea anemone, meaning that they must predate the cnidarian-triploblast split (e.g., xenobiotic receptors, biotransformative genes, ATP-dependent transporters, and genes involved in responding to reactive oxygen species, toxic metals, osmotic shock, thermal stress, pathogen exposure, and wounding). However, in some instances, stress-response genes known from triploblasts appear to be absent from the Nematostella genome (e.g., many metal-complexing genes). This is the first comprehensive examination of the genomic stress-response repertoire of an estuarine animal and a member of the phylum Cnidaria. The molecular markers of stress response identified in Nematostella may prove useful in monitoring estuary health and evaluating coastal conservation efforts. These data may also inform conservation efforts on other cnidarians, such as the reef-building corals.

Expression of heat shock protein 70 in the thermally stressed antarctic clam Laternula elliptica

Heat shock protein 70 (designated Laternula elliptica Hsp70 (LEHsp70)) expression was investigated in an Antarctic mud clam to see whether or not the inducible heat shock response has been conserved throughout over 25 million years of adaptation to constant low environmental temperatures. LEHsp70 cDNA was cloned and sequenced from the Antarctic clam Laternula elliptica. We used degenerated primers designed in the highly conserved regions of Hsp to amplify the corresponding mRNA, and full-length cDNA was obtained by rapid amplification of cDNA ends (RACE). The full length of LEHsp70 cDNA was 2470 bp, with a 5' untranslated region (UTR) of 92 bp, a 3' UTR of 416 bp, and an open reading frame (ORF) of 1962 bp encoding a polypeptide of 653 amino acids with an estimated molecular mass of 71.266 kDa and an estimated isoelectric point of 5.20. LEHsp70 contained highly conserved functional motifs of the cytosolic Hsp70 family. Expression of the LEHsp70 gene was quantified by quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) of digestive gland and gill tissues. Heat shock (10 degrees C for different time periods) caused rapid induction of LEHsp70. A significant 4.6 +/- 0.14-fold increase in the LEHsp70/beta-Actin mRNA ratio occurred in the gill at 12 hours, which returned to baseline after 48 hours. In contrast, the maximum expression in the digestive gland (3.6 +/- 0.36) was reached at 24 hours and was still significant after 48 hours (1.89 +/- 0.21). This indicates that LEHsp70 may play an important role in mediating thermal stress and tolerance in this clam.

Simultaneous quantitative analysis of multiple protein species within a single sample using standard scanning densitometry

It is often desirable, when conducting Western blot analyses, to accurately quantify the relative expression of multiple target proteins in a single sample. A common problem occurs: however, when the target proteins vary beyond the linear range of the detection system; thus precluding accurate densitometric analysis for all samples. For example, analysis of teleost immunoglobulin structure under non-reducing but denaturing conditions, yields multiple, differentially polymerized forms (redox forms) within a single sample, which can exceed single log differences in concentration, as visualized by chemiluminescent and X-ray film development. To resolve this difficulty an efficient technique has been developed that uses dilutions of a single sample, allowing accurate quantification of target proteins within their potentially unique and varied linear range of detection. Upon consideration of the respective dilution factor that yields an appropriate estimate, the multiple targets can be quantified. When the results from this technique are compared to other systems possessing more expansive linear ranges, the results obtained are comparable to within 1%. Thus, laboratories without access to more sensitive and costly densitometric instrumentation can still employ standard densitometric analysis to accurately quantify multiple targets in a single sample.

Heat-shock protein 70 (Hsp70) as a biochemical stress indicator: an experimental field test in two congeneric intertidal gastropods (genus: Tegula)

Although previous studies have demonstrated that heat-shock protein 70 (Hsp70) can be induced by environmental stress, little is known about natural variation in this response over short time scales. We examined how Hsp70 levels varied over days to weeks in two intertidal snail species of the genus Tegula: Sampling was conducted both under naturally changing environmental conditions and in different vertical zones on a rocky shore. The subtidal to low-intertidal T. brunnea was transplanted into shaded and unshaded mid-intertidal cages to assess temporal variation in Hsps under conditions of increased stress. For comparison, the low to mid-intertidal T. funebralis was transplanted into mid-intertidal cages, within this species' natural zone of occurrence. Snails were sampled every 3 to 4 days for one month, and endogenous levels of two Hsp70-kDa family members (Hsp72 and Hsp74) were quantified using solid-phase immunochemistry. Following periods of midday low tides, levels of Hsps increased greatly in transplanted T. brunnea but not in T. funebralis. Levels of Hsps increased less in T. brunnea transplanted to shaded cages than to unshaded cages, suggesting that prolonged emersion and reduction in feeding time per se are factors that are only mildly stressful. Upregulated levels of Hsps returned to base levels within days. In unmanipulated snails collected from their natural zones, Hsp levels showed little change with thermal variation, indicating that these species did not experience thermally stressful conditions during this study. However, under common conditions in the mid-intertidal zone, Hsp70 levels reflected the different thermal sensitivities of the physiological systems of these two species.