Nitric oxide pathway in lower metazoans

The presence of nitric oxide (NO) pathway has been well demonstrated in the main invertebrate groups, showing parallel findings on the role of NO in vertebrates and invertebrates. Noteworthy is the example of the role played by the nitrergic pathway in the sensorial functions, mainly in olfactory-like systems. On the other hand, the emerging molecular information about NOSs from lower metazoans (Porifera, cnidarians up to higher invertebrates) suggests that NO pathways might represent examples of a parallel evolution of the NOS prototypes in different animal lineages. Nevertheless, increasing evidence suggests that NO is one of the earliest and most widespread signaling molecules in living organisms.Here, we attempt to provide a survey of current knowledge of the synthesis and possible roles of NO and the related signaling pathway in lower metazoans (i.e., Porifera and Cnidaria), two phyla forming a crucial bridge spanning the evolutionary gap between the protozoans and higher metazoans. From the literature data here reported, it emerges that future research on the biological roles of NO in basal metazoans is likely to be very important for understanding the evolution of signaling systems.     

Plants versus animals: do they deal with stress in different ways?

Both plants and animals respond to stress by using adaptationsthat help them evade, tolerate, or recover from stress. In asynthetic paper A. D. Bradshaw (1972) noted that basic biologicaldifferences between plants and animals will have diverse evolutionaryconsequences, including those influencing how they deal withstress. For instance, Bradshaw argued that animals, becausethey have relatively well-developed sensory and locomotor capacities,can often use behavior and movement to evade or ameliorate environmentalstresses. In contrast, he predicted that plants will have toemphasize increased physiological tolerance or phenotypic plasticity,and also that plants should suffer stronger selection and showmore marked differentiation along environmental gradients. Herewe briefly review the importance of behavior in mitigating stress,the behavioral capacities of animals and plants, and examplesof plant responses that are functionally similar to behaviorsof animals. Next, we try to test some of Bradshaw's predictions.Unfortunately, critical data often proved non-comparable: plantand animal biologists often study different stressors (e.g.,water versus heat) and measure different traits (photosynthesisversus locomotion). Nevertheless, we were able to test someof Bradshaw's predictions and some related ones of our own.As Bradshaw predicted, the phenology of plants is more responsiveto climate shifts than is that of animals and the micro-distributionsof non-mobile, intertidal invertebrates ("plant" equivalents)are more sensitive to temperature than are those of mobile invertebrates.However, mortality selection is actually weaker for plants thanfor animals. We hope that our review not only redraws attentionto some fascinating issues Bradshaw raised, but also encouragesadditional tests of his predictions. Such tests should be informative.     

Chemical transmission in the sea anemone Nematostella vectensis: A genomic perspective

The sequencing of the starlet sea anemone (Nematostella vectensis) genome provides opportunities to investigate the function and evolution of genes associated with chemical neurotransmission and hormonal signaling. This is of particular interest because sea anemones are anthozoans, the phylogenetically basal cnidarians least changed from the common ancestors of cnidarians and bilaterian animals, and because cnidarians are considered the most basal metazoans possessing a nervous system. This analysis of the genome has yielded 20 orthologues of enzymes and nicotinic receptors associated with cholinergic function, an even larger number of genes encoding enzymes, receptors and transporters for glutamatergic (28) and GABAergic (34) transmission, and two orthologues of purinergic receptors. Numerous genes encoding enzymes (14), receptors (60) and transporters (5) for aminergic transmission were identified, along with four adenosine-like receptors and one nitric oxide synthase. Diverse neuropeptide and hormone families are also represented, mostly with genes encoding prepropeptides and receptors related to varying closeness to RFamide (17) and tachykinin (14), but also galanin (8), gonadotropin-releasing hormones and vasopressin/oxytocin (5), melanocortins (11), insulin-like peptides (5), glycoprotein hormones (7), and uniquely cnidarian peptide families (44). Surprisingly, no muscarinic acetylcholine receptors were identified and a large number of melatonin-related, but not serotonin, orthologues were found. Phylogenetic tree construction and inspection of multiple sequence alignments reveal how evolutionarily and functionally distant chemical transmitter-related proteins are from those of higher metazoans.     

Hypoxic Reptiles: Blood Gases, Body Temperature and Control of Breathing

Our contribution to this symposium is a review of recent modelsand experimental cdata on oxygen homeostasis in vertebrateswith normal intracardiac shunts; i.e., amphibians and reptiles.We focus on the interactions among hemoglobin function, bodytemperature regulation, and cardiovascular shunts under normalconditions (i.e., breathing fresh air at or near sea level)and during external hypoxia (e.g., altitude, burrows) and internalhypoxia (e.g., anemia, hemorrhage). Mathematical models andexperimental data suggest that animals with venous admixturefrom cardiovascular shunts will show biphasic arterial and mixedvenous Po₂ responses to warming; i.e., first increasing andthen, as the dissociation curve shifts too far to the right,decreasing. This has implications for many physiological functionsincluding oxygen consumption by tissues, control of breathing,as well as preferred body temperature and its regulation. Wepresent some of the recent experiments that have explored theseimplications.     

Self/non-self Discrimination in Basal Metazoa: Genetics of Allorecognition in the Hydroid Hydractinia

Colonial basal metazoans often encounter members of their ownspecies as they grow on hard substrata, with the encounterstypically resulting in either fusion of close relatives or rejectionbetween unrelated colonies. These allorecognition responsesplay a critical role in maintaining the genetic and physiologicalintegrity of the colony. Allorecognition responses in basalmetazoans are controlled by highly variable genetic systems.The molecular nature of such systems, however, remains to bedetermined. Current efforts to identify the genes and moleculescontrolling allorecognition in basal metazoans have followedtwo pathways: identification of molecules differentially expressedin incompatible interactions, and positional or map-based cloningof allorecognition genes. Most studies following the first approachhave been performed with marine demosponges, while those followingthe second approach have centered on the cnidarian of the genusHydractinia. Here, I discuss the latter, focusing primarilyon the genetic control of allorecognition responses.     

Genomics of Basal metazoans

An in-depth understanding of the biology of animals will requirethe generation of genomics resources from organisms from allphyla in the metazoan phylogenetic tree. Such resources willideally include complete genome sequences and comprehensiveEST (expressed sequence tag) datasets for each species of interest.Of particular interest in this regard are animals in the earlydiverging non-bilaterian phyla Porifera, Placozoa, Cnidaria,and Ctenophora. Publications describing the results from theuse of genomics approaches in these phyla have only recentlybegun to appear (Kortschak et al., 2003; Yang et al., 2003;Steele et al., 2004). Issues to be considered here include choosingthe basal metazoan species to examine with genomics approaches,the relative advantages and disadvantages of genome sequencingversus EST projects, and the resources and infrastructure requiredto carry out such projects successfully.     

Diverse radial symmetry among the Cambrian Fortunian fossil embryos from northern Sichuan and southern Shaanxi provinces,South China

The Cambrian Fortunian fossil embryos exhibit embryonic development of ancient animals and hence have important bearings on evolutionary developmental biology. They have radial symmetry, and may be early representatives of cnidarians. Here we report new material of three-dimensionally phosphatized fossil embryos from the Fortunian Kuanchuanpu Formation and coeval strata in northern Sichuan and southern Shaanxi provinces, South China. The new material includes previously reported fossil embryos assignable to Pseudooides prima with biradial symmetry or pseudo-hexaradial symmetry, Quadrapyrgites quadratacris with tetraradial symmetry, and Olivooides multisulcatus with pentaradial symmetry. Additionally, we recovered two new types of fossil embryos, i.e., Embryo I with hexaradial symmetry and Embryo II with octaradial symmetry, and they are tentatively suggested to represent new cnidarians. In contrast to the diverse radial symmetry of the Fortunian cnidarians, modern cnidarians exhibit stable tetraradial symmetry in medusozoans, biradial symmetry in anthozoans, and bilateral symmetry in siphonophores (Hydrozoa). The current study supports the view that the tetraradial symmetry of modern medusozoans is a surviving remnant of their Fortunian relatives.     

A Brief Review of Metazoan Phylogeny and Future Prospects in Hox-Research

Underlying any analysis on the evolution of development is aphylogenetic framework, whether explicitly stated or implied.As such, differing views on phylogenetic relationships leadto variable interpretations of how developmental mechanismshave changed through time. Over the past decade, many long-standinghypotheses about animal evolution have been questioned causingsubstantial changes in the assumed phylogenetic framework underlyingcomparative developmental studies. Current hypotheses aboutearly metazoan history suggest that three, not two, major lineagesof bilateral animals originated in the Precambrian: the Deuterostomes(e.g., seastars, acorn worms, and vertebrates), the Ecdysozoans(e.g., nematodes and arthropods), and the Lophotrochozoans (e.g.,annelids, mollusks, and lophophorates). Although informationin Hox-genes bears directly on our understanding of early metazoanevolution and the formation of body plans, research effort hasbeen focused primarily on two taxa, insects and vertebrates.By sampling a greater diversity of metazoan taxa and takingadvantage of biotechnological advances in genomics, we willnot only learn more about metazoan phylogeny, but will alsogain valuable insight as to the key evolutionary forces thatestablished and maintained metazoan bauplans.     

The initiation of metamorphosis as an ancient polyphenic trait and its role in metazoan life-cycle evolution

Comparative genomics of representative basal metazoans leaves little doubt that the most recent common ancestor to all modern metazoans was morphogenetically complex. Here, we support this interpretation by demonstrating that the demosponge Amphimedon queenslandica has a biphasic pelagobenthic life cycle resembling that present in a wide range of bilaterians and anthozoan cnidarians. The A. queenslandica life cycle includes a compulsory planktonic larval phase that can end only once the larva develops competence to respond to benthic signals that induce settlement and metamorphosis. The temporal onset of competence varies between individuals as revealed by idiosyncratic responses to inductive cues. Thus, the biphasic life cycle with a dispersing larval phase of variable length appears to be a metazoan synapomorphy and may be viewed as an ancestral polyphenic trait. Larvae of a particular age that are subjected to an inductive cue either maintain the larval form or metamorphose into the post-larval/juvenile form. Variance in the development of competence dictates that only a subset of a larval cohort will settle and undergo metamorphosis at a given time, which in turn leads to variation in dispersal distance and in location of settlement. Population divergence and allopatric speciation are likely outcomes of this conserved developmental polyphenic trait.     

Male courtship signals and female signal assessment in Photinus greeni fireflies

The evolutionary dynamic of courtship signaling systems is drivenby the interaction between male trait distributions and femalepreferences. This interaction is complex because females maychoose mates based on multiple components of male signals, andfemale preference functions may vary depending on mate availability,female reproductive state, and environmental conditions. InPhotinus fireflies (Coleoptera: Lampyridae), flying males emitbioluminescent flash signals to locate sedentary females, whichreply selectively to attractive male flash signals with theirown response flash. In this study, we first examined temporalvariation in the paired-pulse flash patterns produced by Photinusgreeni males in the field and found significant among-male variation(70% of total variation) in interpulse intervals (IPIs). Therewas no significant relationship between male IPI and spermatophoresize, suggesting that P. greeni male courtship signals do notprovide females with reliable indicators of male material resources.In laboratory playback experiments, we presented P. greeni femaleswith simulated flash signals to assess how IPI and pulse durationindependently affected the likelihood of female flash response.We also examined the effects of female body mass and time duringthe mating season on female preference functions, hypothesizingthat females would be less discriminating when they were heavier(more fecund) and when mate availability declined. We foundthat P. greeni females discriminated among signals within theirspecies' range based primarily on flash pattern IPI. Neitherthe time during the mating season nor female weight alteredfemale preference functions for IPI, although season did influencefemale response to pulse duration. These results reveal thatP. greeni females discriminate among conspecific males basedprimarily on male IPIs, the same signal character previouslyshown to be important for firefly species recognition. Fieldplayback experiments indicated that female responsiveness peakednear the average IPI given by males at different ambient temperatures,suggesting that fireflies exhibit temperature coupling similarto that seen in many acoustically signaling animals.     

Comparative biology of calcium signaling during fertilization and egg activation in animals.

During animal fertilizations, each oocyte or egg must produce a proper intracellular calcium signal for development to proceed normally. As a supplement to recent synopses of fertilization-induced calcium responses in mammals, this paper reviews the spatiotemporal properties of calcium signaling during fertilization and egg activation in marine invertebrates and compares these patterns with what has been reported for other animals. Based on the current database, fertilization causes most oocytes or eggs to generate multiple wavelike calcium oscillations that arise at least in part from the release of internal calcium stores sensitive to inositol 1,4,5-trisphosphate (IP3). Such calcium waves are modulated by upstream pathways involving oolemmal receptors and/or soluble sperm factors and in turn regulate calcium-sensitive targets required for subsequent development. Both "protostome" animals (e.g., mollusks, annelids, and arthropods) and "deuterostomes" (e.g., echinoderms and chordates) display fertilization-induced calcium waves, IP3-mediated calcium signaling, and the ability to use a combination of external calcium influx and internal calcium release. Such findings fail to support the dichotomy in calcium signaling modes that had previously been proposed for protostomes vs deuterostomes and instead suggest that various features of fertilization-induced calcium signals are widely shared throughout the animal kingdom.     

Endocrine-like Signaling in Cnidarians: Current Understanding and Implications for Ecophysiology

The vertebrate endocrine system is well-characterized, with many reports of disruption by environmental chemicals. In contrast, cnidarians are less compartmentalized, physiological regulation is poorly understood, and the potential for disruption is unknown. Endocrine-like activity has not been systematically studied in cnidarians, but several classical vertebrate hormones (e.g., steroids, iodinated organic compounds, neuropeptides, and indoleamines) have been identified in cnidarian tissues. Investigators have made progress in identifying putative bioregulatory molecules in cnidarians, and testing the effects of these individual compounds. Less progress has been made in elucidating signaling pathways. For example, putative gonadotropin-releasing hormone and sex steroids have been identified in cnidarian tissues, but it is unknown whether these compounds are components of a larger signal cascade comparable to the vertebrate hypothalamic-pituitary-gonadal axis. Further, while sex steroids and iodinated organic compounds may help to regulate cnidarian physiology, the mechanisms of action are unknown. Homologs to the vertebrate steroid and thyroid receptors have not been identified in cnidarians, so more research is needed to understand the mechanisms of endocrine-like signaling in cnidarians. Elucidation of cnidarian regulatory pathways will provide insight into evolution of hormonal signaling. These studies will also improve understanding of how cnidarians respond to environmental cues and will provide a basis to investigate disruption of physiological processes by physical and chemical stressors.     

Body size clines in sceloporus lizards: proximate mechanisms and demographic constraints

Although most species of animals examined to date exhibit Bergmann'sclines in body size, squamates tend to exhibit opposing patterns.Squamates might exhibit reversed Bergmann's clines because theytend to behaviorally regulate their body temperature effectively;the outcome of this thermoregulation is that warmer environmentsenable longer daily and annual durations of activity than coolerenvironments. Lizards of the genus Sceloporus provide an opportunityto understand the factors that give rise to contrasting thermalclines in body size because S. undulatus exhibits a standardBergmann's cline whereas S. graciosus exhibits a reverse Bergmann'scline. Interestingly, rapid growth by individuals of both speciesinvolves adjustments of physiological processes that enablemore efficient use of food. Patterns of adult body size arelikely the evolutionary consequence of variation in juvenilesurvivorship among populations. In S. undulatus, delayed maturationat a relatively large body size is exhibited in cooler environmentswhere juveniles experience higher survivorship, resulting ina Bergmann's cline. In S. graciosus, high juvenile survivorshipis not consistently found in cooler environments, resultingin no cline or a reversed Bergmann's cline, i.e., geographicpatterns in body size aren't necessarily produced by naturalselection. Thus, discerning the mechanistic links between thethermal physiology of an organism and environment-specific ratesof mortality will be critical to understanding the evolutionof body size in relation to environmental temperature.     

Aggregation effects on anhydrobiotic survival in the tardigrade Richtersius coronifer

For anhydrobiotic metazoans the rate of desiccation is an important factor influencing the probability of survival in a dry anhydrobiotic state. Formation of animal aggregations, in which the exposed body surface area of individual animals is reduced, represents one way to reduce the rate of evaporation. Such aggregations have earlier been documented in e.g., nematodes. We experimentally evaluate the effect of aggregation size (number of animals in a group of desiccating animals) on anhydrobiotic survival in the eutardigrade Richtersius coronifer. The experiment shows that aggregation provides a clear improvement on anhydrobiotic survival. The most likely explanation for this is that aggregated animals were exposed to a lower rate of desiccation. Although the empirical evidence of aggregation in tardigrades is scarce, our study suggests that aggregation could potentially be an important survival factor for tardigrades living in environments characterized by periods of rapid desiccation.     

Field data confirm the ability of a biophysical model to predict wild primate body temperature

In the face of climate change there is an urgent need to understand how animal performance is affected by environmental conditions. Biophysical models that use principles of heat and mass transfer can be used to explore how an animal's morphology, physiology, and behavior interact with its environment in terms of energy, mass and water balances to affect fitness and performance. We used Niche Mapper™ (NM) to build a vervet monkey (Chlorocebus pygerythrus) biophysical model and tested the model's ability to predict core body temperature (T_b) variation and thermal stress against T_b and behavioral data collected from wild vervets in South Africa. The mean observed T_b in both males and females was within 0.5 °C of NM's predicted T_bs for 91% of hours over the five-year study period. This is the first time that NM's T_b predictions have been validated against field data from a wild endotherm. Overall, these results provide confidence that NM can accurately predict thermal stress and can be used to provide insight into the thermoregulatory consequences of morphological (e.g., body size, shape, fur depth), physiological (e.g. T_b plasticity) and behavioral (e.g., huddling, resting, shade seeking) adaptations. Such an approach allows users to test hypotheses about how animals adapt to thermoregulatory challenges and make informed predictions about potential responses to environmental change such as climate change or habitat conversion. Importantly, NM's animal submodel is a general model that can be adapted to other species, requiring only basic information on an animal's morphology, physiology and behavior.     

Attention-altering signal interactions in the multimodal courtship display of the wolf spider Schizocosa uetzi

Complex signals are common throughout the animal kingdom, consistingof one or more signals in one or more sensory modalities presentedwithin a single display. I tested an efficacy-based backup hypothesisof complex signal function using the bimodal courtship signalingwolf spider Schizocosa uetzi. This hypothesis predicts thatthe visual and vibratory courtship displays function as backupsto each other in the presence of environmental variability.I compared mating frequencies across four environmental treatmentsin which the visual and vibratory environments were manipulatedindependently in a 2 x 2 design with visual treatments of light/dark(i.e., visual signal present/absent) and vibratory treatmentsof filter paper substratum/granite substratum (i.e., vibratorysignal present/absent). Results did not match the predictionsof an efficacy-based backup hypothesis. The vibratory environmentaffected mating frequency, with more mating occurring in thevibration-present treatments compared to the vibration-absenttreatments, but the visual environment had no effect on matingfrequency. A second experiment was then conducted to test foran inter-signal interaction. Using the video-playback technique,I presented females with manipulated video sequences simultaneouswith a controlled vibratory signal to test the hypothesis thatthe presence of a vibratory signal alters a female's responseto the visual signal. In the presence of a vibratory courtshipsignal, females were more receptive to more visually ornamentedmales. This increased receptivity to increased visual ornamentationwas not seen in a previous study conducted on S. uetzi in theabsence of a vibratory signal, suggesting a potential inter-signalinteraction. In a third experiment, I tested whether a female'svisual attention was altered by the vibratory signal by examiningfemale response to a visual "predator" while exposed to allpossible combinations of male courtship signals. Females weremore likely to get caught, and thus less likely to notice apredatory visual stimulus when exposed to a courtship vibration,supporting the hypothesis that the vibratory signal alters afemale's visual attention.