Effects of previous experience on the agonistic behaviour of male crickets, Gryllus bimaculatus

Male solitary animals frequently enter aggressive interactions with conspecific individuals to protect their territory or to gain access to females. After an agonistic encounter, the loser (subordinate individual) changes its behaviour from aggression to avoidance. We investigated agonistic interactions between pairs of male crickets to understand how dominance is established and maintained. Two na?ve males readily entered into agonistic interactions. Fights escalated in a stereotyped manner and were concluded with the establishment of dominance. If individuals were isolated after the first encounter and placed together 15 minutes later, subordinate crickets tended to avoid any further contact with the former dominant opponent. Moreover, subordinate males also avoided unfamiliar dominant and na?ve opponents. They displayed aggressive behaviour only towards unfamiliar subordinate opponents. This suggests that the subordinate male change their behaviour depending on the dominance status of the opponent. Dominant crickets, in contrast, displayed aggressive behaviour towards familiar as well as unfamiliar opponents. If the interval between the first and second encounter was longer than 30 minutes, the former subordinate male showed aggressive behaviour again. However, if the subordinate cricket was paired with the same opponent three consecutive times within 45 minutes, it avoided the former dominant opponent for up to 6 hours following the third encounter. Our results suggest that the maintenance of dominance in male crickets depends largely on the behavioural change of subordinate individuals. Possible mechanisms to maintain dominance are discussed.     

Does Darwin’s Naturalization Hypothesis Explain Fish Invasions?

Darwin’s naturalization hypothesis predicts that introduced species tend not to invade areas containing congeneric native species, because they would otherwise compete with their close relatives and would likely encounter predators and pathogens that can attack them. An opposing view is that introduced species should succeed in areas where native congeners are present because they are more likely to share traits that pre-adapt them to their new environment. A test of both these hypotheses using data on fish introductions from several independent regions fails to support either viewpoints. In contrast to studies of nonindigenous plants, our results suggest that taxonomic affiliation is not an important general predictor of fish invasion success.     

Fish shoal composition: mechanisms and constraints

Observations were made on three fish species (banded killifish (Fundulus diaphanus), golden shiner (Notemigonus crysoleucas) and white sucker (Catostomus commersoni)) in a temperate lake (New Brunswick, Canada) in order to investigate the relationship between shoal choice behaviour of individual fishes and shoal composition. Encounters between shoals were observed to take place every 1.1 min per shoal and an encounter lasted 3.7 s on average. The duration of shoal encounters was influenced by shoal size but not by differences between shoals in either body length or species. Conversely, the outcome of shoal encounters (i.e. ences between shoals in either body length or species. Conversely, the outcome of shoal encounters (i.e. whether or not an individual changes shoal) was influenced by body length and species differences but not by shoal size. Together, these results suggest that encounter duration itself is unlikely to have an important influence on encounter outcome. The collection of ten entire fish shoals showed that they were assorted by species and body length. A simulation model demonstrated that individual shoal choice behaviour alone could account for the generation and maintenance of the observed levels of size assortedness of shoals without invoking the existence of other sorting mechanisms such as differential swimming speeds. However, the generation of species assortedness was not predicted by the model. Furthermore, our data suggest that fish density acts as a constraint on shoal choice, influencing both shoal size and composition. This work has implications for studies on information transfer and reciprocal altruism within populations.     

Does darkening signal submission in territorial contests between juvenile Atlantic salmon, Salmo salar ?

Communication by means of visual signals occurs during the competitive, aggressive and sexual interactions of many animals. Some animals such as fish are able to change their body coloration rapidly, and there is evidence that this is used as a means of signalling. However, the precise meaning of such signals is rarely understood. We examined whether (1) darkness in juvenile Atlantic salmon is associated with submission, and (2) changing to a darker colour could act as a signal to the opponent and hence induce a change in its behaviour. We found that both the sclera of the eye and the overall body coloration tended to darken in fish that were losing territorial encounters, while victors retained their original coloration. The darkening was rapid and usually occurred during a period of sustained attacks by the opponent; however, the aggression level decreased as soon as the losing fish had become darker. We suggest that the darkening of the losing fish was associated with submission and may result in a change in the behaviour of its opponent, so minimizing the potential risk of injury during unnecessarily prolonged fights. Copyright 1999 The Association for the Study of Animal Behaviour.     

Multimodal individual recognition in the crayfish cherax destructor

There is some evidence that macrurans recognize each other as individuals. In freshwater crayfish there are conflicting reports and there is limited information about the sensory mechanisms involved. To determine the extent to which the crayfish Cherax destructor is capable of individual recognition, we performed experiments that familiarized animals with each other and then manipulated their recent success in dominance contests. Crayfish were more likely to win an encounter when paired against a familiar opponent than an unfamiliar one after the manipulation stage. In other experiments, animals were attracted to familiar conspecifics when only visual or chemical cues were present. This demonstrates that C. destructor is able to discriminate between a familiar and an unfamiliar opponent. The results highlight the complex nature of intraspecific communication in crayfish and suggest elements likely to be of importance in the social interactions of groups in the wild state.     

Endocrine Toxicants and Reproductive Success in Fish

There is compelling evidence on a global scale for compromised growth and reproduction, altered development, and abnormal behaviour in feral fish that can be correlated or in some cases causally linked with exposure to endocrine disrupting chemicals (EDCs). Attributing cause and effect relationships for EDCs is a specific challenge for studies with feral fish as many factors including food availability, disease, competition and loss of habitat also affect reproduction and development. Even in cases where there are physiological responses of fish exposed to EDCs (e.g., changes in reproductive hormone titres, vitellogenin levels), the utility of these measures in extrapolating to whole animal reproductive or developmental outcomes is often limited. Although fish differ from other vertebrates in certain aspects of their endocrinology, there is little evidence that fish are more sensitive to the effects of EDCs. Therefore, to address why endocrine disruption seems so widespread in fish, it is necessary to consider aspects of fish physiology and their environment that may increase their exposure to EDCs. Dependence on aquatic respiration, strategies for iono-osmotic regulation, and maternal transfer of contaminants to eggs creates additional avenues by which fish are exposed to EDCs. This paper provides an overview of responses observed in feral fish populations that have been attributed to EDCs and illustrates many of the factors that need consideration in evaluating the risks posed by these chemicals.     

On the function of the ‘eye-spots’ in agonistic behaviour in the fire-mouth cichlid (Cichlasoma Meeki)

During frontal threatening, individuals of the fire-mouth cichlid (Cichlasoma meeki) dilate their opercula, thereby demonstrating two conspicous ‘eye-spots’. In a hostile situation, a fish confronted with an opponent whose eye-spots have been experimentally removed is more likely to react with overt aggression towards the other. Fights also follow a more violent course than does a ‘normal’ fight between two intact males. A tentative explanation to these results is advanced which supposes that the eye-spots may exert an ‘intimidating’ effect upon the opponent during threat and fighting. This hypothesis is also supported by an experiment where males were confronted with a mirror. In this situation the distance between the mirror and the fish during frontal threat was significantly shorter in fishes lacking eye-spots, indicating that the intimidating effect emerging from the mirror image was diminished. In a third set of experiments when two males (one intact and one without eye-spots) competed for the only suitable territory site in an aquarium, the intact male eventually dominated the other in five of six aquariums.     

Immunological Control of Fish Diseases

All metazoans possess innate immune defence system whereas parameters of the adaptive immune system make their first appearance in the gnathostomata, the jawed vertebrates. Fish are therefore the first animal phyla to possess both an innate and adaptive immune system making them very interesting as regards developmental studies of the immune system. The massive increase in aquaculture in recent decades has also put greater emphasis on studies of the fish immune system and defence against diseases commonly associated with intensive fish rearing. Some of the main components of the innate and adaptive immune system of fish are described. The innate parameters are at the forefront of immune defence in fish and are a crucial factor in disease resistance. The adaptive response of fish is commonly delayed but is essential for lasting immunity and a key factor in successful vaccination. Some of the inherent and external factors that can manipulate the immune system of fish are discussed, the main fish diseases are listed and the pathogenicity and host defence discussed. The main prophylactic measures are covered, including vaccination, probiotics and immunostimulation. A key element in the immunological control of fish diseases is the great variation in disease susceptibility and immune defence of different fish species, a reflection of the extended time the present day teleosts have been separated in evolution. Future research will probably make use of molecular and proteomic tools both to study important elements in immune defence and prophylactic measures and to assist with breeding programmes for disease resistance.     

Using Echo Ultrasound from Schooling Fish to Detect and Classify Fish Types

Fish finders have already been widely available in the fishing market for a number of years.However,the sizes of these fishfinders are too big and their prices are expensive to suit for the research of robotic fish or mini-submarine.The goal of thisresearch is to propose a low-cost fish detector and classifier which suits for underwater robot or submarine as a proximity sensor.With some pre-condition in hardware and algorithms,the experimental results show that the proposed design has good per-formance,with a detection rate of 100 % and a classification rate of 94 %.Both the existing type of fish and the group behaviorcan be revealed by statistical interpretations such as hovering passion and sparse swimming mode.     

Discrimination among Fish Models by Hawaiian Eleotris sandwicensis (Eleotridae)1

I examined behavioral responses of the benthic fish Eleotris sandwicensis to painted models (dummies) of fish that Eleotris typically encounter in Hawaii. Eleotris sandwicensis were associated with coarse substrates where their mean (±SE) density was 1.5 (±0.30) fish/m². I hypothesised that Eleotris would retreat from all models in open areas, but not when they were present in shelters. The five models represented Stenogobius hawaiiensis, Awaous guamensis, E. sandwicensis (female coloration), a male E. sandwicensis in breeding colors (black), and a 12 cm block of wood (control). Whether or not Eleotris held its position or retreated was not a function of body size. Differences among the responses of Eleotris to models depended on whether or not the fish was hidden or exposed on substrates. More retreats in response to models occurred when Eleotris were exposed on substrates than when fish were hidden. There were no significant differences in the response of E. sandwicensis to models when fish were exposed on substrates. In contrast, responses of E. sandwicensis to the models were not random for fish that were hidden, indicating that Eleotris discriminated among the models. The basis for discrimination among models was most likely visual. Although Eleotris are typically secretive, their presence on exposed substrates at this study site may be attributed to die lack of benthivorous fishes and few avian predators. The ability of Eleotris to distinguish among fishes when hidden as well as their tendency to retreat in response to all intruders whenever exposed on substrate surfaces could reduce potential interactions between Eleotris and other native and nonindigenous fishes.     

Characterization of behavioural responses in different test contexts after a single social defeat in male golden hamsters (Mesocricetus auratus)

The objective of the present study was to characterize behavioural responses of male hamsters in each of three test contexts after they had experienced either a single social defeat or a neutral encounter. In experiment 1, hamsters were observed in a familiar social context (i.e., their home cages), and defeated males displayed different amounts of time and submissive behaviours towards a known opponent than a novel intruder, whereas males in the neutral-encounter groups did not show such differences. In experiment 2, in an unfamiliar social context (i.e., a Y-maze), defeated males generated submissive behaviours and fear memory towards a known opponent that they re-encountered 5-min and 24-h after the defeat. The formation of long-term memory was interrupted by an injection of anisomycin (210 mg/kg). In experiment 3, in a non-social, anxiogenic context, hamsters that had previously had different social experiences did not demonstrate additional anxiety in an elevated plus-maze, with the exception of males that had previously experienced repeated social defeats. Our data suggested that hamsters’ behavioural changes following defeat are context-dependent and stimulus-specific. The experience of a single social defeat is sufficient to regenerate submissive behaviours and fear memory when reencountering a known opponent.     

Fish in Reservoirs

In all reservoirs the fish fauna is recruited from their riverine antecedents. The nature of the riverine environment, created by its unstable hydrological regime, favours the evolution of generalist species. Of these species, only a few are preadapted to lacustrine conditions. When riverine fish communities are trapped in a reservoir, most of the fish stay close to the shore, the mouth of tributaries and in shallows. The pelagic and deep waters are poorly utilized and the yield of fish is below the natural productivity of these water bodies, especially in the case of deep and large reservoirs. This occurs unless the dammed river contains fish species from families which are preadapted for lacustrine conditions. A positive correlation between the percentage of pelagic fish and the total yield of fish in reservoirs indicates that the pelagial represents a vacant habitat, only seldom invaded by riverine species. This situation probably applies to the deep water of reservoirs too, although sufficient data to demonstrate this are not available. The littoral region of reservoirs is utilized by some generalists of euryoecious species derived from the indigenous riverine fauna which may be preadapted for lacustrine conditions. If such preadapted lacustrine species are not present, the introduction of lacustrine species or those preadapted for the lacustrine environment is desirable under certain circumstances. However, caution must be exercised in any introduction.     

Sex-specific interactions between aggressive and sexual behavior in the rat: Effects of testosterone and progesterone

The influence of progesterone on sexual and aggressive behaviors during aggressive encounters was investigated in pairs of TP-treated male and female rats. Gonadectomized females, chronically injected with testosterone propionate (TP), showed low but consistent levels of feminine sexual behavior which alternated with aggression. Progesterone when given in addition to TP facilitated receptive and proceptive behaviors, but reduced levels of aggression. In TP-treated males, levels of aggression were the same as observed in TP-treated females. However, TP-treated males seldomly showed sexual behavior during aggressive encounters and additional treatment with progesterone did not affect their behavior. After the aggression tests, animals were tested in a social preference test in which an ovariectomized female cage mate and the opponent from the aggressive encounter served as incentives. Positive correlations between levels of aggression and social preference for an opponent were found in both sexes, although correlations only reached statistical significance when progesterone was given in addition to TP. These correlations were found in both sexes, despite the fact that group analysis revealed pronounced sex differences in social preference: males preferred to spend their time near ovariectomized female cage mates, whereas females divided their time equally among female cage mates and opponents.     

Geography of Invasion in Mountain Streams: Consequences of Headwater Lake Fish Introductions

The introduction of fish into high-elevation lakes can provide a geographic and demographic boost to their invasion of stream networks, thereby further endangering the native stream fauna. Increasingly, remaining populations of native salmonids are concentrated in fragmented headwater refugia that are protected by physical or biological barriers from introduced fishes that originate in the pervasive source populations established at lower elevations. Although fish introduced near mainstem rivers frequently encounter obstacles to upstream dispersal, such as steep slopes or falls, we found that brook trout (Salvelinus fontinalis) dispersed downstream through channel slopes of 80% and 18-m-high falls. Thus, headwater lake stocking provides source populations that may be capable of invading most downstream habitats, including headwater refugia of native fishes. The extent of additional area invasible from lakes, beyond that invasible from downstream, depends on the geography of the stream network, particularly the density and distribution of headwater lakes and their location relative to barriers inhibiting upstream dispersal. In the thermal and trophic environments downstream of lakes, fish commonly grow faster and thus mature earlier and have higher fecundity-at-age than their counterparts in other high-elevation streams. The resulting higher rates of population growth facilitate invasion. Larger body sizes also potentially aid the fish in overcoming barriers to invasion. Trout introductions to high-elevation headwater lakes thus pose disproportionately large risks to native fishes—even when the place of introduction may appear to be spatially dissociated from populations of the native species. Mapping the potential invasible area can help to establish priorities in stocking and eradication efforts. Received 28 March 2000; accepted 9 February 2001.     

Prey patchiness, predator survival and fish recruitment

A simple mathematical model is presented for the population dynamics of fish larvae when the main food supply, in this case copepods, is spatially patchy in its distribution. Encounters by an individual predator (larva) with prey patches, and with individual prey within patches, are represented by Poisson processes. It is demonstrated analytically, and confirmed by numerical experiments, that prey patchiness fails to alter mean predator-prey encounter rates from their values for homogeneous prey distributions. Individual variance in encounter rate is, however, much affected. This has significant consequences for the (small) numbers of larvae surviving to metamorphosis and recruitment to the adult fish population.     

Fish TNF and TNF receptors

Tumor necrosis factors(TNFs) are a group of cytokines that play critical roles in regulating a diverse range of physiological processes in vertebrates. TNFs function by activating a large number of structurally related receptors, leading to TNF mediated biological processes which are evolutionarily conserved. Fish have a much diversified TNF family, partly due to the whole genome duplication events which have occurred in this lineage, providing an excellent model to investigate the neo-and subfunctionalised properties of TNF superfamily. Fish possess most of the TNFs and receptors found in mammals and also some homologues exclusively present in fish. It seems that TNFSF4(OX40), TNFSF7(CD27) and TNFSF8(CD30) and their cognate receptors are absent in teleosts. It has been shown that fish viruses are able to produce TNFR homologues to establish infection by manipulating the host immune system. Understanding the roles of TNFSFs in fish immune defence and the pathogenesis of fish diseases will provide insights into the functions of TNFSFs from an evolutionary perspective and better strategies for improving fish health and welfare in aquaculture. This review summarises recent advances in the study of fish TNF biology and focuses on the molecular properties and immunological functions of the TNF and TNFR superfamily.     

Do damselfly larvae recognize and differentially respond to distinct categories of macroinvertebrates?

Zygopteran larvae normally encounter other aquatic macroinvertebrates that are predators, competitors, and prey and should therefore demonstrate varied responses when faced with different categories of opponent. In a laboratory experiment individual final-instarIschnura posita (Hagen) larvae were observed in interactions with six categories of invertebrate opponents. The opponent categories were a nonconspecific damselfly and a small crayfish, which represented threatening opponents because they were larger than theI. posita subject larva, and a mayfly and a stonefly, which constituted nonthreatening opponents because they were smaller than the subject larva. The levels of threat posed by conspecific larvae of final and penultimate instar were inferred by comparison to the other opponent categories. Multivariate analysis showedI. posita's response differed between the two larger opponents, but responses were statistically indistinguishable between the two smaller opponents. Larvae retreated, moved around the stalk, and struck their opponents with their lamellae more often in the presence of a crayfish than the nonconspecific zygopteran. In contrast, they assumed an S-bend posture frequently with the zygopteran. Responses toward final-instar conspecifics differed from responses toward the larger opponents. Effectively, larvae wagged their abdomens only in the presence of final-instar conspecifics and retreated and moved around the stalk less frequently in these trials. Responses toward the smaller conspecifics differed from the responses to the small opponents. Larvae struck penultimate-instar conspecifics with their lamellae more frequently than the other small opponents. Our results suggest that larval zygopteran behaviors (such as S-bend and SCS) that have previously been described as intraspecific displays are of a more general nature and used toward a variety of opponents, whereas wag is unique to intraspecific interactions inI. posita.     

Fish immunoglobulins and the genes that encode them

The nature of fish antibodies (concentrating primarily on the most studied species of bony and cartilaginous fishes) is discussed in terms of their immunoglobulin biochemistry and immunobiology. The major serum immunoglobulin (IgM) is described in detail, and structural variants of IgM are discussed in terms of their distribution in different fish species, and different anatomical sites within a fish (e.g. blood, mucus, bile). Structural variation in IgM includes the size of the constituent heavy and light polypeptide chains, and the extent to which they are covalently associated with one another. The intramolecular heterogeneity of binding sites for antigen on IgM is reviewed and possible mechanisms for the phenomenon are presented. The evidence suggests that some, but not all, species of fish possess a detectable J chain in their IgM. The general nature of the fish immune response is that IgM antibody of moderate affinity is produced and prolonged or repeated immunization: (a) fails to produce a switch to production of a non-IgM class of antibody, and (b) fails to induce substantial increases in the affinity of the specific antibodies. Evidence supports a conclusion that fish lack the typical secondary antibody response seen in mammals, and possess antibodies of limited heterogeneity. Our current understanding of the genetic basis for fish antibodies is presented. Fish appear to utilize the same basic genetic elements as mammals to encode and regulate the expression of their immunoglobulins. The teleost heavy chain (IgH) locus resembles that of mammals and amphibia in its organization. The IgH locus of elasmobranchs is arranged in a unique multicluster organization. The light chain loci of elasmobranchs are organized analogously to the heavy chain locus (in multiclusters). The structure of the light chain locus of teleosts is presently unknown. Teleost fish utilize a unique pattern of RNA processing to generate the secreted and membrane receptor forms of the IgM heavy chain. The genes encoding the unique low molecular weight Ig heavy chain found in skates and rays have been cloned and sequenced, and also display the multicluster pattern of organization. Teleost fish appear to have normal numbers of variable regions: it is hypothesized (but as yet unproven) that the failure of their IgM to increase in affinity is due to a deficiency of somatic hypermutational mechanisms in their Ig gene variable regions during B lymphocyte differentiation.     

Respiratory Adaptations in Intertidal Fish

SYNOPSIS: Intertidal rockpools provide a challenging environmentfor rockpool fish with rapid changes taking place in many environmentalparameters over a tidal cycle. Intertidal fish exhibit a numberof behavioural adaptations such as the avoidance of hypoxicsituations or remaining inactive during aerial "stranding."Other species are, however, well adapted to breathe air andexhibit morphological adaptations such as smaller gill areas,specialized buccopharyngeal epithelia and a proliferation ofcutaneous blood vessels in the skin. Oxygen consumption in rockpoolfish is comparable to non-intertidal fish and responds in asimilar manner to temperature changes. The ability to regulateoxygen consumption down to oxygen tensions below 40 Torr is,however, marked in rockpool species. Aerial and aquatic ratesof respiration are similar in those species which are able tobreathe air and the respiratory quotient normally remains between0.7 and 0.9. A number of intertidal fish are well adapted forcutaneous respiration, satisfying over half of their oxygenand carbon dioxide exchange through the skin. Ventilatory responsesto increased temperature, hyperoxia and hypoxia are similarto those of other fish but cardiac responses may differ in thatno change in heart rate is seen under hypoxia or hyperoxia.Ventilatory and cardiac responses to aerial respiration arewell adapted in some species maintaining ventilation and perfusionduring aerial exposure. A marked Bohr effect, low temperaturesensitivity and a temperature dependent Haldane effect havebeen measured in the haemoglobolin of some intertidal fish.These properties may assist oxygen transport and carbon dioxideexchange during cyclical changes in environmental parameterswithin an intertidal rockpool.     

Fish B lymphocytes: Defining their form and function

Fish B lymphocytes have been defined, as in mammalian systems, as those lymphocytes that express immunoglobulin on their surface and secrete specific antibody in response to antigenic stimuli. Such cells have been identified in a number of fish species. However, the physical characterization of these cells, their distribution, the form of their response, and the antibody product itself have not precisely followed the mammalian paradigm. The implications of these unique features of fish B cell form and function are the focus of this review. The antigenic phenotype of the B cell and the possible function of distinct subpopulations are discussed. The origin of the fish B lymphocyte itself is still a great enigma. The developmental and ontological pathway(s) taken by fish B cell progenitors are still virtually unknown, but considerable data have accrued that allow investigators to postulate possible sources of such lymphocytic stem cells (i.e. bone marrow equivalents), such as the anterior kidney. As opposed to the ontological development of B cells, the nature of the intercellular cooperation and lymphokine requirements for an antibody response seem to parallel mammalian counterparts quite closely. Finally, the coordination of all these cells, factors, and products into a complex function, such as the generation of immunological memory, present an excellent venue for comparative immunologists. In the expression of this complex and highly regulated process, fish have demonstrated some basic similarities to mammals, but differ in other important features. Understanding how fish have circumvented the need for these aspects of memory allows us not only to understand fish function, but enables us to place specific mammalian functions in a broader context. Such analyses will provide new theoretical approaches to the understanding of mammalian as well as fish immune responses.