The response of a bumblebee goby,Brachygobius sabanus,to chemical stimuli from injured conspecifics

Synopsis Brachygobius sabanus move less often and spend less time swimming when they detect chemicals released from injured conspecifics. This resembles the alarm response found in ostariophysan fishes, darters, and at least one other gobiid. Chemicals from injured Poecilia reticulata do not induce an alarm response in B. sabanus.     

Free—living fathead minnows rapidly learn to recognize pike as predators

Individuals from a natural population of approximately 20 000 fathead minnows from a pike–free pond did not respond with appropriate anti–predator behaviour upon encountering pike odour in laboratory tests. However, 14 days after 10 pike were stocked into the pond, minnows had acquired recognition of pike odour. Laboratory studies have indicated several possible mechanisms for acquiring predator recognition in fathead minnows. This study indicates that these, or similar processes, can produce major changes in predator recognition in the wild.     

Epidermal club cells and the innate immune system of minnows

Thousands of fish species belonging to the Superorder Ostariophysi possess specialized club cells in their epidermis. Damage to the cells, as would occur during a predator attack, releases chemical substances that evoke antipredator responses in nearby shoalmates. These chemical substances have often been referred to as alarm substances and the cells that release them as alarm cells. Understanding the evolution of the cells in an alarm context has been difficult. The fish needs to be captured prior to the chemicals being released, hence the benefit to the receiver is unclear. Recent studies have suggested that the club cells are part of the immune system and are maintained by natural selection owing to the benefits that they confer against pathogens, parasites, and general injury to the epidermis. In the present study, we gave fathead minnows intraperitoneal injections of cortisol, a known immunosuppressant, or injections of a control substance (corn oil). We found that fish exposed to cortisol had suppressed immune systems (as measured by a respiratory burst assay) and that they also reduced their investment in club cells. This is the best evidence to date indicating that the club cells of Ostariophysan fishes are part of the innate immune system and that the alarm function of the cells evolved secondarily. © 2009 The Linnean Society of London, Biological Journal of the Linnean Society, 2009, 98 , 891–897.     

Are shoals of minnow Phoxinus phoxinus formed by close kin?

A molecular analysis examining the level of relatedness in shoaling minnows Phoxinus phoxinus was conducted. The results revealed that individuals from within the same shoal were not more closely related to each other than to individuals from other shoals. This led to the conclusion that Schreckstoff may be less likely to have evolved in the context of kin selection.     

Anti‐predator response of naïve and experienced common bully to chemical alarm cues

Histological analysis of the skin of common bully Gobiomorphus cotidianus , a New Zealand native eleotrid fish, revealed the presence of club cells in the epidermis. Epidermal club cells are frequently associated with the production of alarm substance (Schreckstoff). The behavioural responses of perch‐naïve and perch‐experienced common bullies to either conspecific skin extract or chemical cues from an introduced predator, perch Perca fluviatilis , were then examined. Both perch‐naïve and perch‐experienced common bullies exhibited a behavioural response when exposed to conspecific skin extract, indicating the probable presence of an alarm substance. In contrast, only perch‐experienced common bullies recognized and exhibited a subsequent behavioural response to the odour of perch. This study is the first to document the presence of epidermal club cells and a behavioural response to a conspecific chemical alarm signal for fishes in the Eleotridae. The results indicate that common bully can learn to recognize perch odour as a threat, and that this ability may be a result of previous predator labelling involving a conspecific alarm substance.     

Survival of fathead minnows after injury by predators and its possible role in the evolution of alarm signals

Synopsis Some mechanisms proposed to account for the evolution of animal alarm signals require that the signal sender survive in order to benefit. The ostariophysan alarm pheromone system requires mechanical damage for the release of the alarm pheromone. A natural situation is described in which up to 16% of the fathead minnows in a population have survived damaging encounters with predators. This indicates that post-signal selective benefits can operate in the evolution of the ostariophysan alarm system.     

Chemical alarm signals increase the survival time of fathead minnows (Pimephales promelas) during encounters with northern pike (Esox Lucius)

We tested the hypothesis that exposure to a conspecific alarmpheromone improves survival of fathead minnows (Pimephales promelas)during staged encounters with an unfamiliar predator (northernpike: Esox luaus). Minnows exposed to the alarm pheromone survived39. 5% longer than controls. This difference in survival timeappeared to result not from direct inhibition of the pike butrather from some aspect of the minnows' antipredator behavior.Minnows exhibited significant increases in both shoaling andshelter use after exposure to the alarm pheromone. For controlminnows, the degree of shoaling was positively correlated withsurvival time, suggesting that increased shoaling is an effectiveantipredator response. This study provides the first directexperimental evidence that chemical alarm signals in fishesimprove survival of receivers.     

The role of experience and chemical alarm signalling in predator recognition by fathead minnows, Pimephales promelas

Young-of-the-year, predator-naive fathead minnows, Pimephales promelas , from a pikesympatric population did not respond to chemical stimuli from northern pike, Esox Indus , while wild-caught fish of the same age and size did. These results suggest that chemical predator recognition is a result of previous experience and not genetic factors, Wild young-of-the-year minnows responded to pike odour with a response intensity that was similar to that of older fish, demonstrating that the ability to recognize predators is learned within the first year. The intensity of response of wild minnows which had been maintained in a predator free environment for 1 year was similar to that of recently caught minnows of the same age, suggesting that reinforcement was not required for predator recognition to be retained. Naive minnows that were exposed simultaneously to chemical stimuli from pike (a neutral stimulus) and minnow alarm substance exhibited a fright response upon subsequent exposure to the pike stimulus alone. Predator-naive minnows exposed simultaneously to chemical stimuli from pike and glass-distilled water did not exhibit a fright response to the pike stimulus alone. These results demonstrate that fathead minnows can acquire predator recognition through releaserinduced recognition learning, thus confirming a known mechanism through which alarm substance may benefit the receivers of an alarm signal.     

Fright Reaction in Gymnocharacinus bergi (Pisces, Characidae), A Relic Fish from Patagonia

Fright reaction, mediated by pheromones, is an antipredatory mechanism in the scale-less mojarra Gymnocharacinus bergi (Pisces, Characidae). The aim of this study was to characterise and quantify the fright reaction of this species and to analyse the alarm response to different doses of alarm substance. The alarm response consisted in a general decrease in the swimming speed and a tendency to remain at the bottom of the test aquarium. A threshold effect was induced by a very low dose of alarm substance, and the intensity of the fright reaction was positively correlated to the dose concentration. The main characteristics of the alarm response appear to be consistent with G. bergi's environmental conditions such as: a higher predation risk in the upper stratum, the abundant pond-weeds of the stream and the great flow and fast speed of the clear waters.     

Fathead minnows (Pimephales promelas) learn to recognize chemical stimuli from high-risk habitats by the presence of alarm substance

We exposed fathead minnows (Pimephales promelas) to water fromone of two distinct habitat types (an open water site or a vegetatedcover site in the same stream) that we mixed with either alarmsubstance or a distilled water control. Upon subsequent exposuresto the habitat waters alone, minnows showed a fright responseto the habitat water that they received in conjunction withalarm substance but not to the other habitat water. These resultsindicate that minnows can learn to recognize high-risk habitatsbased on the association of habitat specific chemical cues withalarm substance. The ability to recognize these habitats couldpotentially lower the minnows' risk of predation. These resultsprovide evidence of a long-term benefit to receivers of a chemicalalarm signal.