Complex alarm strategy in the most basal termite species

Delattre, Olivier; Sillam‐Dussès, David; Jandák, Vojtěch; Brothánek, Marek; Rücker, Karel; Bourguignon, Thomas; Vytisková, Blahoslava; Cvačka, Josef; Jiříček, Ondřej; Šobotník, Jan

doi:10.1007/s00265-015-2007-9

Cited by 29 publications

(39 citation statements)

References 78 publications

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“…To conclude, termites are eusocial cockroaches ( Lo et al, 2000 ; Inward et al, 2007 ; Cameron et al, 2012 ), and their complex social life made them use more sophisticated means of communication compared to their solitary relatives. Concerning the alarm function, termites and Cryptocercus evolved alarm communication using body vibrations, and the use of alarm pheromones evolved twice among termites, in Mastotermes ( Delattre et al, 2015 ) and in Neoisoptera (present study). Our results demonstrate the dual function of the alarm signalling in C. cyphergaster : In addition to vibratory communication occurring in all termites, the soldier frontal gland secretion contains the alarm pheromone, which is a mixture of abundant [( 1S )-α-pinene, myrcene] and rare [( E )-β-ocimene] monoterpenes, all contributing to the desired function.…”

Section: Discussionmentioning

confidence: 69%

“…Larger molecules were out from the scope of our work, but several sesquiterpenes and a diterpene were previously identified in C. cyphergaster soldier frontal gland secretion as well (see Baker et al, 1984 ; Azevedo et al, 2006 ). The other case of alarm pheromone presence in termites occurred in Mastotermes , but in contrary to Neoisoptera, the pheromone is benzoquinone produced by the labial glands ( Delattre et al, 2015 ).…”

Section: Discussionmentioning

confidence: 99%

“…The other component of termite alarm signalling, the vibroacoustic communication by means of substrate-borne vibrations, occurs in all termite species studied so far (see Hager and Kirchner, 2013 ; Howse, 1962 , 1964 , 1965 ; Stuart, 1963 , 1988 ; Kirchner et al, 1994 ; Connétable et al, 1998 , 1999 ; Röhrig et al, 1999 ; Reinhard and Clément, 2002 ; Hertel et al, 2011 ; Delattre et al, 2015 ), as well as in Cryptocercus ( Bell et al, 2007 ), the sister-group of all termites ( Lo et al, 2000 ; Cameron et al, 2012 ). Although other cockroaches are able to perceive the substrate-borne vibration ( Bell et al, 2007 ), the communication through drumming is an evolutionary novelty of Cryptocercus -Termitoidea clade.…”

Section: Discussionmentioning

confidence: 99%

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The nature of alarm communication in Constrictotermes cyphergaster (Blattodea: Termitoidea: Termitidae): the integration of chemical and vibroacoustic signals

et al. 2015

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Alarm signalling is of paramount importance to communication in all social insects. In termites, vibroacoustic and chemical alarm signalling are bound to operate synergistically but have never been studied simultaneously in a single species. Here, we inspected the functional significance of both communication channels in Constrictotermes cyphergaster (Termitidae: Nasutitermitinae), confirming the hypothesis that these are not exclusive, but rather complementary processes. In natural situations, the alarm predominantly attracts soldiers, which actively search for the source of a disturbance. Laboratory testing revealed that the frontal gland of soldiers produces a rich mixture of terpenoid compounds including an alarm pheromone. Extensive testing led to identification of the alarm pheromone being composed of abundant monoterpene hydrocarbons (1S)-α-pinene and myrcene, along with a minor component, (E)-β-ocimene. The vibratory alarm signalling consists of vibratory movements evidenced as bursts; a series of beats produced predominantly by soldiers. Exposing termite groups to various mixtures containing the alarm pheromone (crushed soldier heads, frontal gland extracts, mixture of all monoterpenes, and the alarm pheromone mixture made of standards) resulted in significantly higher activity in the tested groups and also increased intensity of the vibratory alarm communication, with the responses clearly dose-dependent. Lower doses of the pheromone provoked higher numbers of vibratory signals compared to higher doses. Higher doses induced long-term running of all termites without stops necessary to perform vibratory behaviour. Surprisingly, even crushed worker heads led to low (but significant) increases in the alarm responses, suggesting that other unknown compound in the worker's head is perceived and answered by termites. Our results demonstrate the existence of different alarm levels in termites, with lower levels being communicated through vibratory signals, and higher levels causing general alarm or retreat being communicated through the alarm pheromone.

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Section: Discussionmentioning

confidence: 69%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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The nature of alarm communication in Constrictotermes cyphergaster (Blattodea: Termitoidea: Termitidae): the integration of chemical and vibroacoustic signals

et al. 2015

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“…Vibroacoustic communication is widely diffused among social groups to the emission of warning signals (Hunt & Richard, 2013). In termites, this communication is observed from the most basal groups (Delattre et al, 2015) to the most derived ones (Cristaldo et al, 2015). In addition to alert about risks, vibration in termite is also used during foraging activities to indicate nestmates about the amount of food resources found (Evans et al, 2005).…”

Section: Discussionmentioning

confidence: 99%

Attraction and vibration: Effects of previous exposure and type of food resource in the perception of allocolonial odors in termites

et al. 2018

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Social insects have an efficient recognition system that guarantees social cohesion and protection against intruders in their colonies and territories. However, the energy costs in constant conflicts with neighboring colonies could promote a reduction in the fitness of colonies. Here, we evaluated the effect of previous exposure to allocolonial odor and the consumption of similar food resources on aggressive behavior and choice of allocolonial cues in Nasutitermes aff. coxipoensis (Termitidae: Nasutitermitinae). Our results showed that intercolonial aggressiveness was not affected by previous exposure to allocolonial odor and by the consumption of similar food resources. However, individuals previously exposed to allocolonial odor were more attracted to these odors than individuals who had no prior exposure to allocolonial odor. In addition, individuals from colonies of N. aff. coxipoensis that use similar food resources increased alertness via a greater number of vibration than individuals who consumed different food resources. In general, our results indicate that colonies of N. aff coxipoensis perceive allocolonial cues that have been previously exposed and that the consumption of similar resources triggers an alert signal between individuals. Additional studies are necessary to assess how widespread this capacity of perception is present among the different Isoptera groups and the consequences of colony recognition odor cues on termite space use.

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“…Alarm signals used to inform members of the group about danger can also be considered as a part of defense behavior. Vibrational signals that function to warn conspecifics have been described in termites (e.g., Rosengaus et al, 1999;Hager and Kirchner, 2013;Delattre et al, 2015) and elephants (O'Connell-Rodwell et al, 2007). At present, it is not clear whether footdrumming alarm signals emitted by many mammals in the presence of a predator are perceived as air-borne sound or substrate vibrations, or both (Randall, 2001(Randall, , 2010.…”

Section: Avoiding Enemiesmentioning

confidence: 99%

Predator-Prey Interactions and Eavesdropping in Vibrational Communication Networks

et al. 2019

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Due to human perceptional bias in favor of airborne sounds, substrate-borne vibrational signaling has been traditionally regarded as a highly specialized, inherently short-range and, consequently, a private communication channel, free from eavesdropping by sexual competitors and predators. In this review, we synthesize current knowledge pertinent to the view that most animals live in a rich vibratory world, where vibrational information is available to unintended receivers. In recent years, we realized that vibrational signaling is one of the oldest and taxonomically most widespread forms of communication by mechanical waves and that receptors detecting substrate vibrations are ubiquitous. In nature, substrate vibrations are reliable source of information readily available to all members of the animal community able to detect them. Viewing vibrational communication in more relevant ecological context reveals that animals relying on substrate vibrations live in complex communication networks. Long evolutionary history of this communication channel is reflected in varied and sophisticated predator-prey interactions guided by substrate-borne vibrations. Eavesdropping and exploitation of vibrational signals used in sexual communication have been so far largely neglected; however, existing studies show that generalist arthropod predators can intercept such signals emitted by insects to obtain information about prey availability and use that information when making foraging decisions. Moreover, males which advertise themselves for longer periods than females and with vibrational signals of higher amplitude face higher predation risk. It is likely that eavesdropping and exploitation of vibrational signals are major drivers in the evolution taking place in the vibratory world and we believe that studies of interspecific interactions guided by substrate vibrations will, in the future, offer numerous opportunities to unravel mechanisms that are central to understanding behavior in general.

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Complex alarm strategy in the most basal termite species

Cited by 29 publications

References 78 publications

The nature of alarm communication in Constrictotermes cyphergaster (Blattodea: Termitoidea: Termitidae): the integration of chemical and vibroacoustic signals

The nature of alarm communication in Constrictotermes cyphergaster (Blattodea: Termitoidea: Termitidae): the integration of chemical and vibroacoustic signals

Attraction and vibration: Effects of previous exposure and type of food resource in the perception of allocolonial odors in termites

Predator-Prey Interactions and Eavesdropping in Vibrational Communication Networks

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