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Insect communication

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Bio communication in insects

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BIO COMMUNICATION IN INSECTS PRESENTED TO: Dr. Amritpal Sir PRESENTED BY: Harsimrat Kaur Dulai Ph.D. Roll no. 1952204
INTRODUCTION COMMUNICATION:  It is the exchange of information between individuals.  Adapted for symbolic communication, but most of insect’s "language" skills are acquired through learning.  For members of the insect species, it is an essential part of all social interactions.
COMMUNICATION IN INSECTS  The majority of insect species live a solitary life, with few contacts between conspecific individuals.  Social insects, however, are characterized by communities in which they live in permanent contact with their nestmates.  Bees and bumble bees, wasps, ants and termites since long have fascinated man because of their well organized and often impressive colonies.
Why do insectscommunicate?  Recognition of kin or nestmates.  Locating or identifying a member of the opposite sex.  Facilitation of courtship and mating.  Giving directions for location of food.  Regulating spatial distribution of individuals, aggregation or dispersal; establishing and maintaining a territory.  Warning of danger; setting off an alarm.  Expressing threat or submission.  Mimicry
TYPESOFBIO-COMMUNICATION A. Visual communication B. Chemical communication C. Tactile communication D. Acoustic communication
A. VISUALCOMMUNICATION  Most visual communications are effective during daylight, but some insects can generate their own light and use visual signals that can be seen at night.  Also for partner location, prior to mating, the male’s big compound eyes can help in finding the females .  Male dragonflies recognizes female dragonflies.
 The male Photinus consimilis During a rising flight movement emits a series of 3.5 short flashes and a female responds after a double flash. FIREFLIES
BIOLUMINESCENCE: When oxygen combines with calcium, adenosine triphosphate (ATP) and the chemical luciferin in the presence of luciferase, a bioluminescent enzyme, light is produced. Unlike a light bulb, which produces a lot of heat in addition to light, a firefly's light is cold light, without a lot of energy being lost as heat. LIGHT PRODUCING MECHANISM IN FIREFLIES
1. In order for this reaction to occur, a chemical named “Luciferin”, which emits light, is required. 2. Then, oxygen is needed to oxidize the reaction. 3. As a result of this chemical reaction , energy is released in a form of light due to energy from the excitation of the electrons in the ions. The energy of photons of visible light produced is about 50 kcal.
In alfalfa butterflies, males have U.V. reflective scales and missing scales is a sign for male ageing.
1. Batesian mimicry Danaus chrysippus (The Plain tiger) Model-Non edible Hypolimna smisippus (Female Danaid Eggfly) Mimic-Edible 2. Mullerian mimicry Heliconius butterfly genus TYPES OF MIMICRY
SURPRISEANDSTARTLEEFFECT •Surprise combined with rapid escape flight is often a sufficient defense. •Startle is the combination of the elements of surprise and fright. Hawk moth larva Spinx moth Under winged moth
CRYPSIS  Crypsis, avoiding detection by blending into the background is one of the most common defense mechanisms. Toad bugAmazon caterpillar
EXAMPLES FOR CAMOUFLAGE Brimstone butterfly Camo moth Swallowtail butterfly
BEHAVIOURALAPPROACH 1)APOSEMATISM: The opposite of crypsis or a warning signal to predators. Patterned combinations of reds, yellows, oranges, whites, and blacks. Warning colouration boldly signals that this insect is toxic, is bad tasting, or can sting or cause injury. Cinnabar moth larva Automeris metzli (Saturniidae)
2)THANATOSIS:  Things that eat other things tend to quickly lose interest in dead prey, so some insects that employ the strategy of playing dead and can often escape unharmed.
B.CHEMICAL COMMUNICATION •A total of 731 insect species were involved in responses to the 323 chemical compounds. •Insect behaviours that are modulated by chemical senses, or the complexity of structures responsible for chemical signalling and perception, the chemical communication channel is a predominant feature of insects (Greenfield, 2002). •The small to minute body sizes of insects may be largely responsible for their general reliance on chemical senses.
SEMIOCHEMICALS A broad term for chemicals involved in insect communication is semiochemical, from the Greek semeion sign (Law and Regnier, 1971). Classification: 1.Pheromone (Intraspecific signals) 2.Allelochemicals (interspecific signals) 1. PHEROMONE: chemical substance produced and released into the environment by an animal, especially a mammal or an insect, affecting the behaviour or physiology of others of its species.
TYPES OF PHEROMONE: • PRIMER PHEROMONE • RELEASER PHEROMONE • TRAIL PHEROMONE • ALARM PHEROMONE • AGGREGATION PHEROMONE • SEX PHEROMONE
Primer pheromone: The most famous example of a primer pheromone is the honey bee queen mandibular pheromone (a mixture of two fatty acids: 9-ODA and 9-HDA) which suppresses ovary development in worker bees (Free, 1987).
IN TERMITES:  The king(s) and queen(s) inhibit the formation of neotenics using a putative, non-volatile, inhibitory chemical substance. Which is spread among nestmates by trophallaxis  When this inhibitory signal is decreased neotenics form from the immature termites.  CHC’s may also be involved in fertility signaling or reproductive control. (Liebig et al. 2009; Weil et al. 2009). BROOD CARE BEHAVIOUR: The eggs laid by the queen(s) are collected, handled, piled at specific spots by workers (and in exceptional cases by soldiers; Hanus et al. 2005), and protected from pathogens and desiccation by worker’s saliva.
Releaser pheromone: •The most commonly known are sex pheromones, which are highly species specific and serve to attract mates for reproduction. •The first sex pheromone was identified in 1959 from the silk moth Bombyx mori (Butenandt et al., 1959). •Many further insect sex pheromones have been identified to date and a number are commercially used in pheromone traps for pest control (Bell, 2004)
Name of the insect Pheromone  Pink bollworm, Pectinophora gossypiell  Gabbage looper, Trichoplusia  Tobacco cutworm, Spodopteralitura  Honey bee ueen, Apis sp. Gossyplure Looplure Spodolure, litlure, Helilure Queen’s substance
Trail pheromones, employed by social insects for orientation and to recruit nest mates to a suitable food source. They are produced by a variety of glands and can be composed of numerous different, mostly volatile compounds. When navigating their territory, ants and termites deposit these pheromones on the ground thus developing an extensive net of chemical routes. (Holldobler and Wilson, 1990; Pasteels and Bordereau, 1998; Kaib, 1999). Trail pheromone:
 Lays trails and lead to feed. Chemical nature of trail pheromones are decenoic acids ( in formicine ants). hexanoic, heptanoic, Trail pheromones can be used to kill ants. Trail pheromones mixed with baits can attract ants which when transported by ants to their nest it will kills all young ones. ANTS
 Some ant species use ‘propaganda’ pheromones to confuse the ants and make them fight themselves. enemy among  Honeybee releases orientation pheromones, a mixture of geraniol, citral, farnesol and other minor compounds from their Nasonov gland into the air in a number of orienting situations. (Free, 1987; Winston, 1987).
 Alarm pheromones are chemical substances released by insects to warn members of the same species about the presence of or attack by an enemy (mostly a predator).  This warning elicits different behaviour in different insects as listed below: 1.) Dispersion or escape in aphids and bugs. 2.) Aggression in ants and soldier termites. 3.) Attraction in wasps and worker bees. • The chemical nature of alarm pheromones are terpenes (aphids), aldehydes (Hemiptera) and formic acid (ants). Alarm phermone:
In ants: All Formicid species were subsequently found to produce and use an alarm pheromone (Holldobler and Wilson 1990). The response to “aggressive alarms” is characterized by rapid movements oriented toward the emitter and by aggressive attitudes ranging from mandible and gaster movements. Responses to “panic alarms” entail escape, dispersion, and flight behaviors.
Alarm pheromone in Honeybees: A vital role in honeybee colony defense is played by so-called guard bees, which patrol the nest entrance and represent the first line of colony defense. These guards are also specialized for the production of alarm pheromone which they release to recruit nestmates from the interior of the colony in case of danger (Boch et al., 1962; Collins et al., 1982). The perception of the pheromone increases workers movement and promotes aggression.
 Pheromones which induce aggregation or congregation of insects for protection, reproduction and feeding or combinations are called aggregation pheromones. Eg: Bark beetles start to bore into the bark and release a long range aggregation pheromone.  A mixture of terpenoids some of which are synthesized, others produced by symbiotic bacteria in the beetle gut or sequestered from host tree compounds (Greenfield, 2002; Wyatt, 2003). Aggregation pheromone:
Sex pheromone:  sex pheromones indicate the availability of the female for breeding. Male animals may also emit pheromones that convey information about their species and genotype.  insect species, such as the ant Leptothorax acervorum, the moths Helicoverpa zea and Agrotis ipsilon, the bee Xylocopa varipuncta and the butterfly Edith's checkerspot release sex pheromones to attract a mate, and many lepidopterans (moths and butterflies) can detect a potential mate from as far away as 10 km.  Some insects, such as ghost moths, use pheromones during lek mating.
•The communication between two different species of organisms or insects. •It is classified into Allomones, Kairomones, Synomones, and Apneumones. ALLOMONES: •From Greek word (allos+hormon=excite others) allomone is a chemical or mixture of chemicals released by one organism that induces a response in another organism which is advantageous to the releaser. •The defensive secretions of insects and plants that are poisonous to attacking predators. 2. ALLELOCHEMICALS:
 The neotrophical social wasp Mischocyttarus drewseni applies a secretion to the stem of its nest that repels foraging ants.  Some trophical flowers which are pollinated by bats emit odours which attract bat to the flowers. Examples: oSting gland in bees oFormic acid in ants  Allomones also serve plants as defence mechanism against plants. herbivores and reduce competition with other
KAIROMONES: Kairomone is a chemical or mixture of chemicals released by one organism that induces a response in another organism. Helpful to recipient. Eg.Heptanoic acid released by larva of potato tuber moth Phthorimaea operculella increases searching by its parasitoid Farnesene secreted by codling moth larva attracts its parasitoid
SYNOMONES:  Chemical released by one organism that induce a response in another species.  Helpful to emitter and receiver.  It encourages mutualistic relation between organisms.  Eg. Termites and protozoans . Eg: Flower fragrance: Orchids (Ophrys) attract males of solitary bees or Dacini fruit fly by a mixture of compounds resembling the sex pheromone of con-specific females but males are not awarded with nectar instead they receive pheromone booster.
APNEUMONES:  Chemical substances emitted by a non- living material that evoke a behavioural or physiological reaction adoptively favourable to a receiving organism, but detrimental to another species, which may be found in or on the non- living material.  Eg: An ichunuemonid parasite of Venturia canescens is attracted by the smell of the oatmeal, which is the food of its host.  Here it is advantageous to the recipient which is the parasitoid but detrimental to host insect living on the oat meal (non- living material)
C. TACTILE COMMUNICATION "Keep in touch!" For you, it's probably just a metaphor, but for some insects it's really a channel of communication Since many insects have poor vision and sound perception, physical contact provides an important avenue of communication.
In blister beetles (family Meloidae), courtship begins with a series of antennal taps by the male on each side of the female's body. She signals her receptivity by lifting her wing covers (elytra) and allowing him to climb on her back. But to complete his quest, the male must continue tapping, alternating from side to side at just the right frequency until the female is stimulated to extend her genitalia and begin mating.
Antennal tapping is also an essential component of communication in both ants and termites. It's not clear exactly what information may be exchanged, but it certainly involves nestmate recognition and leads to exchange of food through trophallaxis.
• If tapping stops, leader instinctively turns around and searches in ever-widening circles until she re-establishes contact with the follower. • Antennal tapping on the hind legs is used during tandem running in both ants and termites. • This is a "follow-the-leader" behavior in which the tapping informs the leader that she has not lost her disciple.
IN TERMITES:  Drumming behaviour occurs in both soldiers and workers,  But its alarm pheromone capacity is low.  A chain of vibrating soldiers can spread an alarm across a distance of more than a meter in less than a second (Rohrig et al. 1999).
DANCE LANGUAGE OF HONEY BEES. Karl von Frisch, 1886-1982 Austrian, began work in 1919 Trained European honey bees, Apis mellifera, to feeders First believed bees used flower scents or other odors to find food. Began to pay close attention to dances performed by returning foragers.
1. “Round dance” • When food source is < 50 m from hive. • After distributing some of her new- found nectar to waiting bees the scout will begin running in a small circle, switching direction. • After the dance ends food is again distributed at this or some other place on the comb and the dance may be repeated three or (rarely) more times. • The round dance does not give directional information.
2. “Waggle dance” • When food source is > 50 meters away Waggle run -Abdomen wagging and wing fluttering -Angle repeated with respect to vertical, or gravity (here 20° right)
SCOUT: finds new food sources & dances RECRUITS: follow dances & then forage
Direction of the food source is indicated by the direction the dancer faces during the straight portion of the dance when the bee is waggling. If she waggles while facing straight upward, than the food source may be found in the direction of the sun.
If she waggles at an angle 60 degrees to the left of upward the food source may be found 60 degrees to the left of the sun.
If the dancer waggles 120 degrees to the right of upward, the food source may be found 120 degrees to the right of the sun. The dancer emits sounds during the waggle run that help the recruits determine direction in the darkness of the hive.
COMMUNICATION IN TREEHOPPERS Certain treehoppers (order Hemiptera: family Membracidae) produce vibrations in the tissue of their host plant that can be felt by all other treehoppers on the same plant. The signals apparently work as an alarm system, and in some species, they may be used by nymphs to elicit protective maternal behaviour. Substrate vibrations can be a particularly effective communication system for small insects who cannot generate an acoustic signal loud enough to be heard more than few inches away.
D. ACOUSTIC COMMUNICATION Acoustic communication can be made to vary in frequency, amplitude and periodicity. Together, these three variables can create an extremely wide and complex range of signals from an insect's mating call to human speech and vocal music. Since sound waves move rapidly through air (about 331 m/sec), acoustic signals can be quickly started, stopped, or modified to send a time-sensitive message
courtship songs produced by sex-specific scales on the forewings and mesothorax. In order to protect the pair from conspecific competitors and predators, this male moth produces the sounds in the female’s ear, which provide a private communication channel between them. (Conner, 2014). ACOUSTIC SOUND PRODUCTION IN MOTH:  “Whispering” Moths exemplify another antidetection strategy (Nakano et al., 2008).  Ostrinia furnicalis, moths, use male Asian corn borer specialized very low intensity
 Aposematic sounds often converge structurally having broad frequency ranges, low pattern complexity.  Such signals are readily detected by wide range of predators.  Toxic tiger moths (Arctiidae) send loud return sounds to approaching insectivorous bats.  These sounds warn the bat that the moth is unpalatable and potentially harmful, and may also interfere with the echolocation capabilities of bats. APOSEMATIC SOUND
Drosophila species (Von Schilcher, 1976). CATEGORIES OF SOUND PRODUCING MECHANISMS (Claridge, 2005) A. Vibration (including Tremulation) The oscillatory movement of the wings of an insect sets up regions of compression and rarefaction and a vibrational sound is produced. EXAMPLES : The flight sound, made by the wings, in swarming mosquitoes is considered to be used for species-specific recognition. (Gibson, Warren, & Russell, 2010; Roth, 1948).  Wing vibration is also used in the courtship dances of
B. Percussion – Striking one part of the body against another as a communication system for pair formation. EXAMPLE: 1)The Australian moth (Lepidoptera); males produce ultrasonic acoustical long distance signals to attract sexually receptive females and to establish territorial residency in competition with other males (Alcock & Bailey, 1995). 2)Species of the suborder Arctoperlaria (Plecoptera) produce drumming signals on the substrate as a mating system. The male emits a species-specific call searching for the female. (Stewart & Sandberg, 2005).
•In Orthopteran, insects respond stridulation from the receptive female orientation towards and their locomotion to the male. “Rivalry song” The female arrived near the male, stridulating in response to mate song; the male, once noticing the female, sings the courtship song, engages the genitalia and copulation occurs (Haskell, 1958). C. Stridulation – Stridulation consists of sounds produced by frictional mechanisms, involving the movements of two specialized body parts against each manner (Claridge, 2005). other in a systematic patterned
IN TERMITES:  It produced drumming.  It has also been hypothesized that the synchronized drumming of Macrotermitinae, evokes a rhythmical hissing may act as an aposematic signal to warn away predators. (Howse 1984; Connetable et al. 1999).
D. Click mechanisms • These sounds depend on the deformation of a modified area of cuticle, generally by contraction and relaxation of specialized musculature within the insect body. • This acoustic signal constitutes the first step in pair formation, attracting females at long distances, and is involved in male-male interactions (Sueur & Aubin, 2003).
For example, the males of Tibicina (Hemiptera) cicada species produce a sustained and monotonous calling song by tymbal activity. TYMBALS: Muscular vibration of drum like membranes The loudest calls in the insect world come from male cicadas. The females are silent.
during copulation, and during aggressive encounter. Adults and nymphs of both sexes also hiss when disturbed (Nelson & Fraser, 1980). E. Air expulsion: This sound is described as an exhalatory sound, frequently expelled via the tracheal spiracles, however little is known about its function (Ewing, 1989). EXAMPLE: The Madagascar hissing cockroach Gromphadorhina portentosa produces audible hiss sounds from spiracles.  Adult males hiss in three social contexts: during courtship,
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Insect communication

  • 1. BIO COMMUNICATION IN INSECTS PRESENTED TO: Dr. Amritpal Sir PRESENTED BY: Harsimrat Kaur Dulai Ph.D. Roll no. 1952204
  • 2. INTRODUCTION COMMUNICATION:  It is the exchange of information between individuals.  Adapted for symbolic communication, but most of insect’s "language" skills are acquired through learning.  For members of the insect species, it is an essential part of all social interactions.
  • 3. COMMUNICATION IN INSECTS  The majority of insect species live a solitary life, with few contacts between conspecific individuals.  Social insects, however, are characterized by communities in which they live in permanent contact with their nestmates.  Bees and bumble bees, wasps, ants and termites since long have fascinated man because of their well organized and often impressive colonies.
  • 4. Why do insectscommunicate?  Recognition of kin or nestmates.  Locating or identifying a member of the opposite sex.  Facilitation of courtship and mating.  Giving directions for location of food.  Regulating spatial distribution of individuals, aggregation or dispersal; establishing and maintaining a territory.  Warning of danger; setting off an alarm.  Expressing threat or submission.  Mimicry
  • 5. TYPESOFBIO-COMMUNICATION A. Visual communication B. Chemical communication C. Tactile communication D. Acoustic communication
  • 6. A. VISUALCOMMUNICATION  Most visual communications are effective during daylight, but some insects can generate their own light and use visual signals that can be seen at night.  Also for partner location, prior to mating, the male’s big compound eyes can help in finding the females .  Male dragonflies recognizes female dragonflies.
  • 7.  The male Photinus consimilis During a rising flight movement emits a series of 3.5 short flashes and a female responds after a double flash. FIREFLIES
  • 8. BIOLUMINESCENCE: When oxygen combines with calcium, adenosine triphosphate (ATP) and the chemical luciferin in the presence of luciferase, a bioluminescent enzyme, light is produced. Unlike a light bulb, which produces a lot of heat in addition to light, a firefly's light is cold light, without a lot of energy being lost as heat. LIGHT PRODUCING MECHANISM IN FIREFLIES
  • 9. 1. In order for this reaction to occur, a chemical named “Luciferin”, which emits light, is required. 2. Then, oxygen is needed to oxidize the reaction. 3. As a result of this chemical reaction , energy is released in a form of light due to energy from the excitation of the electrons in the ions. The energy of photons of visible light produced is about 50 kcal.
  • 10. In alfalfa butterflies, males have U.V. reflective scales and missing scales is a sign for male ageing.
  • 11. 1. Batesian mimicry Danaus chrysippus (The Plain tiger) Model-Non edible Hypolimna smisippus (Female Danaid Eggfly) Mimic-Edible 2. Mullerian mimicry Heliconius butterfly genus TYPES OF MIMICRY
  • 12. SURPRISEANDSTARTLEEFFECT •Surprise combined with rapid escape flight is often a sufficient defense. •Startle is the combination of the elements of surprise and fright. Hawk moth larva Spinx moth Under winged moth
  • 13. CRYPSIS  Crypsis, avoiding detection by blending into the background is one of the most common defense mechanisms. Toad bugAmazon caterpillar
  • 15. BEHAVIOURALAPPROACH 1)APOSEMATISM: The opposite of crypsis or a warning signal to predators. Patterned combinations of reds, yellows, oranges, whites, and blacks. Warning colouration boldly signals that this insect is toxic, is bad tasting, or can sting or cause injury. Cinnabar moth larva Automeris metzli (Saturniidae)
  • 16. 2)THANATOSIS:  Things that eat other things tend to quickly lose interest in dead prey, so some insects that employ the strategy of playing dead and can often escape unharmed.
  • 17. B.CHEMICAL COMMUNICATION •A total of 731 insect species were involved in responses to the 323 chemical compounds. •Insect behaviours that are modulated by chemical senses, or the complexity of structures responsible for chemical signalling and perception, the chemical communication channel is a predominant feature of insects (Greenfield, 2002). •The small to minute body sizes of insects may be largely responsible for their general reliance on chemical senses.
  • 18. SEMIOCHEMICALS A broad term for chemicals involved in insect communication is semiochemical, from the Greek semeion sign (Law and Regnier, 1971). Classification: 1.Pheromone (Intraspecific signals) 2.Allelochemicals (interspecific signals) 1. PHEROMONE: chemical substance produced and released into the environment by an animal, especially a mammal or an insect, affecting the behaviour or physiology of others of its species.
  • 19. TYPES OF PHEROMONE: • PRIMER PHEROMONE • RELEASER PHEROMONE • TRAIL PHEROMONE • ALARM PHEROMONE • AGGREGATION PHEROMONE • SEX PHEROMONE
  • 20. Primer pheromone: The most famous example of a primer pheromone is the honey bee queen mandibular pheromone (a mixture of two fatty acids: 9-ODA and 9-HDA) which suppresses ovary development in worker bees (Free, 1987).
  • 21. IN TERMITES:  The king(s) and queen(s) inhibit the formation of neotenics using a putative, non-volatile, inhibitory chemical substance. Which is spread among nestmates by trophallaxis  When this inhibitory signal is decreased neotenics form from the immature termites.  CHC’s may also be involved in fertility signaling or reproductive control. (Liebig et al. 2009; Weil et al. 2009). BROOD CARE BEHAVIOUR: The eggs laid by the queen(s) are collected, handled, piled at specific spots by workers (and in exceptional cases by soldiers; Hanus et al. 2005), and protected from pathogens and desiccation by worker’s saliva.
  • 22. Releaser pheromone: •The most commonly known are sex pheromones, which are highly species specific and serve to attract mates for reproduction. •The first sex pheromone was identified in 1959 from the silk moth Bombyx mori (Butenandt et al., 1959). •Many further insect sex pheromones have been identified to date and a number are commercially used in pheromone traps for pest control (Bell, 2004)
  • 23. Name of the insect Pheromone  Pink bollworm, Pectinophora gossypiell  Gabbage looper, Trichoplusia  Tobacco cutworm, Spodopteralitura  Honey bee ueen, Apis sp. Gossyplure Looplure Spodolure, litlure, Helilure Queen’s substance
  • 24. Trail pheromones, employed by social insects for orientation and to recruit nest mates to a suitable food source. They are produced by a variety of glands and can be composed of numerous different, mostly volatile compounds. When navigating their territory, ants and termites deposit these pheromones on the ground thus developing an extensive net of chemical routes. (Holldobler and Wilson, 1990; Pasteels and Bordereau, 1998; Kaib, 1999). Trail pheromone:
  • 25.  Lays trails and lead to feed. Chemical nature of trail pheromones are decenoic acids ( in formicine ants). hexanoic, heptanoic, Trail pheromones can be used to kill ants. Trail pheromones mixed with baits can attract ants which when transported by ants to their nest it will kills all young ones. ANTS
  • 26.  Some ant species use ‘propaganda’ pheromones to confuse the ants and make them fight themselves. enemy among  Honeybee releases orientation pheromones, a mixture of geraniol, citral, farnesol and other minor compounds from their Nasonov gland into the air in a number of orienting situations. (Free, 1987; Winston, 1987).
  • 27.  Alarm pheromones are chemical substances released by insects to warn members of the same species about the presence of or attack by an enemy (mostly a predator).  This warning elicits different behaviour in different insects as listed below: 1.) Dispersion or escape in aphids and bugs. 2.) Aggression in ants and soldier termites. 3.) Attraction in wasps and worker bees. • The chemical nature of alarm pheromones are terpenes (aphids), aldehydes (Hemiptera) and formic acid (ants). Alarm phermone:
  • 28. In ants: All Formicid species were subsequently found to produce and use an alarm pheromone (Holldobler and Wilson 1990). The response to “aggressive alarms” is characterized by rapid movements oriented toward the emitter and by aggressive attitudes ranging from mandible and gaster movements. Responses to “panic alarms” entail escape, dispersion, and flight behaviors.
  • 29. Alarm pheromone in Honeybees: A vital role in honeybee colony defense is played by so-called guard bees, which patrol the nest entrance and represent the first line of colony defense. These guards are also specialized for the production of alarm pheromone which they release to recruit nestmates from the interior of the colony in case of danger (Boch et al., 1962; Collins et al., 1982). The perception of the pheromone increases workers movement and promotes aggression.
  • 30.  Pheromones which induce aggregation or congregation of insects for protection, reproduction and feeding or combinations are called aggregation pheromones. Eg: Bark beetles start to bore into the bark and release a long range aggregation pheromone.  A mixture of terpenoids some of which are synthesized, others produced by symbiotic bacteria in the beetle gut or sequestered from host tree compounds (Greenfield, 2002; Wyatt, 2003). Aggregation pheromone:
  • 31. Sex pheromone:  sex pheromones indicate the availability of the female for breeding. Male animals may also emit pheromones that convey information about their species and genotype.  insect species, such as the ant Leptothorax acervorum, the moths Helicoverpa zea and Agrotis ipsilon, the bee Xylocopa varipuncta and the butterfly Edith's checkerspot release sex pheromones to attract a mate, and many lepidopterans (moths and butterflies) can detect a potential mate from as far away as 10 km.  Some insects, such as ghost moths, use pheromones during lek mating.
  • 32. •The communication between two different species of organisms or insects. •It is classified into Allomones, Kairomones, Synomones, and Apneumones. ALLOMONES: •From Greek word (allos+hormon=excite others) allomone is a chemical or mixture of chemicals released by one organism that induces a response in another organism which is advantageous to the releaser. •The defensive secretions of insects and plants that are poisonous to attacking predators. 2. ALLELOCHEMICALS:
  • 33.  The neotrophical social wasp Mischocyttarus drewseni applies a secretion to the stem of its nest that repels foraging ants.  Some trophical flowers which are pollinated by bats emit odours which attract bat to the flowers. Examples: oSting gland in bees oFormic acid in ants  Allomones also serve plants as defence mechanism against plants. herbivores and reduce competition with other
  • 34. KAIROMONES: Kairomone is a chemical or mixture of chemicals released by one organism that induces a response in another organism. Helpful to recipient. Eg.Heptanoic acid released by larva of potato tuber moth Phthorimaea operculella increases searching by its parasitoid Farnesene secreted by codling moth larva attracts its parasitoid
  • 35. SYNOMONES:  Chemical released by one organism that induce a response in another species.  Helpful to emitter and receiver.  It encourages mutualistic relation between organisms.  Eg. Termites and protozoans . Eg: Flower fragrance: Orchids (Ophrys) attract males of solitary bees or Dacini fruit fly by a mixture of compounds resembling the sex pheromone of con-specific females but males are not awarded with nectar instead they receive pheromone booster.
  • 36. APNEUMONES:  Chemical substances emitted by a non- living material that evoke a behavioural or physiological reaction adoptively favourable to a receiving organism, but detrimental to another species, which may be found in or on the non- living material.  Eg: An ichunuemonid parasite of Venturia canescens is attracted by the smell of the oatmeal, which is the food of its host.  Here it is advantageous to the recipient which is the parasitoid but detrimental to host insect living on the oat meal (non- living material)
  • 37. C. TACTILE COMMUNICATION "Keep in touch!" For you, it's probably just a metaphor, but for some insects it's really a channel of communication Since many insects have poor vision and sound perception, physical contact provides an important avenue of communication.
  • 38. In blister beetles (family Meloidae), courtship begins with a series of antennal taps by the male on each side of the female's body. She signals her receptivity by lifting her wing covers (elytra) and allowing him to climb on her back. But to complete his quest, the male must continue tapping, alternating from side to side at just the right frequency until the female is stimulated to extend her genitalia and begin mating.
  • 39. Antennal tapping is also an essential component of communication in both ants and termites. It's not clear exactly what information may be exchanged, but it certainly involves nestmate recognition and leads to exchange of food through trophallaxis.
  • 40. • If tapping stops, leader instinctively turns around and searches in ever-widening circles until she re-establishes contact with the follower. • Antennal tapping on the hind legs is used during tandem running in both ants and termites. • This is a "follow-the-leader" behavior in which the tapping informs the leader that she has not lost her disciple.
  • 41. IN TERMITES:  Drumming behaviour occurs in both soldiers and workers,  But its alarm pheromone capacity is low.  A chain of vibrating soldiers can spread an alarm across a distance of more than a meter in less than a second (Rohrig et al. 1999).
  • 42. DANCE LANGUAGE OF HONEY BEES. Karl von Frisch, 1886-1982 Austrian, began work in 1919 Trained European honey bees, Apis mellifera, to feeders First believed bees used flower scents or other odors to find food. Began to pay close attention to dances performed by returning foragers.
  • 43. 1. “Round dance” • When food source is < 50 m from hive. • After distributing some of her new- found nectar to waiting bees the scout will begin running in a small circle, switching direction. • After the dance ends food is again distributed at this or some other place on the comb and the dance may be repeated three or (rarely) more times. • The round dance does not give directional information.
  • 44. 2. “Waggle dance” • When food source is > 50 meters away Waggle run -Abdomen wagging and wing fluttering -Angle repeated with respect to vertical, or gravity (here 20° right)
  • 45. SCOUT: finds new food sources & dances RECRUITS: follow dances & then forage
  • 46. Direction of the food source is indicated by the direction the dancer faces during the straight portion of the dance when the bee is waggling. If she waggles while facing straight upward, than the food source may be found in the direction of the sun.
  • 47. If she waggles at an angle 60 degrees to the left of upward the food source may be found 60 degrees to the left of the sun.
  • 48. If the dancer waggles 120 degrees to the right of upward, the food source may be found 120 degrees to the right of the sun. The dancer emits sounds during the waggle run that help the recruits determine direction in the darkness of the hive.
  • 49. COMMUNICATION IN TREEHOPPERS Certain treehoppers (order Hemiptera: family Membracidae) produce vibrations in the tissue of their host plant that can be felt by all other treehoppers on the same plant. The signals apparently work as an alarm system, and in some species, they may be used by nymphs to elicit protective maternal behaviour. Substrate vibrations can be a particularly effective communication system for small insects who cannot generate an acoustic signal loud enough to be heard more than few inches away.
  • 50. D. ACOUSTIC COMMUNICATION Acoustic communication can be made to vary in frequency, amplitude and periodicity. Together, these three variables can create an extremely wide and complex range of signals from an insect's mating call to human speech and vocal music. Since sound waves move rapidly through air (about 331 m/sec), acoustic signals can be quickly started, stopped, or modified to send a time-sensitive message
  • 51. courtship songs produced by sex-specific scales on the forewings and mesothorax. In order to protect the pair from conspecific competitors and predators, this male moth produces the sounds in the female’s ear, which provide a private communication channel between them. (Conner, 2014). ACOUSTIC SOUND PRODUCTION IN MOTH:  “Whispering” Moths exemplify another antidetection strategy (Nakano et al., 2008).  Ostrinia furnicalis, moths, use male Asian corn borer specialized very low intensity
  • 52.  Aposematic sounds often converge structurally having broad frequency ranges, low pattern complexity.  Such signals are readily detected by wide range of predators.  Toxic tiger moths (Arctiidae) send loud return sounds to approaching insectivorous bats.  These sounds warn the bat that the moth is unpalatable and potentially harmful, and may also interfere with the echolocation capabilities of bats. APOSEMATIC SOUND
  • 53. Drosophila species (Von Schilcher, 1976). CATEGORIES OF SOUND PRODUCING MECHANISMS (Claridge, 2005) A. Vibration (including Tremulation) The oscillatory movement of the wings of an insect sets up regions of compression and rarefaction and a vibrational sound is produced. EXAMPLES : The flight sound, made by the wings, in swarming mosquitoes is considered to be used for species-specific recognition. (Gibson, Warren, & Russell, 2010; Roth, 1948).  Wing vibration is also used in the courtship dances of
  • 54. B. Percussion – Striking one part of the body against another as a communication system for pair formation. EXAMPLE: 1)The Australian moth (Lepidoptera); males produce ultrasonic acoustical long distance signals to attract sexually receptive females and to establish territorial residency in competition with other males (Alcock & Bailey, 1995). 2)Species of the suborder Arctoperlaria (Plecoptera) produce drumming signals on the substrate as a mating system. The male emits a species-specific call searching for the female. (Stewart & Sandberg, 2005).
  • 55. •In Orthopteran, insects respond stridulation from the receptive female orientation towards and their locomotion to the male. “Rivalry song” The female arrived near the male, stridulating in response to mate song; the male, once noticing the female, sings the courtship song, engages the genitalia and copulation occurs (Haskell, 1958). C. Stridulation – Stridulation consists of sounds produced by frictional mechanisms, involving the movements of two specialized body parts against each manner (Claridge, 2005). other in a systematic patterned
  • 56. IN TERMITES:  It produced drumming.  It has also been hypothesized that the synchronized drumming of Macrotermitinae, evokes a rhythmical hissing may act as an aposematic signal to warn away predators. (Howse 1984; Connetable et al. 1999).
  • 57. D. Click mechanisms • These sounds depend on the deformation of a modified area of cuticle, generally by contraction and relaxation of specialized musculature within the insect body. • This acoustic signal constitutes the first step in pair formation, attracting females at long distances, and is involved in male-male interactions (Sueur & Aubin, 2003).
  • 58. For example, the males of Tibicina (Hemiptera) cicada species produce a sustained and monotonous calling song by tymbal activity. TYMBALS: Muscular vibration of drum like membranes The loudest calls in the insect world come from male cicadas. The females are silent.
  • 59. during copulation, and during aggressive encounter. Adults and nymphs of both sexes also hiss when disturbed (Nelson & Fraser, 1980). E. Air expulsion: This sound is described as an exhalatory sound, frequently expelled via the tracheal spiracles, however little is known about its function (Ewing, 1989). EXAMPLE: The Madagascar hissing cockroach Gromphadorhina portentosa produces audible hiss sounds from spiracles.  Adult males hiss in three social contexts: during courtship,