Lesser wax moth

The lesser wax moth (Achroia grisella) is a small moth of the snout moth family (Pyralidae) that belongs to the subfamily Galleriinae. The species was first described by Johan Christian Fabricius in 1794. Adults are about 0.5 inches (13 mm) in length and have a distinct yellow head with a silver-grey or beige body.[2] Lesser wax moths are common in most parts of the world, except in areas with cold climates. Their geographic spread was aided by humans who involuntarily introduced them to many countries.[1][3][4]

Lesser wax moth
Adult specimen
Scientific classification
Kingdom:
Phylum:
Class:
Order:
Family:
Genus:
Species:
A. grisella
Binomial name
Achroia grisella
(Fabricius, 1794)
Synonyms[1]
  • Achroia alvearia (lapsus)
  • Achroia major (Dufrane, 1930)
  • Achroia obscurevittella Ragonot, 1901
  • Acroia major (lapsus)
  • Bombyx cinereola Hübner, 1802
  • Galleria aluearia Fabricius, 1798
  • Galleria alvea Haworth, 1811 (unjustified emendation)
  • Galleria alvearia (lapsus)
  • Meliphora alveariella Guenée, 1845 (unjustified emendation)
  • Tinea anticella Walker, 1863
  • Tinea grisella Fabricius, 1794

The mating systems of the lesser wax moth are well researched because they involve sound production. Lesser wax males produce ultrasonic pulses in order to attract females.[5] Females seek the most attractive males and base their decisions on characteristics of the male sound.[6] While sex pheromones are also emitted by the males, male calling is more effective in attracting mates.[7]

Because lesser wax moths eat unoccupied honey bee combs, they are considered pests to bees and beekeepers. However, unoccupied combs can harbor harmful pathogens that inflict damage to neighboring insects. By eating the combs, the moths can reduce the harm to insects of that region and provide a clean space for other organisms to inhabit.[2]

Geographic range

Lesser wax moths are known or suspected to inhabit most of Africa (including Madagascar), Australia, Europe (especially some more remote regions, such as Greece) and North America, as well as parts of the Neotropics (such as Colombia, Jamaica, Puerto Rico and Trinidad), the Bengal region, Japan, Sri Lanka, and the Marquesas Islands and Tahiti in French Polynesia.[1][4][3]

Climate

Lesser wax moths are found everywhere that honey bees are present, but they are more successful in warmer, tropical areas than in colder climates. Although they cannot live in freezing temperatures for an extended period, they are more successful in lower temperatures than the related greater wax moth.[2]

Food resources

Larvae diet

Feeding occurs only during the larval life stage. Larvae feed on weak bee colonies. Therefore, the amount of food that the larvae can eat depends on the amount of material that the bee colony produced, as well as the number of moth generations that have persisted on the same comb since the initial infestation began.[8] Larvae move through the bee comb and spin silk tunnels. They cover the silk with their frass. Tunneling through honeycombs not only provides food, but also protects the larvae from the defending worker bees.[3][9] The larvae prefer to eat honey bee larvae, pupae, and pollen, but will also feed on honey.[2][8] Unusual foods that larvae can feed on are dried vegetable remains, dried fruits (especially apples and raisins), horn shavings (an organic fertilizer), cork, and even refined sugar.[3][9] Sometimes greater wax moths can be found in the same comb as lesser wax moths. In these cases, the greater wax moths will compete with the lesser wax moths for the best feeding regions of the comb. In general, the greater wax moth is victorious and the lesser wax larvae are forced to feed on the hive floor.[2]

Parental care

Oviposition

Females deposit their eggs in crevices in or near bee hives so that a food source will be close to the emerging larvae. When a female has found an acceptable spot, she extends her body into the crevice and then lays her eggs. A female lays on average 250-300 eggs in her lifetime.[2][10]

Life history

Egg

The eggs are similar to those of greater wax moths. They are spherical and creamy white in color. Eggs hatch in about five to eight days but warmer temperatures shorten the hatching time.[2]

Larvae

Larvae take on average six to seven weeks to fully develop, but they can take up to five months. They reach about 20 mm in length and have narrow white bodies with a brown head. This is the only life stage in which lesser wax moths eat.[2]

Pupa

The pupae are 11 mm in length and are a yellow tan color. The silk cocoon is white but is usually covered with frass. On average, the adults emerge after 37 days, but pupation can take up to 2 months.[2]

Adult

Adults are a silver, grey, or beige with a yellow head. They are thin and are 0.5 inches in length with a wingspan of 0.5 inches. Males tend to be smaller than females. Adults live for about a week and most of their activity, including female oviposition and mating, occurs at night.[2] Males can be seen in their mating position anywhere between six and ten hours in a single night.[11] During the day, the adults hide in foliage close to bee hives.[2]

Enemies

Predators

In order to attract mates, male lesser wax moths stay in a stationary position and emit a high-frequency sound. Bats, such as Rhinolophus ferrumequinum, can hear this sound.[6] Thus, both the male's high-frequency calling and its stationary position leave it vulnerable to attacks by bats. Even though the bats do not exist in some of the areas where moths are currently found, the lesser wax moth has retained its evolutionary mode of defense from its native land.[12]

Defense

The bat calling sound is a long and slowly repeating signal.[12] If males hear the call of an approaching bat or a similar sound, they will stop their mate calling.[6][12] The males will remain silent for several milliseconds to more than a minute. More sexually attractive males, those with higher single pulse pair rates and amplitudes, experience a higher risk of predation because they resume mate calling sooner than less attractive males. This may occur because the attractive males are better equipped to escape from bats, thus decreasing the apparently high risk. Another theory is that risk taking could be a sexually selected trait.[6] Females can decipher between the moth calling and the bat calling sound. During mate calling, females fan their wings. However, when they hear the bat's sound, they stop fanning their wings. In order to avoid being captured by bats, the moths fly erratically, fall to the ground, or fly away from the source of the sound.[12]

Mating

Mate searching behavior

In the lesser wax moth species, the males engage in signaling behavior while the females engage in searching roles.[13]

Pheromones

Lesser wax male moths emit a sex pheromone that is made up of two components: n-undecanal and cis-11-n-octadecenal.[12][14] The pheromone is released from wing glands.[12] It is attractive to females over long distances, but the pheromones alone are not sufficient to generate mating behaviors.[7][12][13][14] When males are under attack by bats, they stop producing calling sounds but will continue emitting the pheromone.[12]

Sound

The lesser wax moth mating system is based on sound. Experiments have shown that sounds from a speaker are able to elicit the same attractive result from females as live males that release both sound and pheromones. Males emit short ultrasonic pulses with a high frequency of 100 kHz and an intensity of 93 dB. The signal of the sound can differ significantly between males. For example, there can be a 15 dB range in peak amplitude between males in the same population.[13] The male calling characteristics may be genetic and inherited.[8] Pulse amplitude is also positively correlated to a male moth's weight.[7]

Effects of temperature

Components of the male ultrasonic pulses are genetically based, but environmental temperature can affect the specific genotype's performance.[15] As temperature increases, a lesser wax moth male's pulse rate increases and the female's acceptance threshold for rates increases. These changes most likely occur due to physiological effects, but the increase in pulse rate and acceptance threshold may also be used to avoid predation. Additionally, the increase in female acceptance threshold allows them to continue choosing the most attractive male by not mistaking a low-quality male for high-quality due to his new, faster pulse rate.[16]

Mate choice

Although pheromones alone do not cause a female to move towards a male for mating, odor, signal location, and male-male interactions may play a role in male attractiveness.[7] Females mainly select males based on the characteristics of their call. Females prefer males with a fast pulse pair rate, high peak song amplitude, and large wing beat asynchrony.[6] This preference may be evolutionary, with signal quality being an indicator of a male's gene quality.[13] Because female choice occurs between aggregated males at leks, they assess a male's call in relation to his neighbors. In other words, at leks, the relative threshold sounds are determinate of male attractiveness rather than absolute threshold. If an individual is in a group of males with high quality sounds, their individual relative attractiveness decreases. There also seems to be some variation in female preference. Because some signal characteristics are heritable, female preference could lead to evolutionary changes in mate calling.[7]

Lekking

Sexual selection occurs near honey bee colonies. The males will group together on grass or leaves near the colony where they spent most of their life.[6][7][12] These leks are small and occur in the night.[6] Because the moths are close together in the leks, some males will purposely run into stationary neighbors who are in the process of signaling in order to move them.[14] Additionally, studies have been conducted that show these moths increase their signal rate when having to compete with others for a local female, but due to the physical demands of an increased signal rate, its duration typically lasts only five to ten minutes. It has been concluded that these are the most prevalent few minutes of the entire six to ten hours spent active each night.[11]

Physiology

Hearing

Sound generation

Males produce ultrasonic pulses to attract mates. The sound is produced by a tymbal on each tegula, which covers the forewing.[5] The left and right tymbals emit pulses slightly asynchronously.[13] In order for sound production to occur, the tegula has to be raised and the wings have to be fanned at a 45° arc.[5] A pair of asynchronous pulses are produced during each up and down stroke of the wings.[13] The pulses of sound have a frequency of 100 kHz which is in the middle of the moth's hearing range (20–200 kHz).[5]

Interactions with humans

Lesser wax moth infested honeycomb

Pest of beekeepers

Bald brood

A disorder called bald brood occurs in hives infested by lesser wax moths. When feeding on the comb, larvae tunnel under capped cells containing honey bee pupae. This movement causes the caps to become defective. The worker bees will then remove the defective caps. The name bald brood refers to the remaining uncapped cells that reveal the residing pupa.[2]

Prevention

In order to prevent a lesser wax moth infestation in honey bee hives, beekeepers must maintain healthy, functioning hives. In healthy hives, workers will remove defective bee larvae and quickly seal up the cell that had contained the larvae. In this way, moths are unable to lay eggs in the vacant cells. If the hives become weak, the workers may not be able to close vacant cells, leaving the hive open to infestation. Therefore, stored combs that do not have any worker bees are highly susceptible to attacks by the lesser wax moths.[2]

Control

Temperature regulation

Temperature can play a crucial role in lesser wax larvae activity and survival. At 37 °F (3 °C), the larvae can survive but they become less active. Larvae cannot survive in freezing temperatures. In order to ensure that hive products are safe for humans to consume, beekeepers can freeze the hives for one to two days at 20 °F (−7 °C). Extreme heat (114 °F (46 °C)) can also be used to kill larvae, but combs are susceptible to melting at similar high temperatures.[2]

Fumigation

Different chemicals can be used to kill lesser wax larvae, but many of them can be harmful to both the comb and humans. For example, carbon monoxide is effective in killing the larvae and the comb is left unharmed, but it is toxic to the person administering the fumes.[2]

Bacillus thuringiensis

Bacillus thuringiensis is a microbial insecticide. When consumed, it is lethal to lesser wax larvae. However, bees are immune to the insecticide's harmful effects because even if the bees ingest the wax, they cannot digest the pesticide. When a powder containing B. thuringiensis is mixed with beeswax present in bee combs, the lesser wax moth is killed and the bees remained unharmed. While a B. thuringiensis-infused liquid can also be used, the powder is more effective and remains protective to bee combs for two years.[17]

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See also

References

  1. Savela, Markku. "Achroia grisella (Fabricius, 1794)". Lepidoptera and Some Other Life Forms. Retrieved 16 October 2018.
  2. Egelie, Ashley A.; Mortensen, Ashley N.; Barber, Lynn; Sullivan, Jessica; Ellis, James D. "University of Florida".
  3. Clarke, John Frederick Gates (1986). "Pyralidae and Microlepidoptera of the Marquesas Archipelago". Smithsonian Contributions to Zoology. 416 (416): 1–485. doi:10.5479/si.00810282.416.
  4. "Fauna Europaea".
  5. Spangler, Hayward G.; Takessian, Alex (1986). "Further Observations on Sound Production by the Lesser Wax Moth, Achroia grisella (F.) (Lepidoptera: Pyralidae)". Journal of the Kansas Entomological Society. 59 (3): 555–557.
  6. Cordes, Nils; Engqvist, Leif; Schmoll, Tim; Reinhold, Klaus (2014). "Sexual signaling under predation: attractive moths take the greater risks". Behavioral Ecology. 25 (2): 409–414. doi:10.1093/beheco/art128.
  7. Jang, Yikweon; Greenfield, Michael D. (1998). "Absolute verses relative measurements of sexual selection: assessing the contributions of ultrasonic signal characters to mate attraction in lesser wax moths, Achroia grisella (Lepidoptera: Pyralidae)". Evolution. 52 (5): 1383–1393. doi:10.1111/j.1558-5646.1998.tb02020.x. PMID 28565373.
  8. Zhou, Yihong; Kuster, Heidi K.; Pettis, Jeffrey S.; Danka, Robert G.; Gleason, Jennifer M.; Greenfield, Michael D. (2008). "Reaction norm variants for male calling song in populations of Achroia grisella (Lepidoptera: Pyralidae): toward a resolution of the lek paradox". Evolution. 62 (6): 1317–34. doi:10.1111/j.1558-5646.2008.00371.x. PMID 18346222.
  9. Grabe, Albert. "Eigenartige Geschmacksrichtungen bei Kleinschmetterlingsraupen [Strange tastes among micromoth caterpillars]". Zeitschrift des Wiener Entomologen-Vereins. 27: 105–109.
  10. "COLOSS".
  11. Jia, Feng-You; Greenfield, Michael D.; Collins, Robert D. (2001). "Ultrasonic Signal Competition Between Male Wax Moths". Journal of Insect Behavior. 14 (1): 19–33. doi:10.1023/A:1007893411662.
  12. Spangler, Hayward G. (1984). "Silence as a defense against predatory bats in two species of calling insects". The Southwestern Naturalist. 29 (4): 481–488. doi:10.2307/3671001. JSTOR 3671001.
  13. Jang, Yikweon; Greenfield, Michael D. (1996). "Ultrasonic communication and sexual selection in wax moths: female choice based on energy and asynchrony of male signals". Animal Behaviour. 51 (5): 1095–1106. doi:10.1006/anbe.1996.0111.
  14. Greenfield, Michael D. (1981). "Moth Sex Pheromones: An Evolutionary Perspective". The Florida Entomologist. 64 (1): 4–17. doi:10.2307/3494597. JSTOR 3494597.
  15. Ingleby, F.C.; Hunt, J.; Hosken, D.J. (2010). "The role of genotype-by-environment interactions in sexual selection". Evolutionary Biology. 23 (10): 2031–2045. doi:10.1111/j.1420-9101.2010.02080.x. PMID 20722891.
  16. Greenfield, Michael D.; Medlock, Chelsea (2007). "Temperature coupling as an emergent property: parallel thermal effects on male song and female response do not contribute to species recognition in an acoustic moth". Evolution. 61–7 (7): 1590–1599. doi:10.1111/j.1558-5646.2007.00140.x. PMID 17598742.
  17. Burges, H.D.; Bailey, L. (1968). "Control of the Greater and Lesser Wax Moths (Galleria mellonella and Achroia grisella) with Bacillus thuringiensis". Journal of Invertebrate Pathology. 11 (2): 184–195. doi:10.1016/0022-2011(68)90148-1. PMID 5672009.

Further reading

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