Bumblebee communication

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Two bumblebees foraging on a flower, taken at Bariloche, Argentina Bumblebees.jpg
Two bumblebees foraging on a flower, taken at Bariloche, Argentina

Bumblebees (Bombus spp.), like the honeybee (Apis spp.) collect nectar and pollen from flowers and store them for food. Many individuals must be recruited to forage for food to provide for the hive. Some bee species have highly developed ways of communicating with each other about the location and quality of food resources ranging from physical to chemical displays.

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While honey bees are known for their specialized dances, such as the waggle dance which recruit other bees to the precise location of the food source, [1] bumblebees are not capable of transmitting this type of detailed information. Instead, the nest serves as a hub where bees receive information about the foraging bouts of her conspecifics. [2] Differences between the communication methods of honeybees and bumblebees are mainly due to differences in colony size and nest structure. [1] Bumblebees are distinct from honeybees because they lack receiver bees (bees in the nest which receive pollen and nectar from incoming foragers during unloading) and are not capable of trophallaxis (the transfer of nectar from one bee to another). They deposit collected nectar directly into the honey pots and don't share information of the quality of the resource with other bees through nectar transfer. [3] Another bee may sample the nectar brought into the nest, and if the colony is in need of food or the nectar is high quality she will likely go out foraging herself. [3] Other means of alerting passive bees to a potentially rewarding resource include releasing pheromone signals and increasing physical activity. [3]

For information on communication methods in honey bees, see bee learning and communication.

Monitoring honey pots

Bumblebee nest with full visible honey pots Bumblebee nest.jpg
Bumblebee nest with full visible honey pots

A bumblebee nest differs in size and structure from that of a honeybee. Bumblebee nests are smaller and contain far fewer individuals which is mostly due to differences in the method of colony reproduction. [1] Honeybee colonies can contain up to 50,000 individuals, whereas bumblebee colonies usually only contain a few hundred. [1] This means the number of bees available for foraging is low and resources must be allocated accordingly. Assessing the level of food stores is not seen in honeybees, likely because the large colonies make such assessment inefficient. [3] Bumblebees only store enough honey for a few days. [4] By monitoring the levels of the honey pots a bumblebee colony can either up or down regulate the number of bees out foraging. [3] Lab experiments by Anna Dornhaus and Lars Chittka in 2005 showed evidence of this up or down regulation by monitoring the activity level of the hive after the addition of 'nectar' to the honey pots. Hive activity increased when high quality nectar was injected into the honey pots, provided the wells weren't already full. When the honey pots were full, there was no significant change in activity regardless of whether the nectar imported was from a high or low quality source. [3] They hypothesized that either the foraging bee does not signal the nest or the nest bees ignore the signal because the demand for food is low. The tropical bumblebee Bombus transversalis has also been shown to respond to honey pot levels in a similar way. [5]

Excited runs

Honeybees have very controlled patterns of movement, such as the waggle or tremble dance which serve to deliver specific coordinates of fruitful sources to potential foragers. Bumblebee movement is comparatively random and does not supply coordinates to other bees. [5] Other experiments by Dornhaus and Chittka (2001) showed increased movement of successful foraging bees upon returning to the nest. Successful bees ran faster and longer compared to unsuccessful bees. A bee may spend several minutes running around the nest before flying out again. [5] As the bee runs, it has been hypothesized that the bee may also offer a form of communication based on the buzzing sounds made from her wings. These 'excited' runs serve in part to rouse other bees into foraging. [5]

Pheromones

Pheromone distribution

Bumblebees produce a signalling pheromone from tergal glands located on their dorsal abdomen as discovered in experiments performed by A. Dornhaus, A. Brockmann and L. Chittka in 2003. They monitored the activity of bee colonies after exposure to products from several glands located along the bee's body. The only one yielding significant changes in activity level came from the tergites VI and VII. [6] This is similar to a pheromone produced from the Nasanov gland in honeybees, but differs in the active compound. [6] It has been suggested that this pheromone may facilitate learning of floral scents, since its release is coupled with the import of the floral scent from the nectar collected by the successful forager. [6] Experiments by Molet, Chittka and Raine in 2009 showed that bumblebees may be able to learn floral scents associated with rewarding flowers better if the particular scent is found in nectar deposited in the honeypots. [7]

Brood recognition pheromones

Many bumblebee species have been observed to use pheromones in the process of brood recognition. In the species Bombus vosnesenskii , brood recognition, and subsequently, brood clump incubation, has been shown to be pheromone induced. Queens will deposit chemical signals on a brood clump to help herself and her workers identify the eggs. However, these pheromones appear to be species' specific, as opposed to specific to individual queens, as queens will also incubate the eggs of conspecific bees. [8]

Queen pheromones

As in other social Hymenoptera, [9] bumblebee queens have also been shown to release characteristic pheromones to signal their presence and stop the workers from reproducing. In Bombus terrestris , for example, two studies have shown that workers resorbed oocytes more often [9] and had fewer developing oocytes in their ovaries [10] after treatment with the queen-characteristic cuticular hydrocarbon pentacosane. Similar activity of queen-specific cuticular hydrocarbons has also been documented in Bombus impatiens , [11] as well as in several other species of ants and wasps. [9]

Related Research Articles

<span class="mw-page-title-main">Bumblebee</span> Genus of insect

A bumblebee is any of over 250 species in the genus Bombus, part of Apidae, one of the bee families. This genus is the only extant group in the tribe Bombini, though a few extinct related genera are known from fossils. They are found primarily in higher altitudes or latitudes in the Northern Hemisphere, although they are also found in South America, where a few lowland tropical species have been identified. European bumblebees have also been introduced to New Zealand and Tasmania. Female bumblebees can sting repeatedly, but generally ignore humans and other animals.

<i>Bombus terrestris</i> Species of bee

Bombus terrestris, the buff-tailed bumblebee or large earth bumblebee, is one of the most numerous bumblebee species in Europe. It is one of the main species used in greenhouse pollination, and so can be found in many countries and areas where it is not native, such as Tasmania. Moreover, it is a eusocial insect with an overlap of generations, a division of labour, and cooperative brood care. The queen is monandrous which means she mates with only one male. B. terrestris workers learn flower colours and forage efficiently.

<i>Bombus ternarius</i> Species of insect

Bombus ternarius, commonly known as the orange-belted bumblebee or tricolored bumblebee, is a yellow, orange and black bumblebee. It is a ground-nesting social insect whose colony cycle lasts only one season, common throughout the northeastern United States and much of Canada. The orange-belted bumblebee forages on Rubus, goldenrods, Vaccinium, and milkweeds found throughout the colony's range. Like many other members of the genus, Bombus ternarius exhibits complex social structure with a reproductive queen caste and a multitude of sister workers with labor such as foraging, nursing, and nest maintenance divided among the subordinates.

<span class="mw-page-title-main">East African lowland honey bee</span> Subspecies of honey bee native to Africa

The East African lowland honey bee is a subspecies of the western honey bee. It is native to central, southern and eastern Africa, though at the southern extreme it is replaced by the Cape honey bee. This subspecies has been determined to constitute one part of the ancestry of the Africanized bees spreading through North and South America.

<i>Bombus hypnorum</i> Species of bee

The tree bumblebee or new garden bumblebee is a species of bumblebee common in the European continent and parts of Asia. Since the start of the twenty-first century, it has spread to Great Britain. These bumblebees prefer habitats that others do not, allowing them to pollinate flowers in areas that many other species do not get to.

<i>Bombus lapidarius</i> Species of bee

Bombus lapidarius is a species of bumblebee in the subgenus Melanobombus. Commonly known as the red-tailed bumblebee, B. lapidarius can be found throughout much of Central Europe. Known for its distinctive black and red body, this social bee is important in pollination.

<i>Bombus bohemicus</i> Species of bee

Bombus bohemicus, also known as the gypsy's cuckoo bumblebee, is a species of socially parasitic cuckoo bumblebee found in most of Europe with the exception of the southern Iberian Peninsula and Iceland. B. bohemicus practices inquilinism, or brood parasitism, of other bumblebee species. B. bohemicus is a generalist parasite, successfully invading several species from genus Bombus. The invading queen mimics the host nest's chemical signals, allowing her to assume a reproductively dominant role as well as manipulation of host worker fertility and behavior.

<i>Bombus hortorum</i> Species of bee

Bombus hortorum, the garden bumblebee or small garden bumblebee, is a species of bumblebee found in most of Europe north to 70°N, as well as parts of Asia and New Zealand. It is distinguished from most other bumblebees by its long tongue used for feeding on pollen in deep-flowered plants. Accordingly, this bumblebee mainly visits flowers with deep corollae, such as deadnettles, ground ivy, vetches, clovers, comfrey, foxglove, and thistles. They have a good visual memory, which aids them in navigating the territory close to their habitat and seeking out food sources.

<i>Bombus lucorum</i> Species of bee

Bombus lucorum, the white-tailed bumblebee, is a species of bumblebee, widespread and common throughout Europe. This name has been widely used for a range of nearly identical-looking or cryptic species of bumblebees. In 1983, Scholl and Obrecht even coined the term Bombus lucorum complex to explain the three taxa that cannot be easily differentiated from one another by their appearances. A recent review of all of these species worldwide has helped to clarify its distribution in Europe and northern Asia, almost to the Pacific. B. lucorum reaches the Barents Sea in the North. However, in southern Europe, although found in Greece it is an upland species with its distribution never quite reaching the Mediterranean.

<span class="mw-page-title-main">Flower constancy</span> Tendency to visit certain flower species

Flower constancy or pollinator constancy is the tendency of individual pollinators to exclusively visit certain flower species or morphs within a species, bypassing other available flower species that could potentially contain more nectar. This type of foraging behavior puts selective pressures on floral traits in a process called pollinator-mediated selection. Flower constancy is different from other types of insect specialization such as innate preferences for certain colors or flower types, or the tendency of pollinators to visit the most rewarding and abundant flowers.

<i>Bombus vosnesenskii</i> Species of bee

Bombus vosnesenskii, the yellow-faced bumblebee, is a species of bumblebee native to the west coast of North America, where it is distributed from British Columbia to Baja California. It is the most abundant species of bee in this range, and can be found in both urban and agricultural areas. Additionally, B. vosnesenskii is utilized as an important pollinator in commercial agriculture, especially for greenhouse tomatoes. Though the species is not currently experiencing population decline, urbanization has affected its nesting densities, and early emergence of the B. vosnesenskii has been implicated in the increasing lack of bee diversity on the West coast.

<i>Bombus occidentalis</i> Species of bee

Bombus occidentalis, the western bumblebee, is one of around 30 bumblebee species present in the western United States and western Canada. A recent review of all of its close relatives worldwide appears to have confirmed its status as a separate species.

<i>Bombus fervidus</i> Species of bee

Bombus fervidus, the golden northern bumble bee or yellow bumblebee, is a species of bumblebee native to North America. It has a yellow-colored abdomen and thorax. Its range includes the North American continent, excluding much of the southern United States, Alaska, and the northern parts of Canada. It is common in cities and farmland, with populations concentrated in the Northeastern part of the United States. It is similar in color and range to its sibling species, Bombus californicus, though sometimes also confused with the American bumblebee or black and gold bumblebee. It has complex behavioral traits, which includes a coordinated nest defense to ward off predators. B. fervidus is an important pollinator, so recent population decline is a particular concern.

<i>Bombus impatiens</i> Species of insect

Bombus impatiens, the common eastern bumble bee, is the most commonly encountered bumblebee across much of eastern North America. They can be found in the Eastern temperate forest region of the eastern United States, southern Canada, and the eastern Great Plains. Because of their great adaptability, they can live in country, suburbs, and even urban cities. This adaptability makes them a great pollinator species, leading to an increase in their commercial use by the greenhouse industry. This increase consequently led to their farther spread outside their previous distribution range. They are considered one of the most important species of pollinator bees in North America.

<i>Bombus frigidus</i> Species of bee

Bombus frigidus, the frigid bumblebee, is a rare species of bumblebee largely found in Canada and parts of the United States.

<i>Bombus affinis</i> Species of bee

Bombus affinis, commonly known as the rusty patched bumble bee, is a species of bumblebee endemic to North America. Its historical range in North America has been throughout the east and upper Midwest of the United States, north to Ontario, Canada, where it is considered a "species at risk", east to Quebec, south to Georgia, and west to the Dakotas. Its numbers have declined in 87% of its historical habitat range. On January 10, 2017, the United States Fish and Wildlife Service placed B. affinis on the list of endangered species, making the rusty patched bumblebee the first bee to be added to the list in the continental United States.

<i>Bombus terricola</i> Species of bee

Bombus terricola, the yellow-banded bumblebee, is a species of bee in the genus Bombus. It is native to southern Canada and the east and midwest of the United States. It possesses complex behavioral traits, such as the ability to adapt to a queenless nest, choose which flower to visit, and regulate its temperature to fly during cold weather. It was at one time a common species, but has declined in numbers since the late 1990s, likely due to urban development and parasite infection. It is a good pollinator of wild flowers and crops such as alfalfa, potatoes, raspberries, and cranberries.

<i>Trigona fulviventris</i> Species of bee

Trigona fulviventris, known by the common names culo-de-vaca, culo-de-señora, mu'ul-kab, culo-de-buey, and culo-de-vieja, is a species of stingless bee found in Mexico and neotropical regions of Central and South America. It is one of the largest and most widespread bees of its genus. They exhibit complex foraging behaviors by integrating spatio-temporal learning and flower scents. T. fulviventris has traditionally been observed to abstain from aggressive behavior with other species; however, more recent analyses have shown that T. fulviventris emit pheromones that act as attack signals particularly when related individuals are captured by predators.

<i>Bombus vancouverensis</i> Species of bee

Bombus vancouverensis is a common species of eusocial bumblebee of the subgenus Pyrobombus. B. vancouverensis inhabits mountainous regions of western North America, where it has long been considered as a synonym of Bombus bifarius, and essentially all of the literature on bifarius refers instead to vancouverensis. B. vancouverensis has been identified as one of the two species of bumblebee observed to use pheromones in kin recognition. The other is the frigid bumblebee, Bombus frigidus.

Bombus hypocrita, also known as the short-tongued bumblebee, is a Japanese bumblebee commonly used in commercial pollination. These short-tongued bumblebees have a proboscis about 7-9mm long, which is folded under their head when flying. Bumblebees are a small fuzzy insect with yellow and black banding along their abdomen. They are round and covered in pile, the hair-like structures that give them their distinct fuzzy appearance.

References

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