Osmia cornifrons

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Horned-face bee
Osmia cornifrons.5.1.08.w.jpg
Scientific classification Red Pencil Icon.png
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Hymenoptera
Family: Megachilidae
Genus: Osmia
Species:
O. cornifrons
Binomial name
Osmia cornifrons
(Radoszkowski, 1887)

Osmia cornifrons, also known as the horned-face bee, is a species of solitary bee indigenous to Northern Asia. Physically, this species of bee is recognized for its horn-like extensions originating from its lower face. Populations of O. cornifrons have been recorded in multiple locations, including Japan, Korea, China, and Russia. O. cornifrons are more docile as compared to other species of bees and are less prone to sting when aggravated.

Contents

History

Osmia cornifrons was first introduced in Japan in the 1940s and were managed for crop pollination. Over a 50-year time period, use of O. cornifrons gradually increased until more than half of the apple orchards in Japan utilized this species. [1] In 1977, O. cornifrons was introduced in the northeastern United States in an attempt to increase pollination productivity of fruit crops. This species was reintroduced multiple times during the following years. [2]

Crop pollination

This species of bee has been utilized for its effectiveness in pollinating flowers at a rapid rate. A single bee can visit up to 2,500 flowers a day and will spend 4–8 minutes per flower. [3] Osmia cornifrons has a high flower constancy, signifying that the bee will return to the same species of flower. Both males and females will create a nest within 130 meters of a crop field; however, nest locations have been noted to exceed this distance; some being situated 700 meters away. It is a diurnal species that is most active between 6AM-8PM, depending on the location of the sun. [2] They will avoid foraging during raining spells, as they are not well suited to fly in that type of weather. [2] O. cornifrons is more adept to humid environments and performs optimally in regions that have consistent humidity, however, are capable of functioning in cooler environments. This ability to perform in a wide range of environmental temperatures makes them highly valued bees for crop pollination as well as making them more effective pollinators than honeybees. [4]

Development and biology

Osmia cornifrons have relatively short adult life spans and spend most of their time undergoing development. Life cycles can be broken up into six different stages, including: spring incubation, pre-nesting, nesting, development, prewintering, and wintering. [2] Male and female emergence times are dependent on weather conditions during spring incubation and wintering periods. The wintering period is when bees are enclosed in cocoons to decrease exposure to cold temperatures. [2] Time of emergence is temperature dependent and the rate at which heat is acquired can advance or delay emergence times. [5] Extended wintering periods increase the risk of mortality due to prolonged consumption of stored body fat. [6] Males emerge from their nests around April, just prior to the blooming of apple orchards. [7] [8] Females arise from their nests 2–3 days later. [1] Emergence periods are consistently close with the blooming of crops. [6] Early emergence increases the risk of inadequate resource accumulation and flower pollination. [6] A male will wait outside of a female’s nest and attempt to court the female by mounting her back and rubbing his antennae against her abdomen. This courtship may last several hours before the female allows the male to mate with her. After mating has completed, both males and females will leave and travel to a nearby field patch where they both serve as pollinators, which is consistent with pre-nesting behavior. [6] Male bees will serve as pollinators for multiple weeks and will eventually die off. Females leave their nests for several days until ovarian development has concluded and will either return to the nest that they emerged from or create a new nest in which to lay their eggs. Poor environmental/weather stability may alter pre-nesting activity, thereby adversely affecting the timing of ovarian development. [6] A female will collect pollen from a nearby crop, bring it into the nest, and then disperse the pollen as a pollen ball. Eggs are placed on top of the pollen ball and are typically 1/10 the length of the female body'. [9] [1] Females can lay up to 30 eggs over the course of their lifespan. [6] It is hypothesized that females are capable of controlling the sex of its progeny through haplodiploid sex determination. Male progeny are haploid and female progeny are diploid. Female bees are provided more pollen as larvae, which is associated with female bees having a larger stature as compared to males. Nests under distress will predominantly have male progeny. Female progeny are more costly and require consistent resources for proper development. [6] Although there is an increased energy cost for females, females are more effective in collecting resources and pollinating crops as compared to males. [6] Larvae development is temperature dependent. Adequate development occurs between 12 °C and 18 °C, but has been noted to occur at 25 °C as well. [5] Development will either decrease significantly or halt outside of this temperature range. O. cornifrons risk death when exposed to temperatures below 10 °F. [5]

Nesting

Osmia cornifrons use bamboo, reeds, and previously existing holes in trees as nesting sites. [9] To determine the size of a location, the bee will enter and move toward the end of the potential new nest. The bees will perform specific physical movements, including turning upside down and moving left and right to inspect the site thoroughly. [5] If females utilize a previously used nest, they will remove all of the remaining debris that has been left. In the nest, females will create individual cells in which they lay a single egg. After an egg has been placed, the female bee closes off the cell with mud.

Parasitism

Populations of Osmia cornifrons are antagonized by different pest species (mites) including, but not limited to, ''Chaetodactylidae nipponicus, Chaetodactylidae hirashimai, and Chaetodactylus krombeini. [2] C. krombeini have been noted to heavily infest O. cornifrons populations and have the highest negative impact on overall productivity and lifespan to horned-face bees. [10] C. krombeini that inhabit a nest will consume the pollen that was provided by a female O. cornifrons for her larvae. [8] The decrease in pollen provisions is great enough that larvae have an increased risk of mortality or inadequate development. [2] Poor development of larvae, especially of female larvae, has been directly correlated with decreased pollination ability and productivity in populations of O. cornifrons infested by mites. [2]

Related Research Articles

<span class="mw-page-title-main">Fruit tree pollination</span>

Pollination of fruit trees is required to produce seeds with surrounding fruit. It is the process of moving pollen from the anther to the stigma, either in the same flower or in another flower. Some tree species, including many fruit trees, do not produce fruit from self-pollination, so pollinizer trees are planted in orchards.

<i>Megachile rotundata</i> Species of bee

Megachile rotundata, the alfalfa leafcutting bee, is a European bee that has been introduced to various regions around the world. As a solitary bee species, it does not build colonies or store honey, but is a very efficient pollinator of alfalfa, carrots, other vegetables, and some fruits. Because of this, farmers often use M. rotundata as a pollination aid by distributing M. rotundata prepupae around their crops. Each female constructs and provisions her own nest, which is built in old trees or log tunnels. Being a leafcutter bee, these nests are lined with cut leaves. These bees feed on pollen and nectar and display sexual dimorphism. This species has been known to bite and sting, but it poses no overall danger unless it is threatened or harmed, and its sting has been described as half as painful as a honey bee's.

<span class="mw-page-title-main">Megachilidae</span> Cosmopolitan family of bees

Megachilidae is a cosmopolitan family of mostly solitary bees. Characteristic traits of this family are the restriction of their pollen-carrying structure to the ventral surface of the abdomen, and their typically elongated labrum. Megachilid genera are most commonly known as mason bees and leafcutter bees, reflecting the materials from which they build their nest cells ; a few collect plant or animal hairs and fibers, and are called carder bees, while others use plant resins in nest construction and are correspondingly called resin bees. All species feed on nectar and pollen, but a few are kleptoparasites, feeding on pollen collected by other megachilid bees. Parasitic species do not possess scopae. The motion of Megachilidae in the reproductive structures of flowers is energetic and swimming-like; this agitation releases large amounts of pollen.

<span class="mw-page-title-main">Mason bee</span> Genus of insects

Mason bee is a name now commonly used for species of bees in the genus Osmia, of the family Megachilidae. Mason bees are named for their habit of using mud or other "masonry" products in constructing their nests, which are made in naturally occurring gaps such as between cracks in stones or other small dark cavities. When available, some species preferentially use hollow stems or holes in wood made by wood-boring insects.

<i>Osmia lignaria</i> Species of bee

Osmia lignaria, commonly known as the orchard mason bee or blue orchard bee, is a megachilid bee that makes nests in natural holes and reeds, creating individual cells for its brood that are separated by mud dividers. Unlike carpenter bees, it cannot drill holes in wood. O. lignaria is a common species used for early spring fruit bloom in the United States and Canada, though a number of other Osmia species are cultured for use in pollination.

<i>Habropoda laboriosa</i> Species of bee

Habropoda laboriosa, the southeastern blueberry bee, is a bee in the family Apidae. It is native to the eastern United States. It is regarded as the most efficient pollinator of southern rabbiteye blueberries, because the flowers require buzz pollination, and H. laboriosa is one of the few bees that exhibit this behavior. It is active for only a few weeks of the year, while the blueberries are in flower during early spring, when the temperature is warm and humid. H. laboriosa are solitary bees that live alone but nest in close proximity with other nests of their species. They have similar features to bumble bees, but they are smaller in size compared to them. H. laboriosa are arthropods so they have segmented bodies that are composed of the head, thorax, and abdomen.

<span class="mw-page-title-main">Eastern carpenter bee</span> Species of insect

Xylocopa virginica, sometimes referred to as the eastern carpenter bee, extends through the eastern United States and into Canada. They are sympatric with Xylocopa micans in much of southeastern United States. They nest in various types of wood and eat pollen and nectar. In X. virginica, dominant females do not focus solely on egg-laying, as in other bee species considered to have "queens". Instead, dominant X. virginica females are responsible for a full gamut of activities including reproduction, foraging, and nest construction, whereas subordinate bees may engage in little activity outside of guarding the nest.

<i>Osmia bicornis</i> Species of bee

Osmia bicornis is a species of mason bee, and is known as the red mason bee due to its covering of dense gingery hair. It is a solitary bee that nests in holes or stems and is polylectic, meaning it forages pollen from various different flowering plants. These bees can be seen aggregating together and nests in preexisting hollows, choosing not to excavate their own. These bees are not aggressive; they will only sting if handled very roughly and are safe to be closely observed by children. Females only mate once, usually with closely related males. Further, females can determine the sex ratio of their offspring based on their body size, where larger females will invest more in diploid females eggs than small bees. These bees also have trichromatic colour vision and are important pollinators in agriculture.

<i>Xylocopa sonorina</i> Species of bee

Xylocopa sonorina, the valley carpenter bee or Hawaiian carpenter bee, is a species of carpenter bee found from western Texas to northern California, and the eastern Pacific islands. Females are black while males are golden-brown with green eyes.

<span class="mw-page-title-main">Alkali bee</span> Species of insect

The alkali bee, Nomia melanderi, is a ground-nesting bee native to deserts and semi-arid desert basins of the western United States. It was described by Theodore Dru Alison Cockerell in 1906. While solitary, these bees nest near each other and can form extremely dense aggregations in areas with favorable conditions.

<i>Osmia latreillei</i> Species of bee

Osmia latreillei is a species of mason bee belonging to the family Megachilidae subfamily Megachilinae.

<i>Euglossa cordata</i> Species of bee

Euglossa cordata is a primitively eusocial orchid bee of the American tropics. The species is known for its green body color and ability to fly distances of over 50 km. Males mostly disperse and leave their home nests, while females have been observed to possess philopatric behavior. Because of this, sightings are rare and little is known about the species. However, it has been observed that adults who pollinate certain species of orchids will become intoxicated during the pollination.

<i>Xylocopa sulcatipes</i> Species of bee

Xylocopa sulcatipes is a large Arabian carpenter bee. These multivoltine bees take part in social nesting and cooperative nesting. They are metasocial carpenter bees that nest in thin dead branches. One or more cooperating females build many brood cells. They have been extensively studied in Saudi Arabia and Israel.

<i>Eufriesea surinamensis</i> Species of bee

Eufriesea surinamensis belongs to the tribe of euglossine bees and as such is a species of orchid bee. This should not be mistaken with the species group surinamensis, which includes Ef. surinamensis among other Eufriesea species.

<i>Xylocopa pubescens</i> Species of carpenter bee

Xylocopa pubescens is a species of large carpenter bee. Females form nests by excavation with their mandibles, often in dead or soft wood. X. pubescens is commonly found in areas extending from India to Northeast and West Africa. It must reside in these warm climates because it requires a minimum ambient temperature of 18 °C (64 °F) in order to forage.

<i>Macropis nuda</i> Species of bee

Macropis nuda is a ground nesting, univoltine bee native to northern parts of North America. Thus, this species cocoons as pupae and hibernates over the winter. The species is unusual as it is an oligolectic bee, foraging exclusively for floral oils and pollen from Primulaceae of the species Lysimachia ciliata.

Chaetodactylus is a genus of parasitic mite primarily associated with solitary bees with over 20 species.

<i>Colletes validus</i> Species of bee

Colletes validus, colloquially known as the blueberry cellophane bee, is a solitary, specialist bee in the family Colletidae. It is found primarily in eastern North America where it nests in sandy soils near ericaceous plants.

<i>Chaetodactylus krombeini</i> Species of mite

Chaetodactylus krombeini,, was described by Karl Krombein and E. W. Baker in the 1960s. The mites are about 0.5 mm across, with the females larger than the males. Pollen mites are a kleptoparasitic pest of Megachilid solitary bees, with Ch. krombeini found with Osmia lignaria of North America,. Pollen mites do not feed on bees, but rather their provisions, and are harmful because they consume the food resources and starve or stunt the developing larvae; there is evidence that pollen mites also directly harm the egg by puncturing it.

<i>Osmia nigriventris</i> Species of bee

Osmia nigriventris, also known as the large black-bellied mason bee, is a species of solitary bee within the family Megachilidae.

References

  1. 1 2 3 McKinney, Matthew I.; Park, Yong-Lak (2012). "Distribution of Chaetodactylus krombeini (Acari: Chaetodactylidae) within Osmia cornifrons (Hymenoptera: Megachilidae) nests: Implications for population management". Experimental and Applied Acarology. 60 (2): 153–61. doi:10.1007/s10493-012-9629-7. PMID   23100109. S2CID   254261427.
  2. 1 2 3 4 5 6 7 8 White, Joseph; Son, Youngsoo; Park, Yong-Lak (2009). "Temperature-Dependent Emergence of Osmia cornifrons (Hymenoptera: Megachilidae) Adults". Journal of Economic Entomology. 102 (6): 2026–32. doi:10.1603/029.102.0602. PMID   20069827. S2CID   46241542.
  3. Abel, Craig A.; Wilson, Richard L.; Luhman, Richard L. (October 2003). "Pollinating Efficacy of Osmia cornifrons and Osmia lignaria subsp. lignaria (Hymenoptera: Megachilidae) on Three Brassicaceae Species Grown Under Field Cages". Journal of Entomological Science. 38 (4): 545–52. doi:10.18474/0749-8004-38.4.545.
  4. Ahn, Jeong Joon; Park, Yong-Lak; Jung, Chuleui (2014). "Modeling spring emergence of Osmia cornifrons Radoszkowski (Hymenoptera: Megachilidae) females in Korea". Journal of Asia-Pacific Entomology. 17 (4): 901–5. doi:10.1016/j.aspen.2014.10.002.
  5. 1 2 3 4 McKinney, Matthew I.; Park, Yong-Lak (2012). "Nesting Activity and Behavior of Osmia cornifrons(Hymenoptera: Megachilidae) Elucidated Using Videography". Psyche: A Journal of Entomology. 2012: 1–7. doi: 10.1155/2012/814097 .
  6. 1 2 3 4 5 6 7 8 Bosch, J.; Kemp, W. (2002). "Developing and establishing bee species as crop pollinators: The example of Osmia spp. (Hymenoptera: Megachilidae) and fruit trees". Bulletin of Entomological Research. 92 (1): 3–16. doi:10.1079/BER2001139. PMID   12020357. S2CID   1942186.
  7. Matsumoto, Shogo; Abe, Ayumi; Maejima, Tsutomu (2009). "Foraging behavior of Osmia cornifrons in an apple orchard". Scientia Horticulturae. 121 (1): 73–9. doi:10.1016/j.scienta.2009.01.003.
  8. 1 2 Matsumoto, Shogo; Maejima, Tsutomu (2010). "Several New Aspects of the Foraging Behavior of Osmia cornifronsin an Apple Orchard". Psyche: A Journal of Entomology. 2010: 1–6. doi: 10.1155/2010/384371 .
  9. 1 2 McKinney, Matthew (2011). Nesting biology of Osmia cornifrons: implications for population management (M.S. thesis). Morgantown, WV, USA: West Virginia University. OCLC   768434708.[ page needed ]
  10. Park, Y.-L.; Kondo, V.; White, J.; West, T.; McConnell, B.; McCutcheon, T. (2009). "Nest-to-nest dispersal of Chaetodactylus krombeini(Acari, Chaetodactylidae) associated with Osmia cornifrons(Hym., Megachilidae)". Journal of Applied Entomology. 133 (3): 174–80. doi:10.1111/j.1439-0418.2008.01351.x. S2CID   84222037.
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