Slowing the Decline of the Bombus

North American Bombus Pollinates a Vibrant Flower.

 

Alexander Neuzil, Science and Biochemistry

Chase Balayo, Building Construction Technology

Eli Lagacy, Enviornmental Science

 

When we think of our favorite apple, we typically do not associate the image with a

school-aged child precariously perched among the uppermost branches, balancing a pot of pollen

in one hand, while holding a paintbrush in the other hand to paint each individual bud with

pollen.  We don’t usually envision hundreds of farmers walking blossom to blossom, hand

pollinating each individual flower one at a time, hoping that it bears fruit that can be sold at a

market.  As far-fetched an image this is, it’s the reality that is happening right now in China.

Goulson (2012) provides such an example in an article he published in early 2012.  In his article,

Goulson describes how declines in natural pollinators in southwest China due to excessive

pesticide use, and the destruction of natural pollinator habitats, has led to the farmers, and their

children, being forced to hand pollinate the apple and peach trees that grow in that region.  He

goes on to describe what a market without bees could look like, describing the lack of berries,

apples, peas, beans, melons, and tomatoes all of which depend on pollinators such as bees to

thrive (Goulson, 2012).  Nearly 75 percent of crops that are grown globally for consumption by

humans require the services of pollinators to ensure adequate yields (Potts et al., 2010).

Furthermore, the sheer demand by consumers for these crops has skyrocketed in the last half

century, on average doubling over that time span (Goulson, 2012).  Potts et al. (2010) indicates

that the steady increase of crop cultivation occurred from 1961 onward (Potts et al., 2010).

Meanwhile Goulson (2012) also indicates that a combination of increased caloric intake per

person increased nearly 30 percent, and the doubling of the worldwide human population from

just over three billion in 1961 to just over seven billion in 2011 has produced an added strain to

pollination services, such as the bumble bee, as there are not enough pollinators to go around

(Goulson 2012; US Census Bureau).  These trends coupled with the decline of pollinators due to

the combination of several factors, including pathogens, pesticides, and habitat loss can have

serious negative impacts to commercial production of crops which are necessary for food

diversity and production.  (Grixti, Wong, Cameron, & Favret 2009).

As shown by the drastic measures China has taken to hand pollinate some of their own

crops, a world without true pollinators would be very different from today. There would be

increased burdens on the agricultural industry as they would have to pollinate, there would be a

lack of food potentially due to human pollinating inefficiencies, and as a direct result food may

become more expensive. While the planet may never become completely devoid of all

pollinators, the scientific community knows that some wild pollinator species are declining

(Pollinators Home Page). One group of species that is exhibiting signs of decline are North

American bumble bees (Bombus) (Colla, Gadallah, Richardson, Wagner & Gall, 2012; Goulson,

Lyle & Darvill, 2008).

Through their unique ecological roles and behaviors, bumble bees are important as

natural pollinators. During the spring and summer months it is common to see bumble bees

foraging during the early morning hours and late in the evening. This is due to their preference

for cooler temperatures, they will typically avoid high activity in hot weather. This contrasts

most other pollinators and as a result, bumble bees help to expand the effective pollinating

efforts of ecosystems (Kricher & Morrison, 1998). Bumble bees also have key morphological

structures that make them unique in their abilities to pollinate. They have some of the longest

tongues among insect pollinators, this allows them to obtain pollen more efficiently from key

agricultural crops such as tomatoes and berries. They are also large in size, and have a distinct

“buzz pollination” method which allows them to easily obtain tightly packed pollen that other

insects cannot access (Cameron et al., 2011; What makes bumblebees such good pollinators?). It

has also been shown that bumble bee populations act as hubs for pollination networks, and that

some wildflowers are exclusively pollinated by bumble bees only (Grixti, et al., 2009). These

factors make bumble bees crucial to natural ecosystems and the agricultural industry.

In Europe, reductions in bumble bee populations have been exhibited over the past 60

years. Here in North America however, there have been little studies considering the declines of

bumble bee species. There are 46 species of bumble bees that live in North America (Bumble

bees of North America: An identification guide), of these species there are several that are in

decline. Goulson et al. (2008) claim that the Western Bumble has declined dramatically since the

early 1990’s. Once the most common species in the American west, they are now rare. Colla et

al. (2012) compiled a survey of 21 eastern bumble bee species, they found that 11 of the species

had reductions in populations greater than 50% and they recommended immediate attention for

conservation (Colla et al., 2012). There may be several reasons why bumble bees are declining in

North America. Whatever the causes are it is reasonable to suggest that reduced populations of

bumble bees will have negative effects on agriculture, food accessibility, and North American

ecosystems.

One contributing factor to the decline of bumble bees are pathogens. Just like how a virus

like the flu harms and effects the human body, diseases and viruses affect the health and ability

for bees to pollinate. In her TED talk: Why bees are disappearing? – bee scholar Marla Spivak

informs us that the number one cause for bees to acquire pathogens is the Varroa destructor

parasite. The parasite sucks the blood of bees and circulates viruses disrupting their immune

systems. Another parasite that is highly prevalent in bees in Nosema Bombi. Although

confirming a direct link between N. bombi and North American bumble bee decline will require

further research (Cameron et al., 2011), pathogens combined with other factors such as pesticides

are causing the decline of this species.

Another hypothesized causal effect for the decline of bumble bees, are pesticides –

specifically neonicotinoid pesticides (Whitehorn, O’Connor, Wackers & Goulson, 2012).

Neonicotinoids are a relatively new class of insecticides that are favored for their water

solubility. They can be applied directly to the ground so that plants can take them up and hold

them in their tissues. They are also highly favorable because they are shown to be safe for most

vertebrates such as mammals and birds (What is a Neonicotinoid?). However, these pesticides

are now candidates for the decline of several insect taxa, including the bumble bee.

Whitehorn et al., (2012) found evidence that neonicotinoids have sub-lethal effects on

bumble bees. They took Buff-tailed bumble bee colonies and exposed them to various field-

realistic levels of imidacloprid (a neonicotinoid). What they found was that control colonies on

average weighed more than colonies that were exposed to imidacloprid at small doses, and even

more than colonies that were exposed to higher doses. The control colonies were upwards of

35% heavier on average. This reduction in weight from the colonies exposed to imidicloprid

signifies less healthy bee colonies due to less mass and eggs. They also found that control

colonies produced more queens than either of the colonies that were exposed to imidacloprid

(13.7 vs 2.0 & 1.4 on average). These results indicate that imidacloprid exposure reduces colony

size and colony productivity for Buff-tailed bumble bees (Whitehorn et al., 2012). Another study

found that exposure to imidacloprid decreased the number of cells that contain eggs by 46% and

that thiamethoxam (another neonicotinoid) reduced the number of live bees by 38% (Carrington,

2016; Moffat et al., 2016). While this study only looks at one species of bumble bee in Europe, it

is still possible for us to look at the close phylogenetic relationship these bumble bees share with

those in North America, and infer that similar negative impacts may be shared.

Along with pesticides, one of the largest factors that has led to the decline of the North

American Bumble Bee is the loss of their natural habitats.  In the United States, a shift towards

monocultures, particularly of corn and soybean crops, has led to the destruction of naturally

occurring and preferred habitats of bumble bees (Grixti, Favret, Cameron, & Wong 2009).  This,

coupled with the reduction of floral resources that are crucial to the survival and longevity of

bumble bees (Goulson, Darvill, & Lye 2008), has fostered an environment that no longer favors

the bumble bee, leading to nearly a 30 percent decline in the number of native bumble bee

species (Grixti et al. 2009).

All of these factors by themselves may pose problems to bumble bees, however in

combination they may also act synergistically with each other and have greater effects. Goulson,

Nicholls, Botias and Rotheray, 2015 state that interactions among multiple stressors have a

higher likelihood of being more harmful than one stressor by itself. For example, fungicides such

as ergosterol biosynthesis inhibitors (EBI’s) have not been shown to pose any risks by

themselves, but in combination with some neonicotinoids can increase the pesticide’s toxicity

1,000-fold. There also may be synergistic effects between nutritional stresses due to habitat

changes, and parasite infections. The pathogen Crithidia Bombi rarely causes mortality in

bumble bees with healthy diets, however, in bumble bees with restricted diets, mortality rates

raise. This increase in mortality may arise due to metabolic costs associated with fighting

pathogens. Infected bumble bees must increase food intake to fight the pathogen, which may

increase their exposure to pesticides. Also, starved bumble bees that become infected may perish

quickly due to their already limited resources (Goulson, Nicholls, Botias & Rotheray, 2015). Due

to changes and losses of habitat, prevalence and transmittance of pathogens between bees, and

the high use of neonicotinoid pesticides, the synergistic effects between these variables are

highly likely to increase mortality rates among bumble bees.

Although pathogens, pesticides, and habitat loss each have different levels of effect on

North American bumble bees, the combination of all these factors most likely contribute to the

decline of these species. An appeal to the students and faculty at Umass Amherst for the

implementation of more bumble bee friendly habitats on campus, such as pollinator gardens, will

be helpful to negate the effects of pathogens, pesticides, and habitat losses in the area. While

Amherst is in a rather rural area of western Massachusetts, there is a high prevalence of

agricultural areas that may pose risks for bumble bees, and a high prevalence of dense forests in

which bumble bees do not prefer as prime habitat. There is currently a pollinator garden on the

north end of campus off Governors drive. However, more bumble bee friendly habitats placed in

other areas around campus will help local pollinators obtain pesticide free, natural food.

According to Marc Carlton (2006), a pollinator garden is a garden that is planted mostly

with flowers that contribute nectar and pollen for a large diversity of pollinating insects (Carlton,

2006).  We propose creating pollinator gardens on the Umass campus focused on native insect

pollinators and bumble bees. To attract and adequately supply bumble bees with their nutrient

demands there are several attributes these pollinator gardens should have. The gardens should

include native plants, which would ensure the evolutionary compatibility between the bumble

bees and the plants. The gardens should also be planted in a sunny area without the use of

pesticides, should have a large variety of plants to span the seasons, and should include logs and

woody debris for bumble bee nesting sites (How gardeners can help pollinators). These bumble

bee friendly pollinator gardens would help bumble bees achieve their nutrient and pollen

requirements. They can reduce distances between colonies and food, and provide food that is

pesticide free. If reliance on pollinator gardens is achieved over sources where pesticides are

applied, this reduces the impact of pesticides on native colonies.

There certainly is a case to be made that it would be feasible to implement a pollinator

garden, and anyone can do so.  The United States Fish and Wildlife Service (USFWS) manages

the Wildlife & Sport Fish Restoration Program, which aims to provide up to 75 percent in costs

associated with planning, and 65 percent of costs associated with implementation of programs

such as pollinator gardens by using federal grant funding.  (State wildlife grant program, 2016).

Grant funding, such as the one mentioned from the USFWS, is not the only resource that is

made available to the general public with regards to the implementation of pollinator gardens.

Many agriculture and eco-friendly universities, such as Umass Amherst, have published easy to

follow guides which explain which plants are pollinator friendly and when they are best planted

throughout the year. Higgins (2013) provides a very detailed listing of species of plants which

provide an appropriate habitat for pollinators such as the bumble bee.  The availability of grant

funding, along with the ease in which one can identify pollinator friendly plant species are two

strong indicators of feasibility regarding the implementation of pollinator gardens at Umass.

As of February 10, 2017, the Rusty-patched bumble bee was declared an endangered

species (Species Profile for Rusty patched bumble bee). This is the first bumble bee in the

United States to be listed as an endangered species as it has declined 90% from its original

territory (Greshko, 2017). According to the Center for Biological Diversity – an organization

whose mission is to save and encourage the saving of all life on earth, the endangered species

act has prevented extinction for 99 percent of species under its protection (The endangered

species act: A wild success). However, there are still individuals that do not think it should be

a priority to save species like the Rusty-patched bumble bee. For example, Juliet Ford argues

in her piece “8 Reasons Why We Need to Stop Worrying About Endangered Species,” that

using funds for the protection of wildlife is a waste and that we should instead focus that

money on helping feed the poor and less privileged instead (Ford, 2014). While on the

surface this argument has some weight, once actually thought through logically it lacks key

concepts. For instance, all organisms provide biological services, so simply letting them

become extinct would not only negatively impact their own ecosystems but also negatively

affect humans that rely on that ecosystem’s services. Bumble bees especially since we rely on

them heavily for agriculture and pollination.

As we’ve seen North American bumble bee species are declining due to a combination

of factors, such as pathogens, pesticides, habitat loss, and the combined effects of these

together. Bumble bees rely on pollen from sources that are available to them, which

sometimes are far away from their colonies or not highly prevalent. These sources also may

contain pollen that have been treated with pesticides. If more pollinator gardens were located

around the Umass Campus, this would help the local bumble bee populations by creating a

hub for healthy, accessible pollen. While this would not help solve the continent-wide decline

in bumble bees it would be a step in the right direction and Umass Amherst would be paving

the way for other individuals and institutions down the road to do the same.

 

References

 

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http://press.princeton.edu/titles/10219.html

Cameron, S. A., Lozier, J., Strange, J., Koch, J., Cordes, N., Solter, L., & Griswold, T. (2011).

Patterns of widespread decline in North American bumble bees. PNAS, 108(2), 662-667.

doi:10.1073/pnas.1014743108

Carlton, M. (2006). What is a Pollinator Garden? – The Pollinator Garden. Retrieved April 2,

2017, from http://www.foxleas.com/what-is- a-pollinator- garden.asp

Carrington, D. (2016, April 28). Two of the world’s top three insecticides harm bumblebees –

study. Retrieved from https://www.theguardian.com/environment/2016/apr/28/two-

worlds-top- three-leading- insecticides-harm- bees-study- shows

Colla, S. R., Gadallah, F., Richardson, L., Wagner, D., & Gall, L. (2012). Assessing declines of

North American bumble bees (Bombus spp.) using museum specimens. Biodiversity

Conservation, 21, 3585-3595. doi:10.1007/s10531-012- 0383-2

The Endangered Species Act: A wild success. (n.d.). Retrieved April 4, 2017, from

http://www.biologicaldiversity.org/campaigns/esa_wild_success/

Ford, J. (2014, September 05). 8 Reasons Why We Need To Stop Worrying About Endangered

Species. Retrieved April 4, 2017, from http://thoughtcatalog.com/juliet-ford/2014/09/8-

reasons-why- we-need- to-stop- worrying-about- endangered-species/

Goulson, D., Lye, G., & Darvill, B. (2008). Decline and conservation of bumble bees. Annual

Review Entomology, 53, 191-208. doi:10.1146/annualrev.ento53.103106.093454

Goulson, D. "Decline of Bees Forces China’s Apple Farmers to Pollinate by Hand." ????

China Dialogue. China Dialogue, 2 Oct. 2012. Web. 04 Apr. 2017.

Goulson, D., Nicholls, E., Botias, C., & Rotheray, E. (2015). Combined stress from parasites,

pesticides and lack of flowers drives bee declines. Science, 347(6229).

doi:10.1126/science.1255957

Greshko, M. (2017, March 22). First U.S. bumble bee Officially Listed as Endangered. Retrieved

April 4, 2017, from http://news.nationalgeographic.com/2017/03/bumble bees-

endangered-extinction- united-states/

Grixti, J. C., Wong, L. T., Cameron, S. A., & Favret, C. (2009). Decline of bumble bees

(Bombus) in the North American midwest. Biological Conservation, 142, 75-84.

doi:10.1016/j.biocon.2008.09.027

Higgins, A. (2013, Sep 12,). Planting for pollinators. The Washington Post

How gardeners can help pollinators. (n.d.). Retrieved April 16, 2017, from

https://www.nrcs.usda.gov/wps/portal/nrcs/main/national/plantsanimals/pollinate/gardeners/

Kricher, J. C., & Morrison, G. (1998). Eastern forests: A field guide to birds, mammals, trees,

flowers, and more (p. 279). Boston: Houghton Mifflin.

Moffat, C., Buckland, S., Sampson, A., McArthur, R., Pino, V., Bollan, K., . . . Connoly, C.

(2016). Neonicotinoids target distinct nicotinic acetylcholine receptors and neurons,

leading to differential risks to bumblebees. Nature: Scientific Reports.

doi:10.1038/srep24764

Pollinators Home Page – U.S. Fish and Wildlife Service. (n.d.). Retrieved March 31, 2017, from

https://www.fws.gov/pollinators/

Potts, S. G., Biesmeijer, J. C., Kremen, C., Neumann, P., Schweiger, O., & Kunin, W. E. (2010).

Global pollinator declines: trends, impacts and drivers. Trends in Ecology & Evolution,

25(6), 345-353. doi://dx.doi.org/10.1016/j.tree.2010.01.007

Species Profile for Rusty patched bumble bee (Bombus affinis). (n.d.). Retrieved April 4, 2017,

from https://ecos.fws.gov/ecp0/profile/speciesProfile?sId=9383

What is a neonicotinoid? (n.d.). Retrieved April 2, 2017, from

http://citybugs.tamu.edu/factsheets/ipm/what-is- a-neonicotinoid/

What makes bumblebees such good pollinators? (n.d.). Retrieved April 13, 2017, from

https://bumblebeeconservation.org/about-bees/faqs/buzz- pollination/

Whitehorn, P., O’Connor, S., Wackers, F., & Goulson, D. (2012). Neonicotinoid pesticide

reduces bumble bee colony growth and queen production. Science, 336, 351-352.

doi:10.1126/science1215025

State Wildlife Grant Program – Overview. (2016). Retrieved from

https://wsfrprograms.fws.gov/Subpages/GrantPrograms/SWG/SWG.htm

 

Evan

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