The yellow fever mosquito was a common vector in Florida until the invasion of the Asian tiger mosquito, Aedes albopictus (Skuse). Since the introduction of the Asian tiger mosquito in 1985, by way of Texas, the population of Ae. aegypti in Florida has declined dramatically, but still thrives in urban areas of South Florida. Aedes albopictus larvae out-compete Ae. aegypti larvae for food, and develop at a faster rate (Barrera 1996). Some research also suggests there is a hybridization of the two species in zones where they overlap, producing sterile offspring (Harper and Paulson 1994).
Yellow fever mosquitoes are container-inhabiting mosquitoes; often breeding in unused flowerpots, spare tires, untreated swimming pools, and drainage ditches. They thrive in urbanized areas, in close contact with people making them an exceptionally successful vector. Aedes aegypti are extremely common in areas lacking piped water systems, and depend greatly on stored water for breeding sites. Male and female adults feed on nectar of plants; however, females bloodfeed primarily on humans in order to produce eggs, and are active in the daytime. Eggs have the ability to survive desiccation for long periods of time, allowing eggs to be easily spread to new locations.
For additional information on mosquitoes, see http://edis.ifas.ufl.edu/IN652.
From the Integrated Taxonomic Information System and International Commission on Zoological Nomenclature.
In the early 1900s, Ae. aegypti distribution extended from the southern United States down to Argentina. The mid-1900s saw the development of a fairly successful Ae. aegypti eradication program throughout its range in North and South America as a method to control yellow fever through education, adult mosquito control, and manipulation of container breeding sites. Though initially successful, Ae. aegypti has reestablished in most of the pre-eradication range due to lack of commitment and financial backing necessary to maintain the eradication program (Nelson 1986). The program is no longer operational today.
In the United States, Ae. aegypti is found in 23 states, including the southeastern U.S., up the east coast to New York, and west to Indiana and Kentucky (Darsie and Ward 2005) although in some areas Ae. aegypti populations are decreasing due to competition with Ae. albopictus. Aedes aegypti is still a common mosquito in urban areas of southern Florida, and in cities along the Gulf coast of Texas and Louisiana.
Females are larger than males, and can be distinguished by small palps tipped with silver or white scales. Males have plumose antennae, whereas females have sparse short hairs. When viewed under a microscope, male mouthparts are modified for nectar feeding, and female mouthparts are modified for blood feeding. The proboscis of both sexes is dark, and the clypeus (segment above the proboscis) has two clusters of white scales. The tip of the abdomen comes to a point, which is characteristic of all Aedes species (Cutwa-Francis and O'Meara 2007).
For a pictorial key of Florida mosquitoes, including Ae. aegypti, see the Florida Medical Entomology Laboratory's Identification Guide to Common Mosquitoes of Florida Web site at: http://fmel.ifas.ufl.edu/Key/index.htm.
Eggs: After taking a complete blood meal, females produce on average 100 to 200 eggs per batch; however, the number of eggs produced is dependent on the size of the bloodmeal. Females can produce up to five batches of eggs during a lifetime. A smaller bloodmeal produces fewer eggs (Nelson 1986). Eggs are laid on damp surfaces in areas likely to temporarily flood, such as tree holes and man-made containers, and are laid singly, rather than in a mass. Not all the eggs are laid at once, but can be spread out over hours or days, depending on the availability of suitable substrates (Clements 1999). Most often, eggs will be placed at varying distances above the water line, and a female will not lay the entire clutch at a single site, but rather spread out the eggs over two or more sites (Foster and Walker 2002).
Eggs of Ae. aegypti are long, smooth, ovoid shaped, and approximately one millimeter long. When first laid, eggs appear white but within minutes turn a shiny black. In warm climates, such as the tropics, eggs may develop in as little as two days, whereas in cooler temperate climates, development can take up to a week (Foster and Walker 2002). Aedes aegypti eggs can survive desiccation for months and hatch once submerged in water, making the control of Ae. aegypti difficult (Nelson 1984).
Larvae: Mosquito larvae are often called "wrigglers" or "wigglers," because they appear to wiggle sporadically in the water when disturbed. Larval Ae. aegypti breathe oxygen through a posteriorly located siphon, which is held above the water surface while the rest of the body hangs vertically. Most Aedes larvae can be distinguished from other genera by the unaided eye by their short siphon (Nelson 1986).
Larvae feed on organic particulate matter in the water, such as algae and other microscopic organisms. Most of the larval stage of Ae. aegypti is spent at the water's surface, although they will swim to the bottom of the container if disturbed or when feeding (Nelson 1984).
Larvae are often found around the home in puddles, tires, or within any object holding water. Larval development is temperature dependent. The larvae pass through four instars, spending a short amount of time in the first three, and up to three days in the fourth instar. Fourth instar larvae are approximately eight millimeters long. Males develop faster than females, so males generally pupate earlier. If temperatures are cool, Ae. aegypti can remain in the larval stage for months so long as the water supply is sufficient (Foster and Walker 2002).
Pupae: After the fourth instar, Ae. aegypti enter the pupal stage. Mosquito pupae are different from many other holometabolous insects in that the pupae are mobile and respond to stimuli. Pupae, also called "tumblers," do not feed and take approximately two days to develop. Adults emerge by ingesting air to expand the abdomen thus splitting open the pupal case and emerge head first.
Yellow fever epidemics still occur frequently in the tropics, and can occur in temperate regions during summer months, although it is not the major threat it once was. Today, there is a very successful vaccine for yellow fever, which has contributed to the decline in cases in the United States. In 1951, Max Theiler won a Nobel Prize for his vaccine, which is the only Nobel Prize given for a vaccine to date (Norrby 2007). For more information on yellow fever, see http://edis.ifas.ufl.edu/IN659.
While the United States rarely experiences yellow fever cases, the most recent concern to the United States and Florida is the transmission of dengue virus. Dengue is also known as "break-bone fever" for the excruciating pain victims feel. Dengue is a dangerous disease due to four different serotypes: DEN-1, DEN-2, DEN-3, and DEN-4 (Rey 2007). Although a person can obtain immunity to one serotype, they are still susceptible to the others. The most deadly is dengue hemorrhagic fever (DHF), which is often fatal. In 1981, Cuba experienced a major DHF outbreak, killing 159 people (Nelson 1984). Though outbreaks in the United States are still rare, Mexico is experiencing major dengue outbreaks, and its close proximation could lead to outbreaks in the United States. Like yellow fever, dengue fever is caused by a flavivirus (attacks the liver), and can only be transmitted by female mosquitoes. To more information on dengue fever, see http://edis.ifas.ufl.edu/IN699.
Aedes aegypti are vectors of other important viruses of concern to North America, such as chikungunya virus. Although chikungunya is not endemic in North America, like dengue, the number of cases is steadily increasing and this virus could become a major threat to public health in the United States. Most cases documented in the United States are associated with international travel, but with the spread and resurgence of the yellow fever mosquito and Asian tiger mosquito in the Americas, chikungunya is a very real threat (Centers for Disease Control, 2007). For more information on chikungunya, see http://fmel.ifas.ufl.edu/fmbuzz/wtchicun.htm and http://edis.ifas.ufl.edu/IN696.
In 1947, the Pan American Health Organization implemented an eradication program for Ae. aegypti in hopes of eliminating yellow fever outbreaks in the Western hemisphere. As of 1965, 19 countries had completed the program and were declared Ae. aegypti free (Soper 1965). After the eradication program ended, low doses of malathion were used for control, but Ae. aegypi rapidly developed resistance to the pesticide (Gubler 1989). In 1965, Florida initiated an Ae. agypti eradication program through the 67 county health departments and the U.S. Public Health Service to prevent yellow fever and dengue outbreaks (Florida State Board of Health 1965).
Unfortunately, Ae. aegypti has reestablished itself throughout the Americas and has expanded its range in the United States. No eradication program is currently operational, but there are several steps individuals can take to reduce localized mosquito numbers. Because Ae. aegypti are container-inhabiting mosquitoes, one of the most successful and cost-effective methods to reducing populations is by preventing containers around the home from collecting water.
By turning over empty flowerpots, properly maintaining swimming pools, and removing unused tires, you can greatly reduce the number of places mosquitoes have to lay eggs. Aerate birdbaths and make sure gutters are free of blockages. Clean pet bowls everyday and always empty overflow dishes for potted plants.
For personal protection from bites, apply an insect repellant, and wear long pants and long sleeves when outside. For more information on mosquito management, please visit the Florida Medical Entomology Laboratory mosquito management website at: http://mosquito.ifas.ufl.edu/Mosquito_Management.htm.
For information regarding mosquito management devices for the home, see http://edis.ifas.ufl.edu/IN171.
Authors: Catherine Zettel and Phillip Kaufman, University of Florida
Photographs: James Gathany, Paul Howell, Frank Hadley Collins, and the Center for Disease Control Public Health Image Library; Catherine Zettel and Michelle M. Cutwa-Francis, University of Florida; RF Darise and RA Ward, University of Florida Press; Simon Hinkley and Ken Walker, Pest and Diseases Image Library; PAHO/WHO
Project Coordinator: Thomas R. Fasulo, University of Florida
Publication Number: EENY-434
Publication Date: May 2008
Copyright 2008 University of Florida
Featured Creatures
Department of Entomology and Nematology
Division of Plant Industry
Electronic Data Information Source
adult female
reinfestation of Americas
U.S. distribution
"lyre" on adult thorax
close-up of "lyre"
bloodfed female
bloodfed female in flight
egg
eggs
eggs
larva
pupa
breeding sites - rain barrels
breeding sites - rain gutters
breeding sites - cans
breeding sites - junk yards