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The
Varroa Mite,
Varroa Jacobsoni
Background
The Varroa mite, Varroa Jacobsoni, is an external
parasite of honeybees. It feeds on the hemolymph of both brood and adult bees.
The entire life cycle of these mites is spent with the bees. The Varroa Mite
originated in Southeast Asia where it is a parasite of the Eastern honeybee,
Apis cerana. It was first discovered on the Western honeybee, Apis mellifera, in
1960. The crossover resulted from beekeepers intermingling the two species, and
further spread has been encouraged by beekeepers transporting colonies. This
mite is now found on every continent except Australia. No one is sure how it
came into the United States but it is most likely that they arrived with queen
bees, which were brought in illegally. By 1992 Varroa mites have been found in
at least 40 of the United States and continue to spread. They were first found
in Wisconsin in late 1987 and shortly thereafter were reported in Florida. They
are assumed to have been in Florida first and moved to Wisconsin with migratory
bees. A further assumption is that they were in the U.S. for at least two years
before discovery. Varroa mites were first found in Massachusetts in 1988, and by
1992 had spread through the eastern half of the state and were slowly moving
west, although the heaviest infestation continues to be in the cranberry growing
areas. We can reasonably expect these mites to spread to all parts of the state
within two to three years.
![[varroa development cycle]](intere1.gif)
Figure
1- Development Cycle
Life
History
The
numbers of mites found in a colony of honeybees varies with the season. The
fewest mites are found in the spring, increasing over the summer to a high point
in the fall, and then falling off over winter and into the spring. During the
spring and summer the mites are found mostly on brood. In fall and winter they
are mostly on adult bees. Within this cycle, only adult female mites are found
outside the brood cells in the hive. The mite's life cycle begins when an adult
female leaves a host bee and enters a brood cell as that host is feeding a young
larva. Though the mite is found on all three castes of the honeybee, its
preference is for drone brood; the mites enter drone cells in greater numbers
than they enter worker cells. Once the mite is in the cell she hides in the
brood food. As many as 21 mites have been found hiding in a single cell, though
smaller numbers are more common. The mite is liberated from the brood food as
the food is eaten by the bee larva. Soon after the cell is capped the mite moves
to the pupa and begins feeding. Sixty hours after the cell is sealed the mite
lays her first egg, with succeeding eggs at approximately 30-hour intervals. The
first egg results in a female, the second a male, and the third and beyond,
females. New young mites reach maturity within the cell and mating takes place.
The male mite then dies, along with any immature females, and the newly mated
females leaves the cell with the emerging bee, moving to a new host bee to
continue the cycle.
For
feeding, the mites move to secluded locations on the bees' body where they are
difficult to detect visually. During the feeding stage mites may transfer to
other adult bees as the bees brush against each other in the hive. The feeding
stage may last for several days. The total development time for an individual
mite from newly laid egg through maturity and mating is 10.5 days. Most of the
races of Apis mellifera are good hosts for the Varroa mite because of the length
of the bees' pupa or post capping development time. This is typically about 12
days. In this time at least one mite can come to term in each cell. However,
some races of A. mellifera (e.g., the African bee, A.m. scutellata and the Cape
bee, A. M. capensis) have a shorter development time and fewer mites can come to
maturity.
Colony
Damage And Mortality
Individual
bees infested with Varroa are harmed in two ways - first, by loss of hemolymph,
which in it self is serious, and second, by the puncture wound, which allows
entry of infections and disease. Even in low infestations, bees suffer weight
loss and shortened life. If the per bee infestation is less than 6 mites, the
bee usually reaches maturity. Developing mites, therefore, also reach maturity.
However, the adult bees are weakened and their lives are shortened as much as
50%. Bees infested with a single mite during the brood stage can lose 6% to 7%
of adult weight. Bees infested with 6-8 mites during the brood stage can lose
25% of adult weight. However, many of these pupae never mature to emerge. Other
damage includes asymmetrical wings, misshapen legs, and shortened abdomens.
Drones have a reduced number of spermatozoa, reduced weight, and lesser
frequency of flight activity. The sum effect on a colony infested with Varroa is
that it is seriously harmed, and if no control measures are taken the colony
will die. Without beekeeper intervention, the probability of mortality is 10-15%
the first year, 20% to 30% the second year, and perhaps 100% in the third year.
At most, an untreated colony is unlikely to live more than five years after
infestation.
Detecting
Mites
Finding
mites by inspecting individual live bees is usually not successful. The mites
are very difficult to see on the bees, even with several mites present. They
blend in with the bee, and when not actively feeding they hide; some method of
removing the mites from the bees is necessary. Even then, mites may be difficult
to find in a light infestation.
Inspecting
Brood
Mites
are easier to detect on brood, especially when dealing with drone brood.
Uncapping and removing some of the drone pupae best do inspection. Very young
pupae are difficult to remove; they break up easily. Older pupae may be removed
from their cells identified by their eyes, which have color. The younger pupae
have little or no eye pigment. Once the cells of the older pupae have been
located, slide the points of the capping scratcher horizontally under the cells
capping so as to impale a number of brood at one time. Lift the capping and the
brood from the cells to inspect. If mites are present they should be obvious on
the white or light colored bodies of the pupae.
![[uncapping drone cells]](intere2.gif)
Figure
2 - Uncapping Drone Cells
A
capping scratcher, or uncapping fork, can be used to uncap cells and remove
immature honeybees. Older pupae are best to examine since they do not break
apart as easily as younger immature.
Examining
a few cells is not enough. A casual inspection should include at least 200 cells
(about 13 sq. in.), but at the height of colony development, about 450 cells
(about 28 sq. in.) need to be examined to identify a mite infestation of 1% at
an accuracy of 99%.
A
method to help detection is to place a frame of drone foundation in the brood
area. This will serve to concentrate a large number of drone brood in one place.
Drone foundation is available from some bee supply sources. Otherwise, you can
place some damaged comb in the brood area, which the bees will probably rebuild
as drone comb.
Inspecting
Adult Bees
Following
are two methods for testing adult bees for mites. These methods are most
effective in the late season when mites are more concentrated on the adult bees,
although they do not give good results with light infestations. *The Ether Roll
is relatively simple and uses a mini- mum of equipment. Required are a glass jar
of about 12 to 16 once with a tightly fitting lid, and a pressure can of ether
(such as automobile starter fluid). Place at least 500 live bees in the jar.
Crack the lid and give them a one second shot of ether. Seal, tilt the jar on
its side, and roll the contents. Moisture will form on the inside of the jar and
after twenty to thirty seconds, if mites are present, they will appear adhering
to the film of moisture as the jar is rolled. Do this test quickly, and then
dump the bees on a clean, exposed surface. They may recover. *The shaking method
is similar to the ether roll. Place a quantity of bees in a jar of alcohol,
detergent, diesel fuel, gasoline or even hot water. Shake vigorously for about
one minute. If mites are present on the bees, they will fall off. Sieve out the
bees and then strain the liquid and look for mites.
Using
Inserts
Bottom
board inserts are commonly used in detecting mite infestations. These can be
purchased, though many beekeepers make their own board. The inserts comprise two
parts - a sheet of sticky paper or cardboard which covers the entire bottom
board, and a screen that covers the sticky paper and serves to keep bees and
larger hive debris off. The screen is raised slightly above the paper and is of
a size that prevents the bees from passing through it. Mites, which are killed
or stunned by appropriate hive treatment, Oxalic Acid aerosol, for instance,
will fall to the bottom of the hive, pass through the screen, and be caught on
the paper. The screen should be of fine enough mesh to pass mites while
retaining the bulk of other debris, but at the same time the debris should not
be allowed to accumulate and prevent the mites from falling through.
The Varroa Mite
MICSCAPE - Article- Varroa (Bee mite and
parasite)
Varroa
jacobsoni
varroa mite - Varroa jacobsoni Oudemans
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