Among honey bee pathogens, viruses are one of the most
major threats to the health and well-being of honey bees and cause serious
concern for researchers and beekeepers.
Viruses were first identified as a new class of pathogens
infecting honey bees when at the beginning of the 20th century, a US scientist
discovered that a filterable agent from diseased bee larvae could cause
sacbrood disease in the honey bee. Since then, at least 18 viruses have
been reported to infect honey bees worldwide. Understanding of these virus
infections has grown considerably over the last three decades. Symptoms
of disease, such as paralysis, have been used as diagnostic markers for
different viruses. However, it has been established that different strains
of the same virus and environmental factors can contribute to make this
form of diagnosis unreliable at best. In addition, the fact that many
apiaries have multiple viruses makes this form of differentiation between
viruses obsolete. Thus, developing simple, alternative diagnostic methods
has become has become a top priority.
Viruses are obligate intracellular parasites that can
only multiply inside living host cells utilizing the host cell's metabolic
machinery. Honey bee viruses usually enter the host through the alimentary
tract during feeding or trauma on the body surface, though they can also
directly enter the blood circulation via bites by varroa mites or other
insects. In order to survive, viruses must have ways to invade hosts and
be transmitted from one host to another. Although bee viruses multiply
abundantly and fatally when injected into bee hemolymph, the initial infection
site of most honey bee viruses usually occurs through the cuticle by direct
contact between healthy and infected bees or in the alimentary tract when
bees ingest virus-contaminated food. Viruses can attack at different development
stages and castes of the honey bees, including eggs, larvae, pupae, adult
worker bees, adult drones, and queen of the colonies. The densely crowded
populations and high contact rate between colony members provide an ideal
environment for transmission of pathogens. They are transferred both horizontally
(between bees, through infested food/ feces or vectored by hive pests,
predominantly varroa mites), or vertically (transferred from queen to
offspring).
Although bee viruses usually persist as unapparent infections
and cause no overt signs of disease, they can dramatically affect honey
bee health and shorten the lives of infected bees under certain conditions.
Since both horizontal and vertical transmission pathways have been demonstrated,
they represent important survival strategies for viruses. Indeed, viruses
choose the appropriate transmission pathway based on the developmental,
physiological, ecological, and epidemiological conditions that abound.
When colonies are under noncompetitive and healthy conditions, viruses
may remain in bee colonies via vertical transmission and exist in a persistent
or latent state. However, under stressful conditions, such as infestation
of varroa mites, coinfection of other pathogens such as N. apis, or decline
in food supply, viruses switch to horizontal transmission and start to
replicate. Other environmental factors, such as cold temperature and unfavorable
flying conditions for long periods of time that keep all the bees in their
hives may create similar circumstances. For example, this may lead to
in-hive fecal deposition from the bee gastrointestinal tract, a major
source of replicating viruses in the bee, which can be a major cause of
rapid spread of disease within the community. High numbers of produced
virions then become much more infectious, leading to the death of hosts
and possible collapse of the whole bee colony.
Some of the more common viruses that infect honey bee colonies include:
A. Deformed Wing Virus (DWV)
DWV is one of a few bee viruses that cause well-defined disease symptoms
in infected bees. Typical disease symptoms of DWV infection include
shrunken, crumpled wings, decreased body size, and discoloration in
adult bees. However, the mechanism by which the DWV causes the morphological
deformities of the infected hosts is unclear. Adult honey bees infected
with DWV usually appear normal but are believed to have a reduced life
span. In addition, it has been shown that DWV infected bees have impaired
learning capabilities. DWV has been shown to be one of the most prevalent
infections in honey bees in recent years, and is known to be transferred
by the varroa mites. Studies of DWV status in varroa showed that it
was present in up to 100% of mites surveyed.
B. Sacbrood Virus (SBV)
SBV attacks both brood and adult stages of bees, but larvae about two
days old are most susceptible to SBV infections. SBV affects adult bees
without causing obvious signs of disease, but as in other viral infections,
the infected adult bees may have a decreased life span. The initial
spread of SBV within a colony occurs when nurse bees become infected
while removing larvae killed by SBV. Virus particles accumulate in the
hypopharyngeal glands of the nurse bees and infected nurse bees can
then spread the virus throughout the colony by feeding larvae with their
glandular secretion and exchanging food with other adult bees, including
foraging bees. Infected foraging bees spread the virus by passing it
from their glandular secretions to the pollen loads as they collect
pollen. Young larvae become infected with the virus by ingesting virus-contaminated
food. A large amount of fluid containing millions of SBV particles accumulates
between the body of a diseased larva and its saclike skin. Affected
larvae appear to be water-filled sacs when removed from the cell.
Prevalence of SBV in honey bees has been found to be prominently seasonal.
During the spring and summer, the rich sources of pollen and nectar
stimulate brood rearing and a great number of new workers hatch from
the brood cells, providing opportunities for SBV to attack bees and
multiply in the colonies. Just as in DWV, SBV is found in and vectored
by varroa mites.
C. Black Queen Cell Virus (BQCV)
BQCV was first isolated from dead queen larvae and prepupae sealed in
their cells that had turned dark brown to black, along with the walls
of the cell, hence the designation of the name. BQCV mainly affects
developing queen larvae and pupae in the capped-cell stage. It too is
extremely common, second only to DWV. BQCV disease outbreak has been
linked with infection of a protozoan, Nosema apis. Although this positive
association between the BQCV and N. apis infections has been documented
in the field observations, definite experimental evidence for deciphering
cause and effect have yet to be determined.
D. Kashmir Bee Virus (KBV)
KBV was detected in honey bees collected from Australia in 1979. It
attacks all stages of the bee life cycle and commonly persists within
brood and adult bees as an unapparent infection. The disease and mortality
caused by KBV infection occurs in different developing stages of bees
without clearly defined disease symptoms. Among all of the viruses infecting
honey bees, KBV, like its almost indistinguishable relative Israeli
Acute Paralysis Virus, is considered to be the most virulent under
laboratory conditions. It multiplies quickly once a few viral particles
are introduced into the bee hemolymph and can cause bee mortality within
three days. KBV is also genetically, serologically, and pathologically
closely related to another bee virus Acute Bee Paralysis Virus. Infection
of KBV in honey bees resembles the infection caused by ABPV in several
ways. KBV usually persists as an unapparent infection in honey bees.
This virus is also efficiently vectored by varroa mites, but the mites
may also activate latent infection to a lethal level.
E. Acute Bee Paralysis Virus (ABPV)
Since its first identification, the presence of ABPV in honey bees of
A. mellifera has been reported in North America, Central and South America,
Europe, Oceania, Asia, Africa, and the Middle East. Spread of ABPV in
the colonies is probably via salivary gland secretion of infected adult
bees when glandular secretions are fed to young larvae or mixed in the
pollen. Infected larvae either die before they are sealed in brood cells
if large amounts of virus particles were ingested, or survive to emerge
as unapparently infected adult bees.
Viruses Summary
Phylogenetic analysis shows that KBV, APBV, and IAPV
are very closely related, as are DWV and SBV. This probably points to
common and recent ancestry. For example, KBV and IAPV are >95% identical,
except for a relatively small region of the genome that seems to have
been recently incorporated into IAPV (or alternatively discarded from
KBV).
A virus causes infection by invading host cells, multiplying new virions,
and exiting the host cell to attack others. As part of their survival
strategies, hosts have evolved effective mechanisms to defend against
viral invaders by employing multifaceted immune responses. Virulence
and pathogenesis are the consequences of the complex interactions between
the infecting virus and host immunity. While the humoral and cellular
immune responses to bacterial and fungal infections have been characterized
and documented in honey bees, relatively little is known concerning
how honey bees recognize and fight viral infections. The commonly observed
phenomenon that viruses persist in apparently healthy colonies as latent
infections is a good indication that honey bees have the innate ability
to resist the multiplication of virus infections.
Recent work has indicated that RNA interference (RNAi) is a natural,
conserved mechanism of antiviral immunity in plants, vertebrates, and
insects. RNAi is an RNA-dependent gene silencing process triggered by
a long double-stranded RNA (dsRNA). When dsRNA is introduced into a
cell, a specific RNaseIII endonuclease, Dicer, binds and cleaves dsRNA
to produce double-stranded fragments of 20-25 base pairs with 2-nt 3?
overhangs, called small interfering RNAs (siRNAs). The siRNAs are integrated
into the RNA-induced silencing complex (RISC) to activate the RISC.
Activated RISC bind to homologous mRNA and cause sequence-specific degradation
of the target mRNA. Positive-stranded RNA viruses are vulnerable to
RNAi because the viruses replicate their genomes through complementary
strands resulting in dsRNA replication intermediates. Since the genomes
of most honey bee viruses are positive-stranded RNA molecules, RNAi
is an important defense mechanism against viruses in honey bees.
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