We
currently live in an era of mass extinction, where many species around the
world are at high risk of being lost forever, and among these species, amphibians
are at much higher risk of extinction than any other (Wake and Vrendenburg,
2008). This comes from a combination of many factors, including climate change,
habitat destruction and human land use, the presence of invasive species, and
as we’ll be looking at here: the fungal infection chytridiomycosis.
Chytridiomycosis
is a skin disease caused by a chytrid fungus, either Batrachochytrium dendrobatidis (Bd), or Batrachochytrium salamandrivorans (Bsal). Though these fungi may be small, they are a big deal when it
comes to the health and stability of amphibian populations. They have been implicated
for the heavy decline or even outright extinction of a large number of
amphibian species, making it potentially the most impactful wildlife disease
known (Scheele et al., 2014). These
fungi have a number of traits that make it easy for them to spread to
amphibians. One such trait is the ability to reside within a host without
causing infection, using it as a reservoir from which it can spread to
more vulnerable species (Fisher, 2017). This can be seen in the example of the
midwife toad and alpine newt, which are carriers for Bsal, and can lead to infection of fire salamander populations.
Figure 1: Potential pathways for the spread of Bsal in Europe, from Fisher 2017. |
The
zoospores of these fungi also have two forms which contribute to their spread
among amphibian population. The first is the motile aquatic form, which allows
them to establish infection during the tadpole stage (Fisher, 2017). The second
is the non-motile form, called an encysted spore, which has a thick cell wall,
and are highly resilient. These encysted spores are capable of persisting in
the environment while retaining their infectiousness, without needing a host at
all for a long period of time. And if that wasn’t enough, it could be the case that birds can act as carriers for these encysted spores,
bringing the fungus to new locations and further contributing to the spread of
disease over larger distances. As noted by Fisher et al. (2017), it really does seem like
amphibians really are in peril from a perfect pathogen. But what exactly do
these fungal infections do to amphibians that make it such a problem?
Amphibians
are cutaneous respirators. They “breathe” through their skin, allowing them to
maintain the correct osmotic balance of electrolytes and water within the body.
This is what makes chytrid fungi such a unique threat to amphibians. To other
organisms the development of a cutaneous chytrid infection is usually not a big
deal, but to amphibians it can directly interfere with their ability to respire
(Voyles et al., 2009). The ensuing
loss of electrolytes impairs the ability of the heart to function, blood flow
to the rest of the body is reduced, and cardiac arrest leads to death as a
result of complete collapse of the circulatory system. However, even before
that occurs, the now physically impaired and lethargic individual is likely to
become a victim of predation or a combination of other stressors as well. As an
example of the potential severity of this disease, fire salamanders in the
Netherlands that were infected with Bsal
experienced a mortality rate of over 96% (Fisher, 2017). A very morbid and unfortunate
situation our amphibian friends find themselves in.
Normally,
the mucus layer present on the skin of amphibians contains a number of
antimicrobial peptides and lysozymes, as well as symbiotic bacteria which all
contribute to innate defenses against invading pathogens (Rollins-Smith et al., 2011). Amphibians have also shown
to be capable of developing an acquired immune response to chytrid fungi after
exposure, with some even developing Bd
specific antibodies. So then why is chytridiomycosis such a problem for
amphibians? The answer appears to be because chytrid fungi are capable of
suppressing immune responses in many species before these defenses are capable
of protecting against infection (Ellison et
al., 2014). Other environmental stressors can also interfere with the
ability of amphibians to mount an appropriate immune defense. Lack of food
resources, temperature stress, or exposure to chemicals like pesticides can all
increase the likelihood of fungal infection (Rollins-Smith et al., 2011). Furthermore, the amphibian life cycle itself can
impair the ability of an individual to resist infection. When a tadpole
undergoes metamorphosis into an adult, the immune system also goes through a
drastic transition to maturity. This period of time provides an opening for
infection to develop while the defenses of the amphibian aren’t at full
capacity. Ultimately, this means that the ability for a species of amphibian to
defend against chytrid fungi varies heavily based on the level of innate and
acquired defenses mounted, the health of the habitat, the climate, and what
part of the life cycle the species in question is in.
It is abundantly clear that amphibian
populations are in great danger as a result of this disease outbreak, so the
obvious follow-up question is what can we do about this ongoing threat? While
there is no silver bullet for stopping chytridiomycosis outright, there are a
number of potentially promising forms of intervention that could help to bring
mortality rates down to less extreme levels. In short-term or small scales, the
direct treatment of individuals with antifungals is shown to be an effective
method of temporarily controlling an outbreak, but more long-term measures are
needed to ensure success in restoring populations (Garner et al., 2016). Scheele et al.
(2014) provide a framework of three potential classes of action to protect
amphibians from fungal infection. The first class is Environmental Manipulation.
As mentioned previously, there are a number of environmental factors that
influence the chance of successful infection. Reducing the presence chemical
pollutants can reduce stress on amphibian populations are lower infection
rates. The creation of warm regions in the habitat, such as warm pools of
water, areas of high sun exposure to bask in, or the introduction of artificial
heat sources can also allow species to initiate behavioural fever, raising
their body temperature to levels that are no longer ideal for chytrid fungi to
survive. Finally, methods such as bio-augmentation, which involves introducing
microbes with the ability to inhibit chytrid fungi to the environment, can
potentially provide an ecosystem-wide treatment, so long as proper testing is
done to ensure that this will not
negatively impact the environment in any way.
Artificial ponds for
the captive breeding of the endangered Pseudophryne
corroboree.
(Figure 2 from
Scheele et al., 2014)
|
When
manipulation is not a reasonable solution, the Amphibian Introduction class is
next in line. This involves the translocation of amphibian populations to
refugia: environments that are ideal for the species, but poor for chytrid
fungus. This method does require that it is ensured that this translocation
will not cause any impacts in the new environment. Alternatively, captive bred
amphibians can be added to wild populations in order to increase the buffering
capacity of the ecosystem, allowing higher likelihood of survival for a
population even after an chytrid epidemic. Finally, failing the previous two
classes, the last class is Ex-Situ Conservation, which involves keeping
colonies in captivity. Infected individuals are treated with chemicals or heat
to kill the fungus, and individuals are bred in order to improve resistance
among the population while maintaining genetic diversity (Scheele et al. 2014).
While
these treatments are still in development and have not been used in proper
field tests yet, they definitely have the potential to rescue amphibian
populations. However, the fact remains that many amphibians around the world
are critically imperilled, so there is clear need for feasibility research as
soon as possible if we want to prevent any more extinctions. The loss of mass
amounts of amphibians could lead to huge impacts on many ecosystems around the
world, and it is all but guaranteed to happen unless we take action.
Literature Cited:
Ellison AR et al. 2014. Fighting a Losing Battle:
Vigorous Immune Response Countered by Pathogen Suppression of Host Defenses in
the Chytridiomycosis-Susceptible Frog Atelopus
zeteki. G3-Genes Genom Genet 4(7): 1275-1289.
Fisher MC. 2017. Ecology:
In peril from a perfect pathogen. Nature 544(7650): 300-301.
Garner TWJ et al. 2016. Mitigating amphibian
chytridiomycoses in nature. Philos T Roy Soc B 371(1709).
Rollins-Smith LA et al. 2011. Amphibian Immune Defenses
against Chytridiomycosis: Impacts of Changing Environments. Integr Comp Biol
51(4): 552-562.
Scheele BC et al. 2014. Interventions for Reducing
Extinction Risk in Chytridiomycosis-Threatened Amphibians. Conserv Biol 28(5):
1195-1205.
Voyles J, et al. 2009. Pathogenesis of
Chytridiomycosis, a Cause of Catastrophic Amphibian Declines. Science
326(5952): 582-585.
Wake DB and Vredenburg
VT. 2008. Are we in the midst of the sixth mass extinction? A view from the
world of amphibians. P Natl Acad Sci USA 105(1): 1466-1473.
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