There is no question that
herbivores and plants have a very direct intimate relationship. Early in elementary school we learn
herbivores are animals that eat plants. What we didn't learn is how complex
that seemingly simple relationship is. Plants actually have evolved in response
to herbivorous pressures. Some plants have developed trichomes, tiny hairs on
the plant's stem, that can impale any insect that tries to land on it or even secrete
sticky compounds (Gurvitch, et al, 2006). Other plants have developed tough, thick
leaves and stems to deter herbivores from eating it. Some plants even create
toxic compounds. An example of this is the wild tobacco plant. It creates a
very well known toxin, nicotine, that poisons anything that tries to eat it
(Cahill, 2015). However, herbivores also adapt to plants' adaptations. The hornworm
caterpillar is unaffected from nicotine and can munch away on wild tobacco, but
the complex relationship doesn't stop there. The plant then releases a chemical
that alerts caterpillar predators of the caterpillars’ location (Cahill, 2015).
Herbivory is also incredibly variable. Many herbivores will eat enough of the
plant to kill it, while others browse sparingly on each individual plant. With
all of this complexity occurring, what happens when fire is introduced into the
relationship?
Picture 1: Hornworm caterpillar on wild tobacco plant. Taken from smithsonian.com
Picture 2: Bison grazing with fire in the background. Taken from wikimedia.com
Although
it appears many plants are more susceptible to herbivory following a fire, this
is not always the case. Just like in response to any environmental pressure,
plants evolve. One specific example came from a study about extrafloral
nectaried shrubs and their relationship with ants. In burned areas the shrub
was more susceptible to herbivory, but this shrub had a defense. Following
fires, the plants stress raised, which lead to more concentrated extrafloral
nectar. The new stronger nectar was much more enticing to ants (51.7% higher to
be exact). With more ants on the shrub, the lower the rate of herbivory, which
helps combat the usual higher rate following a fire (Alves-Silva & Del-Claro, 2013).
Fire
doesn't always just affect rate of herbivory. Often herbivores and fire have
similar effects on a plant community, and sometimes even work together. Hickman's
study showed that grazing reduced stem density, and woody species that would outcompete
grasses in the prairie. She concluded that, "large grazer densities, fire, and annual climatic
variability interact to influence patterns of plant community composition and diversity
in tallgrass prairie"(Hickman et al, 2003). In Europe heathlands, fires create
disturbance and lower nutrients, while herbivores are main factor controlling
the sensitive heath systems (Hobbs & Gimingham, 1987). Together, they help
reduce trees and larger shrubs from overtaking the landscape. The last example
of herbivores and fire working together is in the African savanna. The study
showed that while both fire and grazers helped reduce tree density
individually, only working together do they create such a low tree density that
leads to the coexistence of trees and grasses seen in the savanna (Staver et
al, 2009).
Picture 3: Heathland burring. Taken from JNCC.gov.uk
Picture 4: Antelope standing near fire in African savanna. Take from Jacques Jangoux
Often,
this dual effect of fire and grazers working together creates a large increase
in invertebrate levels, which of many are also herbivores. In the prairies, in
sites where bison had grazed and fire had influenced the landscape, 45% more
grasshopper species were found (Joern, 2005). In Arizona, areas that had been
burned with intermediate intensity and moderately grazed by elk saw a 40% in
abundance of invertebrates. However, in areas with high intensity fires and
heavy elk grazing, there was a 72% lower abundance (Bailey & Whitham, 2002).
Although there is often increase in invertebrates following grazing and fires,
this shows that sometimes there can be too much of a good thing and we are
still far from understanding the complexity of the systems around us.
While
fire's effect on herbivore-plant relationships and how they often work together
have been discussed, herbivores themselves can actually inversely affect fire
and the plant communities. A study done by Kramer, showed that ungulates help
reduce fuel load, regardless of density, and help reduce both the occurrence
and intensity of fires (Kramer et al, 2003). Again, this further shows the
complexity and the unknown of the interactions between fire, herbivores, and
plants.
Works Cited
Alves-Silva,
E., & Del-Claro, K. (2013, April 28). "Effect of post-fire resprouting
on leaf fluctuating asymmetry, extrafloral nectar quality, and
ant–plant–herbivore interactions."
http://link.springer.com/article/10.1007/s00114-013-1048-z
Bailey,
J., & Whitham, T. (2002, June 1). "INTERACTIONS AMONG FIRE, ASPEN, AND
ELK AFFECT INSECT DIVESRSITY: REVERSAL OF A COMMUNITY RESPONSE." http://onlinelibrary.wiley.com/doi/10.1890/0012-9658(2002)083%5B1701:IAFAAE%5D2.0.CO;2/full
Cahill,
J.C. (2015, October 15). PBS. "What Plants Talk About." https://www.youtube.com/watch?v=CkUoVyzPEak
Gurevitch,
J., Scheiner, S. M., & Fox, G. A. (2006). The Ecology of Plants. [pgs.
265-269] Sunderland, MA: Sinauer Associates.
Hickman,
K., Hartnett, D., Cochran, R., & Owensby, C. (2003, March 14).
"Grazing management effects on plant species diversity in tallgrass
prairie." http://www.bioone.org/doi/abs/10.2111/1551-5028(2004)057[0058:GMEOPS]2.0.CO;2
Hobbs,
R., & Gimingham, C. (1987). "Vegetation, Fire and Herbivore
Interactions in Heathland." http://www.sciencedirect.com/science/article/pii/S0065250408600884
Joern,
Anthony. (2005, April 1). "DISTRUBANCE BY FIRE FREQUENCY AND BISON GRAZING
MODULATE GRASSHOPPER ASSEMBLAGES IN TALLGRASS PRAIRIE." http://onlinelibrary.wiley.com/doi/10.1890/04-0135/full
Kramer,
K. Groen, T., & Van Wieren, S. (2003, August). " The interacting
effects of ungulates and fire on forest dynamics: an analysis using the model
FORSPACE." http://www.sciencedirect.com/science/article/pii/S0378112703001348
Moreno,
J., & Oechel, W. (1990, April 30). "Fire intensity and herbivory
effects on postfire resprouting of Adenostoma fasciculatum in
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Staver,
A., Bond, W., Stock, W., Rensburg, S., & Waldram, M. (2009, October 1).
"Browsing and fire interact to suppress tree density in an African
savanna." http://onlinelibrary.wiley.com/doi/10.1890/08-1907.1/full
Vinton,
M., Hartnett, D., Finck, E., & Briggs, J. (1993, January). "Interactive Effects of Fire,
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