AN
ADVANCED AQUARIST SHORT TAKE by ADAM BLUNDELL, M.S.
Sponsored
in part by:
Atlantic
Reef Herbivory
Lead
Author- Adam Blundell M.S., Salt Lake City, United States Research Associate- Silvia Martin, Hamburg, Germany
Fish
herbivory is often overlooked in the aquarium hobby. By understanding
the natural behavior of reef fishes aquarists can create better
ecosystems for their inhabitants. One of the critical categories
of behavior is feeding and foraging. This paper not only analysis
fish herbivory patterns, but also describes the important role
this knowledge plays in the home aquarium.
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Methods
Researchers
gathered and collected data along Bermuda islands. Data was
gathered at varying reefs surrounding the Bermuda island chain.
Many options for analyzing fish populations are available including
diver reconnaissance, videotape surveys, still-camera photography
(Putt et al, 1986). For this study diver reconnaissance using
twenty five square meter quadrats were set up at varying reefs.
Researchers took turn monitoring the quadrats, as they recorded
the numbers of fish and identified the fishes seen in those
areas. Divers also followed individual fish to record feeding
sessions and frequency. While this proved to be a very difficult
task, it did allow for direct observation. Identification was
done by collaboration, using the book Reef Fish Identification
2nd edition by Humann (1994). This book was selected
because of its clarity and resourcefulness, building upon the
first edition as a recommended identification book (Sea Frontiers
1992). Monitoring was also performed by following individual
fishes, and recording the time frame and number of foraging
events taking place.
A
picture of the reef system monitored in this study.
The
blue tang (Acanthurus coeruleus) is responsible for
much of the herbivory on Atlantic reefs.
Divers
equiped with cameras allow for direct observation and
future analysis of surveyed systems
Parrotfish
are important herbivores on nearly all reef systems.
This
picture shows how tape measure lines were used to define
25 square meter areas for analysis
Results
These
observations display characteristics in feeding patterns of
reef fish families. These patterns describe built in genetic
characteristics that guide the feeding of fishes, which of course
is tied directly into a fish's health. In this study, three
families of fishes were compared. The Scaridae (Parrotfishes),
Acanthurdae (Surgeonfishes, Tangs) and Pomacentridae (Damselfishes)
were all monitored, and grouped accordingly. These groupings
are useful since each family feeds differently; Scaridae being
"Scrapers", Acanthuridae being "Grazers" and Pomacentridae being
"Harvesters". Scrapers are fishes that swim over a reef and
physically remove the algae they eat by scraping it right off
of the substrate. Parrotfishes are known for this behavior as
they use their large beaks to scrape coral. Grazers differ from
scrapers in that grazers do not remove all of the algae, and
they leave the holdfast with the substrate. These fishes swim
on reefs eating the fronds of algae and then swim off. Harvesters
differ in that they do not swim along the reef, but rather defend
an area. These fishes will have homes on the reef where they
defend a patch of algae and use it for food. Interestingly enough,
fishes from different families often defend algal patches from
other fishes, but with selective defense. Some surgeonfishes
will not fight off some times of damselfishes (and visa versa)
even though they forage on the same food sources (Robertson
& Polunin, 1981). Figure 1 shows that Acanthurus coeruleus
(Blue Tang) is responsible for the most bites taken on a reef,
followed by Microspathodon chrysurus (Yellowtail Damselfish).
However, as a family, Parrotfishes account for the most bites
on the reef, simply because of the numbers of individual fishes.
This is displayed by combining the individual species in Fig
1 to create Fig 2. It is important to note that numbers of individual
fishes varies among reefs, exampled by Parrotfishes which are
at greatly higher numbers in protected areas as opposed to those
in highly fished reef systems (Alevizon et al, 1985). Higher
numbers of fishes can greatly impact the future development
of the reef. The herbivorous biting sessions described here
can cause great impact on fleshy algae, thus leading to a reef
dominated by crustose algae like Halimeda (McClanahan
et al, 2002).
Figure
#1
(click
for a larger view)
Figure
#2
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Interestingly
enough, the number of bites on the reef does not simply correlate
to the number of individual fishes. What we found in this study
is that species, and families, of fishes will engage in feeding
sessions (# of bites between breaks of at least 3 seconds).
Figure 3 shows how different species of fishes will continue
to bite in long sessions, or in short feedings bouts. This figure
shows Parrotfishes engaging in longer feeding sessions, followed
by Surgeonfishes, and finally Damselfishes, but all results
do not appear to be statistically significant or noteworthy,
at this time. While all of these herbivorous fishes contribute
to algal removal, the benefit to the corals is still difficult
to gauge. Algal removal may be aiding in increased coral growth,
but often times the herbivorous fishes responsible for this
are also the fishes eating the corals (Miller & Hay, 1998).
This statement is countered by studies showing that only one
Parrotfish species (Sparisoma viride) actively feeds
on live coral, while other parrotfishes feed on encrusted algae
or non-living reef structure (Frdyl, 1979).
Figure
#3
Conclusions
Different
families of fishes will spend different amounts of time feeding.
The number of bites taken on a reef is dependent upon the number
of bites a fish takes per minute, and the number of fishes on
the reef. Feeding patterns of the fishes observed showed at
least 4 bites per minute and averaged closer to 8 bites per
minute per fish. This is important because in many home aquariums
feeding is sporadic with a feast or famine type of mentality.
These fishes are naturally continuous grazers, and available
algal food is of great importance. Captive systems designed
to replicate natural environmental conditions must have an abundance
of algal growth.
The
Stoplight Parrotfish is a very common herbivore on the
reef.
Although
all parrotfish have been reported as coralivores, other
studies have shown that only S. viride (the Stoplight
Parrotfish) is the only parrotfish that eats living
coral tissue.
The
Stoplight Parrotfish (Sparisoma viride) is easily recognizable
with its brightly yellow patterned tail.
Although
many herbivorous reef fishes are territorial, often
times these reef fishes live peacefully with each other.
A
photo of the primary researchers in this project Adam
Blundell and Silvia Martin.
Acknowledgements
The
first person I would personally like to thank is Silvia Martin.
Silvia is an excellent biologist and was crucial in the development
of the data used in this project. I would also like to thank
the rest of the Coral Reef Ecology team who helped with the
data collection and monitoring of the reefs used in this study.
A special thanks is owed to the Advanced Aquarist Online Magazine
for their support and publication of this study. Varying individuals,
institutions, and funding sources were used, and all were of
absolute importance to the completion of this project. My personal
thanks to Exxon Mobile for their contributions.
About
the Author
Adam
Blundell M.S. works in Marine Ecology, and in Pathology for
the University of Utah. While not in the lab he is the president
of one of the Nation's largest hobbyist clubs, the Wasatch Marine
Aquarium Society (www.utahreefs.com). He is also Director of The
Aquatic & Terrestrial Research Team, a group which utilizes
research projects to bring together hobbyists and scientists.
His vision is to see this type of collaboration lead to further
advancements in aquarium husbandry. Adam has earned a BS in
Marine Biology and an MS in the Natural Resource and Health
fields. Feedback is welcomed at adamblundell@hotmail.com.
References
Alevizon, W.,
Richardson, R., Pitts, P., Serviss, G., (1985) "Coral
Zonation and Patterns of Community Structure in Bahamian
Reef Fishes", Bulletin-of-Marine-Sciences; 36(2):304-318.
Frdyl, P.,
(1979) "The Effects of Parrotfish Scaridae on Coral in
Barbados West-Indes", Internationale Revue der Gesamten
Hydrobiologie;64(6):737-748.
Humann, Pl,
(1994) " Reef Fish Identification Florida Caribbean Bahamas
2nd edition", New World Publications, Jacksonville,
FL.
Mclanahan,
T.R., Uku, J.N., Machano, H., (2002) "Effect of Macroalgal
Reduction on Coral-Reef Fish in the Watamu Marine National
Park, Kenya", Marine and Freshwater Research; 53(2):223-231.
Miller, M.W.,
Hay, M.E., (1998) "Effects of Fish Predation and Seaweed
Competition on the Survival and Growth of Corals", Oecologia;113(2):231-238.
Putt, R.E.,
Gettleson, D.A., Phillips, N.W., (1986) "Fish Assemblages
and Benthic Biota Associated With Natural Hard-Bottom Areas
in the Northwestern Gulf of Mexico", Northeast Gulf
Science; 8(1):1-64.
Robertson,
D.R., Polunin, N.V.C., (1981) "Coexistance Symbiotic
Sharing of Feeding Territories and Algal Food by Some Coral
Reef Fishes From the Western Indian Ocean", Marine Biology,
Berlin;62(2-3):185-196.
Sea Frontiers,
(1992) "Coral Watch", Book & Product Review-
REEF Coral Identification. International Oceanographic Foundation,
Sea Frontiers; November 1992, Vol. 38, Issue 6, pg 64.
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