FEED YOUR CORALS IT IS THE NATURAL WAY
By Ronald L. Shimek
Feeding of corals, and other cnidarians as well, has been a rather contentious issue in the reef aquarium literature within the past several years. Similar arguments have been found in the scientific literature.
Consequently, in writing this article, I wished to document reasonably well the points I made. The reader may be tempted to recall the old saying, "If you can't bedazzle them with your brilliance, baffle them with your bs." However, such was not the intent; rather the excessive number of references is meant to be illustrative of the available data and an indication of how much work has been done. I have not - honestly - tried to list every reference, literally thousands of papers have been published that bear in some regard on the topic. Rather for those readers who wish to pursue this topic further, I have tried to provide some important benchmarks.
Aquarists that keep marine tanks generally either have fish-only tanks or tanks containing some inhabitants of coral reefs. Generally, the latter types of tanks contain some corals. These are animals regarded by biologists as belonging in the phylum Cnidaria. Over the years, a significant mythology and body of misinformation has built up in the aquarium hobby about the nutritional requirements of such animals.
In my discussions of animals in this medium, and elsewhere, I have always taken the tack that "nature's way is the best way." In other words, animals will always do better under the best of natural conditions. In this article, I would like to discuss the nutritional requirements of corals based on their natural foods and food sources "as we understand them". The latter phrase is a rather critical one as much research in this field is ongoing, and in some instances the data are "subject to change without notice." In addition, there is a second problem with discussing nutrition in the Cnidaria, and that is the unwarranted assumption of uniformity throughout the group.
The phylum Cnidaria is truly a very successful and very diverse group. However, there is an underlying simplicity of body form and structure, and as a result there is a tendency to regard all members of any given group as similar. In other words, one often hears the statements like, "Corals need..." implying that all corals are alike. Such statements often have a grain of truth in them - along with a significant amount of untruth, and it is often very hard to separate the two.
-Nutritional Morphology
The basic morphology of any stony coral is pretty simple. They have a bag or sack-like body with a single internal opening into the gut. Most of them have tentacles around the mouth, and they possess nematocysts which are used to catch, subdue, and kill prey. Nematocysts are often called "stinging cells," but this is an incorrect name, as they are not cells, but are non-living structures produced by cells.
-Nematocysts
Nematocysts are typically small structures consisting of a capsule enclosing an internal space. In this space is a fluid, and a thread-like tube which is turned inside-out projecting into the fluid-filled space in the capsule. In some way that is not totally understood, there is a significant internal pressure contained within the nematocyst capsule. This pressure has been estimated to be about the equivalent of 2200 pounds per square inch or about 155 kilograms per square centimeter. This is an immense pressure for containment in a biologically produced structure and it appears to be created and maintained by a difference in osmotic or ionic balances inside and outside the nematocyst capsule.
Nematocysts can be considered to be biologically-secreted explosive devices specialized to project their internal thread out at exceptionally high velocity. In most nematocysts the thread is hollow, and the cellular contents, which often include some toxins, are ejected from it. Nematocysts are fired by the application of an appropriate stimulus to the capsule. That stimulus seems to vary, from species to species, time to time, and probably from nematocyst type to nematocyst type. Some nematocysts discharge in response to physical contact, some in response to chemical stimulus, some in response to nervous stimulation, and many in response to combinations of other stimuli (Ruppert and Barnes, 1994).
Over 25 different kinds of nematocysts have been described. Generally each major cnidarian group, such as corals, contains several different kinds, and often some distinctive varieties. These nematocysts are distributed differently in the various species, and are often used as a taxonomic character to differentiate groups. The quantity of nematocysts found in the tentacles of cnidarians can be exceptionally large; in the tentacles of some sea anemones or jellyfishes, it is not unusual to find over 10,000 nematocysts per square millimeter (an area about 1/25th of an inch on a side). After nematocysts are used in capturing or killing prey, or after they get too old, they are discarded and new ones are secreted. Given that even a small cnidarian may require millions of nematocysts to capture even a small prey animal, it is obvious that the production of nematocysts is an important part of the metabolism of any cnidarian. It also requires a lot of energy.
-The Gut
Although the basic cnidarian gut is a simple bag, the gut in stony corals is a complex structure with internal divisions formed by tissue walls or septa dividing the basic bag-like gut into sections. These septa extend from the body wall into the bag dividing it like slices of a pie.
This type of gut is found in corals and sea anemones. A few simple corals and sea anemones may have only a few sections, but most have many more and in complex corals and large sea anemones there can be from several hundred to several thousand "pieces of the pie."
The coral skeleton is deposited on by the outside tissues of the body, but these follow the inner folds quite closely, and an indication of the complexity of the coral gut structure can be seen in the examination of coral skeletal cups (See Veron, 1986, for many good examples).
In most corals and sea anemones there are internal tentacles called gastric filaments arising from the edges of these septa. These tentacles are often loaded with nematocysts to subdue prey, and other nematocysts which fasten the filaments to the prey. Digestion occurs in the tiny spaces between the filaments and the prey's body surface. So, although the basic cnidarian gut is simple in concept, it is decidedly more complex in reality. Such complex structures are also metabolically expensive to produce and maintain.
-Zooxanthellae
The next structures related to nutrition in corals are not really part of the animals in which they are found. These structures are zooxanthellae. Zooxanthellae are single-celled algae which live inside of some other organism. Many different types of organisms possess zooxanthellae, including some sponges, some protozoans (so there are single-celled organisms which have other single-celled organisms living in them!), some flatworms, and a few other animals. However, zooxanthellae are found living in rather large number of cnidarians including all reef-forming or hermatypic corals.
The relationships with zooxanthellae are presumed to be symbiotic. The anemone or coral that hosts the zooxanthellae in its tissues supposedly benefits from the photosynthetic production of the algae, and the algal cells presumably benefit by receiving protection and possibly some organic nutrients such as amino acids or ammonia from the cnidarian. The algal cells are typically found living in their hosts gastrodermal tissue, close to gut lining, and typically the algal populations are quite dense.
Zooxanthellae are dinoflagellate algae, and like all good algae they are photosynthetic, capable of making organic nutrients from light, water, and carbon dioxide. The process of photosynthesis creates only sugars, but the algal cell can use those sugars to build other materials such as fats (Al-Moghrabi et al., 1995). If the alga has access to nitrogen containing compounds such as ammonia or amino acids, it can also build proteins and other structural molecules, using the sugars as fuel for this process (Szmant-Froelich, and Pilson, 1984).
Algal cells are notoriously "leaky" and up to about 40 percent of the photosynthate produced by algae leak out into the surrounding medium (Lewis and Smith 1971). If the algal cells are living in an coral, the coral tissues can utilize this material as food, or as an organic nutrient for some other function such as building their skeleton. Coral skeletons are often thought of as being composed only of calcium carbonate, but actually, they have an organic matrix and the calcium carbonate mineral is deposited on this. So, if the organic matrix is lacking or reduced, skeleton production cannot occur.
(CONT)
By Ronald L. Shimek
Feeding of corals, and other cnidarians as well, has been a rather contentious issue in the reef aquarium literature within the past several years. Similar arguments have been found in the scientific literature.
Consequently, in writing this article, I wished to document reasonably well the points I made. The reader may be tempted to recall the old saying, "If you can't bedazzle them with your brilliance, baffle them with your bs." However, such was not the intent; rather the excessive number of references is meant to be illustrative of the available data and an indication of how much work has been done. I have not - honestly - tried to list every reference, literally thousands of papers have been published that bear in some regard on the topic. Rather for those readers who wish to pursue this topic further, I have tried to provide some important benchmarks.
Aquarists that keep marine tanks generally either have fish-only tanks or tanks containing some inhabitants of coral reefs. Generally, the latter types of tanks contain some corals. These are animals regarded by biologists as belonging in the phylum Cnidaria. Over the years, a significant mythology and body of misinformation has built up in the aquarium hobby about the nutritional requirements of such animals.
In my discussions of animals in this medium, and elsewhere, I have always taken the tack that "nature's way is the best way." In other words, animals will always do better under the best of natural conditions. In this article, I would like to discuss the nutritional requirements of corals based on their natural foods and food sources "as we understand them". The latter phrase is a rather critical one as much research in this field is ongoing, and in some instances the data are "subject to change without notice." In addition, there is a second problem with discussing nutrition in the Cnidaria, and that is the unwarranted assumption of uniformity throughout the group.
The phylum Cnidaria is truly a very successful and very diverse group. However, there is an underlying simplicity of body form and structure, and as a result there is a tendency to regard all members of any given group as similar. In other words, one often hears the statements like, "Corals need..." implying that all corals are alike. Such statements often have a grain of truth in them - along with a significant amount of untruth, and it is often very hard to separate the two.
-Nutritional Morphology
The basic morphology of any stony coral is pretty simple. They have a bag or sack-like body with a single internal opening into the gut. Most of them have tentacles around the mouth, and they possess nematocysts which are used to catch, subdue, and kill prey. Nematocysts are often called "stinging cells," but this is an incorrect name, as they are not cells, but are non-living structures produced by cells.
-Nematocysts
Nematocysts are typically small structures consisting of a capsule enclosing an internal space. In this space is a fluid, and a thread-like tube which is turned inside-out projecting into the fluid-filled space in the capsule. In some way that is not totally understood, there is a significant internal pressure contained within the nematocyst capsule. This pressure has been estimated to be about the equivalent of 2200 pounds per square inch or about 155 kilograms per square centimeter. This is an immense pressure for containment in a biologically produced structure and it appears to be created and maintained by a difference in osmotic or ionic balances inside and outside the nematocyst capsule.
Nematocysts can be considered to be biologically-secreted explosive devices specialized to project their internal thread out at exceptionally high velocity. In most nematocysts the thread is hollow, and the cellular contents, which often include some toxins, are ejected from it. Nematocysts are fired by the application of an appropriate stimulus to the capsule. That stimulus seems to vary, from species to species, time to time, and probably from nematocyst type to nematocyst type. Some nematocysts discharge in response to physical contact, some in response to chemical stimulus, some in response to nervous stimulation, and many in response to combinations of other stimuli (Ruppert and Barnes, 1994).
Over 25 different kinds of nematocysts have been described. Generally each major cnidarian group, such as corals, contains several different kinds, and often some distinctive varieties. These nematocysts are distributed differently in the various species, and are often used as a taxonomic character to differentiate groups. The quantity of nematocysts found in the tentacles of cnidarians can be exceptionally large; in the tentacles of some sea anemones or jellyfishes, it is not unusual to find over 10,000 nematocysts per square millimeter (an area about 1/25th of an inch on a side). After nematocysts are used in capturing or killing prey, or after they get too old, they are discarded and new ones are secreted. Given that even a small cnidarian may require millions of nematocysts to capture even a small prey animal, it is obvious that the production of nematocysts is an important part of the metabolism of any cnidarian. It also requires a lot of energy.
-The Gut
Although the basic cnidarian gut is a simple bag, the gut in stony corals is a complex structure with internal divisions formed by tissue walls or septa dividing the basic bag-like gut into sections. These septa extend from the body wall into the bag dividing it like slices of a pie.
This type of gut is found in corals and sea anemones. A few simple corals and sea anemones may have only a few sections, but most have many more and in complex corals and large sea anemones there can be from several hundred to several thousand "pieces of the pie."
The coral skeleton is deposited on by the outside tissues of the body, but these follow the inner folds quite closely, and an indication of the complexity of the coral gut structure can be seen in the examination of coral skeletal cups (See Veron, 1986, for many good examples).
In most corals and sea anemones there are internal tentacles called gastric filaments arising from the edges of these septa. These tentacles are often loaded with nematocysts to subdue prey, and other nematocysts which fasten the filaments to the prey. Digestion occurs in the tiny spaces between the filaments and the prey's body surface. So, although the basic cnidarian gut is simple in concept, it is decidedly more complex in reality. Such complex structures are also metabolically expensive to produce and maintain.
-Zooxanthellae
The next structures related to nutrition in corals are not really part of the animals in which they are found. These structures are zooxanthellae. Zooxanthellae are single-celled algae which live inside of some other organism. Many different types of organisms possess zooxanthellae, including some sponges, some protozoans (so there are single-celled organisms which have other single-celled organisms living in them!), some flatworms, and a few other animals. However, zooxanthellae are found living in rather large number of cnidarians including all reef-forming or hermatypic corals.
The relationships with zooxanthellae are presumed to be symbiotic. The anemone or coral that hosts the zooxanthellae in its tissues supposedly benefits from the photosynthetic production of the algae, and the algal cells presumably benefit by receiving protection and possibly some organic nutrients such as amino acids or ammonia from the cnidarian. The algal cells are typically found living in their hosts gastrodermal tissue, close to gut lining, and typically the algal populations are quite dense.
Zooxanthellae are dinoflagellate algae, and like all good algae they are photosynthetic, capable of making organic nutrients from light, water, and carbon dioxide. The process of photosynthesis creates only sugars, but the algal cell can use those sugars to build other materials such as fats (Al-Moghrabi et al., 1995). If the alga has access to nitrogen containing compounds such as ammonia or amino acids, it can also build proteins and other structural molecules, using the sugars as fuel for this process (Szmant-Froelich, and Pilson, 1984).
Algal cells are notoriously "leaky" and up to about 40 percent of the photosynthate produced by algae leak out into the surrounding medium (Lewis and Smith 1971). If the algal cells are living in an coral, the coral tissues can utilize this material as food, or as an organic nutrient for some other function such as building their skeleton. Coral skeletons are often thought of as being composed only of calcium carbonate, but actually, they have an organic matrix and the calcium carbonate mineral is deposited on this. So, if the organic matrix is lacking or reduced, skeleton production cannot occur.
(CONT)
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