Details of the range of (Bemis, et al., 2003)are difficult to establish (Alves-Gomes et al., 2003). There has not been a lot of research on this species and the specimens that have been identified lack information on their origin.
- Aquatic Biomes
- lakes and ponds
- rivers and streams
- Range depth
- 0 to .50 m
- 0.00 to 1.64 ft
juveniles have a pattern of bright yellow spots which fade away as the fish matures (Alves-Gomes et al., 2003). Adult South American lungfish have a black or grey coloration. Lungfish have solid toothplates instead of individual teeth. Bodies are long and slender, somewhat like salamanders, with a diphycercal tail. These fish can grow up to 125 cm in length (Baensch et al., 1985).
amphibian larvae, with four external gills that they use for breathing until about seven weeks in age. After this time, they become obligate air breathers and regression of the external gills begins (Berra, 2001). They have a reduced bronchial apparatus which allows them to survive during times when oxygen levels are low. During drought, they can burrow into mud to 50 cm below the surface and become dormant until the environment becomes more hospitable (2001). (Bemis, et al., 2003; Baensch and Riehl, 1985; Berra, 2001)young look a bit like
Surfactant composition of South American lungfish resembles that of amphibians. In contrast, the more primitive Australian lungfish, Neoceratodus fosteri, possesses surfactant that is almost identical to primitive air-breathing actinopterygiian fish (Orgeig, 1995). This could be one reason why must breathe air as an adult, while other lungfish can breathe air or water. (Orgeig and Daniels, 1995)
- Sexual Dimorphism
- sexes alike
- Range length
- 125 (high) cm
- 49.21 (high) in
- Range wingspan
- N/A to N/A mm
- to in
- Average wingspan
- N/A mm
Newly hatched (Berra, 2001)resemble amphibian tadpoles. The have four external gills which they use to breathe for the first seven weeks of their lives (Berra, 2001). After this time, they become strictly air breathers and their gills begin to regress (2001). During the breeding season, the males develop gill-like structures that allow them to release oxygen into their burrows for their developing young (2001). These structures disappear after the breeding season is over.
- Development - Life Cycle
There is very little information on the mating systems of.
- Breeding interval
- Unknown; minimum population doubling time is greater than 14 years.
- Breeding season
- Breeding occurs during the rainy months of the year.
Both parents gather debris to make a nest. The nest is then guarded by the male parent. The males can increase oxygen levels for their developing young by using gill-like structures formed during the breeding season. These gill-like structures are highly vascularized, feathery structures developed from the pelvic fin (Berra, 2001). These structures allow the male to release oxygen from his blood into the surrounding nest and remove carbon dioxide (2001). (Berra, 2001)
- Parental Investment
The home range of (Bemis, et al., 2003)is likely small because of its inactive nature.
Communication and Perception
There is not a lot known about communication and perception in. They have small eyes which suggests that relies on other senses to detect prey and potential predators.
- Communication Channels
- Perception Channels
bony fish, algae and weeds, terrestrial plants (stems), shrimp, insects, clams, and snails (Berra, 2001). They are primarily carnivorous. Juveniles, which are strictly aquatic, feed on larval insects and snails. (Berra, 2001)eat a variety of food items including some
South American lungfish capture prey by suction feeding. They use tooth plates, an enlarged cranial rib (which serves as the site for the origin of the muscle that depresses the hyoid apparatus), and a depressor mandibulae to manipulate and chew food prior to swallowing. Hydraulic transport achieved by movements of the hyoid apparatus is used to position prey within the mouth. This is parallel to the function of a tongue (Bemis, 1986). (Bemis and Lauder, 1986)
- Animal Foods
- aquatic crustaceans
- Plant Foods
- wood, bark, or stems
Information on the predators of, as well as any predator/anti-predator adaptations are largely unknown due to lack of research on this species.
- Known Predators
- There is no information on known predators.
This species influences the neotropical ecosystem of the Amazon Basin. (Berra, 2001)prey on some small bony fish, shrimp, clams, snails, and insects (Berra, 2001). Any role that they play as a prey item is largely unknown.
Economic Importance for Humans: Positive
This species does not provide direct economic benefits to humans. It does provide intellectual benefits; lungfish represent an important step in vertebrate evolution and their origin provide insights into the origin of tetrapods (Alves-Gomes et al., 2003). (Bemis, et al., 2003)
- Positive Impacts
- research and education
Economic Importance for Humans: Negative
There are no known adverse effects ofon humans.
Fossil evidence has placed some Devonian lungfish in fully marine habitats as well as freshwater deposits (2003). Lepidosirenids show a clear vicariance pattern that is consistent with the separation of the African and South American continents during the Cretaceous (2003).
Because of their relationship with both fish and tetrapods, lungfish are a very important evolutionary step. More research should be done so that they can be more fully understood. (Bemis, et al., 2003)
Tanya Dewey (editor), Animal Diversity Web.
Stephanie Elliott (author), University of Michigan-Ann Arbor, Kevin Wehrly (editor, instructor), University of Michigan-Ann Arbor.
living in the southern part of the New World. In other words, Central and South America.
- bilateral symmetry
having body symmetry such that the animal can be divided in one plane into two mirror-image halves. Animals with bilateral symmetry have dorsal and ventral sides, as well as anterior and posterior ends. Synapomorphy of the Bilateria.
an animal that mainly eats meat
animals which must use heat acquired from the environment and behavioral adaptations to regulate body temperature
- external fertilization
fertilization takes place outside the female's body
union of egg and spermatozoan
mainly lives in water that is not salty.
having a body temperature that fluctuates with that of the immediate environment; having no mechanism or a poorly developed mechanism for regulating internal body temperature.
An animal that eats mainly insects or spiders.
offspring are produced in more than one group (litters, clutches, etc.) and across multiple seasons (or other periods hospitable to reproduction). Iteroparous animals must, by definition, survive over multiple seasons (or periodic condition changes).
seaweed. Algae that are large and photosynthetic.
A large change in the shape or structure of an animal that happens as the animal grows. In insects, "incomplete metamorphosis" is when young animals are similar to adults and change gradually into the adult form, and "complete metamorphosis" is when there is a profound change between larval and adult forms. Butterflies have complete metamorphosis, grasshoppers have incomplete metamorphosis.
having the capacity to move from one place to another.
specialized for swimming
- native range
the area in which the animal is naturally found, the region in which it is endemic.
reproduction in which eggs are released by the female; development of offspring occurs outside the mother's body.
- seasonal breeding
breeding is confined to a particular season
remains in the same area
reproduction that includes combining the genetic contribution of two individuals, a male and a female
a wetland area that may be permanently or intermittently covered in water, often dominated by woody vegetation.
the region of the earth that surrounds the equator, from 23.5 degrees north to 23.5 degrees south.
uses sight to communicate
Baensch, H., R. Riehl. 1985. Aquarien atlas. Germany: Verlag fur Natur-und Heimtierkunde GmbH.
Bemis, W., G. Lauder. 1986. "Morphology and function of the feeding apparatus of the lungfish, Lepidosiren paradoxa (Dipnoi)." (On-line). Accessed September 26, 2005 at http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=3950967&query_hl=1.
Bemis, W., C. Fernandes, R. e Castro, J. Zuanon, L. Py-Daniel, J. Alves-Gomes, G. dos Santos, F. Machado, L. Malabarba. 2003. "Notes on the Systematics, Distribution and Natural History of the South American Lungfishes in the genus Lepidosiren Fitzinger 1837 (Dipnoi: Lepidosirenidae)" (On-line pdf). Accessed October 08, 2005 at www.bio.umass.edu/biology/bemis/Lungfish_ms.pdf.
Berra, T. 2001. Freshwater fish distribution. San Diego, CA, USA: Academic Press.
Boujard, T., M. Pascal, J. Meunier, P. Le Bail. 1997. Poissons de Guyane. Paris: Institut National de la Recherche Agronomique.
Fishman, A., R. DeLaney, P. Laurent. 1985. "Circulatory adaptation to bimodal respiration in the dipnoan lungfish" (On-line). Accessed September 26, 2005 at http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=4030580&query_hl=1.
Max Planck Institute for Demographic Research, 2005. "Longevity Records: Life Spans of Mammals, Birds, Amphibians, Reptiles, and Fish" (On-line). Index Search. Accessed October 08, 2005 at http://www.demogr.mpg.de/?http://www.demogr.mpg.de/longevityrecords/.
Orgeig, S., C. Daniels. 1995. "The evolutionary significance of pulmonary surfactant in lungfish (Dipnoi)." (On-line). Accessed September 26, 2005 at http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=7626285&query_hl=1.
Planquette, P., P. Keith, P. Le Bail. 1996. Atlas des poissons d'eau douce de Guyane. Paris: IEGB-M.N.H.N.,INRA,CSP.