Atlantic mudskipper

Last updated

Atlantic mudskipper
GambianMudskippers.jpg
Atlantic mudskippers (Periophthalmus barbarus) from Gambia
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Order: Gobiiformes
Family: Oxudercidae
Genus: Periophthalmus
Species:
P. barbarus
Binomial name
Periophthalmus barbarus
(Linnaeus, 1766)
Synonyms
  • Gobius barbarusLinnaeus, 1766
  • Gobius koelreuteriPallas, 1770
  • Periophtalmus koelreuteri(Pallas, 1770)
  • Periophthalmus koelreuteri(Pallas, 1770)
  • Periophthalmus papilio Bloch & Schneider, 1801
  • Periophthalmus koelreuteri papilioBloch & Schneider, 1801
  • Periophthalmus gabonicus Duméril, 1861
  • Periophthalmus erythronemus Guichenot, 1858

The Atlantic mudskipper (Periophthalmus barbarus) is a species of mudskipper native to fresh, marine, and brackish waters of the tropical Atlantic coasts of Africa, including most offshore islands, through the Indian Ocean and into the western Pacific Ocean to Guam. The Greek scientific name Periophthalmus barbarus is named after the eyes that provide the Atlantic mudskipper with a wide field of vision. The Atlantic mudskipper is a member of the genus Periophthalmus, which includes oxudercine gobies that have one row of canine-like teeth.

Contents

The Atlantic mudskipper can grow up to 16 cm (6.3 in) in body length. Similar to other members of the genus, it has dorsally positioned eyes and pectoral fins that aid in locomotion on land and in water. Atlantic mudskippers can skip, crawl, and climb on land using their pelvic and pectoral fins.

Atlantic mudskippers are semi-aquatic animals that occur on tidal flats and mangrove forests, where it readily crosses mud and sand surfaces out of the water. The Atlantic mudskipper is carnivorous and utilises an ambushing strategy to capture prey. Capturing prey is performed through the use of a 'hydrodynamic tongue', which involves using water to suction the prey into the mouth.

Sexual maturity is reached at approximately 10.2 cm (4.0 in) for females and 10.8 cm (4.3 in) for males. The Atlantic mudskipper can live around five years. Atlantic mudskippers have been used by humans for food, bait, and medicinal purposes. The conservation status of the Atlantic mudskipper is classified as 'Least Concern'.

Distribution

Atlantic mudskippers are found throughout West Africa, in mangrove swamps, and primarily brackish bodies of water near the coast. [1] Countries where the mudskipper are found include Angola, the Democratic Republic of the Congo, Cameroon, and Ghana. [1]

The distribution of Atlantic mudskippers within these regions are influenced by the availability of food and shelter. [2] The distribution may also be influenced by the Atlantic mudskipper's hibernation. [2]

Etymology

The scientific name Periophthalmus barbarus originates from Greek, where peri means 'around', and ophthalmos means 'eye', [3] in reference to the Atlantic mudskipper's close-set eyes that provide it with a larger field of vision. [4] In Greek, barbarus means 'foreign', potentially named after the foreign characteristics it has when compared to other gobies. [3] The generic name 'mudskipper', is labelled after the 'skipping' movement on mudflats. [5]

Taxonomy

The Atlantic mudskippers are classified under oxudercine gobies, all of which live both on land and in water. Atlantic mudskippers dig burrows to seek refuge and reproduce. Previously, the Oxudercidae family was described as a one-species family, where members of the family were collectively named the species Oxuderces dentatus . Oxudercinae species are small to medium in body size, with an elongated body that is covered by small and smooth scales. Members of the Oxudercinae subfamily can also be identified through their dorsally positioned eyes and pointed teeth that resemble canine teeth. The dorsal, pectoral, and pelvic fins have spines, the number of which varies. [3]

There are 12 species within the genus Periophthalmus. The genus Periophthalmus can be identified from other genera of the Oxudercinae subfamily through the teeth, that are present in a single row along the upper jaw. Species of Periophthalmus also have a maximum of 16 spines on the pectoral fins. All Periophthalmus live in environments that have either mangroves or mudflats. [3]

Atlantic mudskippers are distinguished from other members of Periophthalmus by either having no spots or some white spots on their back. [3] Additionally, the Atlantic mudskipper can also be identified by counting the scales along its sides, which total to more than 90 scales. [3] The initial identification and description of the species was outlined by Carl Linnaeus, published in 1766 as Gobius barbarus and renamed to Periophthalmus barbarus. [3] The Atlantic mudskipper has also previously been known or misidentified as Gobius koelreuteri, Periophthalmus papilio, Periophthalmus gabonicus, Periophthalmus erythronemus. [3]

Anatomy and morphology

Side view of the Atlantic mudskipper propped up on land using pectoral fins Obyknovennyi ilistyi prygun (Periophthalmus barbarus).JPG
Side view of the Atlantic mudskipper propped up on land using pectoral fins

The Atlantic mudskipper can grow up to 16 cm in length. [6] The body is covered with scales, coated with a mucus layer that helps to retain moisture. [6] The Atlantic mudskippers have more than 90 scales along the side of their body. [3] Atlantic mudskippers also retain moisture by storing water within gill chambers, that allows them to breathe when out of water. [6] Atlantic mudskippers do not have a membrane that covers the gill chambers; instead, they are able to control the opening and closing of the gill chambers. [7] The gill chambers may be controlled through either the muscles around the slits, or through the differences in partial pressures. [7] In addition to retaining moisture by storing water, the surface of the Atlantic mudskipper enables it to breathe through its skin, otherwise known as cutaneous respiration. [8]

Aerial view of the Atlantic mudskipper propped up on land using pectoral fins Atlantic Mudskipper (Periophthalmus barbarus) (7700010340).jpg
Aerial view of the Atlantic mudskipper propped up on land using pectoral fins

Mudskippers have a pair of pectoral fins, which allows them to 'skip' on land and maintain stability within water. [6] [4] [9] The Atlantic mudskipper also has a pair of caudal fins that aid in aquatic locomotion, and pelvic fins that aid the pectoral fins in terrestrial locomotion. [9] The pelvic fins are adapted to terrestrial living by acting as a sucker to attach the Atlantic mudskipper to land. [8] Atlantic mudskippers can also crawl and climb on land using their pelvic and pectoral fins. [8]

The eyes of the Atlantic mudskipper are adapted to terrestrial living by being located closely together, providing the mudskipper with a large field of vision. [4] The eyes can move independent of the other at 360 degrees. [10] The eyes are also positioned further up on the head, enabling the eyes to remain above the water surface whilst their body is submerged underwater. [4] Cup-like structures that hold water are located beneath the eye, which aids in lubricating the eyes when the Atlantic mudskipper is on land. [4] While on land, they perform a whole-body rolling behavior in which their eyes are retracted and the dermal cup structures cover them, such that the dermal cup membrane comes into contact with fluids on the surface they are rolling on. When they finish the roll, their eyes extend again and the dermal cup recedes. This rolling behavior may capture water in these cups and body for lubrication, supported by the fact that they were observed to roll much more frequently when exposed to higher air flow (and thus, higher evaporation) in a laboratory setting. [11] The Atlantic mudskipper has chemosensory receptors that are located within the nose and on the skin's surface. [12]

The Atlantic mudskipper has the ability to rotate its mouth opening so that its jaws can be oriented over prey. [13] Sharp teeth, reflective of their carnivorous diet, are present within the mouth. [14] Atlantic mudskippers have a short digestive system, that is composed of an oesophagus, stomach, intestine, and rectum. [15] The stomach was historically not described in Atlantic mudskippers as it is not well defined unless structures are compared microscopically. [15] The surface of the intestine is folded, which increases the surface area that enhances the absorption of nutrients. [15]

The Atlantic mudskipper has a unique olfactory organ that includes a canal 0.3mm in diameter near its upper lip that increases in size into a chamber-like sac. The chamber-like sacs only serve a mechanical purpose, which is to circulate water through the canals, which are sensory structures. [16] [17]

The Atlantic mudskippers have genital papillae that are located on the abdomen. Females can be distinguished from males, who have less rounded papillae. [18]

Ecology and behaviour

Habitat

Partially submerged mudskippers. Fuding - LongAn - mudskipper ponds - P1220424.JPG
Partially submerged mudskippers.

Atlantic mudskippers are semi-aquatic animals that live in areas with water that is slightly salty, such as river estuaries and mudflats. [10] [19] Generally, Atlantic mudskippers spend the majority of the day on land. [10] In tidal regions, Atlantic mudskippers may appear only during low tide to feed; conversely, they hide in their burrow at high tide. [19] Their burrows can extend to 1.5 metres deep, in which mudskippers can seek refuge from predators. [4] Burrows may contain a pocket of air which the Atlantic mudskipper can breathe from, despite there being low oxygen availability. [4] The Atlantic mudskipper is generally able to tolerate high concentrations of toxic substances produced by industrial waste, including cyanide and ammonia, in the surrounding environments. [20] For example, in the presence of high ammonia contamination, the Atlantic mudskipper can actively secrete ammonia through its gills within highly acidic environments. [4] They are also able to survive in a variety of environments, including waters with different temperatures and salinity levels. [20]

Atlantic mudskipper underwater. Aquarium tropical du Palais de la Porte Doree - Periophthalmus barbarus.JPG
Atlantic mudskipper underwater.

Hot and humid climates are optimal for Atlantic mudskippers as it enhances cutaneous respiration and helps them with maintaining their body temperature. The body temperature of Atlantic mudskippers on the surface can range from 14 to 35 degrees celsius. The Atlantic mudskipper is territorial and builds a wall of mud around its territory and its resources. The territory is approximately 1 metre long and can aid in maintaining Atlantic mudskipper populations by storing food resources. [4]

Predator-prey behaviour

The Atlantic mudskipper is carnivorous, [21] and has adopted an ambushing strategy to capture terrestrial prey. [22] While hunting, the Atlantic mudskipper submerges itself underwater whilst leaving its eyes out, using only sight to identify and locate prey. [22] To ambush prey, Atlantic mudskippers launch onto land using predominantly their pectoral fins, and catch the prey using their mouth. [22] When Atlantic mudskippers are in danger from predation on land, they proceed into 'flight' behaviour and either jump in the water or skip away on mud. [4]

Feeding behaviour

On land, the Atlantic mudskipper feeds by covering its prey with water, then sucking back the water and prey into its mouth, named as the 'hydrodynamic tongue'. [23] The Atlantic mudskipper carries water in their mouth prior to emerging on land, enabling them to feed. [24] In water, the Atlantic mudskipper feeds through suction feeding, similar to other aquatic species. [7] Suction-feeding involves building up pressure by expanding the head and mouth rapidly, which pulls both food and water in. [25] Although the feeding technique is similar in both environments, the Atlantic mudskipper alters the force of suction, such that the flow underwater is stronger than on land. [7] The gape size of the mouth is larger in water, potentially due to water pressure. [25] Furthermore, the Atlantic mudskipper lunges simultaneously as suctioning, in order to catch prey. [25] The direction of the lunge is different between terrains. The Atlantic mudskipper catches prey horizontally underwater; whereas, the Atlantic mudskipper rotates its body and reorientates its mouth on land, such that it feeds on prey from above. [25] The Atlantic mudskippers are diurnal, which means they are active and feed during the day. [10]

Atlantic mudskippers are flexible in regard to their diet choices. Larger Atlantic mudskippers ingest larger-sized prey, potentially due to the correlation between their mouth gape and prey size. [26] The feeding choices also may vary by habitats and seasonally, depending on what resources are most abundant. [26] The Atlantic mudskippers feed more during dry season than wet, reflective of the optimal foraging theory, which proposes that diet flexibility increases with lower food availability. [26] Atlantic mudskippers feed frequently, where larger Atlantic mudskippers feed at higher intensities as they are less prone to predation. [26]

Diet

The Atlantic mudskipper is a consumer of a wide variety of food. [26] In the wild, mudskippers prefer to eat worms, crickets, flies, mealworms, beetles, small fish, and small crustaceans (sesarmid crabs). [27] Mudskippers kept as pets can eat frozen fare such as bloodworm or artemia and flakes. It cannot eat dried food; however, because its stomach swells up. It is recommended to feed it frozen food for a healthy diet. [28]

Reproduction

Females reach sexual maturity at a body length of around 10.2 cm, and males approximately 10.8 cm. The Atlantic mudskipper can spawn throughout the year. [29] However, spawning mainly occurs for male Atlantic mudskippers between February and May, and females between March and May. [30] The peak spawning times are associated with high food availability for their young. [30] The fertility of Atlantic mudskippers increases with the length of their body, as females may be able to carry more eggs at larger sizes. [29] Females lay thousands of eggs at one time; however, the eggs are highly prone to predation. [4] Mudskippers flood their burrows to trigger the eggs to hatch. Only a small proportion of offspring survive as they are highly susceptible to predation. [4]

During courtship, after the male pairs with a female mudskipper, the male and female go into the male's burrow to mate. [29] After the female releases her eggs onto the burrow wall, [29] the male displays a large amount of paternal care. [4] The male Atlantic mudskipper will guard and take care of the eggs within the burrow. [4]

Lifecycle

The average lifespan of an Atlantic mudskipper is approximately five years. The egg laid by the mother in the burrow will hatch into larvae that swim out of the burrow and drift for 30–50 days. As Atlantic mudskippers are territorial, juvenile mudskippers will hide in mud until they are grown enough to protect their established territory. [4]

Usage by humans

The Atlantic mudskippers are used by humans as food, bait, ornamental fishes, and for medicine. [2] [30] It is important to local indigenous peoples as a food fish and can also be found in the aquarium trade. [1] Fishing has caused population declines in parts of the species' range. [30] Mudskippers can be used as a bio-indicator of pollution in marine ecosystems as they are sensitive to the environment and have an absorptive body. [4] Analyses can be performed by examining various organs of the mudskipper. [4] The digestive system, gills, and skin are common places of the Atlantic mudskipper that are contaminated by heavy metals, like copper and iron. [4] A less invasive method of using mudskippers as a bio-indicator is to use their growth and development as a measure for potential contamination. [4]

Threats and conservation

The conservation status of the Atlantic mudskipper is currently classified as a species of 'Least Concern.' [1] Declines in Atlantic mudskipper populations may be a result of overfishing, unregulated pollution, and unsuitable fishing methods, for instance, electric fishing. [31] The Atlantic mudskipper is also threatened by the increase in urban development within its habitat. [1]

Although mudskippers have been found to be able to tolerate cyanide in environments, the use of cyanide can be fatal to all life stages of the Atlantic mudskipper. [31] On the other hand, pollution may also cause a change in distribution of the mudskippers, resulting in local population decline. [31] Changes to the abundance of Atlantic mudskippers can lead to cascading effects, by influencing the abundance of predators and prey of the Atlantic mudskipper. [31]

Different indigenous populations and cultures have applied various conservation practices in order to conserve the Atlantic mudskipper. The Higaonons do not use unsustainable fishing methods and cyanide, in an effort to conserve the Atlantic mudskippers and other effected aquatic organisms in their area. In Iligan city, Atlantic mudskippers can only be fished from a few locations. [31]

Some Atlantic mudskippers are distributed in regions where there is land and water protection. The current recommended conservation actions include managing the number of Atlantic mudskippers caught when fishing. [1]

Related Research Articles

<span class="mw-page-title-main">Stingray</span> Suborder of fishes

Stingrays are a group of sea rays, which are cartilaginous fish related to sharks. They are classified in the suborder Myliobatoidei of the order Myliobatiformes and consist of eight families: Hexatrygonidae, Plesiobatidae, Urolophidae (stingarees), Urotrygonidae, Dasyatidae, Potamotrygonidae, Gymnuridae and Myliobatidae . There are about 220 known stingray species organized into 29 genera.

<span class="mw-page-title-main">Gobiidae</span> Family of fishes

Gobiidae or gobies is a family of bony fish in the order Gobiiformes, one of the largest fish families comprising more than 2,000 species in more than 200 genera. Most of gobiid fish are relatively small, typically less than 10 cm (3.9 in) in length, and the family includes some of the smallest vertebrates in the world, such as Trimmatom nanus and Pandaka pygmaea, Trimmatom nanus are under 1 cm long when fully grown, then Pandaka pygmaea standard length are 9 mm (0.35 in), maximum known standard length are 11 mm (0.43 in). Some large gobies can reach over 30 cm (0.98 ft) in length, but that is exceptional. Generally, they are benthic or bottom-dwellers. Although few are important as food fish for humans, they are of great significance as prey species for other commercially important fish such as cod, haddock, sea bass and flatfish. Several gobiids are also of interest as aquarium fish, such as the dartfish of the genus Ptereleotris. Phylogenetic relationships of gobiids have been studied using molecular data.

<span class="mw-page-title-main">Bluegill</span> Species of fish

The bluegill, sometimes referred to as "bream," "brim," "sunny," or "copper nose" as is common in Texas, is a species of North American freshwater fish, native to and commonly found in streams, rivers, lakes, ponds and wetlands east of the Rocky Mountains. It is the type species of the genus Lepomis, from the family Centrarchidae in the order Perciformes.

<span class="mw-page-title-main">Fish locomotion</span> Ways that fish move around

Fish locomotion is the various types of animal locomotion used by fish, principally by swimming. This is achieved in different groups of fish by a variety of mechanisms of propulsion, most often by wave-like lateral flexions of the fish's body and tail in the water, and in various specialised fish by motions of the fins. The major forms of locomotion in fish are:

<span class="mw-page-title-main">Round goby</span> Species of fish

The round goby is a euryhaline bottom-dwelling species of fish of the family Gobiidae. It is native to Central Eurasia, including the Black Sea and the Caspian Sea. Round gobies have established large non-native populations in the Baltic Sea, several major Eurasian rivers, and the North American Great Lakes.

<span class="mw-page-title-main">Amphibious fish</span>

Amphibious fish are fish that are able to leave water for extended periods of time. About 11 distantly related genera of fish are considered amphibious. This suggests that many fish genera independently evolved amphibious traits, a process known as convergent evolution. These fish use a range of terrestrial locomotory modes, such as lateral undulation, tripod-like walking, and jumping. Many of these locomotory modes incorporate multiple combinations of pectoral-, pelvic-, and tail-fin movement.

<span class="mw-page-title-main">Mudskipper</span> Subfamily of fishes

Mudskippers are any of the 23 extant species of amphibious fish from the subfamily Oxudercinae of the goby family Oxudercidae. They are known for their unusual body shapes, preferences for semiaquatic habitats, limited terrestrial locomotion and jumping, and the ability to survive prolonged periods of time both in and out of water.

<span class="mw-page-title-main">Walking fish</span> Fish species with the ability to travel over land for extended period of time

A walking fish, or ambulatory fish, is a fish that is able to travel over land for extended periods of time. Some other modes of non-standard fish locomotion include "walking" along the sea floor, for example, in handfish or frogfish.

<span class="mw-page-title-main">Gobiiformes</span> Order of fishes

The Gobiiformes are an order of fish that includes the gobies and their relatives. The order, which was previously considered a suborder of Perciformes, is made up of about 2,211 species that are divided between seven families. Phylogenetic relationships of the Gobiiformes have been elucidated using molecular data. Gobiiforms are primarily small species that live in marine water, but roughly 10% of these species inhabit fresh water. This order is composed chiefly of benthic or burrowing species; like many other benthic fishes, most gobiiforms do not have a gas bladder or any other means of controlling their buoyancy in water, so they must spend most of their time on or near the bottom. Gobiiformes means "goby-like".

<i>Periophthalmus</i> Genus of fishes

Periophthalmus is a genus of fish in the family Oxudercidae, native to coastal mangrove wood and shrubland in the Indo-Pacific region, except for P. barbarus from the Atlantic coast of Africa. It is one of the genera commonly known as mudskippers. Periophthalmus fishes are remarkable for being able to live, temporarily, in open air where they feed with insects and small invertebrates; out of water they have limited motion abilities, such as jumping. All Periophthalmus species are aggressive and territorial.

<span class="mw-page-title-main">Fin and flipper locomotion</span>

Fin and flipper locomotion occurs mostly in aquatic locomotion, and rarely in terrestrial locomotion. From the three common states of matter — gas, liquid and solid, these appendages are adapted for liquids, mostly fresh or saltwater and used in locomotion, steering and balancing of the body. Locomotion is important in order to escape predators, acquire food, find mates and bury for shelter, nest or food. Aquatic locomotion consists of swimming, whereas terrestrial locomotion encompasses walking, 'crutching', jumping, digging as well as covering. Some animals such as sea turtles and mudskippers use these two environments for different purposes, for example using the land for nesting, and the sea to hunt for food.

<span class="mw-page-title-main">Western tubenose goby</span> Species of fish

The western tubenose goby is a species of goby native to fresh waters of the Black Sea and Aegean Sea basins. It has recently spread as an invasive species to Central and Western Europe and to North America. Previously Proterorhinus semilunaris was considered as a junior synonym of Proterorhinus marmoratus, but was confirmed as a distinct species based on molecular analysis.

Trypauchen vagina, commonly known as the burrowing goby, is a species of eel goby found in the Indo-Pacific region. It has an elongated body about 20 to 22 cm in length. It is reddish-pink in color and possesses distinctive pouches in the upper edges of its gill covers. It lives in burrows in the silty and muddy bottoms of its marine and brackish habitats. It has reduced eyes that are entirely covered with skin and the anterior portion of its head is protected by thick flesh. Both adaptations aid it in digging its burrows.

Platygobiopsis is a genus of gobies native to the western Pacific Ocean.


Innovations conventionally associated with terrestrially first appeared in aquatic elpistostegalians such as Panderichthys rhombolepis, Elpistostege watsoni, and Tiktaalik roseae. Phylogenetic analyses distribute the features that developed along the tetrapod stem and display a stepwise process of character acquisition, rather than abrupt. The complete transition occurred over a period of 30 million years beginning with the tetrapodomorph diversification in the Middle Devonian.

Darwin's mudskipper is a relatively newly discovered mudskipper in 2004, so little is known about it. It is a brackish water ray-finned fish found in Australia along mud banks never far from mangrove trees. It is in the goby family Gobiidae. It is named after Charles Darwin because the holotype was collected in Darwin Harbour. Its greatest distinguishing characteristic from other mudskippers is its greatly reduced first dorsal fin in both sexes.

<i>Elacatinus figaro</i> Species of fish

Elacatinus figaro, the barber goby or yellow line goby, is a colourful species of marine goby, family Gobiidae, from the southwestern Atlantic, where it is endemic to the coastal waters of Brazil.

Elacatinus colini, the Belize sponge goby, is a species of goby native to the Western Central Atlantic Ocean, near Belize and Honduras.

<i>Boleophthalmus pectinirostris</i> Species of fish

Boleophthalmus pectinirostris, commonly known as the great blue spotted mudskipper, is a species of mudskipper native to the north-western Pacific Ocean. It can be found on the coastlines of Japan, eastern China, Sumatra, Malaysia, Taiwan and the Korean Peninsula.

<i>Boleophthalmus boddarti</i> Species of fish

Boleophthalmus boddarti, commonly known as Boddart's goggle-eyed goby, is a species of mudskipper native to the Indo-Pacific, and the type species of the genus Boleophthalmus.

References

  1. 1 2 3 4 5 6 7 Diouf, K.; Bousso, T.; Lalèyè, P.; Moelants, T. (2020). "Periophthalmus barbarus". IUCN Red List of Threatened Species . 2020: e.T182285A21913503. doi: 10.2305/IUCN.UK.2020-2.RLTS.T182285A21913503.en . Retrieved 20 November 2021.
  2. 1 2 3 Kachhi, Kishwar Kumar; Panhwar, Sher Khan; Waryani, Baradi (2020). "Recent gobies from Pakistan, northern Arabian sea: Diversity and biogeographic affinities". Journal of Applied Ichthyology. 36 (2): 183–188. doi: 10.1111/jai.14007 . S2CID   214222970.
  3. 1 2 3 4 5 6 7 8 9 Murdy, Edward O. (1989). A Taxonomic Revision and Cladistic Analysis of the Oxudercine Gobies (Gobiidae, Oxudercinae). Australian Museum. ISBN   978-0-7305-6374-7.
  4. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 Ansari, A.; Trivedi, S.; Saggu, Shalini; Rehman, H. (2014). "Mudskipper: A biological indicator for environmental monitoring and assessment of coastal waters". Journal of Entomology and Zoology Studies. 2 (6): 22–33. S2CID   54816035 . Retrieved 2020-10-07.
  5. "Definition of mudskipper | Dictionary.com". www.dictionary.com. Retrieved 2020-10-07.
  6. 1 2 3 4 "Atlantic mudskippers: Meet them at Zoo Leipzig!". Zoo Leipzig. Retrieved 2020-10-07.
  7. 1 2 3 4 Michel, K. B.; Aerts, P.; Van Wassenbergh, S. (2016). "Environment-dependent prey capture in the Atlantic mudskipper (Periophthalmus barbarus)". Biology Open. 5 (11): 1735–1742. doi: 10.1242/bio.019794 . PMC   5155533 . PMID   27765755.
  8. 1 2 3 Kutschera, Ulrich; Elliott, J. Malcolm (2013). "Do mudskippers and lungfishes elucidate the early evolution of four-limbed vertebrates?". Evolution: Education and Outreach. 6 (1): 8. doi: 10.1186/1936-6434-6-8 . S2CID   7339626.
  9. 1 2 Pace, C. M.; Gibb, A. C. (2009). "Mudskipper pectoral fin kinematics in aquatic and terrestrial environments". Journal of Experimental Biology. 212 (14): 2279–2286. doi: 10.1242/jeb.029041 . PMID   19561218. S2CID   18176905.
  10. 1 2 3 4 "Atlantic mudskipper". Zoo Zürich. Retrieved 2020-10-11.
  11. Aiello, Brett R.; Bhamla, M. Saad; Gau, Jeff; Morris, John G. L.; Bomar, Kenji; da Cunha, Shashwati; Fu, Harrison; Laws, Julia; Minoguchi, Hajime; Sripathi, Manognya; Washington, Kendra; Wong, Gabriella; Shubin, Neil H.; Sponberg, Simon; Stewart, Thomas A. (April 24, 2023). "The origin of blinking in both mudskippers and tetrapods is linked to life on land". PNAS . 120 (18): e2220404120. doi: 10.1073/pnas.2220404120 . PMC   10160996 . PMID   37094121.
  12. Kuciel, Michał; Rita Lauriano, Eugenia; Silvestri, Giuseppa; Żuwała, Krystyna; Pergolizzi, Simona; Zaccone, Daniele (2014). "The structural organization and immunohistochemistry of G-protein alpha subunits in the olfactory system of the air-breathing mudskipper, Periophthalmus barbarus (Linnaeus, 1766) (Gobiidae, Oxudercinae)". Acta Histochemica. 116 (1): 70–78. doi:10.1016/j.acthis.2013.05.005. PMID   23769676.
  13. Michel, Krijn B.; Adriaens, Dominique; Aerts, Peter; Dierick, Manuel; Wassenbergh, Sam Van (2014). "Functional anatomy and kinematics of the oral jaw system during terrestrial feeding in Periophthalmus barbarus". Journal of Morphology. 275 (10): NA. doi: 10.1002/jmor.20318 . S2CID   221874282.
  14. Sponder, Debra L.; Lauder, G. (2009). "Terrestrial feeding in the Mudskipper Periophthalmus (Pisces: Teleostei): A cineradiographic analysis". Journal of Zoology. 193 (4): 517–530. doi:10.1111/J.1469-7998.1981.TB01501.X. S2CID   4977608.
  15. 1 2 3 Wołczuk, Katarzyna; Ostrowski, Maciej; Ostrowska, Agnieszka; Napiórkowska, Teresa (2018). "Structure of the alimentary tract in the Atlantic mudskipper Periophthalmus barbarus (Gobiidae: Oxudercinae): anatomical, histological and ultrastructural studies". Zoology. 128: 38–45. doi:10.1016/j.zool.2018.04.002. PMID   29755007. S2CID   21659277.
  16. Kuciel, Michał (2013). "The mechanism of olfactory organ ventilation in Periophthalmus barbarus (Gobiidae, Oxudercinae)". Zoomorphology. 132 (1): 81–85. doi:10.1007/s00435-012-0167-y. PMC   3570760 . PMID   23420290.
  17. Kuciel, Michał; Żuwała, Krystyna; Jakubowski, Michał (2011). "A new type of fish olfactory organ structure in Periophthalmus barbarus (Oxudercinae)". Acta Zoologica. 92 (3): 276–280. doi:10.1111/j.1463-6395.2010.00459.x.
  18. Udo, M.; Abiaobo, No; Asuquo, I. (2016). "Aspects of the reproductive biology in mudskippers Periophthalmus barbarus (Gobiidae) (Linnaeus 1766) in mangrove swamps of Iko Estuary, Southeast, Nigeria" (PDF). International Journal of Fisheries and Aquatic Studies. 4 (3): 27–32. S2CID   174791452.
  19. 1 2 "Periophthalmus barbarus (Atlantic Mudskipper) — Seriously Fish" . Retrieved 2020-10-07.
  20. 1 2 Emuebie, Okonji Raphael (2011). "Physicochemical Properties of Mudskipper ( Periophthalmus Barbarus Pallas) Liver Rhodanese". Australian Journal of Basic and Applied Sciences. 5 (8): 507–514.
  21. Clayton, David (1993). "Mudskippers". Oceanography and Marine Biology. 31: 507–577.
  22. 1 2 3 Kutschera, U.; Burghagen, H.; Ewert, J. (2008). "Prey-Catching Behaviour in Mudskippers and Toads: A Comparative Analysis". Online Journal of Biological Sciences. 8 (2): 41–43. doi: 10.3844/OJBSCI.2008.41.43 . S2CID   1121957.
  23. Michel, Krijn B.; Heiss, Egon; Aerts, Peter; Van Wassenbergh, Sam (2015). "A fish that uses its hydrodynamic tongue to feed on land". Proceedings of the Royal Society B: Biological Sciences. 282 (1805): 20150057. doi:10.1098/rspb.2015.0057. PMC   4389620 . PMID   25788596.
  24. Yong, Ed (17 March 2015). "Fish that Walks on Land Swallows With Tongue Made of Water". National Geographic.
  25. 1 2 3 4 Kane, Emily A; Cohen, Hannah E; Hicks, William R; Mahoney, Emily R; Marshall, Christopher D (2019). "Beyond Suction-Feeding Fishes: Identifying New Approaches to Performance Integration During Prey Capture in Aquatic Vertebrates". Integrative and Comparative Biology. 59 (2): 456–472. doi: 10.1093/icb/icz094 . PMID   31225594.
  26. 1 2 3 4 5 Udo, Mfon T. "Tropic attributes of the mudskipper, Periophthalmus barbarus (Gobiidae: Oxudercinae) in the mangrove swamps of Imo River estuary, Nigeria". Journal of Environmental Sciences. 14 (4): 508–517.
  27. "Periophthalmus barbarus". Mudskipper.it. Retrieved 28 October 2016.
  28. Froese, Rainer; Pauly, Daniel (eds.) (2013). "Periophthalmus barbarus" in FishBase . June 2013 version.
  29. 1 2 3 4 Chukwu, K. O.; Deekae, S. N.; Gabriel, U. U. (2010). "Reproductive biology of Periopthalmus barbarus (Linnaeus 1766) in New Calabar River, Nigeria". Agriculture and Biology Journal of North America. 1 (6): 1158–1161. doi: 10.5251/ABJNA.2010.1.6.1158.1161 . S2CID   85038299.
  30. 1 2 3 4 Etim, Lawrence; King, Richard P.; Udo, Mfon T. (2002). "Breeding, growth, mortality and yield of the mudskipper Periophthalmus barbarus (Linnaeus 1766) (Teleostei: Gobiidae) in the Imo River estuary, Nigeria". Fisheries Research. 56 (3): 227–238. doi:10.1016/S0165-7836(01)00327-7.
  31. 1 2 3 4 5 Rebancos, Carmelita (2013). "Indigenous Goby Population in Mandulog River System and its Conservation by Communities in Iligan City, Philippines". Journal of Environmental Science and Management. 16: 11–18.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.