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Mummichog

December 15, 2023

The mummichog (Fundulus heteroclitus) is a small killifish found along the Atlantic coast of the United States and Canada. Also known as Atlantic killifish, mummies, gudgeons, and mud minnows, these fish inhabit brackish and coastal waters including estuaries and salt marshes. The species is noted for its hardiness and ability to tolerate highly variable salinity, temperature fluctuations from 6 to 35 °C (43 to 95 °F), very low oxygen levels (down to 1 mg/L), and heavily polluted ecosystems. As a result, the mummichog is a popular research subject in embryological, physiological, and toxicological studies. It is also the first fish ever sent to space, aboard Skylab in 1973.

Mummichog
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Order: Cyprinodontiformes
Family: Fundulidae
Genus: Fundulus
Species:
F. heteroclitus
Binomial name
Fundulus heteroclitus
Synonyms[2][3][4]
  • Cobitis heteroclita Linnaeus, 1766
  • Cobitis macrolepidota Walbaum, 1792
  • Fundulus mudfish Lacepède, 1803
  • Esox pisciculus Mitchill, 1815
  • Esox pisculentus Mitchill, 1815
  • Fundulus antillarum Fowler, 1916
  • Fundulus badius Garman, 1895
  • Fundulus coenicolus (Bloch & Schneider, 1801)
  • Fundulus fasciatus (Bloch & Schneider, 1801)
  • Fundulus fonticola Valenciennes, 1846
  • Fundulus lozanoi (Gomez Caruana et al., 1984)
  • Fundulus nigrofaciatus (Lesueur, 1817)
  • Fundulus nisorius Cope, 1870
  • Fundulus ornatus (Lesueur, 1817)
  • Fundulus pisciculus (Mitchill, 1815)
  • Fundulus swampinus (Lacepède, 1803)
  • Fundulus vinctus Jordan & Gilbert, 1882
  • Fundulus viridescens DeKay, 1842
  • Fundulus zebra DeKay, 1842
  • Hydargira nigrofaciata Lesueur, 1817
  • Hydrargira ornata Lesueur, 1817
  • Hydrargira swampina Lacepède, 1803
  • Poecilia coenicola Bloch & Schneider, 1801
  • Poecilia fasciata Bloch & Schneider, 1801
  • Valencia lozanoi Gomez Caruana et al., 1984

Taxonomy edit

The genus name Fundulus comes from fundus, meaning bottom, from the fish's habit of swimming near muddy bottoms. The species name heteroclitus means irregular or unusual. The type specimen was first described by Carl Linnaeus in 1766, from near Charleston, South Carolina. Other scientific names now considered synonyms for this species include Cobitis heteroclita, Fundulus fasciatus, Fundulus pisculentus, and Fundulus nigrofasciatus.[5] The mummichog belongs to the order Cyprinodontiformes, and the family Fundulidae. There are two subspecies: F. h. heteroclitus (Linnaeus, 1766), in the south and F. h. macrolepidotus (Walbaum, 1792) in the north. As F. mudfish this species was designated the type species of Fundulus when Lacépède created the genus in 1803.[6]

The name mummichog is derived from a Narragansett term meaning "going in crowds", which reflects the mummichog's strong shoaling tendency.[7] Colloquial names include mummy, killie, kelley, chub, salt water minnow, mud minnow, mud dabbler, marsh minnow, brackish water chub, gudgeon, and common killifish. Some of these terms may lead to confusion: the term minnow should be reserved for species of the family Cyprinidae, the mudminnows are members of the family Umbridae, and the name gudgeon is used for various bottom-dwelling species of cyprinid, eleotrid, and ptereleotrid fishes, none of which belongs to the same family as the fundulid mummichog.[8]

Description edit

 
Mummichog at Saint Michaels, Chesapeake Bay, United States

The body of the mummichog is elongate but thick, with a deep caudal peduncle. Usual length is 7.5 to 9 cm (3.0 to 3.5 in) but a maximum length of up to 15 cm (5.9 in) is possible. The mouth is upturned and the lower jaw protrudes when the mouth is closed. Pectoral and tail fins are round. Mummichogs have 10–13 dorsal fin rays, 9–12 anal fin rays and 16–20 pectoral fin rays. Males have larger dorsal and anal fins than females. There is no lateral line on the body, but lateral line pores are present on the head. The colour is variable (and may even change in shade within the same individual when placed near different backgrounds)[9][10] but is generally olive-brown or olive-green. There can be vertical bars on the sides that are thin, wavy, and silvery. Colors are more intense in males during the reproductive season, as they become dark olive-green on the back, steel-blue on the sides with about 15 silvery bars, and yellow or orange-yellow on the underside; the dorsal fin is mottled and a small eyespot may be present near the rear edge. Females tend to be paler, without bars or the intense yellow on the belly, and their dorsal fin is uniformly coloured.[citation needed]

Adults of the two subspecies can be distinguished based on slight morphological[11] and genomic[12] differences. Further, eggs of the northern subspecies have filaments (adhesive chorionic fibrils) that eggs of the southern subspecies lack. While the northern subspecies deposits eggs in the sand, the southern subspecies often deposits eggs inside empty mussel shells.[13][14]

The mummichog is very similar to the banded killifish, Fundulus diaphanus, and indeed the two species have been known to interbreed.[15] The two species may overlap in their choice of habitat, but in general the banded killifish is more commonly found in freshwater, which is not the case for the mummichog. The banded killifish tends to have thin dark bars on a light side, whereas in the mummichog the bars are thin and light on a dark side. Internally, the banded killifish has 4–7 gill rakers, as opposed to 8–12 in the mummichog.[citation needed]

Distribution and habitat edit

This species ranges along the Atlantic coast of North America, from Gaspé Peninsula, Anticosti Island and Port au Port Bay in the north to northeastern Florida in the south. It is present on Sable Island, 175 km (109 mi) southeast of the closest point of mainland Nova Scotia in the Atlantic Ocean.[16] The approximate geographical division between the two subspecies lies in New Jersey, Delaware and Virginia.[citation needed]

Introduced populations have become established on the Atlantic coast of Portugal and southwestern Spain, starting in the 1970s[17][18][19] and some have now reached the western Mediterranean basin.[20] There may also be introduced populations in Hawaii and the Philippines.[21] As bait fish, mummichogs are sometimes released in freshwater habitats, where they can survive, and there have been reports of individuals in New Hampshire ponds, as well as the upper Ohio River and Beaver River.[22]

The mummichog is a common fish in coastal habitats such as salt marshes, muddy creeks, tidal channels, brackish estuaries, eelgrass or cordgrass beds, and sheltered shorelines. It can be found within coastal rivers but seldom beyond the head of tide. A few landlocked populations may exist in freshwater lakes close to shore, for example on Digby Neck, Nova Scotia.[23]

Diet edit

Mummichogs are agastric omnivores.[24] Analyses of their gut contents have found diatoms, amphipods and other crustaceans, molluscs, fish eggs (including their own species), very small fish, insect larvae, and bits of eelgrass.[5]

Physiology edit

This fish is well known for its ability to withstand a variety of environmental conditions.[25] They can survive temperatures between 6 and 35 °C (43–95 °F); even within the same tidal cycle they can tolerate rapid temperature changes from 15 to 30 °C (59–86 °F).[26] They are able to survive this vast temperature range by altering their metabolic rates at high and low temperatures. This is partly achieved by varying the isoenzyme of the lactate dehydrogenase (Ldh-B) enzyme expressed in warm or cold waters. These two versions of the enzyme allow for faster catalytic function and metabolism depending on if the fish is in northern, colder waters or southern, warmer waters.[27] Based on genetic studies, the enzymes serum esterase (SERE) and malate dehydrogenase (MDH) also appear to play an important role in mummichog temperature control.[28]

They are also among fish species most tolerant of salinity changes (euryhaline).[29] Mummichog larvae can grow in salinities ranging from 0.4 to 100 parts per thousand, the latter being about three times the normal salinity of seawater. Adult mummichogs tolerate low oxygen levels down to 1 mg/L, at which they resort to aquatic surface respiration (breathing in the surface layer of water, richer in oxygen because of contact with air) to survive.[30][31] They can even survive for a few hours in moist air outside of water, breathing air directly.[32]

Populations have developed resistance to methylmercury, kepone, dioxins, polychlorinated biphenyl, and polyaromatic hydrocarbons.[33] One study[34] has looked at the genomic variation exhibited by mummichogs populations living in Newark Bay, New Bedford Harbor, and the Elizabeth River (Virginia) (in some areas heavily polluted with polychlorinated biphenyls and creosote, a complex mixture containing dioxin-like chemicals) and has found that about 20% of their genes were modified as compared to populations living in clean sites.

Behavior edit

Mummichogs live in dense shoals that can include several hundred individuals.[citation needed]

During cold winter months in the northern parts of their range, mummichogs move to upstream tidal pools, where they burrow into the mud at depths up to 20 cm (7.9 in) to overwinter.[35][36] They can also bury themselves in mud if they are caught in a drying tidal pool between spring tides. Alternatively, they can travel short distances on land to get back to the sea.[37]

In the laboratory, mummichogs have yielded clear examples of free-running circadian rhythms, in both body colour[38] and swimming activity.[39] For the latter, clear rhythms were obtained in single individuals as well as in groups of 5 or 25 individuals. Evidence of free-running semi-lunar rhythms have also been obtained in mummichogs: in constant laboratory conditions, egg production peaked every 14.8 days for up to 5 months.[40]

Reproduction edit

Spawning takes place from spring through fall. In the southernmost populations, up to eight spawnings are possible in a season. Spawning takes place most often at high tide and when the moon is new or full. Maximal spawning occurs when high spring tides coincide with night,[41] though spawning during the day remains possible.[citation needed]

During courtship, males may pursue females, and females may attract males by turning on their sides near the bottom and flicking their tails. A male and female may swim together for a while, after which the male crowds the female against a rock or a plant and clasps her: the male's larger dorsal and anal fins curve around the female's body. Fingerlike projections that develop on the male's scales behind and below the dorsal fin may help the male maintain contact with the female. The pair quivers vigorously and eggs and sperm are released.[42]

The eggs are pale yellow, about 2 mm (0.08 in) in diameter, and strongly adhesive. During a spawning event, a female can deposit up to 740 eggs in separate clutches of 10 to 300 eggs at a time.[13] The eggs adhere to plants, algal mats, empty mussel shells, sand, or mud at sites that are reached by water only at high spring tides.[13] Eggs therefore develop while exposed to moist air, and they hatch when the next high spring tides reach them.[43][44][45] The eggs cannot hatch in air, nor can they do so in moving water; hatching is initiated by a lack of oxygen, something that can happen in the boundary layer of relatively still water surrounding the metabolically active egg at high tide, but not in air or in moving water.[46]

As opposed to their northern counterparts, the southern subspecies have eggs that lack filaments (adhesive chorionic fibrils)[47] and they often deposit those eggs inside empty mussel shells.[13][14] The two subspecies are also distinguished based on slight morphological[11] and genomic[12] differences.

Most mummichogs become sexually mature when two years old, around 3.8 cm (1.5 in) in length. Normal lifespan is four years.[13]

Parasites edit

Mummichogs are hosts to a parasitic fluke, Homalometron pallidum, which has a complex lifecycle involving the aquatic snail, Ecrobia truncata.[48] Other parasite species reported in mummichogs include 10 protozoans, eight trematodes, one nematode, two acanthocephalans, and two crustaceans.[49] A study in New Jersey found that mummichogs heavily infested with the digenean gill parasite Ascocotyle phagicola, spent more time near the surface and exhibited conspicuous behaviors such as jerking, an example of a parasite affecting the behavior of its host in a way beneficial to the parasite, as conspicuous behaviors near the surface make the fish more likely to be noticed by predatory wading birds, the next host in the parasite's life cycle.[50]

Interest to humans edit

Mummichogs readily eat mosquito larvae and attempts have been made to use them as biocontrol agents of mosquito populations.[26]

Fishing edit

Mummichogs are sold as bait in sport fisheries for marine species such as summer flounder and bluefish, or even sometimes for freshwater species.[26] They are the most popular baitfish species in the Northeast of America and traditionally when used as bait they were lip hooked and then dressed with a piece of squid.[51]

Scientific utility edit

Mummichogs are considered an important environmental model organism because of their ability to tolerate various extremes of chemical (pollution, etc.) and physical (temperature, salinity, oxygen, etc.) conditions. They are relatively abundant in nature and can be easily captured, transported and reared in laboratory facilities. They are commonly used in scientific studies of stress biology,[52] thermal physiology and toxicology, and have also been studied in the contexts of evolutionary biology, developmental biology, endocrinology, cancer biology, and chronobiology (study of circadian rhythms).[53][54] With the successful sequencing and assembly of the full killifish genome,[55] they serve as a premier scientific model for studying biochemical and physiological responses to varying environmental conditions.[56]

Their remarkable ability to tolerate various extremes of temperature and salinity has made them popular subjects in scientific studies of toxicology. For decades the killifish has been a useful laboratory model for toxicological studies that include exposures to single chemicals, chemical mixtures, and complex contaminated media.[57] It is sometimes the only fish species found in severely polluted and oxygen-deprived waterways, such as the Elizabeth River in Virginia and, in New Jersey, the Hackensack River and the Arthur Kill. A 2008 Virginia Institute of Marine Science report stated that 38% of mummichogs from Elizabeth River had cancerous lesions, and "more than half had pre-cancerous lesions. That was largely due to high levels of polycyclic aromatic hydrocarbons".[58]

Killifish eggs are used in developmental studies and when teaching embryology because the eyes, the beating heart, and the different stages of ontogenesis can be easily examined. Embryos are also extremely durable and easy to manipulate in the laboratory.[57]

Mummichogs were the first fish sent to space.[59] In 1973 a couple of them were flown in a plastic bag aquarium aboard Skylab, during the Skylab 3 mission. In the absence of gravity the fish at first exhibited an unusual swimming behavior: they constantly pitched forward and therefore described tight circles. However, by day 22 of the mission they swam normally. Fifty eggs at an advanced stage of development had also been taken on board, and 48 of them hatched during the flight. The hatchlings swam normally.[60] More experiments with mummichogs in space followed as part of the Apollo-Soyuz Test Project[61] and as part of a biological package aboard the Bion 3/Kosmos 782 satellite.[62]

See also edit

References edit

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  58. ^ Rona Kobell Elizabeth River rises from the depths.Dedicated group is slowly bringing one of nation's most polluted rivers back to life. Bay Journal, July 01, 2011
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  62. ^ NASA . Archived from the original on 2006-09-29.

External links edit

  •   Media related to Fundulus heteroclitus at Wikimedia Commons
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December 15, 2023
mummichog, mummichog, fundulus, heteroclitus, small, killifish, found, along, atlantic, coast, united, states, canada, also, known, atlantic, killifish, mummies, gudgeons, minnows, these, fish, inhabit, brackish, coastal, waters, including, estuaries, salt, ma. The mummichog Fundulus heteroclitus is a small killifish found along the Atlantic coast of the United States and Canada Also known as Atlantic killifish mummies gudgeons and mud minnows these fish inhabit brackish and coastal waters including estuaries and salt marshes The species is noted for its hardiness and ability to tolerate highly variable salinity temperature fluctuations from 6 to 35 C 43 to 95 F very low oxygen levels down to 1 mg L and heavily polluted ecosystems As a result the mummichog is a popular research subject in embryological physiological and toxicological studies It is also the first fish ever sent to space aboard Skylab in 1973 MummichogConservation statusLeast Concern IUCN 3 1 1 Scientific classificationDomain EukaryotaKingdom AnimaliaPhylum ChordataClass ActinopterygiiOrder CyprinodontiformesFamily FundulidaeGenus FundulusSpecies F heteroclitusBinomial nameFundulus heteroclitus Linnaeus 1766 Synonyms 2 3 4 Cobitis heteroclita Linnaeus 1766 Cobitis macrolepidota Walbaum 1792 Fundulus mudfish Lacepede 1803 Esox pisciculus Mitchill 1815 Esox pisculentus Mitchill 1815 Fundulus antillarum Fowler 1916 Fundulus badius Garman 1895 Fundulus coenicolus Bloch amp Schneider 1801 Fundulus fasciatus Bloch amp Schneider 1801 Fundulus fonticola Valenciennes 1846 Fundulus lozanoi Gomez Caruana et al 1984 Fundulus nigrofaciatus Lesueur 1817 Fundulus nisorius Cope 1870 Fundulus ornatus Lesueur 1817 Fundulus pisciculus Mitchill 1815 Fundulus swampinus Lacepede 1803 Fundulus vinctus Jordan amp Gilbert 1882 Fundulus viridescens DeKay 1842 Fundulus zebra DeKay 1842 Hydargira nigrofaciata Lesueur 1817 Hydrargira ornata Lesueur 1817 Hydrargira swampina Lacepede 1803 Poecilia coenicola Bloch amp Schneider 1801 Poecilia fasciata Bloch amp Schneider 1801 Valencia lozanoi Gomez Caruana et al 1984 Contents 1 Taxonomy 2 Description 3 Distribution and habitat 4 Diet 5 Physiology 6 Behavior 6 1 Reproduction 7 Parasites 8 Interest to humans 8 1 Fishing 8 2 Scientific utility 9 See also 10 References 11 External linksTaxonomy editThe genus name Fundulus comes from fundus meaning bottom from the fish s habit of swimming near muddy bottoms The species name heteroclitus means irregular or unusual The type specimen was first described by Carl Linnaeus in 1766 from near Charleston South Carolina Other scientific names now considered synonyms for this species include Cobitis heteroclita Fundulus fasciatus Fundulus pisculentus and Fundulus nigrofasciatus 5 The mummichog belongs to the order Cyprinodontiformes and the family Fundulidae There are two subspecies F h heteroclitus Linnaeus 1766 in the south and F h macrolepidotus Walbaum 1792 in the north As F mudfish this species was designated the type species of Fundulus when Lacepede created the genus in 1803 6 The name mummichog is derived from a Narragansett term meaning going in crowds which reflects the mummichog s strong shoaling tendency 7 Colloquial names include mummy killie kelley chub salt water minnow mud minnow mud dabbler marsh minnow brackish water chub gudgeon and common killifish Some of these terms may lead to confusion the term minnow should be reserved for species of the family Cyprinidae the mudminnows are members of the family Umbridae and the name gudgeon is used for various bottom dwelling species of cyprinid eleotrid and ptereleotrid fishes none of which belongs to the same family as the fundulid mummichog 8 Description edit nbsp Mummichog at Saint Michaels Chesapeake Bay United StatesThe body of the mummichog is elongate but thick with a deep caudal peduncle Usual length is 7 5 to 9 cm 3 0 to 3 5 in but a maximum length of up to 15 cm 5 9 in is possible The mouth is upturned and the lower jaw protrudes when the mouth is closed Pectoral and tail fins are round Mummichogs have 10 13 dorsal fin rays 9 12 anal fin rays and 16 20 pectoral fin rays Males have larger dorsal and anal fins than females There is no lateral line on the body but lateral line pores are present on the head The colour is variable and may even change in shade within the same individual when placed near different backgrounds 9 10 but is generally olive brown or olive green There can be vertical bars on the sides that are thin wavy and silvery Colors are more intense in males during the reproductive season as they become dark olive green on the back steel blue on the sides with about 15 silvery bars and yellow or orange yellow on the underside the dorsal fin is mottled and a small eyespot may be present near the rear edge Females tend to be paler without bars or the intense yellow on the belly and their dorsal fin is uniformly coloured citation needed Adults of the two subspecies can be distinguished based on slight morphological 11 and genomic 12 differences Further eggs of the northern subspecies have filaments adhesive chorionic fibrils that eggs of the southern subspecies lack While the northern subspecies deposits eggs in the sand the southern subspecies often deposits eggs inside empty mussel shells 13 14 The mummichog is very similar to the banded killifish Fundulus diaphanus and indeed the two species have been known to interbreed 15 The two species may overlap in their choice of habitat but in general the banded killifish is more commonly found in freshwater which is not the case for the mummichog The banded killifish tends to have thin dark bars on a light side whereas in the mummichog the bars are thin and light on a dark side Internally the banded killifish has 4 7 gill rakers as opposed to 8 12 in the mummichog citation needed Distribution and habitat editThis species ranges along the Atlantic coast of North America from Gaspe Peninsula Anticosti Island and Port au Port Bay in the north to northeastern Florida in the south It is present on Sable Island 175 km 109 mi southeast of the closest point of mainland Nova Scotia in the Atlantic Ocean 16 The approximate geographical division between the two subspecies lies in New Jersey Delaware and Virginia citation needed Introduced populations have become established on the Atlantic coast of Portugal and southwestern Spain starting in the 1970s 17 18 19 and some have now reached the western Mediterranean basin 20 There may also be introduced populations in Hawaii and the Philippines 21 As bait fish mummichogs are sometimes released in freshwater habitats where they can survive and there have been reports of individuals in New Hampshire ponds as well as the upper Ohio River and Beaver River 22 The mummichog is a common fish in coastal habitats such as salt marshes muddy creeks tidal channels brackish estuaries eelgrass or cordgrass beds and sheltered shorelines It can be found within coastal rivers but seldom beyond the head of tide A few landlocked populations may exist in freshwater lakes close to shore for example on Digby Neck Nova Scotia 23 Diet editMummichogs are agastric omnivores 24 Analyses of their gut contents have found diatoms amphipods and other crustaceans molluscs fish eggs including their own species very small fish insect larvae and bits of eelgrass 5 Physiology editThis fish is well known for its ability to withstand a variety of environmental conditions 25 They can survive temperatures between 6 and 35 C 43 95 F even within the same tidal cycle they can tolerate rapid temperature changes from 15 to 30 C 59 86 F 26 They are able to survive this vast temperature range by altering their metabolic rates at high and low temperatures This is partly achieved by varying the isoenzyme of the lactate dehydrogenase Ldh B enzyme expressed in warm or cold waters These two versions of the enzyme allow for faster catalytic function and metabolism depending on if the fish is in northern colder waters or southern warmer waters 27 Based on genetic studies the enzymes serum esterase SERE and malate dehydrogenase MDH also appear to play an important role in mummichog temperature control 28 They are also among fish species most tolerant of salinity changes euryhaline 29 Mummichog larvae can grow in salinities ranging from 0 4 to 100 parts per thousand the latter being about three times the normal salinity of seawater Adult mummichogs tolerate low oxygen levels down to 1 mg L at which they resort to aquatic surface respiration breathing in the surface layer of water richer in oxygen because of contact with air to survive 30 31 They can even survive for a few hours in moist air outside of water breathing air directly 32 Populations have developed resistance to methylmercury kepone dioxins polychlorinated biphenyl and polyaromatic hydrocarbons 33 One study 34 has looked at the genomic variation exhibited by mummichogs populations living in Newark Bay New Bedford Harbor and the Elizabeth River Virginia in some areas heavily polluted with polychlorinated biphenyls and creosote a complex mixture containing dioxin like chemicals and has found that about 20 of their genes were modified as compared to populations living in clean sites Behavior editMummichogs live in dense shoals that can include several hundred individuals citation needed During cold winter months in the northern parts of their range mummichogs move to upstream tidal pools where they burrow into the mud at depths up to 20 cm 7 9 in to overwinter 35 36 They can also bury themselves in mud if they are caught in a drying tidal pool between spring tides Alternatively they can travel short distances on land to get back to the sea 37 In the laboratory mummichogs have yielded clear examples of free running circadian rhythms in both body colour 38 and swimming activity 39 For the latter clear rhythms were obtained in single individuals as well as in groups of 5 or 25 individuals Evidence of free running semi lunar rhythms have also been obtained in mummichogs in constant laboratory conditions egg production peaked every 14 8 days for up to 5 months 40 Reproduction edit Spawning takes place from spring through fall In the southernmost populations up to eight spawnings are possible in a season Spawning takes place most often at high tide and when the moon is new or full Maximal spawning occurs when high spring tides coincide with night 41 though spawning during the day remains possible citation needed During courtship males may pursue females and females may attract males by turning on their sides near the bottom and flicking their tails A male and female may swim together for a while after which the male crowds the female against a rock or a plant and clasps her the male s larger dorsal and anal fins curve around the female s body Fingerlike projections that develop on the male s scales behind and below the dorsal fin may help the male maintain contact with the female The pair quivers vigorously and eggs and sperm are released 42 The eggs are pale yellow about 2 mm 0 08 in in diameter and strongly adhesive During a spawning event a female can deposit up to 740 eggs in separate clutches of 10 to 300 eggs at a time 13 The eggs adhere to plants algal mats empty mussel shells sand or mud at sites that are reached by water only at high spring tides 13 Eggs therefore develop while exposed to moist air and they hatch when the next high spring tides reach them 43 44 45 The eggs cannot hatch in air nor can they do so in moving water hatching is initiated by a lack of oxygen something that can happen in the boundary layer of relatively still water surrounding the metabolically active egg at high tide but not in air or in moving water 46 As opposed to their northern counterparts the southern subspecies have eggs that lack filaments adhesive chorionic fibrils 47 and they often deposit those eggs inside empty mussel shells 13 14 The two subspecies are also distinguished based on slight morphological 11 and genomic 12 differences Most mummichogs become sexually mature when two years old around 3 8 cm 1 5 in in length Normal lifespan is four years 13 Parasites editMummichogs are hosts to a parasitic fluke Homalometron pallidum which has a complex lifecycle involving the aquatic snail Ecrobia truncata 48 Other parasite species reported in mummichogs include 10 protozoans eight trematodes one nematode two acanthocephalans and two crustaceans 49 A study in New Jersey found that mummichogs heavily infested with the digenean gill parasite Ascocotyle phagicola spent more time near the surface and exhibited conspicuous behaviors such as jerking an example of a parasite affecting the behavior of its host in a way beneficial to the parasite as conspicuous behaviors near the surface make the fish more likely to be noticed by predatory wading birds the next host in the parasite s life cycle 50 Interest to humans editMummichogs readily eat mosquito larvae and attempts have been made to use them as biocontrol agents of mosquito populations 26 Fishing edit Mummichogs are sold as bait in sport fisheries for marine species such as summer flounder and bluefish or even sometimes for freshwater species 26 They are the most popular baitfish species in the Northeast of America and traditionally when used as bait they were lip hooked and then dressed with a piece of squid 51 Scientific utility edit Mummichogs are considered an important environmental model organism because of their ability to tolerate various extremes of chemical pollution etc and physical temperature salinity oxygen etc conditions They are relatively abundant in nature and can be easily captured transported and reared in laboratory facilities They are commonly used in scientific studies of stress biology 52 thermal physiology and toxicology and have also been studied in the contexts of evolutionary biology developmental biology endocrinology cancer biology and chronobiology study of circadian rhythms 53 54 With the successful sequencing and assembly of the full killifish genome 55 they serve as a premier scientific model for studying biochemical and physiological responses to varying environmental conditions 56 Their remarkable ability to tolerate various extremes of temperature and salinity has made them popular subjects in scientific studies of toxicology For decades the killifish has been a useful laboratory model for toxicological studies that include exposures to single chemicals chemical mixtures and complex contaminated media 57 It is sometimes the only fish species found in severely polluted and oxygen deprived waterways such as the Elizabeth River in Virginia and in New Jersey the Hackensack River and the Arthur Kill A 2008 Virginia Institute of Marine Science report stated that 38 of mummichogs from Elizabeth River had cancerous lesions and more than half had pre cancerous lesions That was largely due to high levels of polycyclic aromatic hydrocarbons 58 Killifish eggs are used in developmental studies and when teaching embryology because the eyes the beating heart and the different stages of ontogenesis can be easily examined Embryos are also extremely durable and easy to manipulate in the laboratory 57 Mummichogs were the first fish sent to space 59 In 1973 a couple of them were flown in a plastic bag aquarium aboard Skylab during the Skylab 3 mission In the absence of gravity the fish at first exhibited an unusual swimming behavior they constantly pitched forward and therefore described tight circles However by day 22 of the mission they swam normally Fifty eggs at an advanced stage of development had also been taken on board and 48 of them hatched during the flight The hatchlings swam normally 60 More experiments with mummichogs in space followed as part of the Apollo Soyuz Test Project 61 and as part of a biological package aboard the Bion 3 Kosmos 782 satellite 62 See also editJapanese rice fish Oryzias latipes first fish to breed in space in 1994References edit NatureServe 2013 Fundulus heteroclitus IUCN Red List of Threatened Species 2013 e T189824A18236919 doi 10 2305 IUCN UK 2013 1 RLTS T189824A18236919 en Retrieved 19 November 2021 Nicolas Bailly 2014 Bailly N ed Fundulus heteroclitus heteroclitus Linnaeus 1766 FishBase World Register of Marine Species Retrieved March 12 2015 Nicolas Bailly 2014 Bailly N ed Fundulus heteroclitus macrolepidotus Walbaum 1792 FishBase World Register of Marine Species Retrieved March 12 2015 Eschmeyer William N Fricke Ron amp van der Laan Richard eds Species in the genus Fundulus Catalog of Fishes California Academy of Sciences Retrieved 24 September 2019 a b Scott W B and Crossman E J 1973 Freshwater fishes of Canada Bulletin 184 of the Fisheries Research Board of Canada Ottawa Eschmeyer William N Fricke Ron amp van der Laan Richard eds Fundulus Catalog of Fishes California Academy of Sciences Retrieved 24 September 2019 Mummichog Merriam Webster com Merriam Webster n d Web 6 February 2014 http www merriam webster com dictionary mummichog Helfman G S Collette B B Facey D E and Boweb B W 2009 The Diversity of Fishes 2nd ed Wiley Blackwell Oxford Connolly C J 1925 Adaptive changes in shades and color of Fundulus Biological Bulletin Woods Hole 48 56 77 Bagnara J T and Hadley M E 1973 Chromatophores and color change Prentice Hall New Jersey a b Able K W Felley J D 1986 Geographical variation in Fundulus heteroclitus tests for concordance between egg and adult morphologies American Zoologist 26 145 157 doi 10 1093 icb 26 1 145 a b Brown B L Chapman R W 1991 Gene flow and mitochondrial DNA variation in the killifish Fundulus heteroclitus Evolution 45 5 1147 1161 doi 10 2307 2409722 JSTOR 2409722 PMID 28564171 a b c d e Coad B W 1995 Encyclopedia of Canadian Fishes Canadian Museum of Nature Ottawa 928p a b Taylor M H 1986 Environmental and endocrine influences on reproduction of Fundulus heteroclitus American Zoologist 26 159 171 doi 10 1093 icb 26 1 159 Hubbs C L Walker B W and Johnson R E 1943 Hybridization in nature between species of American cyprinodont fishes Contributions to the Laboratory of Vertebrate Biology of the University of Michigan 23 21 p Garside E T 1969 Distribution of insular fishes of Sable Island Nova Scotia Journal of the Fisheries Research Board of Canada 26 5 1390 1392 doi 10 1139 f69 126 Hernando J A 1975 Nuevas localidades de Valencia hispanica Pisces Ciprinodontidae en el Suroeste de Espana Donana Acta Vertebrata 2 265 267 Coelho M Gomes J Re P B 1976 Valencia hispanica a new fish to Portugal Arquivos do Museu Bocage 6 1 3 Gutierrez Estrada J C Prenda J Oliva F Fernandez Delgado C 1998 Distribution and habitat preferences of the introduced mummichog Fundulus heteroclitus Linneaus sic in South western Spain PDF Estuarine Coastal and Shelf Science 46 6 827 835 doi 10 1006 ecss 1997 0318 hdl 10272 4178 Gisbert E Lopez M A 2007 First record of a population of the exotic mummichog Fundulus heteroclitus L 1766 in the Mediterranean Sea basin Ebro River delta Journal of Fish Biology 71 4 1220 1224 doi 10 1111 j 1095 8649 2007 01579 x Fish Base Mummichog distribution USGS Nonindigenous aquatic species database Mummichog occurrences Klawe W L 1957 Common mummichog and newt in a lake on Digby Neck Nova Scotia Canadian Field Naturalist 71 154 155 Wood Chris M Bucking Carol Grosell Martin 2010 08 01 Acid base responses to feeding and intestinal Cl uptake in freshwater and seawater acclimated killifish Fundulus heteroclitus an agastric euryhaline teleost Journal of Experimental Biology 213 15 2681 2692 doi 10 1242 jeb 039164 ISSN 1477 9145 PMID 20639430 Burnett K G Bain L J Baldwin D S et al 2007 Fundulus as the premier teleost model in environmental biology Opportunities for new insights using genomics Comparative Biochemistry and Physiology D 2 4 257 266 doi 10 1016 j cbd 2007 09 001 PMC 2128618 PMID 18071578 a b c Abraham B J 1985 Species Profiles Life histories and environmental requirements of coastal fishes and invertebrates Mid Atlantic mummichog and striped killifish U S Fish and Wildlife Service Biological Reports 82 11 40 23 p http www nwrc usgs gov wdb pub species profiles 82 11 040 pdf Mitton Jeffry B Koehn Richard K 1975 01 01 Genetic Organization and Adaptive Response of Allozymes to Ecological Variables in Fundulus Heteroclitus Genetics 79 1 97 111 doi 10 1093 genetics 79 1 97 ISSN 1943 2631 PMC 1213263 PMID 1126624 Powers Dennis A Schulte Patricia M September 1998 lt 71 aid jez11 gt 3 0 co 2 j Evolutionary adaptations of gene structure and expression in natural populations in relation to a changing environment A multidisciplinary approach to address the million year saga of a small fish The Journal of Experimental Zoology 282 1 2 71 94 doi 10 1002 sici 1097 010x 199809 10 282 1 2 lt 71 aid jez11 gt 3 0 co 2 j ISSN 0022 104X PMID 9723168 Whitehead A 2010 The evolutionary radiation of diverse osmotolerant physiologies in killifish Fundulus sp Evolution 64 7 2070 2085 doi 10 1111 j 1558 5646 2010 00957 x PMID 20100216 S2CID 23354536 Wannamaker C M Rice J A 2000 Effects of hypoxia on movements and behavior of selected estuarine organisms from the southeastern United States Journal of Experimental Marine Biology and Ecology 249 2 145 163 doi 10 1016 s0022 0981 00 00160 x PMID 10841932 Stierhoff K L Targett T E Grecay P A 2003 Hypoxia tolerance of the mummichog the role of access to the water surface Journal of Fish Biology 63 3 580 592 doi 10 1046 j 1095 8649 2003 00172 x Halpin P M Martin K L M 1999 Aerial respiration in the salt marsh fish Fundulus heteroclitus Fundulidae Copeia 1999 3 743 748 doi 10 2307 1447607 JSTOR 1447607 Weis J 2002 Tolerance to environmental contaminants in the mummichog Fundulus heteroclitus Human and Ecological Risk Assessment 8 5 933 953 doi 10 1080 1080 700291905756 S2CID 85361429 Whitehead A Galvez F Zhang S Williams L M Oleksiak M F 2011 Functional genomics of physiological plasticity and local adaptation in killifish Journal of Heredity 102 5 499 511 doi 10 1093 jhered esq077 PMC 3156563 PMID 20581107 Chidester F E 1920 The behavior of Fundulus heteroclitus in the salt marshes of New Jersey American Naturalist 54 635 244 245 doi 10 1086 279787 S2CID 83738153 Raposa K 2003 Overwintering habitat selection by the mummichog Fundulus heteroclitus in a Cape Cod USA salt marsh Wetlands Ecology and Management 11 3 175 182 doi 10 1023 A 1024244317173 S2CID 27058471 Mast S O 1915 The behavior of Fundulus with especial reference to overland escape from tide pools and locomotion on land Journal of Animal Behavior 5 5 341 350 doi 10 1037 h0075747 Kavaliers M Abbott F S 1977 Rhythmic colour change of the killifish Fundulus heteroclitus Canadian Journal of Zoology 55 3 553 561 doi 10 1139 z77 070 Kavaliers M 1980 Social groupings and circadian activity of the killifish Fundulus heteroclitus Biological Bulletin 158 1 69 76 doi 10 2307 1540759 JSTOR 1540759 Hsiao S M Meier A H 1989 Comparison of semilunar cycles of spawning activity in Fundulus grandis and F heteroclitus held under constant laboratory conditions Journal of Experimental Zoology 252 3 213 218 doi 10 1002 jez 1402520302 Taylor M H Leach G J DiMichele L Levithan W H Jacob W F 1979 Lunar spawning cycle in the mummichog Fundulus Heteroclitus Pisces Cyprinodontidae Copeia 1979 2 291 297 doi 10 2307 1443417 JSTOR 1443417 Newman H H 1907 Spawning behavior and sexual dimorphism in Fundulus heteroclitus and allied fish Biological Bulletin Woods Hole 12 5 314 345 doi 10 2307 1535681 JSTOR 1535681 Taylor M H DiMichele L and Leach G J 1977 Egg stranding in the life cycle of the mummichog Fundulus heteroclitus Copeia 1977 397 399 Taylor M H DiMichele L 1983 Spawning site utilization in a Delaware population of Fundulus heteroclitus Pisces Cyprinodontidae Copeia 1983 3 719 725 doi 10 2307 1444338 JSTOR 1444338 Taylor M H 1999 A suite of adaptations for intertidal spawning American Zoologist 39 2 313 320 doi 10 1093 icb 39 2 313 DiMichele L Powers D A 1984 The relationship between oxygen consumption rate and hatching in Fundulus heteroclitus Physiological Zoology 57 46 51 doi 10 1086 physzool 57 1 30155966 S2CID 87680036 Morin R P Able K W 1983 Patterns of geographic variation in the egg morphology of the fundulid fish Fundulus heteroclitus Copeia 1983 3 726 740 doi 10 2307 1444339 JSTOR 1444339 Stunkard Horace W 1964 The morphology life history and systematics of the digenetic trematode Homalometron pallidum Stafford 1904 PDF The Biological Bulletin 126 1 163 173 doi 10 2307 1539426 JSTOR 1539426 Hoffman G L 1967 Parasites of North American freshwater fishes University of California Press Berkeley 486 pp Santiago Bass C Weis J S 2009 Conspicuous behaviour of Fundulus heteroclitus associated with high digenean metacercariae gill abundances Journal of Fish Biology 74 4 763 772 doi 10 1111 j 1095 8649 2008 02148 x PMID 20735598 Saccente Frank Workhorse Bait Angler s Journal 4 1 38 Schulte P M 1 January 2014 What is environmental stress Insights from fish living in a variable environment The Journal of Experimental Biology 217 Pt 1 23 34 doi 10 1242 JEB 089722 ISSN 0022 0949 PMID 24353201 Wikidata Q34393031 Kavaliers M 1980 Social groupings and circadian activity of the killifish Fundulus heteroclitus Biological Bulletin 158 1 69 76 doi 10 2307 1540759 JSTOR 1540759 Kavaliers M Abbott F S 1977 Rhythmic colour change of the killifish Fundulus heteroclitus Canadian Journal of Zoology 55 3 553 561 doi 10 1139 z77 070 Home Genome NCBI Lister AL Van Der Kraak GJ Rutherford R MacLatchy D 2011 Fundulus heteroclitus ovarian reproductive physiology and the impact of environmental contaminants Comparative Biochemistry and Physiology C 154 4 278 287 doi 10 1016 j cbpc 2011 07 004 PMID 21771666 a b Atz J W 1986 Fundulus heteroclitus in the laboratory A history American Zoologist 26 111 120 doi 10 1093 icb 26 1 111 Rona Kobell Elizabeth River rises from the depths Dedicated group is slowly bringing one of nation s most polluted rivers back to life Bay Journal July 01 2011 Reebs S G 2009 Fish in space Retrieved 12 December 2014 Von Baumgarten R J Simmonds R C Boyd J F Garriott O K 1975 Effects of prolonged weightlessness on the swimming pattern of fish aboard Skylab 3 Aviation Space and Environmental Medicine 46 7 902 906 PMID 1156300 Hoffman R B Salinas G A Baky A A 1977 Behavioral analyses of killifish exposed to weightlessness in the Apollo Soyuz test project Aviation Space and Environmental Medicine 48 8 712 717 PMID 889544 NASA Bion 3 Kosmos 782 Archived from the original on 2006 09 29 External links edit nbsp Media related to Fundulus heteroclitus at Wikimedia Commons Fishbase entry with image Retrieved from https en wikipedia org w index php title Mummichog amp oldid 1175108284, wikipedia, wiki, book, books, library,

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