Hornwrack (Flustra foliacea)

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Summary

Description

Flustra foliacea forms a stiff but flexible bushy clump 6 -10 cm high, occasionally up to 20cm high. Flustra foliacea is much divided into fronds that are usually broadly lobed, occasionally strap-like, and made up of zooids (individuals) on both sides (bilaminar). Fronds are light grey to brown in colour. Zooids are tongue shaped, 0.4 mm long and 0.2 - 0.28 mm wide. They bear 4 to 5 marginal club-like spines at the broad (distal) end of each zooid. The fronds have a distinct smell of lemons when freshly collected. Hornwrack is sometimes found washed ashore after storms.

Recorded distribution in Britain and Ireland

Common on all rocky coasts of Britain and Ireland.

Global distribution

Flustra foliacea occurs in the Kara Sea, White Sea and Barents Sea in the Arctic circle, the North Sea, and extends south as far as Bay of Biscay. Also found on the east coast of Greenland.

Habitat

Found on coarse sediment and rocky substrate in the shallow sublittoral, where it favours current-swept rocky grounds.

Depth range

Sublittoral 1 -200m

Identifying features

  • Bushy clumps of palmate, flattened fronds, 6 -10 cm but occasionally 20 cm high.
  • Distinct smell of lemons when fresh.
  • Zooids are tongue shaped and bear 4 to 5 marginal club-like spines on their broad, distal margin and lacks an ascus (anascan).
  • Fronds composed of a double layered (bilaminar) sheet of zooids.
  • Zooids arranged in a quincunx pattern, i.e. four zooids surrounding a central one.
  • The polypide of each zooid bears 13-14 tentacles.
  • Avicularia about half the size of the autozooids (feeding zooids) and arise at the bifurcation between rows of autozooids.
  • Ovicell immersed, endozooidal, embedded in the base of the distal zooid.

Additional information

Flustra foliacea forms only a flat incrustation during its first year of growth, erect growth occurs in subsequent years. Fronds can often be encrusted by other bryozoans, hydroids and sedentary polychaetes.

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Biology review

Taxonomy

LevelScientific nameCommon name
PhylumBryozoa
ClassGymnolaemata
OrderCheilostomatida
FamilyFlustridae
GenusFlustra
Authority(Linnaeus, 1758)
Recent Synonyms

Biology

ParameterData
Typical abundanceModerate density
Male size range
Male size at maturity
Female size rangeMedium (11-20 cm)
Female size at maturity
Growth formModular, Turf
Growth rate1.6-3cm/year
Body flexibilityHigh (greater than 45 degrees)
MobilitySessile, permanent attachment
Characteristic feeding methodActive suspension feeder
Diet/food sourceOmnivore
Typically feeds onPhytoplankton, detritus and dissolved organic matter.
SociabilitySolitary
Environmental positionEpibenthic
DependencyIndependent.
SupportsSubstratum

Small green algae, bryozoans, hydroids, sessile polychaetes, barnacles, lamellibranchs and tunicates (see additional information below)

Is the species harmful?See additional information

Biology information

Growth form. Detailed diagrams of the autozooid and avicularium of Flustra foliacea are provided by Silén (1977). The newly metamorphosed coronate larvae develop into the first zooid of the new colony, the 'ancestrula'. In its first year of growth, Flustra foliacea forms a flat incrustation on the substratum and commences erect growth during the second year. This is achieved simply by the opposition of actively growing lobes of a colony; on contact two growing edges are deflected vertically (J. Porter, pers. comm.). The two layers of zooids grow, synchronously 'back to back' forming a bilaminar, erect frond at 90 ° to the original encrusting mat. Branching of the erect fronds varies between branches and colonies (Stebbing, 1971a; Silén, 1981). Ryland (1976) suggested that erect growth avoids the spatial constraints (availability of substratum and competition) suffered by encrusting forms. Repair of grazing damage, i.e. removal of one bilaminar layer, may result in the generation of a new bilateral branch (Stebbing, 1971a).

Growth rates. Stebbing (1971a) reported that growth began in late February or early March but stopped in November in specimens off the Gower Peninsula, with a slight check in growth in August, and no growth occurred over winter. Growth stopped in October in Isle of Man specimens (Eggleston, 1963; cited in Stebbing, 1971a). The winter growth check results in visible annual growth lines, which have been used to age colonies (Stebbing, 1971a; Eggleston, 1972; Menon, 1978). Stebbing (1971a) suggested that the growth line formed a line of weakness, which gave the frond flexibility. Stebbing (1971a) stated that the length of time spent as an encrusting form was unclear but assumed the first growth line at the base of the frond represented the first winter, one-year growth. Flustra foliacea colonies regularly reached six years of age, although 12-year-old specimens were reported off the Gower Peninsula (Stebbing, 1971a; Ryland, 1976). Furthermore, O'Dea & Okamura (2000) demonstrated seasonal fluctuations in zooid size synchronous with temperature regimes, with the largest zooids occurring with the lowest temperatures. Stebbing (1971a) reported that growth rates were reasonably consistent between samples, age classes and years. Stebbing (1971a) reported a mean increment in frond height of 16.8mm/yr, whereas Eggleston (1972) reported that annual lines were usually between 2-3 cm apart in Isle of Man specimens, and Menon (1978) reported that Helgoland specimens reached an average of 21.2 mm in height at two years old and an average of 79.3 mm after 8 years. Silén (1981) reported that erect fronds grew in zooid number about 10-20 times that of the encrusting base. Menon (1978) reported that growth rates varied in specimens over five years old. At the base of fronds, in the holdfast area, the zooids give rise to layers of non-feeding frontal buds after three years of age, which strengthen the base of the frond. The number of layers increases with frond height up to 145mm in height, and up to 20 layers deep (Stebbing, 1971a).  Growth rates probably vary between locations. O'Dea & Okumara (2000) noted that colonies of Flustra foliacea from the Bay of Fundy showed reduced growth compared to colonies in the Menai Straits and the Skagerrak. Low primary productivity, genetic variation and parasitism were cited as possible explanations for the difference.

Regeneration and repair. Silén (1981) reported that the experimental removal of a notch in the frond was repaired within 5 -10 days. The newly formed margin grew at normal rates (4-5 zooid lengths per month). Removal of one layer of the bilaminar frond, experimentally (Silén, 1981) or by predators (Stebbing, 1971a) was repaired with similar rapidity, the un-damaged layer, halting growth while the damaged area was repaired (Silén, 1981).

Epiphytes. The epizoic fauna of Flustra foliacea was described by Stebbing (1971b) and consisted of 25 species of bryozoan, five hydroid species, some sessile polychaetes, barnacles, lamellibranchs and tunicates. The bryozoans Bugulina flabellata, Crisia spp. and Scrupocellaria spp. were major epizoites. The stolons of Bugulina flabellata penetrate the zooids of Flustra foliacea. Scrupocellaria spp. settled preferentially on the youngest, distal, portions of the frond, possibly to elevate their branches into faster-flowing water (Stebbing, 1971b). A small green alga Epicladia flustrae was reported to be a specific epiphyte (Nielsen, 1984). Stebbing (1971a) reported that the growth rates of Flustra foliacea were reduced by ca 50% when encrusted by epizoites. Peters et al, (2003) reported the presence of chemical compounds in Flustra foliacea that demonstrated antagonistic effects against the growth of some associated bacterial species, and electron microscopic examination of the distal end of the zooid revealed no microbial settlement. Dyrynda (1985, cited in Peters et al., 1985) reported the toxicity of extracts of Flustra foliacea on larvae of other modular invertebrates, fish and bacteria.

Toxicity. Some people can react to Flustra sp. and some fishermen have reported allergic reactions to it although this is anecdotal information (J. Porter, pers. comm.). Research into biomedical compounds from marine organisms has revealed that a sample of Flustra foliacea from the southern North Sea yielded deformylflustrabromine, which was moderately cytotoxic to the human colon cancer cell line HCT-116 (Lysek et al., 2002; Jha & Zi-rong, 2004).

Habitat preferences

ParameterData
Physiographic preferencesOpen coast, Offshore seabed, Strait or Sound, Sea loch or Sea lough, Ria or Voe
Biological zone preferencesLower circalittoral, Lower infralittoral, Upper circalittoral, Upper infralittoral
Substratum / habitat preferencesBedrock, Cobbles, Large to very large boulders, Mixed, Small boulders
Tidal strength preferencesModerately strong 1 to 3 knots (0.5-1.5 m/sec.), Strong 3 to 6 knots (1.5-3 m/sec.), Very strong > 6 knots (>3 m/sec.), Weak < 1 knot (<0.5 m/sec.)
Wave exposure preferencesExposed, Moderately exposed, Sheltered, Very exposed
Salinity preferencesFull (30-40 psu)
Depth rangeSublittoral 1 -200m
Other preferencesNo text entered
Migration PatternNon-migratory or resident

Habitat Information

Flustra foliacea may colonize any hard substratum, such as shells, stones, or cobbles but forms dense aggregations particularly in otherwise barren, current swept rocky bottoms. Although present in a wide range of tidal streams and wave exposure, Flustra foliacea is abundant in moderately strong to strong tidal streams (Hiscock, 1983). Dyer et al. (1982) reported between <10 to >200 colonies per m² in trawls in the North Sea. Flustra foliacea is associated with strong currents and areas subject to sediment abrasion (Stebbing, 1971a; Knight-Jones & Nelson-Smith, 1977; Hartnoll, 1983; Holme & Wilson, 1985) and requires stable hard substrata (Eggleston, 1972b; Ryland, 1976; Dyrynda, 1994). The abundance of bryozoans is positively correlated with supply of stable hard substrata and hence with current strength (Eggleston, 1972b; Ryland, 1976).

Life history

Adult characteristics

ParameterData
Reproductive typePermanent (synchronous) hermaphrodite
Reproductive frequency Annual episodic
Fecundity (number of eggs)100,000-1,000,000
Generation time1-2 years
Age at maturitySee additional text
SeasonAugust - April
Life span5-10 years

Larval characteristics

ParameterData
Larval/propagule typeCyphonautes
Larval/juvenile development Lecithotrophic
Duration of larval stage< 1 day
Larval dispersal potential See additional information
Larval settlement periodInsufficient information

Life history information

Reproduction. Bryozoan colonies are hermaphrodite, however, zooids may be monoecious, dioecious, protandrous or protogynous, depending on the species (Hayward & Ryland, 1998). Flustra foliacea bears both male and female zooids and is presumably hermaphrodite.

  • Male zooids of Flustra foliacea in the Isle of Man were reported to be full of sperm in September, giving the entire colony a white appearance. Sperm were absent by October. Orange eggs were visible in August and the yellow coloured embryos had entered the ooecia (ovicells) by October (Eggleston, 1970; 1972a). Sperm are shed from pores in the polypide tentacles of male zooids.
  • Fertilization in brooding species such as Flustra foliacea is probably internal (Hayward & Ryland, 1998). In bryozoans, released sperm are entrained by the tentacles of feeding polypides and may not disperse far, resulting in self-fertilization. However, genetic cross-fertilization is assumed in oviparous and brooding bryozoans, although there is evidence of self-fertilization (Hayward & Ryland, 1998).
  • Eggleston (1972a) reported that about one-third of zooids produced a single embryo in their first and second years, but that older zooids were infertile. Embryos were brooded overwinter and larvae were released between February and April.

Fecundity. Dalyell (cited in Hincks, 1880) stated that ca 10,000 larvae were released from a specimen of Flustra foliacea within 3 hrs. Eggleston (1972a) reported that each zooid produced a single embryo, so that fecundity is probably related to the number of sexual zooids and hence size of the colony.

Longevity. Flustra foliacea colonies regularly reached 6 years of age, although 12 year old specimens were reported off the Gower Peninsula (Stebbing, 1971a; Ryland, 1976).

Recruitment. Larvae are positively phototactic on release, and swim for only short periods, although in species in which light stimulus is unimportant, larvae may delay metamorphosis for 12 hours or more (Hayward & Ryland, 1998). Daylength is an important cue for larval release in some species of bryozoa, and Flustra foliacea releases larvae in spring (February- April) (Eggleston, 1972a; Hayward & Ryland, 1998), however, at the depths Flustra foliacea can occur light may not be important. Larvae are probably sensitive to surface contour, chemistry and the proximity of conspecific colonies. However, Hayward & Ryland (1998) suggested that larval behaviour at settlement is only of prime importance to species occupying ephemeral habitats. Eggleston (1972b) demonstrated that the number and abundance of species of bryozoan increased with increased current strength, primarily due to a resultant increase in the availability of stable, hard substrata (Eggleston, 1972b; Ryland, 1976). Dyrynda (1994) noted that the abundance of Flustra foliacea was greatest in the deepest, and most current scoured, mouth of Poole Harbour due to the presence of circalittoral boulders not commonly found in other parts of the harbour, although reduced salinity probably also restricted its distribution within the harbour. Therefore, recruitment is probably dependent on the availability of suitable substratum. The short larval life probably results in good local but poor long-range dispersal. Ryland (1976) reported that significant settlement in bryozoans was only found near a reservoir of breeding colonies. However, the hydrographic regime probably strongly influences potential dispersal, and in the strong currents tolerated by Flustra foliacea, larvae may be transported some distance in a short time, unless constrained within eddies between faunal turf-forming species. The sand abrasion tolerated by Flustra foliacea may remove other species, providing Flustra foliacea with space to colonize.

Sensitivity reviewHow is sensitivity assessed?

Physical pressures

Use / to open/close text displayed

 IntoleranceRecoverabilitySensitivityEvidence / Confidence
Substratum loss [Show more]

Substratum loss

Benchmark. All of the substratum occupied by the species or biotope under consideration is removed. A single event is assumed for sensitivity assessment. Once the activity or event has stopped (or between regular events) suitable substratum remains or is deposited. Species or community recovery assumes that the substratum within the habitat preferences of the original species or community is present. Further details

Evidence

Removal of the substratum would result in the removal of the Flustra foliacea population and its associated fauna. Recovery will depend on recruitment from other populations and is assessed as high (see additional information below).

High High Moderate Moderate
Smothering [Show more]

Smothering

Benchmark. All of the population of a species or an area of a biotope is smothered by sediment to a depth of 5 cm above the substratum for one month. Impermeable materials, such as concrete, oil, or tar, are likely to have a greater effect. Further details.

Evidence

Holme & Wilson (1985) examined the bottom fauna in a tide-swept region of the central English Channel. Flustra foliacea dominated communities were reported to form in, and hence tolerate, areas subject to sediment transport (mainly sand) and periodic, temporary, submergence by thin layers of sand (ca <5 cm). In some cases, Flustra foliacea was seen to be partially buried by sand. It is likely that Flustra foliacea would withstand smothering by 5cm of sediment for a month. Large colonies are likely to be >6cm in height and exposed autozooids, will be able to feed, providing food for the rest of the colony. Therefore, not sensitive has been recorded. However, smothering for protracted periods or by impermeable materials may have a greater impact.

Tolerant Not relevant Not sensitive High
Increase in suspended sediment [Show more]

Increase in suspended sediment

Benchmark. An arbitrary short-term, acute change in background suspended sediment concentration e.g., a change of 100 mg/l for one month. The resultant light attenuation effects are addressed under turbidity, and the effects of rapid settling out of suspended sediment are addressed under smothering. Further details

Evidence

Suspended sediment is likely to cause abrasion and effect suspension feeding physically. But Flustra foliacea dominated communities have been reported from areas subject to sediment abrasion due to strong tidal streams, either by mainly sand (Holme & Wilson, 1985) or by gravel (Knight-Jones & Nelson-Smith, 1977; Hartnoll, 1983). Their toughness and erect form, coupled with their flexibility probably confers tolerance (Knight-Jones & Nelson-Smith, 1977; Holme & Wilson, 1985). Hyman (1959) noted that erect forms were more calcified than encrusting forms, e.g. Flustra foliacea was reported to have a calcareous content of 97-99%. In addition, Flustra foliacea was reported to be abundant in turbid, fast flowing waters of the Menai Straits (Moore, 1977). Therefore, together with evidence of periodic partial burial by sediment (see smothering above) Flustra foliacea is likely to tolerate increased suspended sediment. Bryozoan larvae are reported to avoid areas affected by siltation (Eggleston, 1972b; Ryland, 1976), however, the abundance of Flustra foliacea in areas subject to sediment abrasion and suspended sediment loads subjects that the some of its larvae are also able to settle and survive. An increase in siltation and associated scour may remove competitors and provide additional space for colonization, therefore, 'tolerant*' has been recorded.

Tolerant* Not relevant Not sensitive* Moderate
Decrease in suspended sediment [Show more]

Decrease in suspended sediment

Benchmark. An arbitrary short-term, acute change in background suspended sediment concentration e.g., a change of 100 mg/l for one month. The resultant light attenuation effects are addressed under turbidity, and the effects of rapid settling out of suspended sediment are addressed under smothering. Further details

Evidence

A significant reduction in suspended sediment load for a month (see benchmark) is unlikely to adversely affect Flustra foliacea. Therefore, a rank of tolerant has been recorded. However, the longer term reduction may allow other species to colonize available substratum and increase competition for space with Flustra foliacea.

Tolerant Not relevant Not sensitive Moderate
Desiccation [Show more]

Desiccation

  1. A normally subtidal, demersal or pelagic species including intertidal migratory or under-boulder species is continuously exposed to air and sunshine for one hour.
  2. A normally intertidal species or community is exposed to a change in desiccation equivalent to a change in position of one vertical biological zone on the shore, e.g., from upper eulittoral to the mid eulittoral or from sublittoral fringe to lower eulittoral for a period of one year. Further details.

Evidence

Flustra foliacea is probably highly intolerant of desiccation, and specimens washed ashore are usually dead. However, it is a subtidal species unlikely to be exposed to the air.

Not relevant Not relevant Not relevant Not relevant
Increase in emergence regime [Show more]

Increase in emergence regime

Benchmark. A one hour change in the time covered or not covered by the sea for a period of one year. Further details

Evidence

Flustra foliacea is a subtidal species, and unlikely to be affected by a change in emergence regime at the benchmark level.

Not relevant Not relevant Not relevant Not relevant
Decrease in emergence regime [Show more]

Decrease in emergence regime

Benchmark. A one hour change in the time covered or not covered by the sea for a period of one year. Further details

Evidence

Flustra foliacea is a subtidal species, and unlikely to be affected by a change in emergence regime at the benchmark level.

Not relevant Not relevant Not relevant Not relevant
Increase in water flow rate [Show more]

Increase in water flow rate

A change of two categories in water flow rate (view glossary) for 1 year, for example, from moderately strong (1-3 knots) to very weak (negligible). Further details

Evidence

Flustra foliacea colonies are flexible, robust and reach high abundances in areas subject to strong currents and tidal streams (see distribution; Stebbing, 1971; Eggleston, 1972b; Knight-Jones & Nelson-Smith, 1977; Hiscock, 1983, 1985; Holme & Wilson, 1985). Dyrynda (1994) suggested that mature fronded colonies do not occur on unstable substratum due to the drag caused by their fronds, resulting in rafting of colonies on shells or the rolling of pebbles and cobbles, resulting in destruction of the colony. Dyrynda (1994) reported that the distribution of Flustra foliacea in the current swept entrance to Poole Harbour was restricted to circalittoral boulders, on which it dominated as nearly mono-specific stands. Therefore, an increase in water flow from moderately strong to very strong may not adversely affect colonies on stable substrata. However, colonies, especially if large, on coarse grounds, shells, cobble and pebbles are likely to be more intolerant of increase in water flow, and a proportion of the population may be displaced, although the colony may survive as long as it is not crushed in the process. Therefore, tolerant has been recorded.

Tolerant High Not sensitive High
Decrease in water flow rate [Show more]

Decrease in water flow rate

A change of two categories in water flow rate (view glossary) for 1 year, for example, from moderately strong (1-3 knots) to very weak (negligible). Further details

Evidence

Flustra foliacea reaches high abundances in strong currents (see above) but decreases in abundance in weak currents. Decreased water flow may result in increased siltation and accumulation of fine sediments, increased competition from other space occupying species such as sponges, hydroids and other bryozoans, and a decrease in food availability. While, the pumping activity of the lophophores provide the greatest proportion of the colonies food requirements (Hayward & Ryland, 1998), the current generated is probably very localized and the colonies are dependant on water currents to carry food particles to them. Therefore, a decrease in water flow from, e.g. moderately strong to weak, is likely to result in a decrease in the abundance of Flustra foliacea and an intolerance of intermediate has been recorded.

Intermediate High Low Low
Increase in temperature [Show more]

Increase in temperature

  1. A short-term, acute change in temperature; e.g., a 5°C change in the temperature range for three consecutive days. This definition includes ‘short-term’ thermal discharges.
  2. A long-term, chronic change in temperature; e.g. a 2°C change in the temperature range for a year. This definition includes ‘long term’ thermal discharges.

For intertidal species or communities, the range of temperatures includes the air temperature regime for that species or community. Further details

Evidence

No information concerning temperature tolerance was found. However, Flustra foliacea is an amphiboreal species found in the Arctic Circle and south to the Bay of Biscay, and from the shallow sublittoral to deep circalittoral. Therefore, it is unlikely to be adversely affected by long term changes in temperature within British waters, and a rank of tolerant has been recorded.

Tolerant Not relevant Not sensitive Low
Decrease in temperature [Show more]

Decrease in temperature

  1. A short-term, acute change in temperature; e.g., a 5°C change in the temperature range for three consecutive days. This definition includes ‘short-term’ thermal discharges.
  2. A long-term, chronic change in temperature; e.g. a 2°C change in the temperature range for a year. This definition includes ‘long term’ thermal discharges.

For intertidal species or communities, the range of temperatures includes the air temperature regime for that species or community. Further details

Evidence

No information concerning temperature tolerance was found. However, Flustra foliacea is an amphiboreal species found in the Arctic Circle and south to the Bay of Biscay, and from the shallow sublittoral to deep circalittoral. Therefore, it is unlikely to be adversely affected by long term changes in temperature within British waters, and a rank of tolerant has been recorded.

Tolerant Not relevant Not sensitive Low
Increase in turbidity [Show more]

Increase in turbidity

  1. A short-term, acute change; e.g., two categories of the water clarity scale (see glossary) for one month, such as from medium to extreme turbidity.
  2. A long-term, chronic change; e.g., one category of the water clarity scale (see glossary) for one year, such as from low to medium turbidity. Further details

Evidence

Increased turbidity will reduce light penetration and hence phytoplankton productivity. Small phytoplankton are probably an important food source in the shallow subtidal, although, Flustra foliacea is also found at greater depths, where organic particulates (detritus) are probably more important. Therefore, an increase in turbidity is unlikely to adversely affect Flustra foliacea.

Tolerant Not relevant Not sensitive Low
Decrease in turbidity [Show more]

Decrease in turbidity

  1. A short-term, acute change; e.g., two categories of the water clarity scale (see glossary) for one month, such as from medium to extreme turbidity.
  2. A long-term, chronic change; e.g., one category of the water clarity scale (see glossary) for one year, such as from low to medium turbidity. Further details

Evidence

Decreased turbidity is likely to result in increased primary productivity, and therefore indirectly increase the availability of food (phytoplankton or detritus) for Flustra foliacea, which may, therefore, benefit. Therefore, a rank of tolerant* has been recorded.

Tolerant* Not relevant Not sensitive* Low
Increase in wave exposure [Show more]

Increase in wave exposure

A change of two ranks on the wave exposure scale (view glossary) e.g., from Exposed to Extremely exposed for a period of one year. Further details

Evidence

Flustra foliacea occurs from very wave exposed to sheltered waters, although probably limited to deeper waters in very wave exposed conditions. The oscillatory water flow generated by wave action may be more damaging than constant strong currents, e.g. strong wave action may generate an oscillatory flow of 2m/sec at 20m (Hiscock, 1983, 1985). Flustra foliacea is a common member of the flotsam, having been removed from its substratum by storms. Colonies on unstable substrata or subject to extreme wave exposure and storms are likely to be more intolerant. An increase in wave action from exposed to extremely exposed, or storms (especially in more wave sheltered environments or shallow water populations) are likely to remove a proportion of the population. Therefore, Flustra foliacea is probably of intermediate intolerance to increases in wave action. Recoverability is likely to be high (see additional information below).

Intermediate High Low Moderate
Decrease in wave exposure [Show more]

Decrease in wave exposure

A change of two ranks on the wave exposure scale (view glossary) e.g., from Exposed to Extremely exposed for a period of one year. Further details

Evidence

Flustra foliacea occurs from very wave exposed to sheltered waters. In wave sheltered habitats water flow rates are probably more important than wave action in determining the occurrence and abundance of Flustra foliacea. Water movement (wave or water flow induced) is important for suspension feeding invertebrates such as Flustra foliacea, to prevent siltation and provide adequate food supplies, oxygenation, nutrients and remove waste products. A decrease in wave action to very sheltered or ultra sheltered, in the absence of adequate water flow, may decrease water movement, leading to an increase in fine sediments, loss of suitable substratum and a reduction in food supply and oxygenation. Predation and competition from space occupying species such as hydroids, and macroalgae are likely to increase.
In very wave exposed sites, however, a decrease in wave exposure may be beneficial by reducing the populations vulnerability to storm damage (see above).

 

Overall, Flustra foliacea populations are most abundant in areas of high water movement (e.g. Menai Straits), and a decrease in wave action, in the absence of tidal flow or currents, is likely to result in a reduction of the abundance of Flustra foliacea. Therefore, an intolerance of intermediate has been recorded. Recoverability has been assessed as high (see additional information below).

Intermediate High Low Low
Noise [Show more]

Noise

  1. Underwater noise levels e.g., the regular passing of a 30-metre trawler at 100 metres or a working cutter-suction transfer dredge at 100 metres for one month during important feeding or breeding periods.
  2. Atmospheric noise levels e.g., the regular passing of a Boeing 737 passenger jet 300 metres overhead for one month during important feeding or breeding periods. Further details

Evidence

Bryozoa probably react to local vibrations, that may herald the attach of predators, interrupting feeding. But they are unlikely to be aware of noise at the benchmark level.

Tolerant Not relevant Not sensitive High
Visual presence [Show more]

Visual presence

Benchmark. The continuous presence for one month of moving objects not naturally found in the marine environment (e.g., boats, machinery, and humans) within the visual envelope of the species or community under consideration. Further details

Evidence

Bryozoa probably react to very local shading effects, interrupting feeding. But their visual acuity is probably extremely poor, and they are unlikely to be affected by visual disturbance.

Tolerant Not relevant Not sensitive High
Abrasion & physical disturbance [Show more]

Abrasion & physical disturbance

Benchmark. Force equivalent to a standard scallop dredge landing on or being dragged across the organism. A single event is assumed for assessment. This factor includes mechanical interference, crushing, physical blows against, or rubbing and erosion of the organism or habitat of interest. Where trampling is relevant, the evidence and trampling intensity will be reported in the rationale. Further details.

Evidence

Flustra foliacea is tolerant of sediment abrasion (see smothering and suspended sediment above) but physical disturbance by fishing gear has been shown to adversely affect emergent epifaunal communities. For example, emergent epifauna were indicative of scallop dredge damage on Modiolus modiolus beds (see species review), and hydroid and bryozoan matrices were reported to be greatly reduced in fished areas (Jennings & Kaiser, 1998 and references therein). Mobile gears also result in modification of the substratum, including removal of shell debris, cobbles and rocks, and the movement of boulders (Bullimore, 1985; Jennings & Kaiser, 1998).
Although, Flustra foliacea is flexible physical disturbance by a passing scallop dredge (see benchmark) is likely to damage fronds and remove some colonies, suggesting an intolerance of intermediate. Colonies on hard substrata are probably less vulnerable to fishing activity but would probably be damaged or partially removed. Colonies growing on rocks, cobbles and shells on coarse grounds, may be removed by a scallop dredge (see substratum loss above) and therefore, be highly intolerant. Recovery will depend on local recruitment from surviving colonies (depending on where the nearest undamaged colonies are situated) and a recoverability of high has been recorded (see additional information below).

Intermediate High Low Moderate
Displacement [Show more]

Displacement

Benchmark. Removal of the organism from the substratum and displacement from its original position onto a suitable substratum. A single event is assumed for assessment. Further details

Evidence

Colonies of Flustra foliacea that are displaced while attached to their substratum, e.g. shell debris or rocks will probably survive if moved to a suitable habitat and not crushed in the process. But if removed from its substratum, Flustra foliacea colonies cannot reattach and will probably be washed to deep water or be deposited on the strand line and die. Therefore, an intolerance of high has been recorded, with a recoverability of high (see additional information below).

High High Moderate Moderate

Chemical pressures

Use [show more] / [show less] to open/close text displayed

 IntoleranceRecoverabilitySensitivityEvidence / Confidence
Synthetic compound contamination [Show more]

Synthetic compound contamination

Sensitivity is assessed against the available evidence for the effects of contaminants on the species (or closely related species at low confidence) or community of interest. For example:

  • evidence of mass mortality of a population of the species or community of interest (either short or long term) in response to a contaminant will be ranked as high sensitivity;
  • evidence of reduced abundance, or extent of a population of the species or community of interest (either short or long term) in response to a contaminant will be ranked as intermediate sensitivity;
  • evidence of sub-lethal effects or reduced reproductive potential of a population of the species or community of interest will be assessed as low sensitivity.

The evidence used is stated in the rationale. Where the assessment can be based on a known activity then this is stated. The tolerance to contaminants of species of interest will be included in the rationale when available; together with relevant supporting material. Further details.

Evidence

Bryozoans are common members of the fouling community, and amongst those organisms most resistant to antifouling measures, such as copper containing anti-fouling paints (Soule & Soule, 1979; Holt et al., 1995). Bryan & Gibbs (1991) reported that there was little evidence regarding TBT toxicity in bryozoa with the exception of the encrusting Schizoporella errata, which suffered 50% mortality when exposed for 63 days to 100ng/l TBT. Rees et al. (2001) reported that the abundance of epifauna (including bryozoans) had increased in the Crouch estuary in the five years since TBT was banned from use on small vessels. This last report suggests that bryozoans may be at least inhibited by the presence of TBT. Hoare & Hiscock (1974) suggested that polyzoa (bryozoa) were amongst the most intolerant species to acidified halogenated effluents in Amlwch Bay, Anglesey and reported that Flustra foliacea did not occur less than 165m from the effluent source.
Therefore, an intolerance of high has been recorded. A recoverability of high has been recorded (see additional information).

High High Moderate Very low
Heavy metal contamination [Show more]

Heavy metal contamination

Evidence

Bryozoans are common members of the fouling community, and amongst those organisms most resistant to antifouling measures, such as copper containing anti-fouling paints (Soule & Soule, 1977; Holt et al., 1995). Bryozoans were shown to bioaccumulate heavy metals to a certain extent (Holt et al., 1995). For example, Bowerbankia gracialis and Nolella pusilla accumulated Cd, exhibiting sublethal effects (reduced sexual reproduction and inhibited resting spore formation) between 10-100 µg Cd /l and fatality above 500 µg Cd/l (Kayser, 1990). However, given the tolerance of bryozoans to copper based anti-fouling treatments, as assuming similar physiology between species, an intolerance of low has been recorded albeit with very low confidence.

Low Very high Very Low Very low
Hydrocarbon contamination [Show more]

Hydrocarbon contamination

Evidence

Little information on the effects of hydrocarbons on bryozoans was found. Flustra foliacea is likely to be protected from the direct effects of oil spills by its subtidal habit but may be exposed to water soluble fractions of oils, PAHs or oil adsorbed onto particulates. In addition, Ryland & Putron (1998) did not detect adverse effects of oil contamination on the bryozoan Alcyonidium spp. in Milford Haven or St. Catherine's Island, south Pembrokeshire although it did alter the breeding period. However, it is difficult to extrapolate between species, and no assessment has been made.

No information Not relevant No information Not relevant
Radionuclide contamination [Show more]

Radionuclide contamination

Evidence

Insufficient
information

No information Not relevant No information Not relevant
Changes in nutrient levels [Show more]

Changes in nutrient levels

Evidence

A moderate increase in nutrient levels may increase the food available to Flustra foliacea, either in the form of phytoplankton or detritus. However, no effects of nutrients enrichment on bryozoans were found.

No information Not relevant No information Not relevant
Increase in salinity [Show more]

Increase in salinity

  1. A short-term, acute change; e.g., a change of two categories from the MNCR salinity scale for one week (view glossary) such as from full to reduced.
  2. A long-term, chronic change; e.g., a change of one category from the MNCR salinity scale for one year (view glossary) such as from reduced to low. Further details.

Evidence

Flustra foliacea is unlikely to encounter hypersaline conditions in current swept, subtidal habitats.

Not relevant Not relevant Not relevant Not relevant
Decrease in salinity [Show more]

Decrease in salinity

  1. A short-term, acute change; e.g., a change of two categories from the MNCR salinity scale for one week (view glossary) such as from full to reduced.
  2. A long-term, chronic change; e.g., a change of one category from the MNCR salinity scale for one year (view glossary) such as from reduced to low. Further details.

Evidence

Ryland (1970) stated that, with a few exceptions, the Gymnolaemata were fairly stenohaline and restricted to full salinity (ca 35 psu) and noted that reduced salinities result in an impoverished bryozoan fauna. Similarly, Dyrynda (1994) noted that Flustra foliacea and Alcyonidium diaphanum were probably restricted to the vicinity of the Poole Harbour entrance by their intolerance to reduced salinity. Although, protected from extreme changes in salinity due to their subtidal habitat, the introduction of freshwater, or hyposaline effluents may adversely affect Flustra foliacea colonies. Therefore, an intolerance of high has been recorded, and recoverability assessed as high (see additional information below).

High High Moderate Low
Changes in oxygenation [Show more]

Changes in oxygenation

Benchmark.  Exposure to a dissolved oxygen concentration of 2 mg/l for one week. Further details.

Evidence

No information on the tolerance of Flustra foliacea to changes in oxygenation was found.

No information Not relevant No information Not relevant

Biological pressures

Use [show more] / [show less] to open/close text displayed

 IntoleranceRecoverabilitySensitivityEvidence / Confidence
Introduction of microbial pathogens/parasites [Show more]

Introduction of microbial pathogens/parasites

Benchmark. Sensitivity can only be assessed relative to a known, named disease, likely to cause partial loss of a species population or community. Further details.

Evidence

No information on diseases was found. Stebbing (1971a) reported that encrusting epizoites reduced the growth rate of Flustra foliacea by ca 50% and Stebbing (1971b) described the epizoic fauna of hornwrack in detail. The bryozoan Bugulina flabellata produces stolons that grow in and through the zooids of Flustra foliacea, causing "irreversible degeneration of the enclosed polypide" (Stebbing, 1971b). Therefore, given the reduction in growth caused by epizoic infestation an intolerance of low has been recorded. Recovery and repair would probably be rapid (see additional information below).

Low Immediate Not sensitive High
Introduction of non-native species [Show more]

Introduction of non-native species

Sensitivity assessed against the likely effect of the introduction of alien or non-native species in Britain or Ireland. Further details.

Evidence

No information found.

No information Not relevant No information Not relevant
Extraction of this species [Show more]

Extraction of this species

Benchmark. Extraction removes 50% of the species or community from the area under consideration. Sensitivity will be assessed as 'intermediate'. The habitat remains intact or recovers rapidly. Any effects of the extraction process on the habitat itself are addressed under other factors, e.g. displacement, abrasion and physical disturbance, and substratum loss. Further details.

Evidence

Flustra foliacea is not presently known to be subject to extraction. However, many bryozoans have been recently found to contain pharmacologically active substances (Hayward & Ryland, 1998; Lysek et al., 2002; Peters et al., 2003). Therefore, Flustra foliacea may be subject to harvesting in the future.

Not relevant Not relevant Not relevant Not relevant
Extraction of other species [Show more]

Extraction of other species

Benchmark. A species that is a required host or prey for the species under consideration (and assuming that no alternative host exists) or a keystone species in a biotope is removed. Any effects of the extraction process on the habitat itself are addressed under other factors, e.g. displacement, abrasion and physical disturbance, and substratum loss. Further details.

Evidence

Flustra foliacea may occur on coarse grounds used for fishing of other marine species, e.g. scallops. Mobile fishing gear, such as scallop dredges and beam trawls result in physical disturbance to the sediment surface. Emergent epifauna have been shown to be particularly intolerant of physical disturbance, depending on intensity (see abrasion) and emergent fauna, together with shells, and rocks form part of by-catch. Therefore, an intolerance of high and a recoverably of high have been recorded (see additional information below).

High High Moderate Low

Additional information

Recoverability. Silén (1981) reported that Flustra foliacea could repair physical damage to its fronds within 5-10 days. Presumably, as long as the holdfast remains intact, Flustra foliacea will survive and grow back. The brooded, lecithotrophic larvae of bryozoans have a short pelagic lifetime of several hours to about 12 hours (Ryland, 1976). Recruitment is dependent on the supply of suitable, stable, hard substrata (Eggleston, 1972b; Ryland, 1976; Dyrynda, 1994). Even in the presence of available substratum, Ryland (1976) noted that significant recruitment in bryozoans only occurred in the proximity of breeding colonies. For example, Keough & Chernoff (1987) reported that the population of Bugula nerita demonstrated spatial variation over very small scales, and populations were sometimes absent even when substantial populations were <100 m away.

Flustra foliacea colonies are perennial, and potentially highly fecund when large. In the strong currents occupied by Flustra foliacea populations many larvae are probably swept away, either to colonize other substrata or lost. Recruitment may be enhanced in areas subject to sediment abrasion, where less tolerant species are removed, making more substratum available for colonization, especially if larvae release in spring coincides with the end of winter storms. Once settled, new colonies take at least 1 year to develop erect growth and 1-2 years to reach maturity, depending on environmental conditions. Four years after sinking, the wreck of a small coaster, the M.V. Robert, off Lundy was found to be colonized by erect bryozoans and hydroids, including occasional Flustra foliacea (Hiscock, 1981). The wreck was several hundreds of metres from any significant hard substrata, and hence a considerable distance from potential parent colonies (Hiscock, 1981 and pers. comm.)

Overall, local recruitment is probably good and a damaged or reduced population may recover its numbers and percentage cover in less than 5 years. Where the population was removed, recruitment would depend on the proximity of other populations or individuals and the hydrographic regime and is likely to be more protracted, taking up to 5 years. In areas isolated by either distance or hydrographic regime, Flustra foliacea may take longer to recolonize.

Importance review

Policy/legislation

- no data -

Status

Non-native

ParameterData
Native-
Origin-
Date Arrived-

Importance information

Aggregations of Flustra foliacea provide a habitat for various species of sponges, hydroids, caprellid amphipods and the suspension-feeding crab Pisidia longicornis (as Porcellana), as well as a number of epizoic species (see MCR.Flu and Stebbing, 1971b). Flustra foliacea is the preferred prey of the pycnogonid Achelia echinata, whose feeding behaviour is described by Wyer & King, 1973 and Ryland, 1976. In addition, Flustra foliacea is preyed on by sea urchins such as Echinus esculentus and Psammechinus miliaris (Ryland, 1976) and nudibranchs, especially the dorid Crimora papillata (Picton & Morrow, 1994).

Bibliography

  1. Bullimore, B., 1985. An investigation into the effects of scallop dredging within the Skomer Marine Reserve. Report to the Nature Conservancy Council by the Skomer Marine Reserve Subtidal Monitoring Project, S.M.R.S.M.P. Report, no 3., Nature Conservancy Council.

  2. DWT (Devon Wildlife Trust), 1993. Lyme Bay. A report on the nature conservation importance of the inshore reefs of Lyme Bay and the effects of mobile fishing gear. Devon Wildlife Trust.

  3. Dyer, M.F., Fry, W.G., Fry, P.D. & Cranmer, G.J., 1982. A series of North Sea benthos surveys with trawl and headline camera. Journal of the Marine Biological Association of the United Kingdom, 62, 297-313.

  4. Dyrynda, P.E.J., 1994. Hydrodynamic gradients and bryozoan distributions within an estuarine basin (Poole Harbour, UK). In Proceedings of the 9th International Bryozoology conference, Swansea, 1992. Biology and Palaeobiology of Bryozoans (ed. P.J. Hayward, J.S. Ryland & P.D. Taylor), pp.57-63. Fredensborg: Olsen & Olsen.

  5. Eggleston, D., 1970. Embryo colour in Manx ectoprocts. Report of the Marine Biological Laboratory, Port Erin, Isle of Man, no. 82.

  6. Eggleston, D., 1972a. Patterns of reproduction in marine Ectoprocta off the Isle of Man. Journal of Natural History, 6, 31-38.

  7. Eggleston, D., 1972b. Factors influencing the distribution of sub-littoral ectoprocts off the south of the Isle of Man (Irish Sea). Journal of Natural History, 6, 247-260.

  8. Eno, N.C., MacDonald, D. & Amos, S.C., 1996. A study on the effects of fish (Crustacea/Molluscs) traps on benthic habitats and species. Final report to the European Commission. Study Contract, no. 94/076.

  9. Fish, J.D. & Fish, S., 1996. A student's guide to the seashore. Cambridge: Cambridge University Press.

  10. Hartnoll, R.G., 1983. Substratum. In Sublittoral ecology. The ecology of the shallow sublittoral benthos (ed. R. Earll & D.G. Erwin), pp. 97-124. Oxford: Clarendon Press.

  11. Hayward, P., Nelson-Smith, T. & Shields, C. 1996. Collins pocket guide. Sea shore of Britain and northern Europe. London: HarperCollins.

  12. Hayward, P.J. & Ryland, J.S. (ed.) 1995b. Handbook of the marine fauna of North-West Europe. Oxford: Oxford University Press.

  13. Hayward, P.J. & Ryland, J.S. 1998. Cheilostomatous Bryozoa. Part 1. Aeteoidea - Cribrilinoidea. Shrewsbury: Field Studies Council. [Synopses of the British Fauna, no. 10. (2nd edition)]

  14. Hincks, T., 1880. A history of British marine Polyzoa, vol. I & II. London: John van Voorst.

  15. Hiscock, H., 1985b. Aspects of the ecology of rocky sublittoral areas. In The Ecology of Rocky Coasts: essays presented to J.R. Lewis, D.Sc. (ed. P.G. Moore & R. Seed), pp. 290-328. London: Hodder & Stoughton Ltd.

  16. Hiscock, K., 1981. Marine life on the wreck of the M.V. "Robert". Report of the Lundy Field Society, 32, 40-44.

  17. Hiscock, K., 1983. Water movement. In Sublittoral ecology. The ecology of shallow sublittoral benthos (ed. R. Earll & D.G. Erwin), pp. 58-96. Oxford: Clarendon Press.

  18. Holme, N.A. & Wilson, J.B., 1985. Faunas associated with longitudinal furrows and sand ribbons in a tide-swept area in the English Channel. Journal of the Marine Biological Association of the United Kingdom, 65, 1051-1072.

  19. Hyman, L.V., 1959. The Invertebrates, vol. V. Smaller coelomate groups. New York: McGraw-Hill.

  20. Jennings, S. & Kaiser, M.J., 1998. The effects of fishing on marine ecosystems. Advances in Marine Biology, 34, 201-352.

  21. Jha, R.K. & Zi-rong, X., 2004. Biomedical compounds from marine organisms. Marine Drugs, 2, 123-146.

  22. JNCC (Joint Nature Conservation Committee), 1999. Marine Environment Resource Mapping And Information Database (MERMAID): Marine Nature Conservation Review Survey Database. [on-line] http://www.jncc.gov.uk/mermaid

  23. Kayser, H., 1990. Bioaccumulation and transfer of cadmium in marine diatoms, Bryozoa, and Kamptozoa. In Oceanic processes in marine pollution, vol. 6. Physical and chemical processes: transport and transformation (ed. D.J. Baumgartner & I.W. Duedall), pp. 99-106. Florida: R.E. Krieger Publishing Co.

  24. Keough, M.J. & Chernoff, H., 1987. Dispersal and population variation in the bryozoan Bugula neritina. Ecology, 68, 199 - 210.

  25. Knight-Jones, E.W. & Nelson-Smith, A., 1977. Sublittoral transects in the Menai Straits and Milford Haven. In Biology of benthic organisms (ed. B.F. Keegan, P. O Ceidigh & P.J.S. Broaden), pp. 379-390. Oxford: Pergamon Press.

  26. Lysek, N., Rachor, E. & Lindel, T., 2002. Isolation and structure elucidation of Deformylflustrabromine from the North Sea bryozoan Flustra foliacea. Zeitschrift für Naturforschung, C: Biosciences, 57, 1056-1061.

  27. Menon, N.R., 1975. Observations on growth of Flustra foliacea (Bryozoa) from Helgoland waters. Helgolander Wissenschaftliche Meeresuntersuchungen, 27, 263-267.

  28. Moore, P.G., 1977a. Inorganic particulate suspensions in the sea and their effects on marine animals. Oceanography and Marine Biology: An Annual Review, 15, 225-363.

  29. Nielsen, R., 1984. Epicladia flustrae, E. phillipsii stat. nov., and Pseudoendoclonium dynamenae sp. nov. living in Bryozoans and a hydroid. British Phycological Journal, 19, 371-379.

  30. O'Dea, A. & Okamura, B., 2000. Life history and environmental inference through retrospective morphometric analysis of bryozoans: a preliminary study. Journal of the Marine Biological Association of the United Kingdom, 80, 1127-1128.

  31. Peters, L., König, G.M., Wright, A.D., Pukall, R., Stackebrandt, E., Eberl, L. & Riedel, K., 2003. Secondary metabolites of Flustra foliacea and their influence on bacteria. Applied and Environmental Microbiology, 69, 3469-3475.

  32. Picton, B. E. & Morrow, C.C., 1994. A Field Guide to the Nudibranchs of the British Isles. London: Immel Publishing Ltd.

  33. Picton, B.E. & Costello, M.J., 1998. BioMar biotope viewer: a guide to marine habitats, fauna and flora of Britain and Ireland. [CD-ROM] Environmental Sciences Unit, Trinity College, Dublin.

  34. Reed, C.G., 1991. Bryozoa. In Reproduction of marine invertebrates, vol. VI. Echinoderms and Lophophorates (ed. A.C. Geise, J.S. Pearse & V.B. Pearse), pp. 85-245. California: Boxwood Press.

  35. Ryland, J.S. & Bishop, J.D.D., 1993. Internal fertilization in hermaphroditic colonial invertebrates. Oceanography and Marine Biology: an Annual Review, 31, 445-477.

  36. Ryland, J.S. & De Putron, S., 1998. An appraisal of the effects of the Sea Empress oil spillage on sensitive invertebrate communities. Countryside Council for Wales Sea Empress Contract Report, no. 285, 97pp.

  37. Ryland, J.S., 1967. Polyzoa. Oceanography and Marine Biology: an Annual Review, 5, 343-369.

  38. Ryland, J.S., 1970. Bryozoans. London: Hutchinson University Library.

  39. Ryland, J.S., 1976. Physiology and ecology of marine bryozoans. Advances in Marine Biology, 14, 285-443.

  40. Ryland, J.S., 1977. Taxes and tropisms of Bryozoans. In Biology of bryozoans (ed. R.M. Woollacott & R.L. Zimmer), pp. 411-436.

  41. Silén, L., 1977. Polymorphism. In Biology of bryozoans (ed. R.M. Woollacott & R.L. Zimmer), pp. 183-231.

  42. Silén, L., 1981. Colony structure in Flustra foliacea (Linnaeus) (Bryozoa, Cheilostomata). Acta Zoologica (Stockholm.), 62, 219-232.

  43. Soule, D.F. & Soule, J.D., 1979. Bryozoa (Ectoprocta). In Hart, C.W. & Fuller, S.L.H. (eds), Pollution ecology of estuarine invertebrates. New York: Academic Press, pp. 35-76.

  44. Stebbing, A.R.D., 1971a. Growth of Flustra foliacea (Bryozoa). Marine Biology, 9, 267-273.

  45. Stebbing, A.R.D., 1971b. The epizoic fauna of Flustra foliacea [Bryozoa]. Journal of the Marine Biological Association of the United Kingdom, 51, 283-300.

  46. Wyer, D.W. & King, P.E., 1973. Relationships between some British littoral and sublittoral bryozoans and pycnogonids. In Living and fossil Bryozoa (ed. G.P. Larwood), pp. 199-207. New York: Academic Press.

  47. Zimmer, R.L. & Woollacott, R.M., 1977. Structure and classification of Gymnolaemate larvae. In Biology of Bryozoans (ed. R.M. Woollacott & R.L. Zimmer), pp. 57-89. New York: Academic Press.

Datasets

  1. Centre for Environmental Data and Recording, 2018. IBIS Project Data. Occurrence dataset: https://www.nmni.com/CEDaR/CEDaR-Centre-for-Environmental-Data-and-Recording.aspx accessed via NBNAtlas.org on 2018-09-25.

  2. Centre for Environmental Data and Recording, 2018. Ulster Museum Marine Surveys of Northern Ireland Coastal Waters. Occurrence dataset https://www.nmni.com/CEDaR/CEDaR-Centre-for-Environmental-Data-and-Recording.aspx accessed via NBNAtlas.org on 2018-09-25.

  3. Cofnod – North Wales Environmental Information Service, 2018. Miscellaneous records held on the Cofnod database. Occurrence dataset: https://doi.org/10.15468/hcgqsi accessed via GBIF.org on 2018-09-25.

  4. Dorset Environmental Records Centre, 2018. Ross Coral Mapping Project - NBN South West Pilot Project Case Studies. Occurrence dataset:https://doi.org/10.15468/mnlzxc accessed via GBIF.org on 2018-09-25.

  5. Environmental Records Information Centre North East, 2018. ERIC NE Combined dataset to 2017. Occurrence dataset: http://www.ericnortheast.org.ukl accessed via NBNAtlas.org on 2018-09-38

  6. Fenwick, 2018. Aphotomarine. Occurrence dataset http://www.aphotomarine.com/index.html Accessed via NBNAtlas.org on 2018-10-01

  7. Fife Nature Records Centre, 2018. St Andrews BioBlitz 2014. Occurrence dataset: https://doi.org/10.15468/erweal accessed via GBIF.org on 2018-09-27.

  8. Fife Nature Records Centre, 2018. St Andrews BioBlitz 2016. Occurrence dataset: https://doi.org/10.15468/146yiz accessed via GBIF.org on 2018-09-27.

  9. Kent Wildlife Trust, 2018. Kent Wildlife Trust Shoresearch Intertidal Survey 2004 onwards. Occurrence dataset: https://www.kentwildlifetrust.org.uk/ accessed via NBNAtlas.org on 2018-10-01.

  10. Lancashire Environment Record Network, 2018. LERN Records. Occurrence dataset: https://doi.org/10.15468/esxc9a accessed via GBIF.org on 2018-10-01.

  11. Manx Biological Recording Partnership, 2022. Isle of Man historical wildlife records 1990 to 1994. Occurrence dataset:https://doi.org/10.15468/aru16v accessed via GBIF.org on 2024-09-27.

  12. Merseyside BioBank., 2018. Merseyside BioBank (unverified). Occurrence dataset: https://doi.org/10.15468/iou2ld accessed via GBIF.org on 2018-10-01.

  13. Merseyside BioBank., 2018. Merseyside BioBank Active Naturalists (unverified). Occurrence dataset: https://doi.org/10.15468/smzyqf accessed via GBIF.org on 2018-10-01.

  14. National Trust, 2017. National Trust Species Records. Occurrence dataset: https://doi.org/10.15468/opc6g1 accessed via GBIF.org on 2018-10-01.

  15. NBN (National Biodiversity Network) Atlas. Available from: https://www.nbnatlas.org.

  16. Norfolk Biodiversity Information Service, 2017. NBIS Records to December 2016. Occurrence dataset: https://doi.org/10.15468/jca5lo accessed via GBIF.org on 2018-10-01.

  17. OBIS (Ocean Biodiversity Information System),  2024. Global map of species distribution using gridded data. Available from: Ocean Biogeographic Information System. www.iobis.org. Accessed: 2024-11-23

  18. South East Wales Biodiversity Records Centre, 2018. Dr Mary Gillham Archive Project. Occurance dataset: http://www.sewbrec.org.uk/ accessed via NBNAtlas.org on 2018-10-02

  19. South East Wales Biodiversity Records Centre, 2023. SEWBReC Marine and other Aquatic Invertebrates (South East Wales). Occurrence dataset:https://doi.org/10.15468/zxy1n6 accessed via GBIF.org on 2024-09-27.

  20. Suffolk Biodiversity Information Service., 2017. Suffolk Biodiversity Information Service (SBIS) Dataset. Occurrence dataset: https://doi.org/10.15468/ab4vwo accessed via GBIF.org on 2018-10-02.

  21. Yorkshire Wildlife Trust, 2018. Yorkshire Wildlife Trust Shoresearch. Occurrence dataset: https://doi.org/10.15468/1nw3ch accessed via GBIF.org on 2018-10-02.

Citation

This review can be cited as:

Tyler-Walters, H., & Ballerstedt, S. 2007. Flustra foliacea Hornwrack. In Tyler-Walters H. Marine Life Information Network: Biology and Sensitivity Key Information Reviews, [on-line]. Plymouth: Marine Biological Association of the United Kingdom. [cited 23-11-2024]. Available from: https://www.marlin.ac.uk/species/detail/1609

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Last Updated: 11/09/2007