Dog whelk (Nucella lapillus)
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Researched by | Dr Harvey Tyler-Walters | Refereed by | Dr John Crothers |
Authority | (Linnaeus, 1758) | ||
Other common names | - | Synonyms | Thais lapillus (Linnaeus, 1758) |
Summary
Description
The shell is broadly conical, bearing spiral ridges and consisting of a short pointed spire, dominated by the last whorl. The shell is usually up to 3 cm in height by 2 cm broad but may reach up to 6 cm in height (Crothers, 1985). The shell colour is variable, usually white, but may be grey, brown, or yellow, occasionally with contrasting (usually brown) spiral banding. A short, open siphonal canal leads from base of the aperture. The outer lip of the aperture is thin in young specimens, becoming thickened and toothed internally with age. The shell shape, shell thickness and relative size of the aperture vary with wave exposure. In some populations, mainly sublittoral or from the intertidal in North Kent, the growth lines extend outwards to form flounces or ruffles, and this variety of dog whelk is called Nucella lapillus var. imbricata. The animal itself is white or cream coloured with white speckles, and a flattened head. The head bears two tentacles, each bearing a eye about one third of the length of the tentacle from its base. The egg capsules of Nucella lapillus are vase shaped, about 8mm high, usually yellow, and found attached to hard substrata in crevices and under overhangs.
Recorded distribution in Britain and Ireland
Common on all rocky coasts of Britain and Ireland.Global distribution
Found throughout the littoral zone of the North Atlantic from the Arctic to the Algarve in the east, Iceland and the Faroes, and from Long Island north to south west Greenland in the west.Habitat
Found on wave exposed to sheltered rocky shores from the mid shore downwards. Rarely present in the sublittoral but may be abundant in areas exposed to extremely strong tidal stress. They are gregarious and common amongst barnacles and mussels on which they feed.Depth range
IntertidalIdentifying features
- Shell solid with about 6 swollen whorls.
- Shell forms a short pointed spire, dominated by a large last whorl.
- Last whorl bears 11-14 spiral ridges.
- Siphonal canal open and short.
- Shell with low, strap-shaped spiral ridges, separated by narrow grooves and crossed by growth lines.
- Outer lip of aperture thin and smooth in young specimens but thick and toothed internally in shells that have ceased growth.
- Hypobranchial gland produces a purple secretion.
Additional information
The taxonomy of Nucella lapillus was reviewed by Crothers (1985) and Kool (1993)
Listed by
Biology review
Taxonomy
Level | Scientific name | Common name |
---|---|---|
Phylum | Mollusca | Snails, slugs, mussels, cockles, clams & squid |
Class | Gastropoda | Snails, slugs & sea butterflies |
Order | Neogastropoda | Whelks, drills & cone snails |
Family | Muricidae | |
Genus | Nucella | |
Authority | (Linnaeus, 1758) | |
Recent Synonyms | Thais lapillus (Linnaeus, 1758) |
Biology
Parameter | Data | ||
---|---|---|---|
Typical abundance | Moderate density | ||
Male size range | 17 - 50+mm | ||
Male size at maturity | |||
Female size range | Small-medium(3-10cm) | ||
Female size at maturity | |||
Growth form | Turbinate | ||
Growth rate | See additional information | ||
Body flexibility | None (less than 10 degrees) | ||
Mobility | Creeper | ||
Characteristic feeding method | Predator | ||
Diet/food source | Carnivore | ||
Typically feeds on | Barnacles and mussels (see Crothers, 1985). | ||
Sociability | Gregarious | ||
Environmental position | Epifaunal | ||
Dependency | Independent. | ||
Supports | Host trematode parasites of sea birds, Parorchis acanthus and Lepocreadium sp. | ||
Is the species harmful? | No But not edible, being distasteful (Crothers, 1985). |
Biology information
The ecology, physiology and genetics of Nucella lapillus has been extensively studied. Therefore, the following review is based on more detailed reviews by Fretter & Graham (1994) and Crothers (1985), to which the user should refer for further detail. The original references are given where appropriate.
Growth rate. Growth rates vary depending on wave exposure, prey type and starvation. Sheltered shore populations grow faster than wave exposed shore populations, resulting in larger more elongated shells (Osborne, 1977; Crothers, 1985; Etter, 1989). Feare (1970b) reported that juveniles reached 10 mm within a year, ca 15 mm at two years old and entered maturity at ca 20 mm at Robins Hood Bay in Yorkshire. Moore (1938a) reported that dog whelks reach 10 to 15 mm at one year, 21 to 26 mm at two years and 29.5 mm at maturity. Maturity was calculated to be reached at 2.5 years at which point shell growth stops (Fretter & Graham, 1994). However, Etter (1996) suggested that adults continued to grow but extremely slowly. Osborne (1977) noted that juveniles <12 mm grew at the same speed above which sheltered individuals grew faster than wave exposed individuals. Etter (1996) reported that juveniles grew 6 mm/150 days on wave exposed shores but 9 mm /150 days in sheltered conditions. Mussels supported the highest growth rates (Hughes & Drewett, 1985). Etter (1996) transplanted juveniles between shores of different wave exposure and concluded that growth was determined by environmental factors and depressed by wave exposure since it reduced foraging or feeding time. Crothers (1985) suggested that, although crabs select the largest first-year class dog whelks, rapid growth may allow dog whelks to grow beyond the predator's preferred size range and decrease their susceptibility to predation.
Feeding. Nucella lapillus is an important intertidal predator and preys mainly on barnacles and mussels but may also prey on cockles, other bivalves and gastropods. Key points follow.
- As in many neogastropods, the mouth and radula are born on an extensible proboscis, which in Nucella lapillus is approximately the same length as the shell in each individual (Barnes, 1980; Crothers, 1985).
- Nucella lapillus feeds by either
- pressing the proboscis between the valves of bivalves or plates of barnacles and removing flesh by the rasping radula, or
- by boring a hole in the shell of its prey and inserting the proboscis through the hole.
- The victim's shell is bored by a combination of mechanical rasping by the radula in the proboscis and chemical attack by secretions of the accessory boring organ (ABO) situated in the sole of the foot.
- Once penetrated, the prey is narcotized by secretions of the accessory salivary glands, which also secrete a cement-like substance that may help keep the proboscis attached to the prey (Andrews, 1991; Fretter & Graham, 1994). The hypobranchial gland also secretes a pharmacologically active choline ester that may be involved in narcotization (Carriker, 1981; Crothers, 1985), however, its function is disputed by Fretter & Graham (1994).
- The dog whelk secretes digestive enzymes into the body of the prey and then ingests the resultant tissue 'soup' (Crothers, 1985).
- The 'gape' attack method is energetically more effective (Fretter & Graham, 1994) and is more likely to be used by dog whelks with experience in handling the prey than inexperienced dog whelks and results in a lower prey handling time than boring (Rovero et al., 1999). Large dog whelks can also force the proboscis between the opercular plates of barnacles to apply the narcotic (Carriker, 1981; Fretter & Graham, 1994). The 'gape' attack is presumed to rely on the successful application of the narcotic (Rovero et al., 1999).
- Rovero et al. (1999) reported that the 'gape' attack method resulted in prey handling time (including inspection, narcotization and ingestion) of 49-51 hrs depending on experience, compared with a handling time of ca 100 hrs by boring. Morgan (1972) reported that boring could take 3 days to complete. Therefore, handling time can span several tidal cycles during which the dog whelk is vulnerable to desiccation, wave exposure and predation (Hughes & Drewett, 1985; Rovero et al., 1999).
- It has been shown that experience of a particular food type reduces handling time (Dunkin & Hughes, 1984; Hughes & Dunkin, 1984), which may partly explain dog whelk's preference for a particular type of prey even in the presence of others.
- Once fed the dog whelk rests in a crevice or other shelter, up to 2-4 tides after feeding on barnacles and 7-9 tides after mussels (Hughes & Drewett, 1985). However, larger dog whelks have higher energy demands and rest for shorter periods (Bayne & Scullard, 1978).
- Crothers, (1985; Table 1) lists 24 potential recorded food species. Nucella lapillus usually favours Semibalanus balanoides > Balanus spp. > Mytilus edulis > Elminius modestus > (Crothers, 1985).
- Larger dog whelks tend to handle larger prey than small dog whelks. Hughes & Burrows (1993 ) found that dog whelks avoided mussels <5 mm and preferred 10-20 mm mussels (Hunt & Scheibling, 1998). Hunt & Scheibling (1998) noted that although juveniles (<3 mm) rarely fed on mussels <2 mm and post-recruits (<5 mm) only rarely consumed mussels <5 mm both were capable of feeding on the full-size range of mussels presented. Mussels >4 cm seem to be safe from dog whelk attacks, and Crothers (1985) suggested that 2 cm long mussels were optimum for a 3 cm long dog whelk (Bayne & Scullard, 1978; Crothers, 1985).
- Feeding rates vary, depending on the size (hence shell thickness) of prey, temperature and season.
- Crothers (1985) suggested a mean annual consumption of 15-40 mussels per dog whelk (Largen, 1967a; Bayne & Scullard, 1978) and reported rates of 0.5 or 0.59 mussels/day or 1.1 Semibalanus balanoides /day in summer (Connell, 1961; Fretter & Graham, 1962; Anala, 1974).
- Largen (1967b) noted that feeding rates decreased with temperature, from an average of 16 barnacles or 0.7 mussels per week at 20 C to 10.2 barnacles and 0.4 mussels per week at 15 C.
- Connell (1961) noted that the time spent feeding on open rock surfaces decreased from about 60% in July to September to only 13% in January to March.
- Although foraging patterns on a given shore are similar, they vary between locations depending on the type of shore, its wave exposure, and local weather. Dog whelks from sheltered shores forage less in sunny, warm weather, whereas animals from wave exposed shores favoured calm periods even when sunny (Burrows & Hughes, 1989; Fretter & Graham, 1994).
- Stickle et al. (1985) demonstrated that starvation could overcome the dog whelks tendency to avoid stressful conditions e.g. low salinity. Feeding rates were reduced at low salinity and temperature, e.g. only 25% of dog whelks examined fed at 25 psu and 5C or 15 psu and 8.5C. When exposed to air (emersion) ingestion rates were affected by the air and water temperatures, the difference between these temperatures, salinity, humidity, weather conditions and appetite (Stickle et al., 1985) (see sensitivity).
- Dog whelks avoid dense mussel beds, preferring the diffuse margins between the mussel bed and the surrounding barnacle-dominated substratum, or solitary mussels (Petraitis, 1987; Fretter & Graham, 1994; Davenport et al., 1996). This was partly because mussels can immobilise gastropods (Nucella lapillus and Littorina littorea) crossing the mussel bed with their byssus threads. Davenport et al., (1996) found that although Littorina littorea broke free of at least 14 byssus threads within 45 mins, Nucella lapillus attached by 1-18 byssus threads took 4-12 hrs to escape. Some specimens, however, were found immobilised by at least 30 byssus threads. Dog whelks take a long time to feed, hence, increasing the chance of them being immobilised. Petraitis (1987) suggested that mussels co-operated to flip over predatory dog whelks. However, Davenport et al., (1996) found that byssus attachments occurred to areas of the shell closest to the substratum, there was no evidence of selective attachment to flip the shell over. Petraitis (1987) calculated that nearly 30% of dog whelks in a mussel bed perished due to being immobilised.
Shell colour and sculpture variation. Nucella lapillus is highly variable in the appearance of its shell, depending on wave exposure and location (see Crothers, 1983; 1985 for review).
- Shell colour may be white, brown shading to black, mauve grading to pink, yellow shading to orange and rarely true orange, pink or black (Moore, 1936; Berry & Crothers, 1974; and Crothers, 1985, Plate 2). The white form predominates in the UK, but coloured shells predominate in the southern limits of its range (Portugal and Northern Spain) and in northern populations in Iceland (Crothers, 1985).
- Nucella lapillus also exhibits a variety of banded forms, with a mixture of un-banded, thin or thick banded (see Crothers, 1985 for discussion).
- Palmer (1984) demonstrated the inheritance of colour, banding and spiral shell sculpture using breeding experiments in Nucella emarginata. Similar breeding experiments have not been carried out in Nucella lapillus (Crothers, 1985), however it seems likely that colour and banding are under genetic control.
- In some populations, mainly sublittoral or from the intertidal in North Kent, the growth lines extend outwards to form flounces or ruffles, and this variety of dog whelk is called Nucella lapillus var. imbricata. The imbrication is genetically determined but may appear less marked due to abrasion (Largen, 1971; Crothers, 1985).
- The shell may also bear white dentiform tubercles on the inside edge of the shell lip, which develop once the shell has stopped growing (ca 2 years ). However, interruption of growth earlier in life, possibly due to starvation or parasitism may result in additional rows of teeth (Crothers, 1985).
Shell shape variation. Variation in shell shape and length has been extensively studied (see Crothers, 1985 for a review). Key points follow.
- Sheltered shore animals grow faster than wave exposed individuals (Osborne, 1977) and sheltered shore populations have longer shells than wave exposed populations. Populations of exceptional length (up to 60 mm) occur subtidally or at extreme low water at Porlock Weir in the Severn Estuary, between Swanage and Kimmeridge, Dorset and at some sites in western Scotland (Crothers, 1985).
- Nucella lapillus from wave exposed shores tend to have shorter, squatter shells than those from sheltered shores, which are more elongate. A progression from squat to elongate form is seen with decreasing wave exposure (Cooke, 1895; Kitching & Ebling, 1967; Crothers, 1985). The shape of the shell can be expressed in terms of the shell length relative to the aperture length (see Crothers, 1985 for review). The possible reasons for the relationship between wave exposure and shell shape are noted below.
- Short squat shells offer less resistance to water flow and wave action and exhibit a larger aperture and larger foot and hence increased pedal surface area, which increases their adhesion the substratum (Cooke, 1895; Kitching & Ebling, 1967; Crothers, 1985; Etter, 1988).
- Etter (1988) noted that the foot grows faster in wave exposed conditions rather than in sheltered conditions and that foot size increased in dog whelks transplanted to more wave exposed shores but change little in the reciprocal transplant (Etter, 1988; Fretter & Graham, 1994).
- Longer, elongated shells have a relatively smaller foot but can hold a significantly greater volume of water within their mantle cavity when emmersed and are more tolerant of desiccation (see sensitivity) (Osborne, 1977, Kirby, 1994a).
- Short squat shells are more prone to predation, their rounded shape makes them easier to swallow for birds such as gulls and eider duck. In addition, the animal is not able to withdraw completely into the shell making them susceptible to crabs and oystercatchers whereas the elongated shell form can withdraw completely and the narrow aperture does not allow crabs to gain adequate purchase on the shell. (Osborne, 1977) (see sensitivity to wave exposure).
- Crothers (1985) reported that the squat shell shape was absent from wave exposed sites in south-east England, the north coast of Wales, the Solway Firth and the Severn Estuary. Crothers (1985, Figure 33) suggested that the UK population of Nucella lapillus was divided into two groups, a southwestern group bearing the genes for the squat shell shape and another north-eastern from, which lacks the genes for the squat form and can only develop as the elongate form.
Genetic variation. In addition to the colour variation mentioned above, Nucella lapillus has been shown to demonstrate clines in allozyme (Day & Bayne, 1988; Day, 1990; Kirby, 1994a, b) and mitochondrial DNA polymorphisms (Kirby et al.,1997), Robertsonian translocation (Staiger, 1957; Bantock & Cockayne, 1975; Page 1988; Pascoe & Dixon, 1994; Pascoe et al., 1996), peri-and para-centric chromosomal inversions (Page 1988; Pascoe & Dixon, 1994; Pascoe et al., 1996; Pascoe, 2002). Variation in chromosome number was found to vary greatly between different populations, within some populations and even within some individuals (Pascoe, 2002).
Habitat preferences
Parameter | Data |
---|---|
Physiographic preferences | Open coast, Strait or Sound, Sea loch or Sea lough, Ria or Voe, Estuary, Enclosed coast or Embayment |
Biological zone preferences | Lower eulittoral, Mid eulittoral, Sublittoral fringe |
Substratum / habitat preferences | Artificial (man-made), Bedrock, Caves, Crevices / fissures, Large to very large boulders, Overhangs, Rockpools, Small boulders, Under boulders |
Tidal strength preferences | Moderately 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 preferences | Exposed, Extremely exposed, Extremely sheltered, Moderately exposed, Sheltered, Very exposed, Very sheltered |
Salinity preferences | Full (30-40 psu), Variable (18-40 psu) |
Depth range | Intertidal |
Other preferences | No text entered |
Migration Pattern | Non-migratory or resident |
Habitat Information
- Nucella lapillus is widely distributed approximately between the 19 °C summer isotherm in the south and the -1 °C winter isotherm in the north (Moore, 1936), except in areas of reduced salinity such as the Baltic Sea (Crothers, 1985).
- Dog whelks occur below of mid tidal level, approximating to 10-75% emersion (Fretter & Graham, 1994).
- Nucella lapillus may form aggregations on the shore. In summer (May - October) aggregations of 20-500 individuals of mixed ages may form on the open rock surface of extensive shores (e.g. at Robins Hoods Bay) giving the appearance of a hunting pack (Feare, 1971; Lewis, 1964; Crothers, 1985). In winter individuals aggregate in crevices and pools, presumably to avoid dislodgement, since they have difficulty re-attaching in cold weather. Winter aggregations may form into pre-breeding and breeding aggregations in which the juveniles leave to feed but the adults remain (Feare, 1971; Crothers, 1985).
Life history
Adult characteristics
Parameter | Data |
---|---|
Reproductive type | Gonochoristic (dioecious) |
Reproductive frequency | Annual protracted |
Fecundity (number of eggs) | 100-1,000 |
Generation time | 2-5 years |
Age at maturity | 2.5 years |
Season | Spring - Autumn |
Life span | 5-10 years |
Larval characteristics
Parameter | Data |
---|---|
Larval/propagule type | - |
Larval/juvenile development | Oviparous |
Duration of larval stage | Not relevant |
Larval dispersal potential | <10 m |
Larval settlement period | Not relevant |
Life history information
Breeding occurs throughout the year but is maximal in spring and autumn.
Spawning. Adult Nucella lapillus may be seen spawning or copulating in spawning aggregations. Pre-spawning and spawning aggregations develop in early spring, sometimes summer, and may comprise 30 or (many) more individuals, dominated by adults. Pre-spawning aggregations may be difficult to distinguish from winter aggregations, except that the winter aggregations consist of all age classes. Winter and spawning aggregations occur in sheltered areas of the shore (e.g. crevices or under hangs and leeward faces), which are also perfect sites for spawning. Adults do not feed during mating and spawning and may remain in their winter aggregation sites for 4-5 months without feeding or moving significantly (Crothers, 1985).
Egg capsules. Nucella lapillus lays its eggs in protective egg capsules on hard substrata in damp crevices and under stones. Copulation is repeated at intervals, between which a few egg capsules are laid, one at a time (Fretter & Graham, 1994). Larger females lay larger capsules, however, most capsules are vase-shaped, 9 to 10 mm high, 3 to 4 mm across and yellow to brown in colour. Capsules are cemented to the substratum by the ventral pedal gland and foot and is sealed with a 'plug' at the opposite end. (Crothers, 1985; Graham, 1988; Fretter & Graham, 1994). The gametogenesis, oviposition and structure of egg capsules are discussed in detail by Ankel (1937), Fretter (1941), Feare (1970a), and Fretter & Graham, (1985, 1994).
Fecundity. The number of capsules laid depends on the female's food reserves, age and temperature, e.g. populations in the White Sea lay ca 20-30 capsules per season, while temperate Atlantic populations may lay 5 times this number. Although each capsule may contain ca 600 eggs, 94% of the eggs are unfertilized and function as 'nurse eggs' and are fed upon by the developing embryos (Fretter & Graham, 1994; Crothers, 1985). Capsules have been reported to release 12 -15 'crawl-away' hatchlings per capsule (Crothers, 1977), 13-36 hatchlings per capsule (Feare, 1970b) or 25-30 hatchlings per capsule (Graham, 1988). Fretter & Graham (1994) estimated that each female could produce 1030 hatchlings per year. Etter (1989) noted that, in Massachusetts, adults from wave exposed shores laid about twice as many egg capsules and released about twice as many hatchlings per capsule (albeit ca 20% smaller) as adults from sheltered shores. The number and size of offspring produced was dependent on wave exposure, and formed a cline across the wave exposure gradient (Etter, 1989).
Impact of TBT on reproduction. The effects of tributyl tin (TBT), used in anti-fouling paints, on Nucella lapillus have been extensively documented and represent one of the best-known examples of the effects of chemical pollution (see sensitivity). The following is based upon reviews by Hawkins et al. (1994) and Bryan & Gibbs (1991) to which the reader should refer for further detail.
- TBT is thought to increase the levels of testosterone in the female causing the development of male sexual characteristics, termed 'imposex' (Smith, 1980).
- With increasing TBT concentration a penis and vas deferens develop in the female, until the vas deferens occludes the genital papillae of the female, preventing the release of egg capsules and effectively rendering the female sterile. The aborted capsules eventually build up until they rupture the capsule gland of the female, and kill the individual. The different stages of development are described by the vas deferens sequence (VDS) (Gibbs & Bryan, 1983). The degree of imposex may also be measured by the relative size of the female and male penises and termed the relative penis size (RPS).
- Both RPS and VDS have been used to estimate the degree of TBT contamination to which a population has been exposed and to environmental monitoring of TBT (Bryan & Gibbs, 1991; Evans et al., 1991; Moore et al., 2000)
Larval development. The equivalent of the veliger stage occurs within the capsule. Nucella lapillus larvae feed on the nurse cells in the late veliger stage, during which development is halted for about 1 week. Development is slow and temperature dependant, taking ca 4 months in temperate areas but up to seven months in the White Sea, where the eggs overwinter (Fretter & Graham, 1994). Once larvae have become miniature adults they leave the capsule via the terminal plug, although if this exit is blocked by other hatchlings they may bore through the capsule wall. Hatchlings may be termed crawl-aways (Crothers, 1985; Fretter & Graham, 1994).
Longevity and mortality. Feare (1967) suggested that a large proportion of the 69% mortality of Nucella lapillus observed on the Yorkshire coast in the winter of 1965 -66 was due to predation by oystercatchers (Haematopus ostralegus). Adults are also preyed on by gulls and eiders, which swallow the dog whelk whole. Adult dog whelks of 4 cm or more long are probably safe from birds (Crothers, 1985). Juveniles are eaten by rock pipits, turnstones, and purple sand-pipers. Feare (1970b) estimated juvenile mortality to be 90% within the first year, ca. 50% in the second year and 27% in the third. Feare (1967; 1970b) reported that the purple sand-piper favoured 2-5 mm long dog whelks (occasionally 8 mm) and accounted for most of the 90% mortality in juvenile dog whelks in the winter of 1965-66 in Robin Hood's Bay. Juveniles are also susceptible to crab predation. Feare (1967) reported that most of the juvenile mortality between the summer and autumn of 1966-67 (Robin Hood's Bay) was due to crabs. Carcinus maenas can handle dog whelks up to 1.5 cm in length whereas Necora puber can handle up to 2.5 cm (Crothers, 1985). Crothers (1985) suggested that lobsters, which can crush any size adult, may be a significant predator below low water. Feare (1970b) estimated a life expectancy of at least 6 years, although Crothers (1985) suggested that this may be an under-estimate.
Dispersal. Nucella lapillus lacks a dispersive pelagic larval phase. They are relatively inactive as adults, moving mostly at night (males more than females) but rarely far. Several movement estimates have been reported, for example, an average of 100 mm /tidal cycle (Connell, 1961), or 123 mm/day over barnacles and 329 mm/day over a cockle bed (Morgan, 1972; Fretter & Graham, 1994). Crothers (1985) reported that marked specimens were recovered within 30 cm of their release site after one year, and suggested that with an abundant food supply, there was little stimulus to move far from their site of birth. Castel & Emery (1981) reported that adults do not move more than 30 m in their lifetime. Nucella lapillus recolonizing Watermouth Cove in north Devon, following the effects of TBT pollution (Crothers, 1998), have advanced at least 30 m in a minimum of 13 years (Crothers, in prep). Palmer (1984) also noted that a few Nucella emarginata moved more than 10 m in a year in the USA. Similarly, Gosselin & Fu-Shiang Chia (1995) reported that dispersal was limited to a few meters from the egg capsules in Nucella emarginata (in the USA). Poor dispersal as adult and hatchling results in low rates of recruitment from or migration between adjacent populations, and may lead to relatively high levels of genetic isolation and variation within the population (population sub-division). However, Martel & Fu-Shiang Chia (1991) collected two hatchling Nucella emarginata drifting in the intertidal, suggesting that dispersal by passive transport by currents can occur occasionally. Gosselin & Fu-Shiang Chia (1995) point out that occasional drifting by small numbers of hatchlings, while rare, may still result in significant gene flow, and that since dislodgement increases with wave exposure, more gene flow (hence less population subdivision) may occur in wave exposed rather than sheltered shores.
Sensitivity review
The MarLIN sensitivity assessment approach used below has been superseded by the MarESA (Marine Evidence-based Sensitivity Assessment) approach (see menu). The MarLIN approach was used for assessments from 1999-2010. The MarESA approach reflects the recent conservation imperatives and terminology and is used for sensitivity assessments from 2014 onwards.
Physical pressures
Use / to open/close text displayed
Intolerance | Recoverability | Sensitivity | Evidence / Confidence | |
Substratum loss [Show more]Substratum lossBenchmark. 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 EvidenceRemoval of the substratum would cause removal of adult and juvenile dog whelks together with their egg capsules. Therefore, an intolerance of high has been recorded. Given their poor dispersal ability, recruitment from other populations is likely to be slow, therefore a recoverability of low has been recorded. | High | Low | High | Moderate |
Smothering [Show more]SmotheringBenchmark. 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. EvidenceLittle information on the effect of smothering was found. However, dog whelks are found at the mouths of highly turbid estuaries, such as the Severn Estuary where rock pools are often filled with silt. Dog whelks are therefore probably not adversely affected by temporary smothering. If smothering occurs, there will be an energetic expenditure involved in freeing itself from the smothering material. Hence, an intolerance of low has been recorded. | Low | Immediate | Not sensitive | Moderate |
Increase in suspended sediment [Show more]Increase in suspended sedimentBenchmark. 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 EvidenceNucella lapillus is found in turbid estuaries such as the Severn estuary, and is, therefore, unlikely to be adversely affected by an increase in suspended sediment concentration. However, the accumulation of silt or mud may restrict their distribution in silty estuaries such as the Severn. In addition, the abundance of their prey (barnacles and mussels) may be restricted by increased suspended sediment, reducing their food supply. Therefore, an intolerance of low has been recorded. | Low | Immediate | Not sensitive | Low |
Decrease in suspended sediment [Show more]Decrease in suspended sedimentBenchmark. 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 EvidenceNucella lapillus is found on a variety of shores from wave exposed to sheltered and is, therefore, unlikely to be affected by a decrease in suspended sediment concentration. Hence, Nucella lapillus has been recorded as 'tolerant' to a decrease in suspended sediment. | Tolerant | Not relevant | Not sensitive | High |
Desiccation [Show more]Desiccation
EvidenceDesiccation tolerance is dependant on the volume of water held inside the mantle cavity of the shell and hence the shell shape. Squat shells characteristic of some wave exposed shores have wider apertures and shorter spires which results in less water being retained within the shell when emersed and a greater rate of evaporation through the larger aperture.
The effect of a change in desiccation will be dependent on the level of wave exposure. Increased desiccation on sheltered shores is likely to reduce the upper limit on dog whelks on the shore. Wave exposed shores are less susceptible to desiccation due to increase humidity due to wave action, however, the wave exposed shell form (squat shell shape) of Nucella lapillus is more intolerant of desiccation than the sheltered, elongate form. It should be remembered that on most shores of intermediate wave exposure, intermediate shell shapes will occur. Similarly, on shores with a large tidal range, the upper shores may experience a high level of desiccation since at low tide the sea is so far away that no spray reaches the upper shore (Crothers, pers comm.). Putting aside any migration downshore, desiccation at the level of the benchmark (see benchmark) is likely to result in high mortality. | Intermediate | High | Low | Moderate |
Increase in emergence regime [Show more]Increase in emergence regimeBenchmark. A one hour change in the time covered or not covered by the sea for a period of one year. Further details EvidenceThe distribution of dog whelks on the shore is centred around the mid-tidal level and between 10-75% emersion (Fretter & Graham, 1994). Dog whelks extend higher upshore in Scotland or Norway than in south Britain (Dr John Crothers pers comm.), presumably because of the lower average air temperatures in more northern latitudes. In Norway, they can reach the uppermost Semibalanus and can eat-out their food supply. | Intermediate | High | Low | Moderate |
Decrease in emergence regime [Show more]Decrease in emergence regimeBenchmark. A one hour change in the time covered or not covered by the sea for a period of one year. Further details EvidenceThe distribution of dog whelks on the shore is centred around the mid-tidal level between 10-75% emersion (Fretter & Graham, 1994). Decreased emergence would allow the population to follow their prey as they colonized further up the shore. However, it may also expose the individuals at the bottom of the shore to increased predation from crabs and starfish. It is likely that dogwhelks would migrate up the shore and the benefits of increased access to prey would balance out the possibility of increased predation, therefore an intolerance of tolerant has been recorded. | Tolerant | Not relevant | Not sensitive | Moderate |
Increase in water flow rate [Show more]Increase in water flow rateA 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 EvidenceChange to water flow rate mostly relevant to subtidal area. Etter (1988a) demonstrated that the tenacity of dog whelks to resist water flow was proportional to the pedal surface area. Tenacity of dog whelks from sheltered shores was lower than dog whelks form wave exposed shores. He also demonstrated that dog whelks from sheltered shores would develop a larger foot when transplanted to wave exposed shores. Therefore, Nucella lapillus exhibits considerable phenotypic plasticity in response to wave exposure and most likely current flow. Although, the most elongate specimens are probably highly intolerant of increases in water flow rates, hatchlings and juveniles, which are still growing, will probably adapt to the increase water flow regime. Therefore, an overall intolerance of low has been recorded. A recoverability of very high has been recorded to represent the time taken for juveniles to recolonize and adapt (see additional information below). | Low | Very high | Very Low | Moderate |
Decrease in water flow rate [Show more]Decrease in water flow rateA 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 EvidenceIt is unlikely that a decrease in water flow rate will directly affect dog whelks even though the longer foot associated with strong flows becomes superfluous. However, the biotope may change and prey species, predominantly barnacles, become less abundant. Etter (1988a) demonstrated that the tenacity of dog whelks to resist water flow was proportional to the pedal surface area. A decrease in water flow may result in an increase in the mean shell length of the population (depending on wave exposure) but Nucella lapillus is otherwise probably tolerant of a decrease in water flow. | Tolerant | Not relevant | Not sensitive | Low |
Increase in temperature [Show more]Increase in temperature
For intertidal species or communities, the range of temperatures includes the air temperature regime for that species or community. Further details EvidenceLargen (1967) reported that feeding rate was maximal between 20 -22 °C and fell steeply to zero at 25 °C whilst crawling reached zero at 27 °C. Sandison (1968); (reported unpublished in Lewis, 1964) noted that heat coma occurred in Nucella lapillus at 27 -28 °C, and death at 32 -33 °C. Largen (1967) noted that feeding rates were temperature dependant, dog whelks averaged consumption of 16 barnacles or 0.7 mussels per week at 20 °C but only 10.2 barnacles and 0.4 mussels per week at 15 °C. Newell (1979) noted that oxygen consumption (hence metabolic rate) fell with decreased temperature and starvation, being low in winter but high in summer. This resulted in a high scope for activity, and dog whelks responded rapidly to increases in temperature in the spring. Newell (1979) pointed out that dog whelks could adjust their metabolic rate with temperature and season. Stickle et al. (1985) also noted that feeding and ingestion rates decreased with decreasing temperature and salinity. Etter (1988b) noted that white shells reflected more light (reducing the rate of heating and the temperature reached within unit time) and that dog whelks were cooled by evaporation of the water retained within the shell during emersion. | Intermediate | High | Low | Moderate |
Decrease in temperature [Show more]Decrease in temperature
For intertidal species or communities, the range of temperatures includes the air temperature regime for that species or community. Further details EvidenceThe northern geographical limit of Nucella lapillus is close to the 0 °C winter isotherm. Therefore, Crothers (1985) suggested that they were limited by ice, and that although dog whelks themselves could avoid ice in cracks and crevices, their prey (barnacles and mussels) could not avoid ice-scour. Cold torpor was apparent in dog whelks acclimated to 5 °C (Stickle et al., 1985). Speed of movement increases rapidly above 5 °C (Largen, 1967), and activity begins at 3 °C , however, Nucella lapillus is totally inactive at 0 °C and will fall off steep substrata (Largen, 1967; Crothers, 1985). Dog whelks crept into sheltered crevices in winter and probably effectively hibernate over winter (Moore, 1936; Largen, 1967). Cold torpor is likely, therefore, to increase this species risk of being washed offshore or of predation. Low temperatures make dog whelks less tolerant of low salinity (Dr John Crothers, pers comm.). Feeding and ingestion rates also decrease with temperature. Largen (1967) noted that spawning began once temperatures increased to 9-10 °C , and was interrupted by a fall in temperature. Largen (1967) reported that dog whelks averaged consumption of 16 barnacles or 0.7 mussels per week at 20 °C but only 10.2 barnacles and 0.4 mussels per week at 15 °C. Newell (1979) noted that oxygen consumption (hence metabolic rate) fell with temperature and starvation, being low in winter but high in summer. This resulted in a high scope for activity, and dog whelks responded rapidly to increases in temperature in the spring. Newell (1979) pointed out that dog whelks could adjust their metabolic rate with temperature and season. Stickle et al. (1985) also noted that feeding and ingestion rates decreased with decreasing temperature and salinity. During the severe winter of 1962/63, Nucella lapillus were reportedly unaffected in Anglesey, north Wales and the South Wales coast although many were reported killed in the Beaulieau River, Hampshire (Crisp ed., 1964). Overall, it appears that Nucella lapillus can survive temperatures as low as 3 °C and possibly 0 °C, although evidence for duration is lacking, the effects of low temperatures are sub-vital and an intolerance of low, at the level of the benchmark, has been recorded. | Low | Very high | Very Low | Moderate |
Increase in turbidity [Show more]Increase in turbidity
EvidenceNucella lapillus is an active carnivore and is unlikely to be adversely affected by increases or decreases in light attenuation due to turbidity and has been recorded as 'tolerant' to this factor. | Tolerant | Not relevant | Not sensitive | High |
Decrease in turbidity [Show more]Decrease in turbidity
EvidenceNucella lapillus is an active carnivore and is unlikely to be adversely affected by increases or decreases in light attenuation due to turbidity and has been recorded as 'tolerant' to this factor. | Tolerant | Not relevant | Not sensitive | High |
Increase in wave exposure [Show more]Increase in wave exposureA 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 EvidenceDog whelks adapt to wave action through their shell shape and size of foot (Crothers, 1985). Etter (1988a) demonstrated that the tenacity of dog whelks to resist wave action was proportional to the pedal surface area. Tenacity of dog whelks from sheltered shores was lower than dog whelks from wave exposed shores. He also demonstrated that dog whelks from sheltered shores would develop a larger foot when transplanted to wave exposed shores. Therefore, Nucella lapillus exhibits considerable phenotypic plasticity in response to wave exposure and current flow. It is also found from very wave exposed to very sheltered shores. An increase in wave action, for example from sheltered to exposed (see benchmark) is likely to increase mortality due to dislodgement and result in loss of a proportion of the population. Very sheltered and sheltered shores are likely to be more intolerant of such an increase. Therefore, an intolerance of intermediate has been recorded. Recent juveniles colonizing the shore in autumn and winter in the UK, are likely to adapt their phenotype to the prevalent conditions. Therefore a recoverability of high (see additional information below) has been recorded. | Intermediate | High | Low | High |
Decrease in wave exposure [Show more]Decrease in wave exposureA 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 EvidenceGrowth adaptations of the dog whelk to strong wave action result in a thinner shell and longer pedal opening. Therefore, although adhesion to the substrate will be more than adequate with an increase in shelter. However, wave exposed forms may be more liable to predation from crabs and to desiccation (see above). Therefore, an intolerance of intermediate has been recorded. Recent juveniles colonizing the shore in autumn and winter in the UK, are likely to adapt their phenotype to the prevalent conditions. Therefore a recoverability of high (see additional information below) has been recorded. | Intermediate | High | Low | High |
Noise [Show more]Noise
EvidenceWhile Nucella lapillus is probably sensitive to local vibration within its vicinity, possibly similar to that caused by a predator, it is unlikely to be adversely affected by noise of the type or levels addressed in the benchmark. | Tolerant | Not relevant | Not sensitive | High |
Visual presence [Show more]Visual presenceBenchmark. 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 EvidenceNucella lapillus bears light sensitive eyes on its tentacles. However, its visual acuity is probably low and it is unlikely to be adversely affected by movement or shading due to anthropogenic activities. | Tolerant | Not relevant | Not sensitive | High |
Abrasion & physical disturbance [Show more]Abrasion & physical disturbanceBenchmark. 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. EvidenceShells of Nucella lapillus are likely to show signs of abrasion due to wave action or sediment scour. The flounces of Nucella lapillus var. imbricata may also be reduced due to abrasion. However, no information concerning the effect of abrasion such as trampling on dog whelks was found. It is likely that some individuals may be dislodged and some washed to deep water and lost as a result. The most adverse affect is likely to be indirect due to a loss of prey such as mussels or barnacles due to trampling or removal by an abrasive force. However, dog whelks are capable to switching to another prey source in the absence of their preferred prey, so an intolerance of low has been recorded. | Low | Immediate | Not sensitive | Moderate |
Displacement [Show more]DisplacementBenchmark. 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 EvidenceDisplaced and dislodged individuals may become subject to increased desiccation if up turned, or washed to deep water and lost. However, Bryan (1968) reported that adults, presumably narcotized by oil and dispersants and washed below low water recolonized the shore within about 6 months, suggesting that displaced individuals could return to the intertidal. However, Nucella lapillus does not readily crawl across sediment, therefore individuals displaced to unsuitable substrata may not be able to return. Therefore, a precautionary intolerance of intermediate has been recorded. Recruitment from surviving adults and recolonization by juveniles from below water may result in recovery within about two years and a recoverability of high has been recorded (see additional information below). | Intermediate | High | Low | Moderate |
Chemical pressures
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Intolerance | Recoverability | Sensitivity | Evidence / Confidence | |
Synthetic compound contamination [Show more]Synthetic compound contaminationSensitivity 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:
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. EvidenceThe effects of tributyl tin (TBT), used in anti-fouling paints, on Nucella lapillus have been extensively documented and represent one of the best known examples of the effects of chemical pollution. The following is based upon reviews by Hawkins et al. (1994) and Bryan & Gibbs (1991) to which the reader should refer for further detail.
| High | Low | High | High |
Heavy metal contamination [Show more]Heavy metal contaminationEvidenceBryan (1984) suggested that adult gastropod molluscs were relatively tolerant of heavy metal pollution. Bryan & Gibbs (1983) noted that Nucella lapillus accumulated Cu and Zn in the Fal estuary, but was excluded from the highly heavy metal contaminated Restronguet Creek. Food is the main route of uptake of iron (Fe) and zinc (Zn) in Nucella lapillus (Young, 1977). Nucella lapillus exhibits detoxification systems e.g. granules containing phosphate, calcium, zinc, magnesium (Mg) and copper occur in the digestive gland, which may explain their tolerance of high levels of Zn and copper (Cu), (Ireland, 1979; Bryan, 1984), Cadmium (Cd) is detoxified by storage as a metallothionien (Bryan, 1984). Therefore, an intolerance of low has been recorded. | Low | Very high | Very Low | Moderate |
Hydrocarbon contamination [Show more]Hydrocarbon contaminationEvidence
Overall, while Nucella lapillus is probably more resistant to oiling and emulsifiers than most gastropods (except Osilinus lineatus), the above evidence indicates that population are severely affected by oil but especially emulsifiers depending on concentration. Therefore, an intolerance of intermediate has been recorded. Where, adults survive or juveniles are represent below low water, recolonization may take up to 2 years (see additional information below). | Intermediate | High | Low | High |
Radionuclide contamination [Show more]Radionuclide contaminationEvidenceInsufficient | No information | No information | No information | Not relevant |
Changes in nutrient levels [Show more]Changes in nutrient levelsEvidenceGibbs et al. (1999) reported a massive kill of Nucella lapillus in Bude Bay, north Cornwall. Gibbs et al. (1999) suggested that the mass mortalities may have been caused by eutrophication and summer algal blooms due to a new sewage outfall in the area that received only primary treated sewage. Nucella lapillus has been shown to be severely affected by toxic algal blooms. For example, Robertson (1991) reported up to 98-99% mortality of dog whelks exposed to a toxic bloom of Chrysochromulina polylepis in Gullmar Fjord, west Sweden in June 1988. As a result, the distribution and abundance were reduced, 1-2 yr. olds (three years recruitment) suffered heavy mortality and subsequent reproductive capacity was reduced (Robertson, 1991). Similarly, Nucella lapillus was shown to be severely affected by a bloom of Gyrodinium aureolum in south west Ireland in 1979 (Cross & Southgate, 1980) and strongly affected by a bloom of Chrysochromulina polylepis in the Kattegat, Skagerrak and Norwegian coast of the North Sea, May -June, 1988 (Underdal et al., 1989). Therefore, an intolerance of high has been recorded. Given their poor dispersal and recruitment from other populations, recovery may take many years (see additional information below). | High | Low | High | Moderate |
Increase in salinity [Show more]Increase in salinity
EvidenceKirby et al. (1994b) simulated the effects of hyper-osmotic shock due to evaporation of mantle cavity retained seawater in Nucella lapillus. Exposure to 35, 45, 55, 65 and 75 psu over periods of 6, 12 and 24 hrs at 15 °C resulted in an increase in alanine production, with concomitant decrease in aerobic respiration and, on return to 35 psu, an increase in nitrogen excretion due to increased protein metabolism. However, no mortalities were observed during the experiment, although the dog whelks remained in their shells for the duration of the experiment (Kirby pers. comm.). Kirby et al. (1994b) noted that the wave exposed (short spired shell) form of Nucella lapillus suffered a greater decrease in aerobic respiration and increase in protein metabolism and hence greater stress than the sheltered site forms. Kirby et al. (1994b) also noted a correlation between the physiological effects of hyperosmotic shock and different alleles at the leucyl-amino peptidase (Lap) locus suggesting a genetic component to hyper-osmotic shock tolerance. Overall, it appears that Nucella lapillus would tolerate an acute, short term increase in salinity, albeit at metabolic cost, suggesting an intolerance of 'low'. | Low | Very high | Very Low | Moderate |
Decrease in salinity [Show more]Decrease in salinity
EvidenceNucella lapillus is unable to feed under brackish conditions and are likely to be absent from areas of fresh water influence on the shore (Crothers, 1985). Feare (1970b) noted that in rock pools at full salinity 100% of egg capsules hatched, whereas only 27% hatched in areas subject to fresh water runoff at low tide. Stickle & Bayne (1985) reported that, at between 5 -20 °C, dog whelks over 20 mm in length tolerated between 14.2 and 16.2 psu, whether exposed abruptly or after acclimation. In their experiments smaller dog whelks were able to tolerate salinities as low as 12.7 psu. Stickle et al., 1985 noted that reduced salinity and temperature reduced feeding rates in Nucella lapillus, e.g. only 10% fed at 25 psu and 5 °C or 15 psu and 8.5 °C. They reported that Nucella lapillus was a poor volume regulator and did not quantitatively regulate their free amino acid pool. Crothers (1985) noted that Nucella lapillus is usually absent from estuaries and although found in the Severn Estuary it is restricted to the lower shore up-channel from Minehead where they presumably avoid reduced salinities. Therefore, a reduction in salinity below 18 psu is likely to adversely affect reproduction and feeding. Hence, a reduction in salinity at the benchmark level is likely to reduce the extent or abundance of Nucella lapillus and an intolerance of intermediate has been recorded. Gibbs et al. (1999) reported that dog whelks surviving a mass kill were able to re-establish the population within 2 years, except where mortalities were extensive, and a recoverability of high has been recorded (see additional information below). | Intermediate | High | Low | Moderate |
Changes in oxygenation [Show more]Changes in oxygenationBenchmark. Exposure to a dissolved oxygen concentration of 2 mg/l for one week. Further details. EvidenceNo information regarding tolerance to anoxic conditions was found. Nucella lapillus is able to maintain aerobic respiration when emmersed (Sandison, 1968; Houlihan et al., 1981; Innes & Houlihan, 1985) and unlikely to suffer anoxia at low tide. Nucella lapillus is reported to be capable of anaerobic respiration (Sandison, 1966 cited in Gibbs et al., 1999). Gibbs et al. (1999) suggested that its ability to respire aerobically at low tide would compensate for any anoxia experienced when immersed and that it is probably relatively tolerant of low oxygen conditions. Gelder-Ottaway (1976a) demonstrated mortalities (8-40%) in dog whelks held for 5 days in seawater under films of oil. Although the experiment was intended to demonstrate mortalities due to oil film, the death observed probably owed more to oxygen deficiency than the oil itself. Therefore, exposure to 2 mg/l O2 for one week is likely to result in some mortality in dog whelk populations, and an intolerance of intermediate is recorded, although the ability to respire during emersion will probably keep mortalities to a minimum. Gibbs et al. (1999) reported that dog whelks surviving a mass kill were able to re-establish the population within 2 years, except where mortalities were extensive, and a recoverability of high has been recorded (see additional information below). | Intermediate | High | Low | Low |
Biological pressures
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Intolerance | Recoverability | Sensitivity | Evidence / Confidence | |
Introduction of microbial pathogens/parasites [Show more]Introduction of microbial pathogens/parasitesBenchmark. Sensitivity can only be assessed relative to a known, named disease, likely to cause partial loss of a species population or community. Further details. EvidenceIntertidal gastropods often act a secondary hosts for trematode parasites of sea birds. Nucella lapillus may be infected by cercaria larvae of the trematode Parorchis acanthus. Infestation causes castration and continued growth (Feare, 1970b; Kinne, 1980; Crothers, 1985). Infected individuals may exhibit a deformed and enlarged shell, additional rows of teeth in the aperture, and an additional seventh whorl (Feare, 1970b). Feare (1970b) reported 15% infestation in one sample, in which the shells showed 3-4 rows of teeth. In one population, however, Feare (1970b) reported an infestation rate of 69%. Kinne (1980) notes that Nucella lapillus may also be infested with larvae of Lepocreadium sp., which cause reduced or non-functional gonads and a reduction in penis size in males. Castration of a proportion of the population may result in a reduction in recruitment and a reduced decline in population size eventually. Therefore an intolerance of intermediate has been recorded. Recoverability is dependant on recruitment from within the population. Gibbs et al. (1995) noted that a small number of individuals surviving the effects of an algal bloom (see nutrients) in north Cornwall, were able to re-establish the population within two years but noted that it would probably take many years for the population to regain its former abundance. Therefore, a recoverability of high is reported. | Intermediate | High | Low | High |
Introduction of non-native species [Show more]Introduction of non-native speciesSensitivity assessed against the likely effect of the introduction of alien or non-native species in Britain or Ireland. Further details. EvidenceThe introduced American oyster drill Urosalpinx cinerea may feed on barnacles when not feeding on oyster spat and hence may compete with Nucella lapillus for either food or space. However, no further information was found. | No information | Not relevant | No information | Not relevant |
Extraction of this species [Show more]Extraction of this speciesBenchmark. 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. EvidenceNucella lapillus is not subject to targeted extraction in the UK. However, whelks (including the dog whelk) were once collected for the production of Tyrian purple (see Baker, 1974 for review; Crothers, 1985). | Not relevant | Not relevant | Not relevant | Not relevant |
Extraction of other species [Show more]Extraction of other speciesBenchmark. 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. EvidenceMussels are subject to extraction (see Mytilus edulis) and are a major food species for dog whelks where they occur. However, dog whelks are able to switch to a more abundant prey, such as barnacles (albeit slowly) if necessary and are therefore, likely to suffer a brief interruption in feeding and possibly temporary reduction in reproductive capacity. Therefore, an intolerance of low has been recorded. | Low | Very high | Very Low | High |
Additional information
Recoverability. Nucella lapillus demonstrates low dispersal ability as adults and as juveniles (low vagility) (see reproduction and longevity). If a local population became extinct recovery would be dependant on recruitment from surrounding populations. Although passive dispersal by drifting has been observed in juveniles (Martel & Fu-Shiang Chia, 1995) it is probably an occasional event and would not contribute greatly to recruitment. On continuous stretches of coast recruitment could occur, albeit slowly, by crawling. However, in isolated bays recovery would take much longer. Gibbs et al. (1999) reported that the small numbers of dog whelks surviving a mass-kill in July -October 1995 were able to re-establish the population within two years. They also pointed out that in the worst affected parts of the area, the individuals were widely distributed so that breeding aggregations were not possible and suggested that it would take many years for dog whelks to regain their former abundance. However, on re-inspection six years after pre mass-kill in May 2001, the Bude population had recovered to its former abundance and areas of much higher mortality were well on their way to a full recovery (P. Gibbs pers. comm.).
In Watermouth Cove, north Devon, TBT pollution rendered Nucella lapillus extinct with the cove, whilst it remined common at the entrance (Crothers, 1998). Recolonization occurred after a maximum of 13 years (Crothers, in prep.).
Bryan (1968) examined the recolonization of Porthleven, south Cornwall after oiling and subsequent treatment with dispersants (BP1002) after the Torrey Canyon oil spill in March 1967. Although the population of Nucella lapillus was decimated in areas subject to dispersant treatment, the population recovered from 1-5 /m² in June 1967 to 100 /m² by November 1968 (ca 2 years). The majority of the initial recolonization was due to juveniles that had been feeding below low water at the time of the spill and suffered low levels of predation, since their predators were either killed or driven off by dispersant treatment. Fortunately the barnacle Chthamalus stellatus was particularly resistant to oil and dispersant so that recolonizing dog whelks had an adequate food source. However, Bryan (1968) noted that dog whelks were very slow to reappear in areas that received heavy dispersant treatment. Therefore it appears that populations of Nucella lapillus are capable of recovering with about 2-5 years if survivors are present either intertidally on below low water. However, should a population need to recruit from surrounding area recovery may take significantly longer.
Importance review
Policy/legislation
Designation | Support |
---|---|
OSPAR Annex V | Yes |
Status
National (GB) importance | Not rare or scarce | Global red list (IUCN) category | - |
Non-native
Parameter | Data |
---|---|
Native | - |
Origin | - |
Date Arrived | Not relevant |
Importance information
- Nucella lapillus is an important predator of mussels and barnacles on the rocky shore. The presence of dog whelks on the shore also mediates the effect of limpet grazing on fucoids and contributes to the cycle of barnacle - fucoid dominance. Nucella lapillus often shelters under fucoids, where their feeding on barnacles may undermine clumps of fucoids by killing the barnacles to which the holdfasts are attached. Similarly, reduced dog whelk abundance may result in increased barnacle density and hence reduced limpet grazing and allow fucoids to become established. No clear community effects resulting from the decline in dog whelks numbers due to TBT have been demonstrated (see Hartnoll & Hawkins, 1985 and Hawkins et al., 1994 for reviews).
- However, in southwest Britain, where Semibalanus balanoides is less common, Nucella lapillus has a noted effect on mussel abundance (Dr John Crothers, pers comm.). At Porlock Weir, Somerset, mussels only thrive where a fresh water stream runs across the beach (Wilson et al., 1985); elsewhere newly-settled mussel spat are targeted by dog whelks. There has been a noticeable increase in the abundance of mussels in Watermouth Cove, Devon following the demise of Nucella lapillus (Dr John Crothers, pers comm.).
- Nucella lapillus is preyed on by numerous sea birds and wildfowl, however, the dog whelk is not considered to be an important food source, except where alternative food sources are absent (Crothers, 1985).
- Whelks, including the dog whelk were once collected in Ireland for the production of the dye Tyrian purple (see Baker, 1974 for review).
- Nucella lapillus is listed in the UK Biodiversity Action Plan long list of species of conservation concern (Biodiversity Steering Group, 1995)
Bibliography
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Datasets
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Last Updated: 08/06/2007