rocky shores extension of the marine environment - interface dynamic environments densely populated and high diversity range of problems
tides -caused by gravitational attraction - variation in tidal hieghts - spring and neap - semidirunal tides in the uk - emersion/immersion patterns cause problems for organisms
coping
behavioural -shelter in crieves, burrows and under boulders - clamps to rocks - close into shells - huddle together - stay in pools
physiological produce mucus tolerant to desiccation
Morpological- size -shape
wave exposure wave exposure exerts more influence then anywhere else - destructive mechanical effect - disturbs sediment , circulates water and renews oxygen - extends limits of the intertidal zone - structural damage, moves aniamals
coping - fix to substarte -thick shell - live in crevices or under rocks - live sheltered zone - adaptive morphology
Vertical distribution - not random biota are found in distinct zones at particular hieghts = zonantion they are the same around the world in places with similair conditions
zones high shore - littoral zone - small snails, lichens and blue-green algaemid-shore - eulittoral zone - barnacles, limphetrs, mussels and fucoid algae - low shore - sublittoral zone red green algae and kelps
causes - Originally assumed related to emersion tolerance - but organisms adapt to number of factors both physical and biological
Biological
physical
desiccation - influenced by tolerance ability - can set upper limits of organisms especially in high shore
Temperature- sublethal effects on the intertidal organisms - may die from either cooking or freezing ie pelvetia and fucus spiralis
light - direct exposure to UV waves - unknown if this contols distribution
algae - could be a regulator - different algae absorb different wave lengths - diff pigments green - red brown - yellow/ green red - green no experimental evidence that it does this
competition - main one is space
predation - not only prey but also other
grazing herbivore grazing excludes algae
behaviour movement in relation to tides
larval settlement affected by substrate
limitations - patterns not always clear - overlapping zones - more then one factor for each zone for each species- visual patterns only picks up main species - can be used to predict genral but not specific patterns
tidal height- most are marine in origin - species on upper shore adapted to survive long periods out of the water - lower shore are fully marine almost - correlation between hieght and tolerance - changes for motile and no-motile
effects on the upper limits of non-motile- upper contorlled by abiotic factors - occasional extremes of temperature - effects of temperature may be subtle - juveniles more vulnerable than adults - biotic factors may also be important in setting upper limits of distribution
lower limits most likely controlled by biotic factors - competition between flucoid algae grazing by patella vulgatadrier upper zones inhabitedby more tolerant organisms - can grow anywhere on the shore in optimum conditions most intertidal species will grow offshore - often larger in these favourable conditions
effectscommunities comprising zones vary from shore to shore = effects zonantion patterns- sheltered shores covered in dense turf of macroalgae - exposed shores fewer plants and more barnacles - biological exposure scales have been developed
sheltered shores - zonation may not be as immediately visible - dense macroalgae - no obvious splash zone - animals abundant under cover - littorina littorea - barnacles are patchy - patella vulgata limited to a few large individuals - Ascophyllum nodosim present
semi-exposed shore - algae patchy no ascophyllum - fucus in the form with no air bladders barnacles and nucella lapillus widespread - patella widespread- kelps abundant in sublittoral zone digitata- obvious black littoral fringe due to verrucaria maura
very exposed - few brown algae saccharina in sublittoral - fucus absent and replaced by red algae - mostly covered with vulgata, barnacles and nucella lapillus- vesiculosus stunted and in patches
extreme exposure - alaria esculenta upto midhsore - crustose coralline algae an open rock to midshore and even upper shore hieghts - vulgata stunted in size and rare ulyssiponensiscommon on open rocks at all heights - lapillus extremely thin shell
physical battering on morphology and size attaching species it means risk of destruction increase with size smaller on exposed shores weak clinigin power means easily dislodged = affects distribution - more sheltered shores nucella lapillus - investment in too greater cling of foot = less into anti predator of shell = thinner shell walls
salinity open shores - fairly constant - very local change- greatest changes in tide pools and estuaries - dominated by ulva species which have a high tolerance of salinity chnages
estuaries - richness decrease as you increase the distant - due to dcreasing or varianle salinity - suspended silt blocking feedind mechanisms or biotic factors - changes in salinity affect sizes and distribution ie spiralis and vesiculoseus replaced by ceranoides
effects of temperature
low temperature- harsh freezing = frozen cell contents-mollusc are tolerant - as low as -20 -sudden are more deadly then general - freezing of extracellular fluids occurs first and has desiccating effects - intracellure freezing and ice formation damages cell walls
high temperatures - high shore especially when uncovered for days - structures that seal them off - gastropod operculum - vulgata - mucus seal gap of shell and subsratum increased problems with desiccation
plants similiar to animals - can survive at low temps -phtotsythetic recovery depends on temperature and time at certain temperatures - also high shore species are better at withstanding low temperatures
grazing - pp - red, green, brown algae - can be substantial but microalgae = main food - diatoms and blue-green algae and macroalgae food for herbivores - size increase = less eaten = enter food chain as ditritus
algal-grazer relationship this is a complex relationship which depends on three main factors which are physical such as wave action, species specific consumers and predator influence.
effects of predatiom important structuring communities few but specilised predators so prey is either sessile or motile ,aim = gastropod molluscs - whelk nucella lapillus shore crab moves with tide to crieves and pools fish (gobbies) invade at high tide - birds are low tide predators
predators affect vertical distribution depends upon physical = wave action direct effects on density amd distribution effects on density and distribution of prey indirect effect on the balance of competition on the shore
recruitment- meroplankton dependent on phytoplankton = relationship with dpring bloom may be crucial for animal larvae losses = huge only few reach maturnity unclear in many cases whether larvea settle passively or not depends on the weather
competition inter,intra and aggression important in structuring communties in moderately harsh conditions levels of competition can be affected by recruitment
high = competition/predation become important in structuring low = competion and predation become unimportant