• A change in a habitat causing a change in the make-up of a community.

Succession on Sand Dunes

• Pioneer plants like sea rocket (Cakilemaritima) and prickly sandwort (Salsola kali) colonise the sand just above the high water mark - tolerate salt water, lack of freshwater and unstable sand.
• Wind-blown sand builds up around the base of these plants, forming a 'mini' sand dune.
• As plants die and decay, nutrients accumulate in this mini sand dune.
• As the dune gets bigger, plants like sea sandwort (Honkenyapeploides) and sea couch grass (Agropyronjunceiforme) colonise it, which have long roots to stabilise it in the sand.
• With more stability and accumulation of more nutrients, plants like sea spurge (Euphorbaparalias) and marram grass (Ammophilaarenaria) start to grow.
• Marram grass traps sand, as the sand accumulates, the shoots grow taller to stay above the growing dune trapping more sand.
• As the sand dune and nutrients build up, other plants colonise the sand, such as hare's foot clover (Trifoliumarvense) and bird's foottrefoil (Lotuscorniculatus).
• These have bacteria in their root nodules to convert nitrogen into nitrates.
• With nitrates available, more species like sand fescue (Festucarubra) and viper'sbugloss (Echiumvulgare) colonise the dunes, stabilising the dunes further.

• Decomposers, such as bacteria and fungi, break down dead and waste organic material.

• Bacteria and fungi feed saprotrophically so are called saprophytes.

• They secrete enzymes onto dead and waste material.

• The enzymes digest the material into small molecules, which are then absorbed into the organisms body.

• Having been absorbed, the molecules are stored or respired to release energy.

• If bacteria and fungi did not break down dead organisms then energy and valuable nutrients would remain trapped in the dead organisms.

• Microbes get a supply of energy to stay alive, and the trapped nutrients are recycled.

When it comes to A2/A-level Biology, do you know how microorganisms recycle nitrogen within ecosystems?

• Nitrogen gas is very unreactive, so is impossible for plants to use it directly.
• Nitrogen is needed to make proteins and nucleic acids.
• Plants need fixed nitrogen as ammonium ions (NH₄⁺) or nitrate ions (NO3).
• Bacteria is involved in the recycling of nitrogen.

• Nitrogen fixation can occur when lightning strikes or through the Haber process - only 10% of total nitrogen fixation.
• Nitrogen-fixing bacteria live freely in the soil and fix nitrogen using it to make amino acids.
• Nitrogen-fixing bacteria, such as Rhizobium, also live inside the root nodules of legumes (bean plants).
• They have a mutualistic relationship with the plant, fixing nitrogen and receiving carbon compounds such as glucose in return.
• Proteins, such as leghaemoglobin, in the nodules absorb oxygen to keep the conditions anaerobic.
• Under these conditions, the bacteria use nitrogen reductase to reduce nitrogen gas to ammonium ions (NH₄⁺) that can then be used by the host plant.

• Nitrification happens when chemoautotrophic bacteria in the soil absorb ammonium ions.
• Ammonium ions (NH₄⁺) are released by bacteria involved in putrefaction of proteins found in dead or waste organic matter.
• Chemoautotrophic bacteria obtains energy by oxidising ammonium ions (NH₄⁺) to nitrites (NO₂^-) (Nitrosomonas bacteria), or by oxidising nitrites (NO₂^-) to nitrates (NO₃^-) (Nitrobacter bacteria). 
• As oxidation requires oxygen, these reactions only happen in well-aerated soils.
• Plants need nitrates to make amino acids, proteins, enzymes, DNA, RNA, etc.

• Other bacteria convert nitrates back to nitrogen gas.
• When the bacteria grows under anaerobic conditions, such as waterlogged soils, they use nitrates (NO₃^-) as a source of oxygen for their respiration and produce nitrogen gas (N₂) and nitrous oxide (N₂O).

That's the end of the topic!

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