1. THE NITROGEN CYCLE

2. By the end of this lesson I will:
(k) describe the role of decomposers in the decomposition of organic material;
(l) describe how microorganisms recycle nitrogen within ecosystems. (Only Nitrosomonas, Nitrobacter and Rhizobium need to be identified by name).

3. Nitrates are essential for plant growth
Plant protein
Root uptake
Nitrate NO3-

4. Nitrates are recycled via microbes
Root uptake
Nitrate NO3-
Plant protein
Animal protein
Soil organic nitrogen
Ammonification
Ammonium NH4+
Nitrification
Nitrite NO2-
Nitrification

5. Amino acids + 11/2O2  CO2 + H2O + NH3 + 736kJ
Ammonification
Nitrogen enters the soil through the decomposition of protein in dead organic matter
Amino acids + 11/2O2  CO2 + H2O + NH kJ
This process liberates a lot of energy which can be used by the saprotrophic microbes

6. Nitrification This involves two oxidation processes
The ammonia produced by ammonification is an energy rich substrate for Nitrosomas bacteria
They oxidise it to nitrite:
NH3 + 11/2O2  NO2- + H2O kJ
This in turn provides a substrate for Nitrobacter bacteria oxidise the nitrite to nitrate:
NO3- + 1/2O2  NO kJ
This energy is the only source of energy for these prokaryotes
They are chemoautotrophs

7. Nitrogen from the atmosphere
Out gassing
Atmospheric fixation
Atmospheric Nitrogen
4 000 000 000 Gt
Root uptake
Nitrate NO3-
Plant protein
Soil organic nitrogen
Biological fixation

8. Atmospheric nitrogen fixation
Electrical storms
Lightning provides sufficient energy to split the nitrogen atoms of nitrogen gas,
Forming oxides of nitrogen NOx and NO2

9. Atmospheric Pollution
This also happens inside the internal combustion engines of cars
The exhaust emissions of cars contribute a lot to atmospheric pollution in the form of NOx
These compounds form photochemical smogs
They are green house gases
They dissolve in rain to contribute to acid rain in the form of nitric acid
The rain falling on soil and running into rivers
They contribute to the eutrophication of water bodies
© 2008 Paul Billiet ODWS

10. Biological nitrogen fixation
Treatments
Yield / g
Oats
Peas
No nitrate & sterile soil
0.6
0.8
Nitrate added & sterile soil
12.0
12.9
No nitrate & non-sterile soil
0.7
16.4
Nitrate added & non-sterile soil
11.6
15.3

11. Conclusion
Adding nitrate fertiliser clearly helps the growth of both plants
The presence of microbes permits the peas to grow much better than the oats
The peas grow better in the presence of the microbes than they do with nitrate fertiliser added
The difference is due to the present of mutualistic nitrogen fixing bacteria which live in the pea roots.

12. Root nodules Alafalfa (Medicago sativa) USDA - ARS
University of Sydney

13. Only prokaryotes show nitrogen fixation
These organisms possess the nif gene complex which make the proteins, such as nitrogenase enzyme, used in nitrogen fixation
Nitrogenase is a metalloprotein, protein subunits being combined with an iron, sulphur and molybdenum complex
The reaction involves splitting nitrogen gas molecules and adding hydrogen to make ammonia
N2  2N kJ
2N + 8H+  NH3 + H kJ
This is extremely energy expensive requiring 16 ATP molecules for each nitrogen molecule fixed
The microbes that can fix nitrogen need a good supply of energy

14. The nitrogen fixers
Cyanobacteria are nitrogen fixers that also fix carbon (these are photosynthetic)
Rhizobium bacteria are mutualistic with certain plant species e.g. Legumes
They grow in root nodules
Azotobacter are bacteria associated with the rooting zone (the rhizosphere) of plants in grasslands

15. The human impact Atmospheric Nitrogen Industrial fixation
Nitrate NO3-
Atmospheric fixation
Out gassing
Plant protein
Atmospheric Nitrogen
Ammonium NH4+
Soil organic nitrogen
Industrial fixation
Biological fixation

16. Industrial N-Fixation
The Haber-Bosch Process
N2 + 3H2  2NH3 - 92kJ
The Haber process uses an iron catalyst
High temperatures (500°C)
High pressures (250 atmospheres)
The energy require comes from burning fossil fuels (coal, gas or oil)
Hydrogen is produced from natural gas (methane) or other hydrocarbon

17. The different sources of fixed nitrogen
Production / M tonnes a-1
Biological
175
Industrial 50
Internal Combustion 20
Atmospheric 10

18. Eutrophication Nutrient enrichment of water bodies
Nitrates and ammonia are very soluble in water
They are easily washed (leached) from free draining soils
These soils tend to be deficient in nitrogen
When fertiliser is added to these soils it too will be washed out into water bodies
There algae benefit from the extra nitrogen
This leads to a serious form of water pollution

19. Fertilisers washed into river or lake Sewage or other organic waste
Eutrophication
Fertilisers washed into river or lake
ALGAL BLOOM
Rapid growth of algae
Dead leaves
New limiting factor imposes itself
Sewage or other organic waste
Death of algae
Decomposers (bacteria) increase in numbers

20. Making things worse! Pollution from oil or detergents
Decomposers (bacteria) increase in numbers
Pollution from oil or detergents
Hot water from industry
(Thermal pollution)
Increased Biochemical Oxygen Demand (BOD)
Reduction in dissolved O2

21. The death of a lake Death/emigration of freshwater fauna
Reduction in dissolved O2
ANAEROBIC CONDITIONS
Increased nitrite levels
NO3-  NO2-
Death/emigration of freshwater fauna
Methaemoglobinaemia in infants
Stomach cancer link
(WHO limit for nitrates 10mg dm-3)

22. The future of industrial nitrogen fixation
Food production relies heavily upon synthetic fertilisers made by consuming a lot of fossil energy
Food will become more expensive to produce
Nitrogen fixing microbes, using an enzyme system, do the same process at standard temperatures and pressures essentially using solar energy
Answer: Genetically engineered biological nitrogen fixation?

23. Making things better
The need for synthetic fertilisers can be reduced by cultural practices
Avoiding the use of soluble fertilisers in sandy (free draining soil) prevents leaching
Rotating crops permits the soil to recover from nitrogen hungry crops (e.g. wheat)
Adding a nitrogen fixing crop into the rotation cycle
Ploughing aerates the soil and reduces denitrification
Draining water logged soil also helps reduce denitrification

24. Return to the atmosphere: Denitrification
Nitrates and nitrites can be used a source of oxygen for Pseudomonas bacteria
Favourable conditions: Cold waterlogged (anaerobic) soils
2NO3-  3O2 + N2providing up to 2385kJ
2NO2-  2O2 + N2 
The liberated oxygen is used as an electron acceptor in the processes that oxidise organic molecules, such as glucose
These microbes are, therefore, heterotrophs

25. Soil organic nitrogen 9500 Gt
Sediments 10 Gt
Nitrification
Root uptake
Biological fixation
Ammonium NH4+
Ammonification
Nitrite NO2-
Dissolved in water
6000 Gt
Denitrification
Leaching
Nitrate NO3-
Soil organic nitrogen 9500 Gt
Atmospheric fixation
Out gassing
Industrial fixation
Plant protein
3500 Gt
Animal protein
Atmospheric Nitrogen
4 000 000 000 Gt