Oct. 6 - Nitrogen in Lakes

advertisement
BIO321 Aquatic Biology
Nitrogen in Lake Ecosystems
Horne & Goldman Chapter 8 - Know and understand all figures
I. Why is Nitrogen important in aquatic ecosystems?
A. Life requires Nitrogen as it is the 4th most abundant material in living cells, making up 5%
of living organisms by weight (C>H>O>N).
B. How is N used?
1. DNA, RNA, proteins, Hemoglobin, Chlorophyll
2. Breakdown products of metabolism
NH4, Uric acid, Urea - WHY is N the main waste form?
II. The nitrogen equation is really a complex cycle that is global in nature.
A. Review the Nitrogen Cycle (see Horne & Goldman)
B. Aquatic components of the cycle are similar to and connect into the larger terrestrial cycle.
C. Major Components
N2 or N=N is an intert component that makes up 80% of the atmosphere
NH4+-N (ammonium) is a reduced form readily used by plants in aquatic systems
NO3--N (nitrate)is an oxidized form also readily used by plants in aquatic systems
NO2--N (nitrite) is a minor intermediate form that is "toxic"
NH2-N is the most common biological form
III. How do these forms get into aquatic systems and what roles do they play?
A. N2 profiles are largely determined by physical factors:
1. is less soluble than O2
2. higher partial pressure
3. 1 & 2 result in the same concentration of dissolved N2 in water as O2
4. Temperature is the main factor determining the distribution of N2 in water, since
outside of formation processes (denitrification) and breakdown processes (fixation) N2
is biologically inert.
Summer depth profiles
oligotrophic
ml N2/l
eutrophic
ml N2/l
depth
depth
B. Breakdown processes = Nitrogen fixation
1. The equation: N2
NH4+
nitrogenase (with Mb& Fe factions)
dichotomy
2. Energy is required to break the triple bond
a. High energy via lightening, volcanoes, oil power
b. Biological energy under special low O2 conditions
blue green algae in the epilimnion
bacteria and attached blue green algae in the sediments
photosynthesis which requires O2 provides the energy and ironically fixation can
only happen in the absence of O2, which reduces the high energy cost of breaking
the triple bond. - a contradiction?
3. Nitrogenase only functions in a reducing atmosphere (anoxic conditions)
Such conditions are found under only special conditions or in special places
a.
b.
4.
In the sediments O2 is often low enough for bacteria and attached bluegreen
algae to fix N2
Bluegreen algae
i. Heterocyst formation provides a low O2 environment in the epilimnion
while still allowing access to O2
If the C:N ration is > 8:1 N may be limiting and heterocyst formation is
induced [conversely a negative feedback system exists in that high
concentrations of NO3- or NH4+ inhibit nitrogenase synthesis bringing
about a reduction in heterocysts in the population. Nutrition and
nitrogenase flow through the polar canals from the smaller vegetative
cells. The heterocyst is yellow because it
lacks the O2 producing Photosynthesis II)
ii. Non-heterocyst forming BGA's can also fix N2 if
they lower the O2 concentration via other methods like a
mucilagenous matrix around a colonial or individual form. The mucus
contains sulfhydryl compounds that absorb free O2
iii. Benthic BGA or BGA in an anoxic hypolimnion
iv. summer blooms of Anabaena, Aphanizomenon, Nostoc, Microcystis,
Oscillatoria when N is low.
Nitrogen fixation is important in lakes.
a. In Eutrophic lakes fixation is a major process as first NH4+ then NO3- are
used and BGA's begin to bloom as they can fix N2. In Clear Lake CA
overy 1/2 of the annual N budget is provided by Fixation
b. In Oligotrophic fixation is minor as there are very few users of N. N is
also very rarely the limiting factor for life in these lakes.
C. Biological sources of other nitrogen forms
1. NH4 comes as a major waste product from most aquatic physiologies. This
form is rapidly used (NH4  NH2) by algae and plants
a. oligotrophic lakes 0 - 5 mg/l
b. eutrophic lakes 5 - 10 & >mg/l
2. Ammonification is the breakdown of dead organic nitrogen(NH 2) by
heterotrophic bacteria to form NH4+
3. Nitrificaton is a two step process where NH4+ is broken down to NO3-
NH4+
-NH2
Heterotrophic bacteria
Bionitrogen
ammonium
4.
NO2Nitrosomonas
Nitrobacter
nitrite
Nitrate reductase
nitrate
Plants then reconvert the NO3- to the form they use via the enzyme nitrate
reductase
NO2-
NO3-
NO3- + energy
NH4+
nitrate reductase
Note: Since this process requires costly enzymes, plants prefer to
use NH4+ when it is available
5. Since redox factors apply to these equations, NH4+ is the most available
form of N in low O2 environments, while in high O2 environments,
NO3- predominates
D. Seasonal patterns and depth profiles of nitrogen forms
See Horn and Goldman Figures 8-2, 8-3, 8-4, & 8-5.
Heterocycst in
Anabaena
Download