Lab7 - Nitrogen Symbiotic Fixing by Rhizobium PDF

Summary

This document covers the nitrogen cycle and nitrogen fixation. It describes the role of microorganisms in this cycle and examines specific nitrogen-fixing bacteria, including Rhizobium. Diagrams and tables are included.

Full Transcript

Ecological and Environmental Microbiology Dr. Abeer Aloufi

Ecological and Environmental Microbiology

Env 231

Prepared By:

Dr. Abeer Salem Aloufi

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Ecological and Environmental Microbiology Dr. Abeer Aloufi

Seventh lab

A- Nitrogen symbiotic Fixing by Rhizobium

Nitrogen in the air
Nitrogen is required by all living organisms for the synthesis of proteins,
nucleic acids, and other nitrogen-containing compounds. The earth’s
atmosphere contains almost 80% nitrogen gas. It cannot be used in this
form by most living organisms until it has been fixed, that is reduced
(combined with hydrogen), to ammonia. Green plants, the main producers
of organic matter, use this supply of fixed nitrogen to make proteins that
enter and pass through the food chain. Microorganisms (the decomposers)
break down the proteins in excretions and dead organisms, releasing
ammonium ions. These two processes form part of the nitrogen cycle.

The nitrogen cycle
The nitrogen cycle is a series of processes that convert nitrogen gas to
organic substances and back to nitrogen in nature. It is a continuous cycle
that is maintained by the decomposers and nitrogen bacteria. The nitrogen
cycle can be broken down into four types of reaction and microorganisms
play roles in all of these as the table below shows.

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 Ecological and Environmental Microbiology Dr. Abeer Aloufi

Reaction Microorganism Condition Process
Nitrogen fixation Nitrogen-fixing aerobic/anaerobic The first step in the synthesis of virtually all nitrogenous
bacteria compounds.
e.g. Rhizobium Nitrogen gas is fixed into forms other organisms can use.
Ammonification Ammonifying aerobic/anaerobic The decomposers, certain soil bacteria and fungi, break
(decay) bacteria down proteins in dead organisms and animal wastes
(decomposers) releasing ammonium ions which can be converted to
other nitrogen compounds.
Nitrification Nitrifying Aerobic Nitrification is a two-step process. Ammonia or
bacteria ammonium ions are oxidized first to nitrites and then to
e.g. nitrates, which is the form most usable by plants.
Nitrosomonas &
Nitrobacter
Denitrification Denitrifying Anaerobic Nitrates are reduced to nitrogen gas, returning nitrogen to
the air and completing the cycle.
bacteria

Nitrogen fixation
Nitrogen can be fixed in three ways:
1. Atmospheric fixation: this occurs spontaneously due to lightning; a
small amount only is fixed this way.
2. Industrial fixation: the Haber process, which is very energy
inefficient, is used to make nitrogen fertilizers.
3. Biological fixation: nitrogen-fixing bacteria fix 60% of nitrogen gas.

Biological fixation:
The reduction of nitrogen gas to ammonia is energy intensive. It requires
16 molecules of ATP and a complex set of enzymes to break the nitrogen
bonds so that it can combine with hydrogen. Its reduction can be written
as:
energy
N2+3H2 2NH3
Fixed nitrogen is made available to plants by the death and lysis of free-
living nitrogen-fixing bacteria or from the symbiotic association of some
nitrogen-fixing bacteria with plants.

Examples of nitrogen-fixing bacteria are shown in the table below:

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Ecological and Environmental Microbiology Dr. Abeer Aloufi

Nitrogen-fixing bacteria
Free-living Symbiotic association with
plants
Aerobic Anaerobic Legumes Non-legumes
e.g., peas, beans e.g., alder tree
Azotobacter Clostridium Rhizobium Frankia

Rhizobium
Rhizobium is the most well-known species of a group of bacteria that acts
as the primary symbiotic fixer of nitrogen. These bacteria can infect the
roots of leguminous plants, leading to the formation of lumps or nodules
where the nitrogen fixation takes place. The bacterium’s enzyme system
supplies a constant source of reduced nitrogen to the host plant and the
plant furnishes nutrients and energy for the activities of the bacterium.
About 90% of legumes can become nodulated.

In the soil the bacteria are free-living and motile, feeding on the remains of
dead organisms. Free-living Rhizobia cannot fix nitrogen and they have a
different shape from the bacteria found in root nodules. They are regular in
structure, appearing as straight rods; in root nodules, the nitrogen-fixing
form exists as irregular cells called Bacteroides which are often club and
Y-shaped.

Rhizobium is bacilli bacteria, non-spore-forming, motile, and aerobic.
1- Rhizobium is free living in the soil.
2- Penetration of Rhizobia into deformed root hair.
3- Secretion of different things e.g., Flavonoids.
4- The bacteria show different shapes like T-Y-L-X-V, this phase is
called Bacteroid.

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Ecological and Environmental Microbiology Dr. Abeer Aloufi

Name of experiment:
Nitrogen symbiotic Fixing by Rhizobium.

Aim of experiment:
Determine and identify the nitrogen symbiotic fixing bacteria by using a
microscope.

Material:
Root nodule containing bacteria.
sterile distilled water.
Petri dish.
Sterile tongs.
Flam.
Dettol.
Cotton.

Method:
1- Open the flam, with cotton and Dettol clean up the work area (the
bench).
2- Separate the root nodule from the root.
3- Wash the nodule with water-containing drops of antiseptic to avoid
contamination.
4- Put the nodule in a flask containing 95% of Ethanol for 30-60
seconds.
5- Move the nodule by sterile tongs to a tube containing sterile distilled
water.

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Ecological and Environmental Microbiology Dr. Abeer Aloufi

6- Mash the nodule in a Petri dish then prepare a bacterial smear after
that stain the bacteria by using Gram stain and examine of bacteria
under the microscope.

Result and conclusion:

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