Agricultural Microbiology PDF Lecture Notes

Summary

These lecture notes cover agricultural microbiology, specifically focusing on soil microbiology and ecosystem organization. The document details different types of microorganisms, their role in soil, and the interaction of these microorganisms with each other and the environment.

Full Transcript

11/23/2021

Agricultural Microbiology

Lec. 1
Prof. Dr. Mona S. Zayed

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Agricultural Microbiology
Agricultural microbiology is a branch of science that studies different types of microorganisms that are
associated with plants, soil, and even animal (either with positive or negative effect)

Soil Microbiology

the soil microbiology concern about the study of microorganisms and their processes in soil.

In fact, soil is an active habitat for enormous variety of life-forms including microorganisms.

The interaction of enormous microorganisms with each other and also with their environments is covered
under the branch of soil microbiology.

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Organization of Ecosystems

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Organization of Ecosystems
1- Biosphere
The first level of the ecological pyramid, which is made up of the Earth's surface and
atmosphere.
It is also known as the zone of life on Earth, (all lifeforms found on the planet coexist on it).

Simply:
It is the thick envelope of life that surrounds the earth’s surface
it is the sum of all the ecosystems of this planet.

made up of:
hydrosphere (water)
lithosphere (soil)
atmosphere (air)

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2- Biomes
Climatic regions

Biome: is a large region of Earth which is typically characterized by having a certain climate
conditions and certain types of dominant living things.

Each biome has many ecosystems

Some of the most noticeable biomes of the world include

The desert biome,

Rainforest biome,

Savannah biome

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Ecosystem

Ecosystem: it is referring to of the biotic and abiotic factors in an area.

The environment that containing all the living organisms (biotic
factors such as : plants, animals and microbes) and non-living things
(abiotic factors such as: air, soil, and water) are linked together in a
particular region and the interaction between them.

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Communities
Community: is all of the different species that live together in the
same geographical area and interact with each other.

A community is composed of all of the biotic factors of an area.

This interaction between the members of these communities often
revolves around different concepts such as predator-prey and
symbiotic relationships.

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Population

Population: is a group of organisms belonging to the same species
living together in the same geographical area and interact with one
another

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Species
Is the lowest level of ecological organization

Is a group of individuals that are genetically related and can interbreed
to produce fertile young.

If the individuals cannot interbreed to produce a progeny (so they are
not members of the same species)

Every single species, (from microscopic bacteria, fungi, plant and
animal species to huge blue whale), finds a place at this level of the
ecological pyramid.

The distribution of these species is governed by abiotic factors of the
region.

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Niche
Niche is defined in a general as a cavity, hollow,

However, in biologically and ecologically, a niche refer to the following:
(1) the specific area where an organism inhabits
(2) the role or function of an organism or species in an ecosystem
(3) the interrelationship of a species with all the biotic and abiotic factors affecting it.

Therefore the ecological niche refers to the interrelationship of a species with all the biotic and abiotic factors affecting it.

Small ecosystem

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Habitat
the physical location in the environment to which an organism has adapted

Niche
overall role that regulator species, or population, serves in a community;
nutritional intake, position in the community, and rate of population growth

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Biosphere
made up of:
Lithosphere (soil)
Atmosphere (air)
Hydrosphere (water)

Lithosphere: solid, rocky crust that covers the surface of the earth
including the bottom of the oceans

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The Soil Environment

 Soil is a structured environment that “holds” a wealth of organisms with diverse activities and functions.

 microorganisms have a central place, as they play major roles in key soil processes.

 The inorganic particles of soil are classified into three major groups according to their size: sand, silt, and clay.
The proportions of these particles in any soil determine the soil texture.

 soil aggregates are habitats that allow the survival of one or more species of soil microorganisms.

 The niches of soil are mainly the soil pore walls.

 Soil water passes more rapidly through wider pores by means of gravity mass flow and diffusion than through
narrow pores.

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Schematic of a section through a 2 mm-diameter soil aggregate microsite yielding habitats for
bacteria based on physiological requirements.

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Soil Biology and Microbiology

*Mineral Particles
*Air

Soil consists of: *Water
*Soil Organic Matter
*Plant Roots
*Living Soil Organisms.

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 The microbial habitat in soil
The soil pores is a porous medium that varies both spatially and temporally.
The structural form of this porous medium is the product of many different processes. (Biological,
physicochemical, and mechanical processes) as they act together to aggregate, compact, crack, and fragment the
soil, resulting in a soil structure consisting of solids and pores.

The soil habitat generally constitutes an aerobic, oligotrophic (nutrient-poor) environment, which is not
conducive to high population densities and activities of microorganisms.

In contrast, the rhizosphere provides an environment in which elevated population sizes and activities of fast-
growing microorganisms that supported by plant- derived carbon substrates, in the form of exudates and cell
lysates.

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Schematic illustration of the soil environment around plant roots in terms of diffusion of materials (substrate
carbon and nutrients) and information (signal molecules).

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Factors affect Soil life (microorganisms) and Physicochemical Environment)

1) Water, The Essential Factor For Soil Life

 “Understanding the movement of water in soil is understanding the most significant feature of the soil as a habitat for
microbial life”.

Where water moves, so do ions and nutrients.
 Water carries dissolved gases and heat, and also bacteria and their predators.

 It protects microhabitats from desiccation and opens other potential habitats while closing others.

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The range of water-influenced soil properties and processes which determine the microbial activity.
Eh: redox potential.

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Moisture Controlling Growth

Moisture – Water Activity
Water Activity (Aw) is the measure of “free” water available to the
microorganism for growth

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The importance of soil water activity to microorganisms
Water activity (Aw) is the best determinant of the water requirements of microorganisms.
It is the availability of water for reaction in a substrate.
The relationship between moisture content and Aw is unique to each soil due to its physical and chemical
nature and its organic matter content.
This can lead to change soil bacterial communities,
Aw can also determine how microbial growth and activity are affected by moisture in soil.

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Water Activity
Aw is affected by the presence of solutes (sugars
and salts) Salt or Sugar

Lowering aw will reduce the ability for
microorganisms to grow

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If a soil's Aw is too low for microbial activity to occur, then even the most biodiverse microbial community
with significant biomass will be unable to undertake any ecosystem processes.
What is the relationship of a soil’s moisture content to its water activity?

The relationship between moisture content and Aw is unique to each soil due to its physical and chemical
nature and its organic matter content.

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2) Soil as an energy and nutrient Source
soil microorganisms are classified according to how they use their sources of energy and carbon.

Light as a source of energy only present at the surface of the soil.

The chemical energy for chemoautotrophs is supplied in the form of reduced inorganic chemicals

Organic matter provides the energy source for the heterotrophic microbial community of the soil.

This organic matter ranges from the readily decomposable and more resistant fractions of plant litter

In addition to soil organic matter, the organic carbon that is directly released from plant roots represents a key
energy source.

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Metabolic Classification of Microorganisms
E nergy S ource C lassification C arb on S ou rce

P hotoautotrophs
“Autotrophs”

Light
(P hototrophs) Ph oto heterotroph s
P S I: anaerobic, H 2 S
PS I+II: aerobic, H 2O CO2
(A utotrophs)

C hem olithoautotrop hs
Inorganic
(C hem olithotrophs)
A erobic (m ajority) C hem olithoheterotro ph s
A naerobic (few ) (or M ixotrophs)
C hem ical O rgan ic
(C hem otrophs) (H eterotrophs)
“Heterotrophs”
O rganic C hem oorg anoheterotrph s
(C hem oorgan otrophs)
Ae robic respiration
A na erobic respiration
Ferm entation C hem oorganoautotrophs

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Carbon Source
Autotroph
CO2 = principle carbon source

Heterotroph
Utilize more reduced and complex carbon sources derived from other organisms organic
carbon (“nourished by others”)
Use organic compounds as a source of carbon

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Energy Source
Phototroph
Light energy harvested by photosynthetic processes

Chemotroph
Organic or inorganic compounds provide energy by oxidative processes

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“Chemotroph”

Lithotrophs
Use reduced inorganic compounds as electron source

Organotrophs
Use organic compounds as H and electron donors

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Metabolic Classification of Microorganisms
En ergy S ou rce C lassification C arbo n S ou rce

P h otoautotro phs
“Autotrophs”

Lig ht
(P hototrophs) P h oto heterotroph s
P S I: anaerobic, H 2 S
P S I+II: aerobic, H 2 O CO2
(A utotrophs)

C hem olithoautotro ph s
In org anic
(C hem olithotrophs)
A erobic (m ajority) C h em o lithoheterotroph s
A naerobic (few ) (or M ixotrophs)
C hem ical O rg anic
(C hem otrophs) (H eterotrop hs)

O rgan ic “Heterotrophs”
C h em oorgano heterotrp hs
(C hem oorgan otrophs)
A erobic respiration
A naerobic respiration
Ferm entation C hem oorgan oautotrophs

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Energy and Nutritional Flow in Ecosystems

Organisms derive nutrients and energy from their habitat.

Food chain or energy pyramid summarizes the feeding levels:

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Insert figure 26.3
Trophic and energy pyramid

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Producers (called autotrophs)

Provide fundamental energy source that initiate the trophic pyramid

The only organisms in an ecosystem that can produce organic carbon compounds such as
carbohydrates by assimilating simple inorganic sources (CO2 and water) from the
atmosphere

An organism that uses light energy or other forms of energy to make energy-rich
compounds (or their own food) is a producer

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Consumers

They cannot build up carbohydrates from simple inorganic sources. They depend on ready
made organic materials.
Feed on other living organisms and obtain energy from chemical bonds present in the organic
substrates they contain.
They break it down enzymatically into simpler compounds which can be absorbed
Consumers cannot use the sun’s energy directly like producers. They depend on autotrophs
for nutrients and energy.

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Consumers
Consumers must consume or eat producers or other consumers

Pyramid usually has several levels of consumers
Primary consumers: consume producers
Secondary consumers: feed on primary consumers
Tertiary consumers: feed on secondary consumers
Quaternary consumers: feed on tertiary consumers

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Types of consumers

a. Herbivores- obtain energy by eating only plants
b. Carnivores- eat animals (snakes, dogs, owls, etc.)
c. Omnivores- eat both plants and animals (e.g. humans)

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Decomposers
Decomposers break down and absorb the organic matter of dead and
decaying organisms (plants and animals) into simpler molecules that
can be more easily used by other organisms.
they recycle materials (organic matter ) into inorganic minerals and gases,
mineralize nutrients

Decomposers- breaks down organic matter (bacteria and fungi)

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Carbon source categories

Autotrophs
(Producers)

Carbon dioxide Organic carbon

Heterotrophs
(Consumers & Decomposers)

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Autotroph Heterotroph

Producer Producer Consumer Decomposer

Phototrophic Chemolithotrophic Organotrophic Organotrophic

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3) Soil temperature
Temperature in soil is a key determinant of both the distribution and the activity of soil
microorganisms.
As temperature directly affects microbial physiology, and it indirectly affects through
changes in factors such as nutrient and substrate diffusion and water activity.
Soil temperature is the product of solar energy, modified by a series of factors.
soil temperature is affected by seasonal factors, as well as “edaphic” factors such as soil
type/depth and the nature of the vegetation present.

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Soil temperature
Temperature is a strong selective force and is a key driver of physical, chemical, and
physiological reactions.
So,…. soil microbial communities can be defined on the basis of temperature values

the classification of soil microorganisms on the basis of temperature preference

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Temperature is Controlling Growth

T =Temperature
Optimal Growth
Thermophiles – like hot conditions

Mesophiles – like warm conditions (around body temperature)

Psychrotrophs – can grow at refrigeration temperatures

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Temperature Classifications
*Based on optimum temperature for growth;
*Psychro=cold
*Meso = middle
*Thermo= warm
*Trophic =growing
*Duric=withstand
*Phil or philic-prefers or loves

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Categories of Microbes Based on Temperature Range

Image: Pearson Education Inc. (2004) publishing
as Benjamin Cummings

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Classification of bacteria based on optimum temperature of growth

1) Psychrophiles:

 Bacteria that can grow at 0°C or below but the optimum temperature of growth is 15 °C or below and
maximum temperature is 20°C are called psychrophiles

 Psychrophiles have polyunsaturated fattyacids in their cell membrane which gives fluid nature to the cell
membrane even at lower temperature.

2) Psychrotrops (facultative psychrophiles):

 Those bacteria that can grow even at 0°C but optimum temperature for growth is (20-30)°C

3) Mesophiles:

 Those bacteria that can grow best between (25-40)C but optimum temperature for growth is 37C

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Classification of bacteria based on optimum temperature of growth

4) Thermophiles:

 Those bacteria that can best grow above 45C..

 True thermophiles are called as Stenothermophiles, they are obligate thermophiles,

 Thermophils contains saturated fatty acids in their cell membrane, so their cell membrane does not become
too fluid even at higher temperature.

 Thermophiles capable of growing in mesophilic range
6) HypethermophilesThose bacteria that have optimum temperature of growth above 80C.
 Mostly Archeobacteria are hyperthermophiles.

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4) solar energy (light)
solar energy is responsible of energy in the soil–plant system.
As solar energy affects soil temperature, which in turn influences soil microbial activity.
Solar light also directly affects the microbial distribution and activity at or near the soil surface (where light
can penetrate), providing energy and driving photoautotrophic soil microorganisms such as algae and
cyanobacteria.
Under the conditions of high photoautotrophic activity, however, considerable amounts of polysaccharides
can be produced in the soil, which play important roles in soil aggregate start and stabilization, thus
enhancing the stability of the soil.
The most important effect of light, from a soil microbiological point of view, is that it stimulates plant seed
germination, seedling establishment, and growth and is necessary for some algae and cyanobacteria to grow
on soil surface and other surfaces.

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5) Soil atmosphere

The typical concentrations of the major soil gases in the air and soil atmosphere are indicated in Table 2.

soil microbial activity, and the characteristics of the soil atmosphere are strongly related to the soil water regime.

Typical Composition of the Soil Atmosphere Compared to the Open Atmosphere

N2 O2 CO2

Typical concentration in air (%) 79 21 0.035

Typical concentration in soil atmosphere (%) 79 20–21 0.1–1.0

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O = Oxygen
Based on oxygen requirements;
 Aerobic-Need oxygen to grow
 Anaerobic-Can grow only if oxygen is absent
 Facultative-Can grow with or without oxygen

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Oxygen Controlling Growth

Tolerance to oxygen in the surrounding environment

Facultative
Anaerobic Aerobic Anaerobes

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Classification of bacteria on the basis of gaseous requirement
1. Obligate aerobes:

a) Those bacteria require oxygen and cannot grow in the absence of O2.
b) Examples; Bacillus sp.
2. Facultative anaerobes:

a) Those bacteria that do not require O2 but can use it if available.
b) Growth of these bacteria become better in presence of O2
c) Examples: E. coli, Klebsiella sp., Salmonella sp.
3. Aerotolerant anaerobes;

a) Those bacteria do not require O2 for growth but can tolerate the presence of O2.
b) Growth of these bacteria is not affected by the presence of O2.
c) Example: lactobacillus sp.

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Classification of bacteria on the basis of gaseous requirement

4. Microaerophiles:

a) Those bacteria that grow on low concentration of Oxygen but at atmospheric level of Oxygen growth of
these bacteria is inhibited.

b) These bacteria only have oxidative type of metabolism

c) Example: Campylobacter
5. Obligate anaerobes:

a) Those bacteria that can grow only in absence of Oxygen.

b) Oxygen is harmful to obligate anaerobes

c) Examples: Peptococcus, Peptostreptococcus, methanococcus

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6) Soil pH
Soil pH is a major determinant of soil microbial distribution and activity.
The pH of a soil, or of a microsite (microbial habitat) in the soil, is the product of numerous
factors and processes.
1) First, it is determined by the parent material from which the soil is formed (acid soils
tending to form from rocks such as granite and alkaline soils from chalks and limestones),
2) the degree to which mineral weathering has occurred since soil formation.
3) Types of biological processes that can modify the soil pH to varying degrees.

acidophiles, preferring low pH conditions;
alkaliphiles, preferring high pH conditions

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Classification of bacteria on the basis of optimum pH of growth
1. Acidophiles:
a) Those bacteria that grow best at acidic pH
b) The cytoplasm of these bacteria are acidic in nature.

c) Some acidopiles are thermophilic in nature, such bacteria are called Thermoacidophiles.

d) Examples: Thiobacillus thioxidans, Thiobacillus, ferroxidans, Thermoplasma, Sulfolobus

2. Alkaliphiles:
 Those bacteria that grow best at alkaline pH
 Example: vibrio cholerae: optimum pH of growth is 8.2

3. Neutriphiles:
 Those bacteria that grow best at neutral pH (6.5-7.5)
 Most of the bacteria grow at neutral pH
 Example: E. coli

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The distribution and activity of soil microbes as a result of pH
Many soil microorganisms can tolerate particular pH conditions that are far from their optimum.
For example,
 many of the fungi found in acid forest soils are not acidophiles.
 When isolated from these environments, some fungi show a favorite for near-neutral
conditions, but they are highly competitive under considerable acidity
 A further complication in understanding pH-related microbial activity in soils is that
most microbes are attached to soil surfaces and many grow in colonies and even
biofilms, which can protect them from the pH effects in the soil solution.
 The assumptions came from in vitro physiological evidence of the pH requirements of
the soi microorganisms, it did not take into account the properties of surface-colonizing
populations or of the heterotrophic microorganisms which have wider pH ranges than
their autotrophic counter- parts.

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Thanks

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