chapter 27 prokaryotes “all the world’s bacteria essentially have access to a single gene pool...
TRANSCRIPT
Chapter 27Prokaryotes
“All the world’s bacteria essentially have access to a single gene pool and hence to the adaptive mechanisms of the entire bacterial kingdom. The speed of recombination over that of mutation is superior: it could take eukaryotic organisms a million years to adjust to a change on a worldwide scale that bacteria can accommodate in a few years.” --Lynn Margulis
Characteristics of Prokaryotes
Very small--1-5μm in diameter.
Comes in a wide variety of shapes: Bacilli Cocci Spirilla
Very small--1-5μm in diameter.
Comes in a wide variety of shapes: Bacilli Cocci Spirilla
Characteristics of Prokaryotes
Has a cell wall, provides many functions: Helps it maintain its shape Provides protection Keeps the cell from bursting in hypotonic environments.
Has a cell wall, provides many functions: Helps it maintain its shape Provides protection Keeps the cell from bursting in hypotonic environments.
Prokaryotic Cell Wall
The cell wall of a prokaryotic cell is different from that of a eukaryote: Eukaryotic cell walls are made of cellulose or
chitin. Prokaryotic cell walls contain peptidoglycan--
modified sugar polymers cross-linked to short peptides.
Archean cell walls contain a variety of polysaccharides but lack peptidoglycan.
The cell wall of a prokaryotic cell is different from that of a eukaryote: Eukaryotic cell walls are made of cellulose or
chitin. Prokaryotic cell walls contain peptidoglycan--
modified sugar polymers cross-linked to short peptides.
Archean cell walls contain a variety of polysaccharides but lack peptidoglycan.
Gram Staining
Hans Christian Gram developed the Gram staining technique and it is used to classify many bacterial species into 2 categories. Gram positive Gram negative
Hans Christian Gram developed the Gram staining technique and it is used to classify many bacterial species into 2 categories. Gram positive Gram negative
Gram Positive Bacteria
Gram positive bacteria have a large amount of peptidoglycan in their cell walls. 60-90% of the entire wall.
They have very little protein (except streptococci).
Gram positive bacteria have a large amount of peptidoglycan in their cell walls. 60-90% of the entire wall.
They have very little protein (except streptococci).
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Gram Positive Bacteria
Their thick cell walls allow them to retain the crystal-violet dye. Yeast cells have thick walls and no peptidoglycan but still retain the stain. Wall thickness, not peptidoglycan.
Their thick cell walls allow them to retain the crystal-violet dye. Yeast cells have thick walls and no peptidoglycan but still retain the stain. Wall thickness, not peptidoglycan.
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Gram Negative Bacteria
Gram negative bacteria have less peptidoglycan (thin cell wall), and cell walls that are structurally more complex. 10-20% of wall is peptidoglycan. They have an outer bilayer membrane that acts as a coarse sieve.
Gram negative bacteria have less peptidoglycan (thin cell wall), and cell walls that are structurally more complex. 10-20% of wall is peptidoglycan. They have an outer bilayer membrane that acts as a coarse sieve.
Gram Negative Bacteria
Gram negative bacteria have less peptidoglycan (thin cell wall), and cell walls that are structurally more complex. It has little control over the movement of substances into and out of the cell.
It does control the movement of proteins.
Gram negatives are less sensitive to penicillin because this sieve acts to keep penicillin out.
Gram negative bacteria have less peptidoglycan (thin cell wall), and cell walls that are structurally more complex. It has little control over the movement of substances into and out of the cell.
It does control the movement of proteins.
Gram negatives are less sensitive to penicillin because this sieve acts to keep penicillin out.
Gram Negative Bacteria
Their outer membrane contains the endotoxin lipopolysaccharide.
No retention of the crystal violet-iodine stain due to the thin cell wall and large amount of lipoprotein and lipopolysaccharide.
Their outer membrane contains the endotoxin lipopolysaccharide.
No retention of the crystal violet-iodine stain due to the thin cell wall and large amount of lipoprotein and lipopolysaccharide.
Gram Negative Bacteria
Many pathogenic prokaryotes are Gram Negative: they usually cause illness by producing endotoxins.
Many pathogenic prokaryotes are Gram Negative: they usually cause illness by producing endotoxins.
Gram Negative Bacteria
Endotoxins are lipopolysaccharides released by the outer membrane of Gram negative bacteria when they die and their cell walls break down.
The bacteria that produce endotoxins are not normally found in healthy animals. Examples: cholera, botulism, salmonella
Endotoxins are lipopolysaccharides released by the outer membrane of Gram negative bacteria when they die and their cell walls break down.
The bacteria that produce endotoxins are not normally found in healthy animals. Examples: cholera, botulism, salmonella
Usefulness of Gram Staining
Gram staining is useful in medicine. Gram negative bacteria are usually more pathogenic and the LPS is usually toxic and sometimes lethal.
Gram negatives are often more resistant to antibiotics due to the outer membrane.
The outer membrane of Gram negatives protect against the body’s defenses. Some prokaryotes contain a capsule which is a sticky outer coat of polysaccharide or protein which shields the bacteria from the host’s defense system.
Gram staining is useful in medicine. Gram negative bacteria are usually more pathogenic and the LPS is usually toxic and sometimes lethal.
Gram negatives are often more resistant to antibiotics due to the outer membrane.
The outer membrane of Gram negatives protect against the body’s defenses. Some prokaryotes contain a capsule which is a sticky outer coat of polysaccharide or protein which shields the bacteria from the host’s defense system.
Structural Differences Between Prokaryotes
and Eukaryotes
The flagella of prokaryotes are much different from those of eukaryotes. Prokaryotic flagella are much smaller.
The flagella of prokaryotes are much different from those of eukaryotes. Prokaryotic flagella are much smaller.
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Structural Differences Between Prokaryotes
and Eukaryotes
The flagella of prokaryotes are much different from those of eukaryotes. Prokaryotic flagella are much smaller.
The flagella of prokaryotes are much different from those of eukaryotes. Prokaryotic flagella are much smaller.
Structural Differences Between Prokaryotes
and Eukaryotes
Although prokaryotes lack internal organization and membranous organelles, they can have internal membranes that perform certain functions--infoldings of the plasma membrane. Some membranes similar to cristae--function in cell respiration.
Others have thylakoid membranes.
Although prokaryotes lack internal organization and membranous organelles, they can have internal membranes that perform certain functions--infoldings of the plasma membrane. Some membranes similar to cristae--function in cell respiration.
Others have thylakoid membranes.
Structural Differences Between Prokaryotes
and Eukaryotes
Eukaryotic chromosomes have about 1000x as much DNA as do prokaryotes.
Prokaryotes’ chromosomes are circular vs. linear; there is hardly any protein associated with them.
Prokaryotic DNA is found in the nucleoid region, eukaryotic in the nucleus.
Prokaryotic DNA is often associated with plasmids.
Eukaryotic chromosomes have about 1000x as much DNA as do prokaryotes.
Prokaryotes’ chromosomes are circular vs. linear; there is hardly any protein associated with them.
Prokaryotic DNA is found in the nucleoid region, eukaryotic in the nucleus.
Prokaryotic DNA is often associated with plasmids.
Plasmids
Recall, plasmids are small rings of DNA with a few genes that usually confer some sort of benefit to the bacterium.
Plasmids often increase a bacterium’s chance of survival in certain environments, but they are not essential to survival.
Recall, plasmids are small rings of DNA with a few genes that usually confer some sort of benefit to the bacterium.
Plasmids often increase a bacterium’s chance of survival in certain environments, but they are not essential to survival.
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Plasmids
Plasmids generally have contingency functions: Provide resistance to antibiotics
Direct the metabolism of rarely encountered nutrients.
Plasmids generally have contingency functions: Provide resistance to antibiotics
Direct the metabolism of rarely encountered nutrients.
The Success of Prokaryotes
Prokaryotes are successful because they can reproduce quickly--via binary fission. Typically a 1-3 hour generation time. Some every 20 minutes in optimal conditions.
36 hours would cover the Earth in 18” of bacteria 3 days would exceed the mass of the Earth
They are limited by metabolic wastes, food supply and consumption by other organisms.
Prokaryotes are successful because they can reproduce quickly--via binary fission. Typically a 1-3 hour generation time. Some every 20 minutes in optimal conditions.
36 hours would cover the Earth in 18” of bacteria 3 days would exceed the mass of the Earth
They are limited by metabolic wastes, food supply and consumption by other organisms.
The Success of Prokaryotes
The success of prokaryotes is also due to their ability to withstand harsh environments.
Natural selection has enabled prokaryotes to adapt quickly to changing environments.
Their fast generation time allows them to propagate mutations quickly. These mutations are often beneficial to survival.
Some bacteria form endospores when the environment becomes harsh.
The success of prokaryotes is also due to their ability to withstand harsh environments.
Natural selection has enabled prokaryotes to adapt quickly to changing environments.
Their fast generation time allows them to propagate mutations quickly. These mutations are often beneficial to survival.
Some bacteria form endospores when the environment becomes harsh.
Endospores
Endospores are produced when the prokaryote wraps a copy of its DNA in a tough wall and then removes the water.
The metabolism inside the spore comes to a halt a picks up again when conditions improve.
Endospores are produced when the prokaryote wraps a copy of its DNA in a tough wall and then removes the water.
The metabolism inside the spore comes to a halt a picks up again when conditions improve.
Metabolism in General
Phototrophs-obtain energy from light.
Chemotrophs-obtain energy from chemicals in the environment.
Autotrophs-only need CO2 as a carbon source, they make everything else they need themselves.
Heterotrophs-require at least one source of organic carbon to sustain themselves.
Phototrophs-obtain energy from light.
Chemotrophs-obtain energy from chemicals in the environment.
Autotrophs-only need CO2 as a carbon source, they make everything else they need themselves.
Heterotrophs-require at least one source of organic carbon to sustain themselves.
Prokaryotic Metabolism
There are a number of different ways for organisms to obtain energy and carbon.
On the whole, prokaryotes are much more diverse than eukaryotes.
All nutrition types seen in eukaryotes are found in prokaryotes. Prokaryotes also have other means of obtaining energy and carbon.
There are a number of different ways for organisms to obtain energy and carbon.
On the whole, prokaryotes are much more diverse than eukaryotes.
All nutrition types seen in eukaryotes are found in prokaryotes. Prokaryotes also have other means of obtaining energy and carbon.
Prokaryotic Metabolism
With respect to oxygen, a prokaryote’s metabolism can vary.
Obligate aerobes require oxygen to survive.
Facultative anaerobes use O2, but can get along without it.
Obligate anaerobes are poisoned by O2. Some obligate anaerobes live exclusively with fermentation. Others obtain energy from anaerobic respiration. Substances such as NO3- and SO4
2- accept electrons in the place of O2 at the end of the ETC.
With respect to oxygen, a prokaryote’s metabolism can vary.
Obligate aerobes require oxygen to survive.
Facultative anaerobes use O2, but can get along without it.
Obligate anaerobes are poisoned by O2. Some obligate anaerobes live exclusively with fermentation. Others obtain energy from anaerobic respiration. Substances such as NO3- and SO4
2- accept electrons in the place of O2 at the end of the ETC.
Prokaryotic Metabolism
Nitrogen metabolism. Nitrogen is essential for the production of amino acids. Eukaryotes are limited by the types of nitrogen compounds they can use.
Prokaryotes can use nitrogen from a wide variety of sources.
Nitrogen fixation is the process by which certain prokaryotes use N2 to make NH3. The NH3 is then used along with CO2 and H2O to create a wide variety of organic molecules.
Nitrogen metabolism. Nitrogen is essential for the production of amino acids. Eukaryotes are limited by the types of nitrogen compounds they can use.
Prokaryotes can use nitrogen from a wide variety of sources.
Nitrogen fixation is the process by which certain prokaryotes use N2 to make NH3. The NH3 is then used along with CO2 and H2O to create a wide variety of organic molecules.
Prokaryotic Metabolism
There are four main modes of nutrition:
1. Photoautotrophs 2. Chemoautotrophs 3. Photoheterotrophs 4. Chemoheterotrophs
There are four main modes of nutrition:
1. Photoautotrophs 2. Chemoautotrophs 3. Photoheterotrophs 4. Chemoheterotrophs
1. Photoautotrophs
Are photosynthetic organisms that use light energy to drive the synthesis of organic compounds from CO2.
Examples: cyanobacteria, plants, algae
Are photosynthetic organisms that use light energy to drive the synthesis of organic compounds from CO2.
Examples: cyanobacteria, plants, algae
2. Chemoautotrophs
These oxidize inorganic substances (H2S, NH3, and Fe2+) and use CO2 as a carbon source to drive the synthesis of organic compounds.
*This is unique to prokaryotes.
These oxidize inorganic substances (H2S, NH3, and Fe2+) and use CO2 as a carbon source to drive the synthesis of organic compounds.
*This is unique to prokaryotes.
3. Photoheterotrophs
Use light energy and carbon from an organic source for nutrition. *Many marine prokaryotes use this.
Use light energy and carbon from an organic source for nutrition. *Many marine prokaryotes use this.
4. Chemoheterotrophs
Consume organic compounds for energy and carbon. Examples: Found in prokaryotes, protists, fungi, and animals.
Consume organic compounds for energy and carbon. Examples: Found in prokaryotes, protists, fungi, and animals.
The 2 Domains of Bacteria
1. Bacteria-the vast majority of prokaryotes of which most people are aware. Pathogenic-cause infections Beneficial-produce many foods
2. Archea-share traits with both prokaryotes and eukaryotes. Extremeophiles-live in hostile environments where few other organisms can survive.
Example: extreme thermophiles, extreme halophiles, methanogens.
1. Bacteria-the vast majority of prokaryotes of which most people are aware. Pathogenic-cause infections Beneficial-produce many foods
2. Archea-share traits with both prokaryotes and eukaryotes. Extremeophiles-live in hostile environments where few other organisms can survive.
Example: extreme thermophiles, extreme halophiles, methanogens.
Extreme Thremophiles
Live in very hot environments. Sulfur-rich volcanic hot springs, 90°C+ Genus Sulfolobus.
Deep-sea hydrothermal vents, 113°C Pycolobus fumarri.
Some grow at temperatures of 600°F+ and 265+ atm of pressure.
Live in very hot environments. Sulfur-rich volcanic hot springs, 90°C+ Genus Sulfolobus.
Deep-sea hydrothermal vents, 113°C Pycolobus fumarri.
Some grow at temperatures of 600°F+ and 265+ atm of pressure.
Extreme Halophiles
Live in highly saline environments. The Great Salt Lake, Dead Sea. Some tolerate the salt, others require it.
Live in highly saline environments. The Great Salt Lake, Dead Sea. Some tolerate the salt, others require it.
Methanogens
Methanogens are named for their mode of energy production. They use CO2 and oxidize H2 releasing CH4 in the process.
These bacteria are the strictest anaerobes. They are poisoned by O2.
Methanogens are named for their mode of energy production. They use CO2 and oxidize H2 releasing CH4 in the process.
These bacteria are the strictest anaerobes. They are poisoned by O2.
The Importance of Prokaryotes
Prokaryotes are important for the cycling of chemical elements of living and non-living components of the environment.
Decomposers break down a variety of substances. They extract nutrients from a variety of things such as dead organisms and waste products.
These metabolites are then returned to the environment.
Prokaryotes are important for the cycling of chemical elements of living and non-living components of the environment.
Decomposers break down a variety of substances. They extract nutrients from a variety of things such as dead organisms and waste products.
These metabolites are then returned to the environment.
The Importance of Prokaryotes
Many prokaryotes also convert usable forms of inorganic compounds into those that can be used by other organisms. Examples: autotrophic prokaryotes use CO2 to make organic compounds which are passed up the food chain.
Cyanobacteria produce O2 and fix N2 into compounds other organisms use to make proteins.
Many prokaryotes also convert usable forms of inorganic compounds into those that can be used by other organisms. Examples: autotrophic prokaryotes use CO2 to make organic compounds which are passed up the food chain.
Cyanobacteria produce O2 and fix N2 into compounds other organisms use to make proteins.
Symbiosis
Symbiosis is the ecological relationship between 2 organisms of different species.
The host is the larger organism, while the symbiont is the smaller one.
There are three types of symbiosis:
1. Mutualism 2. Commensalism 3. Parasitism
Symbiosis is the ecological relationship between 2 organisms of different species.
The host is the larger organism, while the symbiont is the smaller one.
There are three types of symbiosis:
1. Mutualism 2. Commensalism 3. Parasitism
1. Mutualism
In mutualism, both symbiotic organisms benefit.
The well being of many organisms depends on mutualistic prokaryotes. Example: the human intestines are home to between 500-1000 species of bacteria that help us break down food, keep other bacteria at bay, and activate genes which stimulate our intestines to produce blood vessels and absorb food.
In mutualism, both symbiotic organisms benefit.
The well being of many organisms depends on mutualistic prokaryotes. Example: the human intestines are home to between 500-1000 species of bacteria that help us break down food, keep other bacteria at bay, and activate genes which stimulate our intestines to produce blood vessels and absorb food.
2. Commensalism
Commensalism is where one organism benefits where neither of the organisms is harmed.
These are difficult to document in nature because any close association between organisms is likely to benefit both of them. Hitchihiking species of algae is an example.
Commensalism is where one organism benefits where neither of the organisms is harmed.
These are difficult to document in nature because any close association between organisms is likely to benefit both of them. Hitchihiking species of algae is an example.
3. Parasitism
With parasitism, the symbiont (a parasite) benefits while the host suffers. Tapeworms.
With parasitism, the symbiont (a parasite) benefits while the host suffers. Tapeworms.
Controlling Prokaryotes
Antibiotics have done a good job of containing disease and preventing death. However, the rapid production of bacteria enables them to propagate a mutation that confers resistance throughout the population.
Natural selection favors these mutants and allows them to survive.
Antibiotics have done a good job of containing disease and preventing death. However, the rapid production of bacteria enables them to propagate a mutation that confers resistance throughout the population.
Natural selection favors these mutants and allows them to survive.
Usefulness of Prokaryotes
For all of the harm that bacteria cause, we reap many benefits from them as well.
Can be used to produce vitamins, hormones, etc.
Bioremediation uses prokaryotes to remove pollutants from the air, soil, and water.
For all of the harm that bacteria cause, we reap many benefits from them as well.
Can be used to produce vitamins, hormones, etc.
Bioremediation uses prokaryotes to remove pollutants from the air, soil, and water.
Biomining
Prokaryotes can also be used to recover precious metals from ores in a process called biomining. 30 billion kg of Cu from copper sulfides each
year. 1 million kg of gold concentrate is processed
each day extracting the gold in Ghana, Africa.
Prokaryotes can also be used to recover precious metals from ores in a process called biomining. 30 billion kg of Cu from copper sulfides each
year. 1 million kg of gold concentrate is processed
each day extracting the gold in Ghana, Africa.
The microbiology of biomining: development and optimization of mineral-oxidizing microbial consortia. Douglas E. Rawlings and D. Barrie Johnson