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19–1 Bacteria Photo Credit: Michael T. Sedam/CORBIS Copyright Pearson Prentice Hall
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Classifying Prokaryotes
The smallest and most common microorganisms are prokaryotes—unicellular organisms that lack a nucleus. All prokaryotes were once placed in the Kingdom Monera. Recently, biologists divided them into two different kingdoms: the Eubacteria and the Archaebacteria. Copyright Pearson Prentice Hall
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Classifying Prokaryotes
Eubacteria Indeterminate number of phyla needed to classify. Eubacteria have a cell wall that protects the cell and determines its shape. The cell wall contains peptidoglycan, a carbohydrate. Eubacteria have a cell membrane that surrounds the cytoplasm. Some eubacteria have a second membrane that provides added protection. Eubacteria live in a variety of environments, including fresh and salt water, land, and the human body. Copyright Pearson Prentice Hall
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Classifying Prokaryotes
E. coli, a Typical Eubacterium Ribosomes Cell Wall Cell Membrane Peptidoglycan A bacterium such as E. coli has the basic structure typical of most prokaryotes: cell wall, cell membrane, and cytoplasm. Some prokaryotes have flagella that they use for movement. The pili are involved in cell-to-cell contact. The cell walls of eubacteria contain peptidoglycan. Flagellum DNA Pili Copyright Pearson Prentice Hall
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Classifying Prokaryotes
Archaebacteria Look very similar to Eubacteria: Small Lack nuclei Cell walls The cells walls of archaebacteria do not contain peptidoglycan. Archaebacteria have different membrane lipids. Key differences: DNA sequences of key genes are more like those of eukaryotes than those of eubacteria. Copyright Pearson Prentice Hall
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Classifying Prokaryotes
Archaebacteria Many archaebacteria live in extreme environments. Methanogens live in oxygen-free environments, such as thick mud and animal digestive tracts. Other archaebacteria live in salty environments or in hot springs where water temperatures approach the boiling point. Copyright Pearson Prentice Hall
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Identifying Prokaryotes
shape chemical nature of their cell walls way they move way they obtain energy Copyright Pearson Prentice Hall
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Identifying Prokaryotes
Shapes Rod-shaped prokaryotes are called bacilli. Prokaryotes can be identified by their shapes. Photo Credit: ©David Scharf/Peter Arnold, Inc. Bacilli Copyright Pearson Prentice Hall
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Identifying Prokaryotes
Spherical prokaryotes are called cocci. Prokaryotes can be identified by their shapes. Photo Credit: ©David M. Phillips/Visuals Unlimited Cocci Copyright Pearson Prentice Hall
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Identifying Prokaryotes
Spiral and corkscrew-shaped prokaryotes are called spirilla. Prokaryotes can be identified by their shapes. Photo Credit: ©Scott Camazine/Photo Researchers, Inc. Spirilla Copyright Pearson Prentice Hall
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Identifying Prokaryotes
Arrangement: Many bacteria also are found in distinct arrangements These groups form when cells divide without separating. Cells in pairs are called diplo-(shape),diplococci. Cells in chains are called strepto-(shape), steptococci. Four cells arranged in a cube are called tetrads. Eight cells arranged in a cube are called sarcinae. Grape-like clusters are called staphylo-(shape), staphylococci. Prokaryotes can be identified by their shapes. Photo Credit: ©Scott Camazine/Photo Researchers, Inc. Copyright Pearson Prentice Hall
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Identifying Prokaryotes
Prokaryotes can be identified by their shapes. Photo Credit: ©Scott Camazine/Photo Researchers, Inc. Copyright Pearson Prentice Hall
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Identifying Prokaryotes
Cell Walls Two different types of cell walls are found in eubacteria. A method called Gram staining tells them apart. Two dyes: violet (primary) and red (counterstain). Gram-positive bacteria have thick cell walls with large amounts of peptidoglycan – stain color violet. Gram-negative bacteria have thinner cell walls inside an outer lipid layer – stain color pink/red. Copyright Pearson Prentice Hall
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Identifying Prokaryotes
Movement Prokaryotes can be identified by whether they move and how they move. Can be immobile, propelled by flagella, spiral or lashing, or slow gliders. Copyright Pearson Prentice Hall
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Metabolic Diversity Metabolic Diversity Prokaryotes are divided into two main groups: Heterotrophs get their energy by consuming organic molecules made by other organisms. Autotrophs make their own food from inorganic molecules. Copyright Pearson Prentice Hall
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Copyright Pearson Prentice Hall
Metabolic Diversity Heterotrophs Prokaryotes that take in organic molecules for both energy and a supply of carbon are called chemoheterotrophs. Prokaryotes that use sunlight for energy, but take in organic compounds as a carbon source are called photoheterotrophs. Copyright Pearson Prentice Hall
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Copyright Pearson Prentice Hall
Metabolic Diversity Autotrophs Photoautotrophs use light energy to convert carbon dioxide and water to carbon compounds and oxygen in a process similar to green plants. Chemoautotrophs perform chemosynthesis. They make organic carbon molecules from carbon dioxide, but do not require light as energy. Instead they use energy directly from chemical reactions involving ammonia, hydrogen sulfide, nitrites, sulfur, or iron. Copyright Pearson Prentice Hall
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Copyright Pearson Prentice Hall
Metabolic Diversity Releasing Energy Bacteria need a constant supply of energy, which is released by the processes of cellular respiration or fermentation or both. Obligate aerobes require a constant supply of oxygen. Bacteria that live without oxygen because they may be killed by it are called obligate anaerobes. Bacteria that can survive with or without oxygen are known as facultative anaerobes. Able to switch between respiration and fermentation. E.coli Copyright Pearson Prentice Hall
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Growth and Reproduction
In favorable conditions, prokaryotes can grow and divide at rapid rates: as often as every 20 minutes! Growth and reproduction are controlled by availability of food and the production of wastes. Prokaryotes can reproduce by binary fission, take part in conjugation and/or produce spores. Copyright Pearson Prentice Hall
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Growth and Reproduction
Binary Fission Binary fission is a type of asexual reproduction in which an organism replicates its DNA and divides in half, producing two identical daughter cells. Most prokaryotes reproduce by binary fission, producing two identical “daughter” cells. Photo Credit: ©Dr. Dennis Kunkel/Phototake Binary Fission Copyright Pearson Prentice Hall
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Growth and Reproduction
Conjugation During conjugation, a hollow bridge forms between two bacterial cells, and genes move from one cell to the other. This transfer of genetic information increases genetic diversity in populations of bacteria. Copyright Pearson Prentice Hall
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Growth and Reproduction
Spore Formation In unfavorable growth conditions, many bacteria form spores. An endospore forms when a bacterium produces a thick internal wall that encloses its DNA and some of its cytoplasm. Spores can remain dormant for months or years. Spores allow bacteria to survive harsh conditions. Copyright Pearson Prentice Hall
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Importance of Bacteria
Bacteria are vital to the living world. Some are producers that capture energy by photosynthesis. Others are decomposers that break down the nutrients in dead matter. Still other bacteria have human uses. Copyright Pearson Prentice Hall
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Importance of Bacteria
Decomposers Bacteria recycle nutrients and maintain equilibrium in the environment. Bacteria also help in the treatment of sewage. Copyright Pearson Prentice Hall
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Importance of Bacteria
Nitrogen Fixers Plants need nitrogen gas to be changed chemically to ammonia or other nitrogen compounds to produce amino acids. Certain bacteria produce the nitrogen compounds needed in most plants. The process of converting nitrogen gas into a form plants can use is known as nitrogen fixation. Many plants have symbiotic relationships with nitrogen-fixing bacteria. Rhizobium in soybean root systems Copyright Pearson Prentice Hall
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Importance of Bacteria
Human Uses of Bacteria We depend on bacteria for many things, including: foods and beverages removal of waste and poisons from water mining minerals from the ground synthesis of drugs and chemicals via genetic engineering production of vitamins in human intestines Copyright Pearson Prentice Hall
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