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Chapter 19-1 - Prokaryotes

Chapter 19-1 - Prokaryotes. New Technology Leads to New Discovery. The invention of the microscope allowed humans to see things never before seen The work of Hooke and van Leeuwenhoek opened our eyes to the world of microorganisms. Prokaryotes.

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Chapter 19-1 - Prokaryotes

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  1. Chapter 19-1 - Prokaryotes

  2. New Technology Leads to New Discovery • The invention of the microscope allowed humans to see things never before seen • The work of Hooke and van Leeuwenhoek opened our eyes to the world of microorganisms

  3. Prokaryotes • Prokaryote – a single-celled organism that lacks a nucleus (“pro” = before, “karyote” = nucleus) • Prokaryotes are typically referred to as bacteria • Prokaryotes are the smallest & most common microorganisms • Prokaryotes cover nearly ever centimeter of the earth • Prokaryotes are the oldest and most successful organisms on the planet

  4. Prokaryotic Cell Structure • A typical prokaryotic cell has a cell wall, cell membrane, cytoplasm, DNA, ribosomes, flagella, and pili • Flagella (pl. flagellum) – a whip-like structure used for movement • Pili – projections on the outer part of the cell involved in cell to cell contact • DNA – bacteria have a single, circular chromosome and small circles of DNA called plasmids • Capsule – an outer covering that helps protect the bacteria cell • Bacteria have no membrane-bound organelles (nucleus, mitochondria, etc.)

  5. Classifying Prokaryotes • There are 2 kingdoms of bacteria: • Eubacteria • “true bacteria” • Well adapted to most current earth habitats\ • The bacteria we refer to as “germs” are eubacteria • Archaebacteria • “ancient bacteria” • Well adapted to extreme habitats, some of which may closely resemble the ancient earth (~3bya)

  6. Eubacteria: A closer look • Most prokaryotes are eubacteria • The kingdom eubacteria includes a wide range of bacteria with varying habitats and lifestyles • The cell walls of eubacteria are composed of a carbohydrate called peptidoglycan • Eubacteria are found all around, on, and in us, all the time, wherever we go!

  7. Archaebacteria: A closer look • Archaebacteria are similar in structure to eubacteria, yet have a few key differences: • No peptidoglycan in cell wall • Different membrane lipids • Live in extreme environments (high salt, high heat, etc.)

  8. An ancestor to eukaryotes? • Certain important archaebacteria genes (EX. RNA polymerase gene) are more similar to eukaryotic genes than to eubacterial genes • Scientists now believe this is evidence that eukaryotes evolved from archaebacteria, and are not directly descended from the more common eubacteria

  9. Types of Archaebacteria • Methanogens – Live in environments with no oxygen (mud pits, landfills, intestinal tracts) and get energy by converting H2 and CO2 into CH4 (methane) • Extreme Halophiles – Live in high salt environments, use salt to generate ATP • Thermoacidophiles – Live in acidic and/or high temperature environments (hydrothermal vents, volcanoes, hot springs) and get energy by breaking down sulfur compounds

  10. Identifying Prokaryotes • Shapes – Prokaryotes usually have one of three shapes: • Bacilli (bacillus) – rod-shaped bacteria • Cocci (coccus) – spherical bacteria • Spirilla (spirillum) – spiral-shaped bacteria • Some bacteria-naming prefixes: • Diplo = pairs of cells (EX. Diplobacilli) • Staphylo = clusters of cells (EX. Staphylococcus) • Strepto = chains of cells (EX. Streptococcus)

  11. Identifying Prokaryotes • Cell Walls – Eubacteria have 2 different types of cells walls (single or double) • Gram staining is a process used to indicate the cell wall type – two stains, violet and pink, are applied and the bacteria are then observed • Gram-positive bacteria have a a cell wall made of a thick peptidoglycan layer (single wall) and appear purple when stained (both stains absorbed) • Gram-negative bacteria have a cell wall made of a thin peptidoglycan layer and an outer lipid layer (double wall), and appear pink when Gram stained (only pink stain is absorbed)

  12. Obtaining Energy • Some bacteria are autotrophs (“self-feeders”) that make their own organic molecules (food) • Photoautotrophs – bacteria that carry out photosynthesis similar to plants • EX. Cyanobacteria contain light absorbing pigments and are found all over the world • Chemoautotrophs – bacteria that make organic molecules using energy from the breakdown of inorganic (no carbon) molecules such as ammonia or sulfur • EX. Bacteria living on or around hydrothermal vents on the ocean floor

  13. Obtaining Energy • Some bacteria are heterotrophs (“other-feeders”) that get energy by taking in organic molecules (eating). • Heterotrophic bacteria compete with humans for food (food “spoilage” is due to bacteria) • Many heterotrophic bacteria secrete toxic chemicals to prevent other organisms from stealing their food • EX. Salmonella bacteria secrete a toxic substance that causes food poisoning

  14. Obtaining Energy • Some bacteria are photoheterotrophs that capture sunlight for energy and consume organic molecules

  15. Carrying Out Respiration • Bacteria get energy by breaking down molecules during the process of respiration and/or fermentation • Obligate aerobes (aerobic bacteria) require oxygen and depend mainly on respiration for energy • The necessary proteins for respiration are found in the cell membrane (bacteria have no mitochondria)

  16. Carrying Out Respiration • Obligate anaerobes (anaerobic bacteria) do not require oxygen and cannot survive in oxygen-rich environments • Fermentation only • EX. Clostridium tetani, Clostridium botulinum • Facultative anaerobes can survive with or without oxygen • Able to switch between respiration and fermentation • Can survive just about anywhere

  17. Growth and Reproduction • In favorable conditions, prokaryotes can grow and divide quickly • A single prokaryotic organism with unlimited resources, dividing every 20 minutes, would produce a mass of bacteria 4000X the mass of the earth in 48 hours • This doesn’t happen due to lack of resources and the production of waste

  18. Growth and Reproduction • Bacteria reproduce by binary fission • Cell grows until double in size • DNA is replicated • Cell splits in half producing identical daughter cells • Binary fission is asexual reproduction, it does not involve the exchange or recombination of genetic information (all DNA comes from one parent)

  19. Growth and Reproduction • Conjugation – process where a DNA plasmid is copied and passed from one bacteria cell to another • Two bacteria are joined by pilus • DNA plasmids move from one cell to the other • This increases the genetic diversity of a bacteria population • Transformation – when bacteria take up pieces of DNA secreted by live bacteria or released by dead bacteria giving them new traits

  20. Growth and Reproduction • Some bacteria are able to survive harsh environmental conditions for long periods • Endospore – A thick, internal wall enclosing a bacteria cell’s DNA and a portion of the cytoplasm • Formed when growth conditions are unfavorable • Can remain dormant for months or even hundreds of years • Makes it possible for bacteria to survive harsh conditions (extreme heat, lack of food, etc.)

  21. Chapter 19-2 – Bacteria in Nature

  22. Bacteria play an essential role in maintaining the ecosystem • Decomposer – organism that breaks down dead organisms/organic material for food • Many bacteria are decomposers • Decomposers break down dead matter into simpler substances which are released to the soil where they can be reused by plants • What would happen without decomposers? • There would be dead stuff piled up everywhere!

  23. Bacteria play an essential role in maintaining the ecosystem • Nitrogen Fixation – The process of converting atmospheric nitrogen gas (N2) to ammonia (NH3) or other nitrogen compounds that plants can use • Plants need nitrogen to make amino acids which in turn are used to make proteins • Plants cannot use N2 directly • Nitrogen-fixing bacteria provide enrich the soil with nitrogen containing compounds • Animals get their nitrogen from plants (either directly or indirectly)

  24. Bacteria and Disease • There are approximately 10X as many bacteria cells in you than human cells • Most are on your skin or somewhere in your digestive system • These bacteria are kept under control by your immune system • A few are actually beneficial • Aid in digestion • Produce necessary vitamins • Compete for living space with potentially harmful bacteria

  25. Escherichia coli in the human intestines • E. coli normally colonizes an infant's intestines within 40 hours of birth, arriving with food or water or with the individuals handling the child • Harmless strains of E. coli benefit the host by producing vitamin K (necessary for blood coagulation) • They also prevent harmful bacteria from becoming established in the intestine

  26. Bacteria and Disease • A few types of bacteria cause disease (pathogenic bacteria) • Pathogen – a disease-causing agent, like some bacteria • Bacteria cause disease in one of two general ways: • Damaging tissues of host organism by breaking them down for food • EX. Tuberculosis bacteria break down lung tissue • Releasing toxins that harm the body • EX. Tetanus is caused by a neurotoxin produced by Clostridium tetani bacteria

  27. Bacterial Diseases • Tetanus • Typhoid Fever • Diptheria • Syphilis • Cholera • Food poisoning • Leprosy • Tuberculosis • Meningitis

  28. Bacteria and Disease • Many bacterial diseases can be prevented • Vaccines stimulate the body’s immune system and prevent bacteria from colonizing body tissues • Antibiotics – compounds that block the growth or reproduction of bacteria • Penicillin, the first antibiotic, was developed in 1942 • For the first time, humans had a way to treat bacterial infections (short of sawing off appendages!) • Good personal/environmental hygiene help prevent bacterial infections from spreading (hand washing, sewage system, etc.) • Major reason for increased life expectancy = increased knowledge of preventing and treating bacterial diseases

  29. The discovery of antibiotics • 1928 -Alexander Fleming investigates staphylococci. • August 1928 - Fleming goes on vacation, leaves all his cultures of staphylococci on a bench in the lab • On returning, Fleming notices that one that the colonies of staphylococci culture was contaminated with a fungus, and bacteria that had immediately surrounded it had been destroyed • The fungus was from a group of fungi called Penicillum, and he called the bacteria-killing substance it produced penicillin

  30. Discovery of Penicillin

  31. Antibiotic Resistance – Too much of a good thing? • Many bacteria have developed resistance to certain antibiotics • The more we use antibiotics, the more we risk the development of resistant bacteria strains • Antibiotics are frequently prescribed unnecessarily, and taken irresponsibly • Antibiotics are used extensively in agriculture • In some cases, bacteria can be resistant to more than one type of antibiotic • Resistance is determined by genes, and can be transferred from one bacteria to another via transformation or transduction • Antibiotic resistance poses a significant problem for human health now and in the future

  32. Controlling Bacteria • Sterilization – destroying bacteria with either heat or chemicals • Cooking food kills most bacteria • Disinfectant – a chemical solution that kills bacteria • Refrigeration/freezing prevents food spoilage • Bacteria grow more slowly at low temperatures • Different preservation techniques can be used to store food for long periods • Canning – sealing sterilized food in cans or glass jars • Salting – draws moisture out of food/bacteria cells • Pickling – vinegar is highly acidic and prevents most bacterial growth

  33. Canning Tomatoes250 lbs of tomatoes + 10-12 hours = 45 to 50 quarts of crushed tomatoes

  34. Human Uses of Bacteria • Bacteria are used in the production of a variety of foods • Cheeses, buttermilk, yogurt, sour cream, pickles, sauerkraut, vinegar • Bacteria are used in industry • Water treatment, oil spill clean up, botox • Insulin is produced using bioengineered bacteria, as is human growth hormone, antibiotics, and other chemicals

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