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Chapter 6: Bacteria and Viruses 6-1: Classifying Organisms • Today, Scientists have identified at least 1.7 million organisms on earth. • This includes: Bacteria Simple Protists Fungi Plants Animals Complex • It is important for Biologists to organize all living things so they are easier to study. • Classification is the process of grouping things based on similarities. • The scientific study of classification is called taxonomy. • 1) 2) 3) Early Classification Systems The first classification system was developed by Aristotle in 4th Century B.C. and it had three groups: Those that fly Those that swim Those that crawl, walk, or run What was this first system based on? Movement • The next classification system was developed by Carlos Linnaeus in the 1750’s • It was based on observable features of organisms. • Linnaeus also devised a naming system called binomial nomenclature- each organism had a 2-part name. Kingdom Phylum Class Order Family Genus Species Levels of Classification Largest/Broadest Category Smallest/Most Specific Category • In Linneaus’ System, the 2-part name is made up of: First word: Genus- grouping of similar, closely related organisms. Second Word: Species- grouping of similar organisms that can mate and produce fertile offspring; Often describes a distinctive feature. Q: Why is Linneaus’ System important? What is this? ______________ Cougar? Mountain Lion? Panther? Puma? Scientific Name: Felis concolor A: For many species, there are regional differences in their common name. 5 It is kind of like the way you are named: Example: Malik would be like the “genus”….but there are other Maliks. Stephanie would be the species that distinguishes me from other Maliks. How to write an organism’s name in binomial nomenclature: 1) The Genus is ALWAYS capitalized 2) The Species is ALWAYS lower case 3) It is ALWAYS in latin 4) It is ALWAYS written in italics. Example: Felis domesticus is a house cat Classification Today: • The theory of evolution changed the way biologists think about classification. • Certain organisms share a common ancestor. • When organisms share a common ancestor, they share evolutionary history. • Today’s system considers evolutionary history. • Species with similar evolutionary histories are classified more closely together. Comparing Classification Levels to Everyday Concept: Kingdom: Earth Phylum: United States (Country) Class: Michigan (State) Order: Temperance (City) Family: Silo Meadows (Neighborhood or Street) Genus: 627 Briar Lane (Address) Species: Individual Living There Classifying an Owl (pg. 187): Kingdom: Phylum: Class: Order: Family: Genus: Species: Q: How do you learn the identity of an organism? A: Using a Taxonomic Key (Dichotomous Key)- A series of paired opposite statements that describe physical characteristics of different organisms. Practice with Non-living things: Step 1:Brainstorm Characteristics Present: Long and tubular For writing Not Plastic Plastic Short non-tubular Not for writing has a cap no cap Green and gray Blue and clear Black and silver Silver 9 Step 2: Make a spider key 2 Main groups (as close to 50-50 as you can get) Further breakdown 10 Step 3: Using your spider key as a guide, construct your dichotomous key. When something can no longer be divided, name it! ***You cannot fill in 1b until later….leave it blank at first. 11 6-2: The Six Kingdoms Archaebacteria Prokaryote No Nucleus Might resemble some of earth’s early life forms Unicellular Autotroph or Heterotroph Live on ocean floor, in salty water, or hot springs. Live in Harsh Conditions Archaebacteria means : “Ancient Bacteria” DNA is free floating. Eubacteria Prokaryote Bacteria that causes strep throat is classified here No Nucleus Help make yogurt Unicellular “Common” Bacteria Autotroph or Heterotroph Different chemical make-up than archaebacteria Live in common places DNA is free floating. Protists Eukaryote Nucleus Present Other cell structures: cilia, flagella, pseudopods Unicellular, some multicellular Seaweed and other algae are examples Sometimes called the “junk drawer” kingdom. Autotroph or Heterotroph Other examples: ameba, euglena, paramecium DNA is in the nucleus Fungi Nucleus Present Eukaryote Cell walls contain chitin Multicellular, one unicellular: yeast Mushrooms, mildew, and molds are examples Found almost all over the world on land, very few in water. Heterotrophs Most feed on dead or decaying organisms Absorb their food through their cell walls. DNA is in the nucleus Plants Nucleus Present Eukaryote Cell walls contain cellulose Multicellular Dandelions, mosses, and vegetables are examples Plants feed almost all the heterotrophs on earth. Autotrophs Some produce flowers, some do not Make their own food using sunlight DNA is in the nucleus Animals Eukaryote No cell wall, just a cell membrane Nucleus Present Multicellular Jellyfish, fleas, fish, birds, frogs, snakes, birds, and dogs are all examples Different adaptations allow them to locate, capture, and digest food. Heterotrophs Found in diverse environments on Earth DNA is in the nucleus 6-2 Classification of Life Table Kingdom Archaebacteria Cell Type Eubacteria Protists Fungi Plants Prokaryote Prokaryote Eukaryote Eukaryote Eukaryote Eukaryote Cell Structures No Nucleus Cilia Flagella Pseudopods Cell Wall with Chitin Cell Wall with Cellulose No Cell wall Number of Cells Unicellular Unicellular Unicellular or Multicellular Mostly Multicellular Multicellular Multicellular Nutrition Autotroph, Autotroph, Autotroph, HeteroHeteroHeterotroph troph troph Heterotroph Autotroph Heterotroph Other Info. Live in harsh conditions Absorb food Many varieties No Nucleus “common” bacteria “Junk Drawer” Kingdom Animals 19 Adaptations to get food 6-3: Bacteria • Bacteria are found in nearly every place on earth. • There are more bacteria in your mouth than there are people on earth. • Bacteria- single celled prokaryotic organisms • Since bacteria are the only prokaryotes (all other living things are eukaryotes) you can use either word: BACTERIA = PROKARYOTES • Since bacteria are prokaryotes, they do not have a nucleus. Q: Where then is the DNA of a prokaryote located? A: Throughout the cytoplasm • Bacteria also lack many other organelles, but are still able to carry out all life functions: use energy, grows, responds, reproduces. Bacteria Shapes 1) Spherical (Round)- Coccus 2) Rodlike (Pill Shaped)- Bacilli 3) Spiral- Spirilla Bacteria Arrangements 1) Chains- Strepto 2) Clusters- Staphylo 3) Pairs- Diplo Example: The bacteria that causes strep throat is chains of round bacteria, therefore would be called: Streptococcus Q: What would a cluster of pill shaped bacteria be called? A: Staphylobacilli Diplococcus Streptococcus Staphylococcus 1) 2) 3) 4) 5) 6) Bacteria Structures Cell Wall- Protects the cell Cell Membrane- Controls what passes in and out Cytoplasm- Jelly-like substance that holds other structures. Ribosomes- Make proteins Chromosome (DNA)- Circular strand that contains the instructions for building proteins Flagellum- Whip-like structure that helps the cell move Q: If a bacteria cell does not have flagellum, how does it move from place to place? A: Air, water, human activity Q: What are the two Kingdoms of Bacteria? A: Archaebacteria, Eubacteria Archaebacteria • Live in extreme environments like hot springs, acidic waters, mud swamps, and sewage. Eubacteria • Live EVERYWHERE!!! Like in your bodies and all over surfaces. • Help maintain the earth’s physical conditions and help other organisms survive by being at the beginning of a food chain: sunlight----autrophic bacteria----small hertotrophs----larger heterotrophs • May have been responsible for adding oxygen to the earth’s early atmosphere. • Help keep the level of oxygen in the atmosphere at 20% • • • • Reproduction in Bacteria When bacteria are in favorable conditions, they can reproduce rapidly. Sometimes as often as doubling their population every 20 minutes. Fortunately conditions are rarely ideal…because if they were, the earth would be covered in bacteria! Asexual Reproduction Asexual Reproduction- is the type of reproduction that involves only one parent and produces offspring that are identical to the parent. Bacteria reproduce asexually using a process called binary fission- the process by which one cell divides to make two identical cells. • 1) 2) 3) 4) In binary fission, these steps occur: DNA is copied (replication)- one copy for each new cell. Cytoplasm is divided evenly into 2 new cells. Ribosomes divided evenly into 2 new cells. Two new cells “pinch” off to live independently. Sexual Reproduction • Sometimes, bacteria undergo a simple form of sexual reproduction called conjugation- a process where one bacterial cell transfers genetic information to another cell using a thin, hollow bridge called a pili. • Conjugation does not increase the number of bacteria, but it does increase the new combinations of genetic material in bacteria (makes more variety) • After conjugation, binary fission takes place. Describe the two types of reproduction in bacteria . Bacteria Survival Needs • Both kingdoms of bacteria need certain things to survive: 1) A way of obtaining food 2) A way of using that food for energy (respiration) 3) Survival techniques when conditions become unfavorable (endospore formation) Obtaining Food • Autotrophic bacteria can use the sun to make food. • Some bacterial autotrophs don’t live in places where the sun shines like deep in oceans and in mud. Therefore they are called chemoautotrophs- use chemical substances to make food. • Some bacteria are heterotrophs that consume other organisms. Respiration • Most bacteria use the same kind of respiration you learned about in chapter 2. • Some bacteria need oxygen for this process to take place. • However there are some bacteria that do not use oxygen, in fact it is poison to them! Endospore Formation • When conditions become unfavorable for reproduction, bacteria have a way to protect themselves. • Bacteria can form an endospore- a small, round, thick walled cell that forms inside of the bacterial cell that contains the DNA. • The endospore protects the DNA from being destroyed by freezing, heating, drying, and can survive for many years. Describe the three basic survival needs of bacteria. Bacteria and the Living World Bacteria are involved in fuel and food production as well as in environmental recycling and clean-up. However some bacteria cause diseases and other harmful effects. Fuel • Archaebacteria that live deep in muddy places produce a gas called methane. • Methane is in about 20% of the earth’s deposits of natural gas. • Natural gas is used to heat homes and cook foods. Food • Bacteria help make foods like cheese, yogurt, and apple cider. • Bacteria can also be harmful to food and spoil it. Environmental Recycling • Bacteria that live in soil are “recyclers” or in other words decomposers- organisms that break down large chemicals in dead organisms into small chemicals. • Decomposers are “natures recyclers” because they return basic chemicals to the environment for other living things to use. • Example: a tree dies and fall in the forest- bacteria break down the dead leaves and return nutrients to the soil so something new can grow there. • There is bacteria that lives in symbiosis with a plants roots that helps the plant survive. Environmental Clean-up • There is a type of bacteria that feasts on oil. • These bacteria help clean up oil spills. Describe the four ways bacteria are useful in the world. Illness and Health • Some bacteria can cause infectious disease- illnesses that pass from one organism to another. • Ways infectious disease spreads: 1) Direct contact- touching, kissing 2) Indirect contact- coughing, sneezing 3) Environmental contact- in the soil, enters through a wound. These types of bacteria produce a toxinpoison that causes harm. • Fortunately bacterial diseases can be cured with medicines known as antibiotics- a chemical that can kill a bacteria without harming the persons’ own cells. • Example of antibiotic- penicillin • There are bacteria that help keep you healthy- like in your intestines Define: infectious disease, toxin, and antibiotics 6-4: Viruses • Virus- a small, non-living particle that invades and then reproduces inside a living cell. Q: Why are viruses considered non-living? To answer this, look back in chapter 1 and list the characteristics of living things below: Cellular Organization Contain Similar Chemicals Use Energy Grow and Develop Respond to Their Surroundings Reproduce Now, let’s check off the characteristics that viruses have A: Since viruses do not have all of these characteristics, they are considered non-living. • Viruses are similar to other organisms in one main way: The way they can multiply (reproduce). • Viruses can only reproduce when they are living inside of a living cell. • The organism that the virus enters and reproduces inside of is called the host. The host provides a source of energy. • An organism that lives inside another organism and causes harm is called a parasite. • Viruses act a lot like parasites because they destroy cells when they multiply. • All organisms can be infected by a virus, but viruses are specific to what type of species they infect. Examples: Cold virus- nose and throat cells of humans Tobacco Mosaic Virus- leaf cells of tobacco plants Naming Viruses • Remember most organisms are named using binomial nomenclature….but viruses are not living. So they are not named using this system. • Viruses are named in one of these ways: How it is named Example By the disease it causes Polio Virus By the organism it infects Tomato Mosaic Virus By where it was first found Ebola Virus By the scientists who discovered it Epstein-Barr Virus The Shapes and Sizes of Viruses There are a wide variety of virus shapes and sizes. Shapes: Shape Example Round Influenza (Flu) German Measles Spaceship/Insect Bacteriophagevirus that only infects bacteria Rod/Tube Tobacco Mosaic Bullet Rabies Picture The Shapes and Sizes of Viruses Sizes: • Viruses are smaller than cells and smaller than bacteria. • It takes a powerful microscope to view viruses. • They are measured in nanometers (nm). Nanometers are one-billionth of a meter (m). • Most viruses measure between 50 and 60 nm in diameter. • • 1) 2) Virus Structure Although viruses look much different from one another, they all have a similar overall structure. All viruses have two basic parts: An outer coat of made of protein- protection and ID An inner core of genetic material- code for reproduction Label the two parts below: • • • The protein coat plays an important role in the virus invasion process: The protein coat is unique to each virus. Depending on the shape of the proteins in the coat, that determines what type of host cell it will attach to and invade. It is kind of like a lock and key: only one fits: = The proteins on the host cell surface = The proteins in the virus coat 1) Why are viruses considered non-living? 3 2) What is one way viruses are LIKE other living things? 6 3) Describe the relationship between a host and a parasite. 9 4) How are viruses like parasites that harm? 12 5) List the four ways viruses are named. 3 6) List the four shapes of viruses. 6 7) What are viruses measured in? 9 8) Which is the largest? 12 a) a eukaryotic cell b) a prokaryotic cell (bacterial cell) c) a virus 9) Give the two basic structures of a virus and the functions of each. 3 10) List three examples of viruses. 6 • • • • • 1) 2) How Viruses Multiply After a virus attaches to its host, it enters inside. Once inside the virus takes over the cell’s functions. The genetic material directs the cell to produce the virus’s genetic material and protein instead of the cell’s genetic material and protein. After the instructions are switched to the virus’s, new viruses are assembled. There are two types of ways in which this process takes place: Active Viruses (Lytic Infection) - Active viruses act immediately and destroy the host cell quickly. Hidden Viruses (Lysogenic Infection) - Hidden viruses are inactive for long periods of time before they destroy the host cell. Active Viruses: Lytic Cycle 1 5 2 4 3 1) 2) 3) 4) 5) Steps of Active Viruses: Lytic Cycle The virus attaches to the surface of the host cell. The virus injects its genetic material into the host cell. The virus’s genetic material takes over the host cell and the starts to produce virus parts. The virus parts assemble into new viruses and fill the host cell. The host cell bursts open and releases new viruses that can go and infect new cells. Hidden Viruses: Lysogenic Cycle 1 6 2 5 3 4 1) 2) 3) 4) 5) 6) Steps of Hidden Viruses: Lysogenic Cycle The virus attaches to the surface of the host cell. The virus injects its genetic material into the host cell. The virus’s genetic material becomes part of the genetic material of the host. After time, the virus’s genetic material removes itself and becomes active. The cell produces virus parts that assemble into new viruses. The new viruses fill the host and burst out. Viral Diseases • Some viral diseases are mild and don’t last long- like the flu. • Some viral diseases can cause death- like HIV/AIDS • Viral diseases are spread in the same ways bacterial diseases are spread. Examples of Viral Diseases: - AIDS - Chicken Pox - Measles - Polio - Rabies • There are no medications that cure viral diseases, just some that help control symptoms. • The best treatment is rest, eating healthy, and drinking water. Preventing Infectious Diseases • One important way to prevent the spread of infectious disease is a vaccine- a substance that stimulates the body to produce chemicals that destroy viruses and bacteria. Q: How are vaccines made and given? A: Vaccines are made from dead or weakened bacteria or viruses. Then they are usually injected into the body to “activate” the body’s immune system. • So when you are given a vaccine, your body goes “on alert.” If a strong virus or bacteria happens to enter your body, your immune system will hopefully destroy it before it causes symptoms. Common Vaccines: tetanus, pertussis, measles, mumps, polio.