2.2 Prokaryotic Cells �
Please use your text to complete the handout on the Prokaryotic cell outcomes
2.2 PROKARYOTIC CELLS 2.3 EUKARYOTIC CELLS AND MICROSCOPE ANATOMY! IB Bio SL
2.3 Eukaryotic Cells �
Please use your text to complete the worksheet on the Eukaryotic Cell outcomes
What is a Prokaryotic Cell? �
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The beginning of life �
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Prokaryotic cells are thought to be the first to have appeared on earth. Prokaryotic cells still play a large role in the world today. Bacteria is a good example.
Are cells that lack membrane bound organelles or any type of cells nucleus. They are cells that are much smaller and simpler than Eukaryotic cells. In fact most Prokaryotic cells are less than one micrometre in diameter!
Features of Prokaryotic Cells �
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The features of the Prokaryotic cell that you will have to identify are: Cell wall Plasma membrane Pili &Flagella Ribosomes Nucleoid
Cell wall � �
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Plasma membrane
Protects and maintains the shape of the cell. In most prokaryotes the cell wall is composed of a carbohydrate-protein complex called peptidoglycan. Some bacteria have an additional layer outside the cell wall that allows them to stick to teeth, skin and food.
Pili � � �
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Are hair-like growths on the outside of the cell wall. They are used for attachment. Their main function is in joining bacteria cells in preparation for the transfer of DNA. (sexual reproduction)
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Function as the sites of protein synthesis. Ribosomes typically occur in very large numbers in cells with high protein production. The ribosomes in prokaryotic are small (70s)
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Controls the movement of materials into and out of the cell. It also plays a role in binary fission (stay tuned)
Flagella
Ribosomes �
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Are hair-like growths (longer than pili) that are used for cell motility.
Nucleoid Region �
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cells
Because bacteria cells are non-compartmentalized and contain a single, long, continuous, circular thread of DNA... This region is involved in the control of the cell as well as reproduction.
Binary Fission �
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Is the simple process by which prokaryotic cells divide. The circular DNA is copied Two daughter chromosomes become attached to different regions on the plasma memberane. The cells divide into two genetically identical daughter cells. The process includes; elongating of the cell, and partitioning of the newly produced DNA.
Endosymbiotic Theory �
Binary Fission
http://learn.genetics.utah.edu/content/begin/cells/ organelles/
Global Connections... � � �
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Prokaryotes and clean water resources Lifesaver bottle with Michael Pritchard http://www.ted.com/talks/lang/eng/michael_pritc hard_invents_a_water_filter.html
We’ll revisit this idea in the evolution unit!
2.3 Eukaryotic Cells
What do you need to know? �
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Draw a diagram of a liver cell including... Free ribosomes rough endoplasmic reticulum lysosome Golgi apparatus
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mitochondrion nucleus
Free Ribosomes �
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very small structures (about 80S) that carry out protein synthesis in the cell. Free ribosomes are found floating in the cytoplasm and others are found attached to the rough ER. Ribosomes are composed of RNA and protein and are larger in eukaryotic cells than prokaryotic cells. Eukaryotic ribosomes are composed of two subunits.
The advantage of having ribosomes attached to ER is that as the ribosomes synthesize proteins they can be transported by the ER to become parts of cell membranes, enzymes for the cell or messengers between cells. The smooth ER has many functions such as production of membrane phospholipids, production of sex hormones, breaks down harmful substances, stores calcium ions, transports lipid based compounds, and aid liver cells in releasing glucose into the blood when needed.
Endoplasmic reticulum �
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an extensive network of channels that stretches from the nucleus to the plasma membrane. Its function is to transport materials through the cell. There are two types of ER, rough ER and smooth ER. The rough ER is distinguished by the ribosomes attached to its exterior surface.
Lysosome �
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single membrane bound organelles produced by the Golgi apparatus that contain strong hydrolytic enzymes which break down biological molecules. They can contain up to 40 different enzymes and can also break down worn out cell parts that are no longer functioning properly. Lysosomes are involved in breaking down materials brought into a cell via phagocytosis.
Golgi apparatus �
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this organelle is composed of many flattened sacs called cisternae which are stacked on top of each other and it is normally located between the ER and plasma membrane. The Golgi apparatus collects, packages, modifies and distributes materials throughout the cell. It is located close to the ER to receive products transported by the ER and close to the plasma membrane so it can discharge materials needed outside the cell. This organelle is found in high numbers in cell that produce and secrete substances (i.e. pancreas cells).
Mitochondrion �
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very large, double membrane bound rod-shaped organelles that are found scattered in the cytoplasm and contain their own DNA. Their outer membrane is smooth while their inner membrane is highly folded into cristae which increase the surface area of the inner mitochondria for cellular respiration, the main function of the mitochondria.
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Due to its size and ability to produce energy in the form of ATP, mitochondria also have their own ribosomes. Mitochondria are found in high numbers in cells that have high energy needs (i.e. muscle cells).
Nucleus �
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eukaryotic DNA is housed inside the double membrane or nuclear envelop of the nucleus. The double membrane allows the DNA to remain separate from the rest of the cell and carry out its functions without interference from the other parts of the cell. The nuclear membrane contains pores that allows for communication with the rest of the cell.
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DNA is contained in the form of chromosomes within the nucleus. The nucleus is normally located in the center of the eukaryotic cell but is often pushed to the side in plant cells due to the large vacuole. Most cells have one nuclei but some have multiple nuclei while others have none (i.e. red blood cells). If there is no nucleus the cell cannot reproduce. Most nuclei often have a nucleolus a dark area inside the nucleus where ribosomes are manufactured.
See inside a cell! �
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http://learn.genetics.utah.edu/content/begin/cells/ insideacell/ http://www.cellsalive.com/cells/3dcell.htm
Comparison between prokaryotic and eukaryotic cells Feature Genetic material
Location of genetic material
PROKARYOTIC CELLS
Feature
Located inside the double membrane of the nucleus; sometimes referred to as the nuclear envelop.
PROKARYOTIC CELLS
EUKARYOTIC CELLS
Mitochondria
Prokaryotes do not contain Eukaryotic cells all contain mitochondria. The surface of hundreds of mitochondria. the cell membrane and the mesosome are used to produce cellular energy.
Ribosomes
Ribosomes are smaller in prokaryote cells. (70S)
Ribosomes are larger in eukaryote cells. (80S)
Membrane bound organelles or internal membranes
Few or none are present.
Eukaryotic cells contain several membrane bound organelles such as ER, Golgi apparatus and lysosomes.
Size
Measure less than 10 micrometers.
Measure more than 10 micrometers.
EUKARYOTIC CELLS
Contain a naked loop of Contain four or more chromosomes DNA. Sometimes referred to as consisting of strands of DNA a nucleoid. associated with protein.
Naked DNA found in region of the cytoplasm called nucleoid.
Cont’d
Difference between plant and animal cells FEATURE
ANIMAL CELL
PLANT CELL
Cell wall
No cell wall. Cells have a plasma membrane only.
Contains a cell wall with a plasma membrane just inside.
Chloroplasts
Not found in animal cells.
All plants that carry out photosynthesis contain chloroplasts.
Carbohydrate storage
Animal cells store carbohydrates in the form of glycogen.
Plant cells store carbohydrates in the form of starch.
Cont’d
Extracellular components
FEATURE
ANIMAL CELL
PLANT CELL
Vacuole
Not normally present in animal cells. Some small vesicles are sometimes formed.
Plant cells contain one large central fluid filled vacuole.
Shape
Centrioles
Usually a rounded shape but the Plant cells have a fixed shape plasma membrane is flexible and due to the cell wall. Often boxcan change shape. like or angular in shape. Contains centrioles within a centrosome area.
Do not contain centrioles within a centrosome area.
The Cell Wall �
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The cell wall is composed of cellulose microfibrils which form a thick wall surrounding the entire cell. The cell wall grows with the cell, continually adding more cellulose to maintain its thickness. The cell wall protects the plant cell and helps to maintain its shape. The cell wall also protects the cell from too much water entering and helps the cell maintain osmotic balance. Since it is made of cellulose, the plant cell can use the cell wall to store carbohydrates.
Extracellular matrix of animal cells �
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The extracellular matrix of animal cells is composed of glycoproteins and collagen fibres. Together they form a fibre-like structure that anchors the matrix to the plasma membrane. The ECM adds strength to the plasma membrane, allows cell to cell interactions, and allows adjacent cells to attach to one another Cartilage is made of cells with a lot of extracellular material which gives cartilage its firm, resilient structure
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Extracellular components are structures outside the plasma membranes of cells. One commonly known example is the cell wall in plant cells. Another example of an extracellular component is the extracellular matrix of animal cells as well as bone and cartilage.
The Parts of a Light Microscope
Light Microscopes • The ocular lens in the eyepiece magnifies and transmits the image to your eye
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Light source: Could be a mirror, but most likely it is a bulb built into the base
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Diaphragm: Adjusts the amount of light striking an object
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Objective lens: Gathers light and magnifies image
• The magnification of the ocular lens is 10X •
• To find the total magnification of the microscope you are using, multiply the magnification of the objective lens by the magnification of the ocular lens.
Ocular lens (eyepiece): Magnifies objects and focuses light to your eye
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Stage: Holds slide
• For example: 40X (objective lense) x 10X (ocular lense) = 400X magnification
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Stage clips: Hold slide in place
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Base and arm: Structural support for the microscope
Can you name the parts? Start on the left side and work from the top down. Then go to the right side and work from the top down.
– Can be moved using the coarse or fine adjustment knobs to bring the object into focus
Images Produced by Light Microscopes
Ocular lens (eyepiece)
Arm
Objective Lenses
Stage clip Stage
Amoeba
Streptococcus bacteria
Anthrax bacteria
Human cheek cells
Plant cells
Yeast cells
Course adjustment
Diaphragm
Fine adjustment
Light Source
Base
Nice Job !
Fun in the lab! � �
Cells that you eat! Yumm! You will examine several plant and animal cells under the light microscope – super-fun!
