1. October 8

2. Dispatch 1)What is the function of the mitochondria? 2)What is the function of the chloroplast? 3)Make a Venn Diagram comparing prokaryotes, plant and animal cells Osmosis/Diffusion Pre-lab due Tuesday. Background on cell membranes, diffusion, osmosis Ecology FAQs due Wed Pick up cell model questions and attach them to your notebook

3. Endosymbiotic theory http://www.sumanasinc.com/webcontent/ani mations/content/organelles.html http://www.sumanasinc.com/webcontent/ani mations/content/organelles.html

4. Endosymbiotic Theory Mitochondria and chloroplasts were once free living prokaryotes that were engulfed by ameoba-like eukayotic cells. Evidence: 1) same size as bacteria 2) double membrane 3) presence of ribosomes 4) presence of DNA 5) reproduce on their own

5. Vacuoles membrane-bound sacs (larger than vesicles) Store substances Storage in of water, sugars, salts, pigments in plants

6. Peroxisomes Single membrane Produce hydrogen peroxide (H 2 O 2 ) in cells Metabolism of fatty acids; detoxification of alcohol (liver) Hydrogen peroxide then converted to water

7. The cytoskeleton The cytoskeleton is a network of filaments and tubules that extend from the nucleus to plasma membrane. Fibrous network in cytoplasm Support, cell motility, biochemical regulation Microtubules: thickest; tubulin protein; shape, support, transport, chromosome separation Microfilaments : thinnest; actin protein filaments; motility, cell division, shape Intermediate filaments: middle diameter; keratin; shape, nucleus anchorage

8. Actin filaments or Microfilaments Microfilaments are fine, thread-like protein fibers, 3-6 nm in diameter. They are composed predominantly of a contractile protein called actin. Microfilaments' association with the protein myosin is responsible for muscle contraction. Microfilaments can also carry out cellular movements including gliding, contraction, binding proteins, and cytokinesis. They interact with motor molecules, which are proteins that can attach, detach, and reattach along an actin filament.

9. Intermediate filaments Intermediate Filaments Intermediate filaments are about 10 nm diameter and provide tensile strength for the cell. They are ropelike assembly of fibrous protein. Some support nuclear envelop, plasma membrane, in skin cells

10. Microtubules Microtubules are cylindrical tubes, 20-25 nm in diameter. They are composed of subunits of the protein tubulin--these subunits are termed alpha and beta. Microtubules act as a scaffold to determine cell shape, and provide a set of "tracks" for cell organelles and vesicles to move on. Microtubules also form the spindle fibers for separating chromosomes during mitosis. When arranged in geometric patterns inside flagella and cilia, they are used for locomotion.

11. Centrioles The centrosome, also called the "microtubule organizing center", is an area in the cell where microtubles are produced. Within an animal cell centrosome there is a pair of small organelles, the centrioles, each made up of a ring of nine groups of microtubules. There are three fused microtubules in each group. The two centrioles are arranged such that one is perpendicular to the other. During animal cell division, the centrosome divides and the centrioles replicate (make new copies). The result is two centrosomes, each with its own pair of centrioles. The two centrosomes move to opposite ends of the nucleus, and from each centrosome, microtubules grow into a "spindle" which is responsible for separating replicated chromosomes into the two daughter cells.

12. Cilia and flagella, external movement Cellular movement is accomplished by cilia and flagella. Cilia are hair-like structures that can beat in synchrony causing the movement of unicellular paramaecium. Cilia are also found in specialize linings in eukaryotes. For example, cilia sweep fluids past stationary cells in the lining of trachea and tubes of female oviduct. Flagella are whip-like appendages that undulate to move cells. They are longer than cilia, but have similar internal structures made of microtubules. Prokaryotic and eukaryotic flagella differ greatly. Both flagella and cilia have a 9 + 2 arrangement of microtubules. This arrangement refers to the 9 fused pairs of microtubules on the outside of a cylinder, and the 2 unfused microtubules in the center. Dynein "arms" attached to the microtubules serve as the molecular motors. Defective dynein arms cause male infertility and also lead to respiratory tract and sinus problems.

13. Cytoskeleton questions Which component of the cytoskeleton is most important in: 1)holding the nucleus in place within the cell 2) Guiding transport vesicles from the Golgi to the plasma membrane 3) contracting muscle cells

14. Ribosomes Ribosomes: Are found in prokaryotes and eukaryotes Are where protein manufacturing occurs Are composed of 2 subunits (large + small) Receive RNA from the nucleus Types of ribosomes: 1) Free cytosol; protein function in cell 2) Bound endoplasmic reticulum; membranes, organelles, and export

15. Endomembrane system: includes nuclear envelope, ER, Golgi, and vesicles Starts in ER Endoplasmic reticulum (ER) is made of flattened vessicles. Rough ER with ribosomes is connected to the nuclear envelop metabolism of carbohydrates synthesis of secretory proteins (glycoproteins), membrane production Smooth ER is connected to rough ER no ribosomes synthesis of lipids, detoxification of drugs and poisons

16. Endomembrane system, from ER to Golgi Golgi apparatus Looks like a stack of pancakes In animal cells, 1 side of the pancake is directed towards the ER and the other to the plasma membrane. WHY?? In the Gogi, ER products are modified, stored, and then shipped Trans face (shipping) & Cis face (receiving) Cisternae: flattened membranous sacs The Golgi packages its products in transport vesicles that depart at the outer face.

17. The Story of Protein Production

18. DNARNA Golgi Apparatus Nucleus RibosomesER Outside the Cell The DNA holds all the genetic information. But there’s a problem. The DNA can’t leave the nucleus. This information gives us our traits, such as eye color, hair type and skin tone. To get the genetic information out to the cell, DNA makes a copy of itself.

19. DNARNA ER Golgi Apparatus Nucleus Ribosomes Outside the Cell Unlike DNA, this copy (called RNA) CAN leave the nucleus. The RNA leaves the nucleus and travels to one of the many ribosomes. At the ribosome, the RNA is translated into protein. In this case it is the protein that gives us our skin tone.

20. DNA Golgi Apparatus Nucleus RibosomesER Outside the Cell This newly made protein is not quite done yet. It must be modified. The ER modifies the protein by making a few additions to it. The protein is almost done. It is packaged into a bubble called a transport vesicle. Then it shipped to the Golgi apparatus. At the Golgi, some last modifications are made. Then it is shipped to the cell membrane where it will be secreted from the cell. This skin protein will travel to a skin cell to give the skin cell color.

22. Protein Presentations 1)With your partner, practice moving the cards and saying the script 2) You will be called randomly to present