front 1 Explain the difference between magnification and resolution | back 1 Magnification is the degree to which the size of an image is larger
than the image itself. |
front 2 Explain the need for staining samples for use in light microscopy and electron microscopy | back 2 A lot of biological material inside a cell isn't coloured, so it
might be difficult to distinguish between different |
front 3 Describe the major steps of cell fractionation and explain why it is a useful technique. | back 3 The major steps of cell fractionation are homogenization and differential centrifugation. It is a useful technique because it enables researchers to prepare specific cell components in bulk and identify their functions. |
front 4 Distinguish between prokaryotic and eukaryotic cells. | back 4 In a prokaryotic cell, the DNA is concentrated in the nucleoid
without a membrane separating it from the rest of the cell. |
front 5 Explain why there are both upper and lower limits to cell size. | back 5 A cell can get too small to contain all the components necessary for
life. |
front 6 Explain the advantages of compartmentalization in eukaryotic cells. | back 6 Different cell organelles perform different functions, many of which require specialized components for specific targets. Compartmentalization creates appropriate microenvironments for these diverse processes, allows damage limitation, minimizes non-specific interactions and consequently increased cellular efficiency. |
front 7 Briefly explain how the nucleus controls protein synthesis in the cytoplasm. | back 7 The nucleus directs protein synthesis by synthesizing messenger RNA (mRNA) according to instructions provided by the DNA. The mRNA is then transported to the cytoplasm via the nuclear pores. Once an mRNA molecule reaches the cytoplasm, ribosomes translate the mRNA's genetic message into the primary structure of a specific polypeptide |
front 8 Explain how the nucleolus contributes to protein synthesis. | back 8 It creates ribsomal RNA which creates ribosomes in the cell and ribosomes create proteins. |
front 9 Distinguish between free and bound ribosomes in terms of location and function. | back 9 Free ribosomes are in the cytosol and bound ribosomes are stuck to the outside of the ER or nuclear envelope |
front 10 List the components of the endomembrane system, and describe the structure and functions of each component. | back 10 The ER, the Gogli apparatus, lysosomes and vacuoles.ER: consists of cisternae, functions as a seperator of the internal compartment of the ER lumen. Golgi apparatus: consists of flattened cisternae, functions by modifying ER and storing it then sending to different destinations. Lysosomes: membranous sac of hydrolytic enzymes, functions in animals to digest macromolecules. Vacuoles: membrane bound vesicles, functions as maintenance in cell compartments. |
front 11 Describe three examples of intracellular digestion by lysosomes. | back 11 Phagocytosis is when smaller organisms or other food particles are eaten. Autophagy is when a damaged organelle or small amout of cytosol becomes surrounded by a double membrane and a lysosome fuses with the outer membrane of the visicle. Enzymes break down the material. Food vacuoles fuse with a lysosome, whose enzymes digest the food. |
front 12 Name three different kinds of vacuoles, giving the function of each kind. | back 12 1. Contractile vacuole: pumps excess water out. 2. Central vacuole:helps maintain plants' shape and structure by storing water. 3. Food vacuole: storage for molecules that is a food source for the cell (phagocytosis). |
front 13 Name the intercellular junctions found in plant (1) and animal (3) cells and list the function of each type of junction. | back 13 Plants: plasmodesmata- allow cells to share materials. Animals: (1) Tight Junctions:binds cells together. (2) Desmosomes: fasten cells together into strong sheets(anchoring junctions) (3) Gap Junctions: communicating junctions. |
front 14 Explain how the extracellular matrix may act to integrate changes inside and outside the cell. | back 14 The ecm is made up of a network of proteoglycans. |
front 15 Explain how the ultrastructure of cilia and flagella relates to their functions. | back 15 THE ULTRASTRUCTURE IS MADE UP OF DYNEINS, WHICH ARE LIKE "FEET" AND ENABLE THE CILIA AND FLAGELLA TO "WALK", WHICH CONTRIBUTES TO THEIR SPECIALIZED MOVEMENT. |
front 16 Describe the functions of the cytoskeleton. | back 16 A cytoskeleton acts as a framework that gives the cell it's shape and protects it to a certain degree. It also enables cellular motion. |
front 17 Explain the roles of peroxisomes in eukaryotic cells. | back 17 PEROXISOMES = |
front 18 Describe the structure of a mitochondrion. | back 18 a mitochondrion contains outer and inner membranes composed of phospholipid bilayers and proteins.[5] the two membranes, however, have different properties. because of this double-membraned organization, there are five distinct compartments within the mitochondrion. there is the outer mitochondrial membrane, the intermembrane space (the space between the outer and inner membranes), the inner mitochondrial membrane, the cristae space (formed by infoldings of the inner membrane), and the matrix (space within the inner membrane). |
front 19 Describe the structure of a chloroplast | back 19 CHLOROPLASTS ARE THE SITES OF PHOTOSYNTHESIS. THESE DOUBLE-MEMBRANE BOUND ORGANELLES ENCLOSE ADDITIONAL MEMBRANES CALLED THYLAKOIDS. THE DISC-SHAPED THYLAKOIDS POSSESS AN INTERIOR SPACE. THE THYLAKOIDS ARE STACKED TO FORM GRANA, WHICH ARE SUSPENDED IN THE STROMA OF THE CHLOROPLASTS. DEMONSTRATE YOUR KNOWLEDGE OF CHLOROPLAST STRUCTURE BY PLACING THE LABELS IN THEIR CORRECT LOCATIONS. |
front 20 Describe the structure and function of the nuclear envelope, including the role of the pore complex. | back 20 THE NUCLEAR ENVELOPE IS A DOUBLE MEMBRANE PERFORATED BY PORES. THE PORE COMPLEX LINES EACH PORE, REGULATING THE PASSAGE OF CERTAIN LARGE MACROMOLECULES AND PARTICLES. |
front 21 Compare the structure and functions of smooth and rough ER. | back 21 smooth er = smooth surface, synthesis of lipids, metabolism of carbohydrates, calcium storage, detoxification of drugs and poisons. rough er = has ribosomes attached to its surface, and aids in synthesis of secretory and other proteins from bound ribosomes; adds carbohydrates to glycoproteins; produces new membrane. |
front 22 Briefly describe the energy conversions carried out by mitochondria and chloroplasts. | back 22 MITOCHONDRIA = CELLULAR RESPIRATION = GENERATE ATP BY EXTRACTING ENERGY FROM SUGARS, FATS, AND OTHER FUELS WITH THE HELP OF OXYGEN. CHLOROPLASTS = PHOTOSYNTHESIS = CONVERT SOLAR ENERGY TO CHEMICAL ENERGY AND SYNTHESIZE NEW ORGANIC COMPOUNDS SUCH AS SUGAR FROM CO2 AND H2O. |
front 23 Describe the structure of a mitochondrion. | back 23 a mitochondrion contains outer and inner membranes composed of phospholipid bilayers and proteins.[5] the two membranes, however, have different properties. because of this double-membraned organization, there are five distinct compartments within the mitochondrion. there is the outer mitochondrial membrane, the intermembrane space (the space between the outer and inner membranes), the inner mitochondrial membrane, the cristae space (formed by infoldings of the inner membrane), and the matrix (space within the inner membrane). |
front 24 Describe the structure of a chloroplast | back 24 CHLOROPLASTS ARE THE SITES OF PHOTOSYNTHESIS. THESE DOUBLE-MEMBRANE BOUND ORGANELLES ENCLOSE ADDITIONAL MEMBRANES CALLED THYLAKOIDS. THE DISC-SHAPED THYLAKOIDS POSSESS AN INTERIOR SPACE. THE THYLAKOIDS ARE STACKED TO FORM GRANA, WHICH ARE SUSPENDED IN THE STROMA OF THE CHLOROPLASTS. DEMONSTRATE YOUR KNOWLEDGE OF CHLOROPLAST STRUCTURE BY PLACING THE LABELS IN THEIR CORRECT LOCATIONS. |