![BIO508: Cell Biology, Trimester III, 2016 Assignment Topics for](http://s1.studyres.com/store/data/020244885_1-57375f8acad72a5811be7faf25aeb737-300x300.png)
BIO508: Cell Biology, Trimester III, 2016 Assignment Topics for
... Assignment Topics for Students 1. The 2016 Nobel Prize in Physiology or Medicine to Prof. Yoshinori Ohsumi for his discoveries of mechanisms for autophagy. 2. Different types of cancer in Fiji: Factors concerning for emerging cancer in Fiji. 3. Principles of Electron Microscopy: Contribution in Cell ...
... Assignment Topics for Students 1. The 2016 Nobel Prize in Physiology or Medicine to Prof. Yoshinori Ohsumi for his discoveries of mechanisms for autophagy. 2. Different types of cancer in Fiji: Factors concerning for emerging cancer in Fiji. 3. Principles of Electron Microscopy: Contribution in Cell ...
Analytical Approaches in Cell Biology
... “Make everything as simple as possible, but not simpler” -Albert Einstein 1. Separation of cell components 2. Cell culture, fusion and hybridomas ...
... “Make everything as simple as possible, but not simpler” -Albert Einstein 1. Separation of cell components 2. Cell culture, fusion and hybridomas ...
Note taking guide
... Membrane-bound sac found in plant and animal cells that’s used for storage. It has a variety of functions, including playing a role in intracellular digestion and the release of cell waste. A plant cell has single large central vacuole; animal cells have varying numbers and sizes. ...
... Membrane-bound sac found in plant and animal cells that’s used for storage. It has a variety of functions, including playing a role in intracellular digestion and the release of cell waste. A plant cell has single large central vacuole; animal cells have varying numbers and sizes. ...
Study Guide for Cell Structure, Function, and Division
... e. Bulk Movement 8. Will a cell surrounded by pure water shrink or blow up? 9. What is the cell membrane made up of? 10. Why do cells divide? 11. What is the surface to volume ratio of a cube 5 mm on each side? 12. What is the longest phase of the cell cycle? 13. Define the phases of interphase: ...
... e. Bulk Movement 8. Will a cell surrounded by pure water shrink or blow up? 9. What is the cell membrane made up of? 10. Why do cells divide? 11. What is the surface to volume ratio of a cube 5 mm on each side? 12. What is the longest phase of the cell cycle? 13. Define the phases of interphase: ...
Eukaryotic cells Section review model answers Ribosomes are
... large vacuoles instead), which animal cells do have. 5. Ribosomes are the organelles where proteins are made. All cells need protein in order to live. 6. Mitochondria are organelles that produce most of a cell’s energy. If its mitochondria were destroyed, a cell would eventually die because it would ...
... large vacuoles instead), which animal cells do have. 5. Ribosomes are the organelles where proteins are made. All cells need protein in order to live. 6. Mitochondria are organelles that produce most of a cell’s energy. If its mitochondria were destroyed, a cell would eventually die because it would ...
WHAT LIMITS CELL SIZE
... DIFFUSION: Diffusion is a fast and efficient process over short distances, however becomes slow and inefficient as distance increases Ex: mitochondria at center of very large cell – can’t get necessary nutrients from diffusion ...
... DIFFUSION: Diffusion is a fast and efficient process over short distances, however becomes slow and inefficient as distance increases Ex: mitochondria at center of very large cell – can’t get necessary nutrients from diffusion ...
Cellular Functions
... 1. They move material into cells. 2. They move material into and out of the central vacuole. 3. The cell membrane surrounds material that needs to be transported. 4. They move material out of cells ...
... 1. They move material into cells. 2. They move material into and out of the central vacuole. 3. The cell membrane surrounds material that needs to be transported. 4. They move material out of cells ...
Northeast High School GHSGT Junior Academy
... Number of hydroxide ions in solution is greater than water NaOH Na+ + OH- ...
... Number of hydroxide ions in solution is greater than water NaOH Na+ + OH- ...
Eukaryotic Cell Structure
... Nuclear Envelope Separates the nucleus from the cytoplasm. Double membrane. Made up of two phospholipid bilayers containing small nuclear pores for substances to pass through. ...
... Nuclear Envelope Separates the nucleus from the cytoplasm. Double membrane. Made up of two phospholipid bilayers containing small nuclear pores for substances to pass through. ...
Cellular Biology Crossword
... organelles called ribosomes to produce proteins from amino acids. 14 - Protein packaging plant -Sends vesicles of macromolecules to destination in cell. 15 - Processes whereby certain organisms obtain energy from organic molecules. 16 - These cells contain a high concentration of solute relative to ...
... organelles called ribosomes to produce proteins from amino acids. 14 - Protein packaging plant -Sends vesicles of macromolecules to destination in cell. 15 - Processes whereby certain organisms obtain energy from organic molecules. 16 - These cells contain a high concentration of solute relative to ...
CELLS The cell is the basic unit of life. All living organisms are
... The cell is the basic unit of life. All living organisms are composed of cells and their products. Under a microscope, the human body is seen to be composed of many different cells; muscle cells, brain cells, liver cells - all of which are quite dissimilar. Yet the differences, while important, shou ...
... The cell is the basic unit of life. All living organisms are composed of cells and their products. Under a microscope, the human body is seen to be composed of many different cells; muscle cells, brain cells, liver cells - all of which are quite dissimilar. Yet the differences, while important, shou ...
Direction of Osmosis
... when they are not soluble in lipids or are too large (e.g. glucose) to pass through pores in membrane • A molecule binds to a carrier protein on one side of the cell membrane. • Carrier Protein • specific for one type of molecule • changes its shape and transports the molecule ...
... when they are not soluble in lipids or are too large (e.g. glucose) to pass through pores in membrane • A molecule binds to a carrier protein on one side of the cell membrane. • Carrier Protein • specific for one type of molecule • changes its shape and transports the molecule ...
ZOOMING DOWN THE TREE OF LIFE TO LIFE`S BUILDING BLOCKS
... You have found carbohydrates in maple syrup, in the tree trunk, and in green leaves. What do they all have in common? What makes them similar and what makes them different from the other groups of macromolecules in a living cell? ...
... You have found carbohydrates in maple syrup, in the tree trunk, and in green leaves. What do they all have in common? What makes them similar and what makes them different from the other groups of macromolecules in a living cell? ...
7.3 Structures and Organelles
... acids together to make proteins · can be free or attached to ER · ROLE: manufactures proteins ...
... acids together to make proteins · can be free or attached to ER · ROLE: manufactures proteins ...
Chapter 7 Cell Structure and Function
... defect that prevents the formation of an essential enzyme that breaks down lipids These lipids build up in the body and can cause nerve damage; prognosis is not good ...
... defect that prevents the formation of an essential enzyme that breaks down lipids These lipids build up in the body and can cause nerve damage; prognosis is not good ...
membranes
... The fluid mosaic model of cell membrane structure You have 15 seconds to remember as much as possible! ...
... The fluid mosaic model of cell membrane structure You have 15 seconds to remember as much as possible! ...
Scientists, Cell Theory and Prokaryote vs. Eukaryote
... 2. All living things are made of cells. ...
... 2. All living things are made of cells. ...
Scientists, Cell Theory and Prokaryote vs. Eukaryote
... 2. All living things are made of cells. ...
... 2. All living things are made of cells. ...
Cell Parts
... Phospholipid bilayer acts like a fluid The lipids and proteins can move laterally within the bilayer Mosaic- pattern is constantly changing ...
... Phospholipid bilayer acts like a fluid The lipids and proteins can move laterally within the bilayer Mosaic- pattern is constantly changing ...
Scientists, Cell Theory and Prokaryote vs. Eukaryote
... 2. All living things are made of cells. ...
... 2. All living things are made of cells. ...
File
... Explain how each organelle contributes to a cell’s function. Draw a diagram of a cell and label each part. The drawing of each organelle should reflect what it actually looks like as best as possible. ...
... Explain how each organelle contributes to a cell’s function. Draw a diagram of a cell and label each part. The drawing of each organelle should reflect what it actually looks like as best as possible. ...
Cell Theory
... • Cytoplasm (cell interior) – Plasma substance that fills up the ‘space’ around cell organelles ...
... • Cytoplasm (cell interior) – Plasma substance that fills up the ‘space’ around cell organelles ...
Cytosol
![](https://en.wikipedia.org/wiki/Special:FilePath/Crowded_cytosol.png?width=300)
The cytosol or intracellular fluid (ICF) or cytoplasmic matrix is the liquid found inside cells. It is separated into compartments by membranes. For example, the mitochondrial matrix separates the mitochondrion into many compartments.In the eukaryotic cell, the cytosol is within the cell membrane and is part of the cytoplasm, which also comprises the mitochondria, plastids, and other organelles (but not their internal fluids and structures); the cell nucleus is separate. In prokaryotes, most of the chemical reactions of metabolism take place in the cytosol, while a few take place in membranes or in the periplasmic space. In eukaryotes, while many metabolic pathways still occur in the cytosol, others are contained within organelles.The cytosol is a complex mixture of substances dissolved in water. Although water forms the large majority of the cytosol, its structure and properties within cells is not well understood. The concentrations of ions such as sodium and potassium are different in the cytosol than in the extracellular fluid; these differences in ion levels are important in processes such as osmoregulation, cell signaling, and the generation of action potentials in excitable cells such as endocrine, nerve and muscle cells. The cytosol also contains large amounts of macromolecules, which can alter how molecules behave, through macromolecular crowding.Although it was once thought to be a simple solution of molecules, the cytosol has multiple levels of organization. These include concentration gradients of small molecules such as calcium, large complexes of enzymes that act together to carry out metabolic pathways, and protein complexes such as proteasomes and carboxysomes that enclose and separate parts of the cytosol.