III - Humble ISD
... “Cell postmaster”; Receives transport vesicles from ER; modifies, stores, and ships products. The “receiving side” is known as the cis face; shipping side is known as the trans face. Suspended in cytosol or found on rough ER; site of protein production in a cell ...
... “Cell postmaster”; Receives transport vesicles from ER; modifies, stores, and ships products. The “receiving side” is known as the cis face; shipping side is known as the trans face. Suspended in cytosol or found on rough ER; site of protein production in a cell ...
CELLS UNIT 1 Learning Targets - Milton
... Draw/create a bacteria, plant, and animal cell and place the appropriate organelles in each cell type. Name the four cell structures in common to all cell types. Describe Anton Van Leeuwen hoek’s contribution to cellular biology. List the three principles of the cell theory. Describe the function of ...
... Draw/create a bacteria, plant, and animal cell and place the appropriate organelles in each cell type. Name the four cell structures in common to all cell types. Describe Anton Van Leeuwen hoek’s contribution to cellular biology. List the three principles of the cell theory. Describe the function of ...
Cell Analogies Poster Project – BIO II
... Cell Analogies Poster Project – BIO II Purpose: For this project you will be challenged to make 15 original and appropriate functional analogies between cell structures and everyday objects. What is an analogy? “A comparison between two things which are similar in some respects, but otherwise are di ...
... Cell Analogies Poster Project – BIO II Purpose: For this project you will be challenged to make 15 original and appropriate functional analogies between cell structures and everyday objects. What is an analogy? “A comparison between two things which are similar in some respects, but otherwise are di ...
Cell basics & structure
... Structure = Flattened pancake-like layers a) Uses Vesicles to move things ...
... Structure = Flattened pancake-like layers a) Uses Vesicles to move things ...
The Cell Theory
... atoms --> DNA --> virus --> bacteria -->mitochondria--> Eukaryotic cells Cells must remain small in size due to the ratio of surface area and volume As the cell increases in size, its surface area becomes too small to support its internal structures. Oxygen and other important substances cannot diff ...
... atoms --> DNA --> virus --> bacteria -->mitochondria--> Eukaryotic cells Cells must remain small in size due to the ratio of surface area and volume As the cell increases in size, its surface area becomes too small to support its internal structures. Oxygen and other important substances cannot diff ...
Finding your way around the animal cell
... 8. Ribosomes: molecular machines, built from ribosomal RNA (rRNA) and protein, that make new proteins from mRNA through a process called translation. They are found as ‘free ribosomes’ in the cytoplasm and bound to the rough endoplasmic reticulum. 9. Golgi apparatus: one of the wondrously complex me ...
... 8. Ribosomes: molecular machines, built from ribosomal RNA (rRNA) and protein, that make new proteins from mRNA through a process called translation. They are found as ‘free ribosomes’ in the cytoplasm and bound to the rough endoplasmic reticulum. 9. Golgi apparatus: one of the wondrously complex me ...
Document
... Are involved in the production of enzymes and other proteins (protein synthesis) according to the directions of the DNA. Proteins Ribosome mRNA ...
... Are involved in the production of enzymes and other proteins (protein synthesis) according to the directions of the DNA. Proteins Ribosome mRNA ...
Details
... giant 1.5-MDa protein is produced by the Antarctic marine bacterium Marinomonas primoryensis and is composed of ~130 domains. Several domains at its N-terminal end anchor the protein to the bacterial outer membrane. Following this section are ~120 identical Ca2+-bound extender domains that project t ...
... giant 1.5-MDa protein is produced by the Antarctic marine bacterium Marinomonas primoryensis and is composed of ~130 domains. Several domains at its N-terminal end anchor the protein to the bacterial outer membrane. Following this section are ~120 identical Ca2+-bound extender domains that project t ...
8D Unicellular Organisms
... Unicellular organisms can only grow to a certain size. If the organism is too big, it cannot get enough of the substances it needs throughout the cell because diffusion is too slow. The tissues in multicellular organisms need to have raw materials transported to them because diffusion would be too s ...
... Unicellular organisms can only grow to a certain size. If the organism is too big, it cannot get enough of the substances it needs throughout the cell because diffusion is too slow. The tissues in multicellular organisms need to have raw materials transported to them because diffusion would be too s ...
Section 3.2 – Moving Cellular Materials Selectively Permeable
... Section 3.2 – Moving Cellular Materials ...
... Section 3.2 – Moving Cellular Materials ...
BY1101-AF L1
... • Eukaryotes are more structurally and func7onally complex • Eukaryotes have a membrane – bound nucleus • Eukaryotes have a diverse collec7on of organelles • Replica7on is more complex –mitosis and meoisis • Euka ...
... • Eukaryotes are more structurally and func7onally complex • Eukaryotes have a membrane – bound nucleus • Eukaryotes have a diverse collec7on of organelles • Replica7on is more complex –mitosis and meoisis • Euka ...
Cell Test Review - Okemos Public Schools
... Under a microscope, you view a green, multicellular organism. It is not moving, has a cell wall, and not every cell is identical. What kingdom is it from? ...
... Under a microscope, you view a green, multicellular organism. It is not moving, has a cell wall, and not every cell is identical. What kingdom is it from? ...
The Cell
... Network of protein filaments that helps the cell to maintain its shape. Microtubules are hollow structures that also play an important part in cell division. In animal cells, these microtubules are called centrioles. ...
... Network of protein filaments that helps the cell to maintain its shape. Microtubules are hollow structures that also play an important part in cell division. In animal cells, these microtubules are called centrioles. ...
Plant Cells vs. Animal Cells
... • Storage tank for cell food (proteins, carbohydrates, salt, water) or waste products • filled with liquid • FUNCTION: These plant-cell vacuoles provide plants with structural support during rapid growth. • NOTE: Because animals need to move around and often have skeletal systems they would not bene ...
... • Storage tank for cell food (proteins, carbohydrates, salt, water) or waste products • filled with liquid • FUNCTION: These plant-cell vacuoles provide plants with structural support during rapid growth. • NOTE: Because animals need to move around and often have skeletal systems they would not bene ...
A Tour of the Cell
... and animal cells Describe the complex structural and functional interconnections among the organelles of the endomembrane system Describe the structure of the eukaryotic nucleus, mitochondrion and chloroplast ...
... and animal cells Describe the complex structural and functional interconnections among the organelles of the endomembrane system Describe the structure of the eukaryotic nucleus, mitochondrion and chloroplast ...
bio12_sm_02_1
... 1. The main difference between eukaryotic cells and prokaryotic cells is that eukaryotic cells have membrane-bound organelles, while prokaryotic cells do not. Membrane-bound organelles can maintain their own structure and function while simultaneously being able to integrate their function with othe ...
... 1. The main difference between eukaryotic cells and prokaryotic cells is that eukaryotic cells have membrane-bound organelles, while prokaryotic cells do not. Membrane-bound organelles can maintain their own structure and function while simultaneously being able to integrate their function with othe ...
THE EUKARYOTIC CELL
... The eukaryotic cell is surrounded by a structure called plasma membrane. The nucleus is a main organelle that contains the genetic material. It is surrounded by a nuclear envelope, a double membrane with pores. The whole nucleus (with its nuclear envelope) is surrounded by various tube- and sheet-li ...
... The eukaryotic cell is surrounded by a structure called plasma membrane. The nucleus is a main organelle that contains the genetic material. It is surrounded by a nuclear envelope, a double membrane with pores. The whole nucleus (with its nuclear envelope) is surrounded by various tube- and sheet-li ...
Bacteria PPT
... Plasmid = extra chromosome that can replicate separately from the main chromosome ...
... Plasmid = extra chromosome that can replicate separately from the main chromosome ...
Flagellum
A flagellum (/fləˈdʒɛləm/; plural: flagella) is a lash-like appendage that protrudes from the cell body of certain prokaryotic and eukaryotic cells. The word flagellum in Latin means whip. The primary role of the flagellum is locomotion but it also often has function as a sensory organelle, being sensitive to chemicals and temperatures outside the cell. Flagella are organelles defined by function rather than structure. There are large differences between different types of flagella; the prokaryotic and eukaryotic flagella differ greatly in protein composition, structure, and mechanism of propulsion. However, both are used for swimming.An example of a flagellate bacterium is the ulcer-causing Helicobacter pylori, which uses multiple flagella to propel itself through the mucus lining to reach the stomach epithelium. An example of a eukaryotic flagellate cell is the mammalian sperm cell, which uses its flagellum to propel itself through the female reproductive tract. Eukaryotic flagella are structurally identical to eukaryotic cilia, although distinctions are sometimes made according to function and/or length.