Plant & Animal Cells
... nutrients, waste and other substances. Vesicles can also be used for transporting substances in the cell. Storage rooms & Boxes!!! ...
... nutrients, waste and other substances. Vesicles can also be used for transporting substances in the cell. Storage rooms & Boxes!!! ...
cells
... of cells by diffusion. The net (overall) movement of particles is from a high concentration to a lower concentration (down a concentration gradient). The greater the difference in concentration, the faster the rate of diffusion. Example: Oxygen gas diffuses into cells through the cell membrane and i ...
... of cells by diffusion. The net (overall) movement of particles is from a high concentration to a lower concentration (down a concentration gradient). The greater the difference in concentration, the faster the rate of diffusion. Example: Oxygen gas diffuses into cells through the cell membrane and i ...
Cells - hdueck
... campus.queens.edu/faculty/jannr/cells/index.htm www.ndpteachers.org/perit/biology_image_galle... www.emc.maricopa.edu/.../BioBookAnimalTS.html types of organ tissue cells www.answers.com/topic/cell-organization ...
... campus.queens.edu/faculty/jannr/cells/index.htm www.ndpteachers.org/perit/biology_image_galle... www.emc.maricopa.edu/.../BioBookAnimalTS.html types of organ tissue cells www.answers.com/topic/cell-organization ...
CELL PART DESCRIPTION/LOCATION FUNCTION 1. Cell
... Tiny particles composed of RNA and protein attached to RER and also scattered in cytoplasm ...
... Tiny particles composed of RNA and protein attached to RER and also scattered in cytoplasm ...
Pre-AP Biology Cell Transport Worksheet
... 4. What would happen to a plant cell in each of the following solutions? a. Hypertonic: The cell would ____________________________ because the water molecules would _____________________. b. Hypotonic: The cell would _______________________________ because the water molecules would _______________ ...
... 4. What would happen to a plant cell in each of the following solutions? a. Hypertonic: The cell would ____________________________ because the water molecules would _____________________. b. Hypotonic: The cell would _______________________________ because the water molecules would _______________ ...
File
... This organelle is made of an inner and outer membrane with round shaped sacs inside. Found randomly in cell but usually near the cell membrane. It is responsible for photosynthesis. A membrane bound organelle that had DNA inside. It runs all cell activity ...
... This organelle is made of an inner and outer membrane with round shaped sacs inside. Found randomly in cell but usually near the cell membrane. It is responsible for photosynthesis. A membrane bound organelle that had DNA inside. It runs all cell activity ...
Organelles in cellular transport
... The ribosomes on the rough endoplasmic reticulum synthesize which enter the channels of the endoplasmic reticulum packaging and shipping to the Golgi bodies. They are enveloped into pockets. These pockets, vesicles, leave the ER to transport the proteins to other parts of the cell for use. ER Video ...
... The ribosomes on the rough endoplasmic reticulum synthesize which enter the channels of the endoplasmic reticulum packaging and shipping to the Golgi bodies. They are enveloped into pockets. These pockets, vesicles, leave the ER to transport the proteins to other parts of the cell for use. ER Video ...
File
... _____ 3. The energy needed to power the sodium-potassium pump is provided by the a. binding of ATP to the c. removal of a phosphate group pump. from ATP. b. transport of ATP by the pump. d. formation of ATP. _____ 4. Pinocytosis involves the transport of a. large particles out of a cell. c. whole ce ...
... _____ 3. The energy needed to power the sodium-potassium pump is provided by the a. binding of ATP to the c. removal of a phosphate group pump. from ATP. b. transport of ATP by the pump. d. formation of ATP. _____ 4. Pinocytosis involves the transport of a. large particles out of a cell. c. whole ce ...
Chloroplast
... Additional information: Plant cells normally contain another type of organelle that is not found in animals:chloroplasts. Chloroplasts convert light energy (from the sun) to chemical energy via the process of photsnthesis . The main pigment (green color) located in chloroplasts and involved in photo ...
... Additional information: Plant cells normally contain another type of organelle that is not found in animals:chloroplasts. Chloroplasts convert light energy (from the sun) to chemical energy via the process of photsnthesis . The main pigment (green color) located in chloroplasts and involved in photo ...
CELL MEMBRANES
... specific molecules to pass freely. molecules move in and out more quickly than they could through regular diffusion and is known as facilitated diffusion. ...
... specific molecules to pass freely. molecules move in and out more quickly than they could through regular diffusion and is known as facilitated diffusion. ...
Name - Triton Science
... 15. What is meant by aerobic respiration? What are the three steps of cellular respiration, how many ATP are produced in each step, and what is the molecule that first enters the cycle? ...
... 15. What is meant by aerobic respiration? What are the three steps of cellular respiration, how many ATP are produced in each step, and what is the molecule that first enters the cycle? ...
Chapter 6 Guided Notes
... Each outer doublet also has pairs of ___________________________________________________ that are responsible for the bending movements. ...
... Each outer doublet also has pairs of ___________________________________________________ that are responsible for the bending movements. ...
Actin dynamics - Journal of Cell Science
... monomer and Arp2/3 complex (shown in red), an assembly of seven subunits including two actin-related proteins. Arp2/3 complex then initiates the growth of a new actin filament as a branch on the side of an older actin filament. The branch grows rapidly at its barbed end by addition of actin-profilin ...
... monomer and Arp2/3 complex (shown in red), an assembly of seven subunits including two actin-related proteins. Arp2/3 complex then initiates the growth of a new actin filament as a branch on the side of an older actin filament. The branch grows rapidly at its barbed end by addition of actin-profilin ...
Osmosis in a Plant Cell
... Paramecium, have contractile vacuoles. These structures collect and pump out excess water that accumulates in the cell. • Explain why these organisms needs such a structure. ...
... Paramecium, have contractile vacuoles. These structures collect and pump out excess water that accumulates in the cell. • Explain why these organisms needs such a structure. ...
What`s on the Test - hrsbstaff.ednet.ns.ca
... State the 3 postulates (statements) of the Cell Theory as written by Rudolf Virchow. Give technological advances that led to the current understanding of Cell Theory. Give scientific discoveries that led to the current understanding of Cell Theory. Describe paradigm shifts that occurred during the d ...
... State the 3 postulates (statements) of the Cell Theory as written by Rudolf Virchow. Give technological advances that led to the current understanding of Cell Theory. Give scientific discoveries that led to the current understanding of Cell Theory. Describe paradigm shifts that occurred during the d ...
ppt - Faculty
... Methanogens (prokaryotes that produce methane); Extreme halophiles (prokaryotes that live at very high concentrations of salt (NaCl); Extreme (hyper) thermophiles (prokaryotes that live at very high temperatures). All archaea have features that distinguish them from Bacteria (i.e., no murein in cell ...
... Methanogens (prokaryotes that produce methane); Extreme halophiles (prokaryotes that live at very high concentrations of salt (NaCl); Extreme (hyper) thermophiles (prokaryotes that live at very high temperatures). All archaea have features that distinguish them from Bacteria (i.e., no murein in cell ...
Muscle
... Ca2+ released from the sarcoplasmic reticulum binds to Troponin C on actin filaments, which subsequently leads to the troponin complex being physically moved aside to uncover cross-bridge binding sites on the actin filament. ...
... Ca2+ released from the sarcoplasmic reticulum binds to Troponin C on actin filaments, which subsequently leads to the troponin complex being physically moved aside to uncover cross-bridge binding sites on the actin filament. ...
1-Cells-and-Organells
... ROUGH ENDOPLASMIC RETICULUM Have ribosomes attached to the surface RIBOSOMES – where ...
... ROUGH ENDOPLASMIC RETICULUM Have ribosomes attached to the surface RIBOSOMES – where ...
Chapter 9 Pre-test Answer Key 1. true 2. true 3
... 24. Fossils of single-celled prokaryotes were found in rocks that were over 3 billion years old. At that time, the atmosphere contained very little oxygen Anaerobic bacteria do not need oxygen for cellular respiration but aerobic bacteria do, therefore anaerobic bacteria must have evolved first. 25. ...
... 24. Fossils of single-celled prokaryotes were found in rocks that were over 3 billion years old. At that time, the atmosphere contained very little oxygen Anaerobic bacteria do not need oxygen for cellular respiration but aerobic bacteria do, therefore anaerobic bacteria must have evolved first. 25. ...
HB Unit 3 Homeostasis and Cell Transport
... freshwater organisms. • Cell walls in plants resist turgor pressure in hypotonic conditions. • Plasmolysis (wilting) occurs in plant cells in hypertonic conditions. • Cytolysis (bursting) occurs in animal cells in hypertonic conditions. ...
... freshwater organisms. • Cell walls in plants resist turgor pressure in hypotonic conditions. • Plasmolysis (wilting) occurs in plant cells in hypertonic conditions. • Cytolysis (bursting) occurs in animal cells in hypertonic conditions. ...
Cytoplasmic streaming
Cytoplasmic streaming, also called protoplasmic streaming and cyclosis, is the directed flow of cytosol (the liquid component of the cytoplasm) and organelles around large fungal and plant cells through the mediation of actin. This movement aids in the delivery of organelles, nutrients, metabolites, genetic information, and other materials to all parts of the cell. Cytoplasmic streaming occurs along actin filaments in the cytoskeleton of the cell.Cytoplasmic streaming was first discovered in the 1830s. The scientific breakthrough assisted scientists in developing an understanding of the different roles of cells and how they function as the basic operating systems of life.This process occurs through the operation of motor proteins called myosins.These proteins use energy of adenosine triphosphate (ATP) to act as a molecular motor, which slides along actin filaments. This works in a manner that tows the organelles and other cytoplasmic contents in the same direction. Myosin proteins consist of two conjoined proteins. If one protein remains attached to the substrate, the substance acted upon by the protein, such as a microfilament, has the ability to move organelles through the cytoplasm.The green alga genus Chara and other genera in the Division Charophyta, such as Coleochaete, are thought to be the closest relatives of land plants. These haploid organisms contain some of the largest plant cells on earth, a single cell of which can reach up to 10 cm in length. The large size of these cells demands an efficient means to distribute resources, which is enabled via cytoplasmic streaming.Cytoplasmic streaming is strongly dependent upon intracellular pH and temperature. It has been observed that the effect of temperature on cytoplasmic streaming created linear variance and dependence at different high temperatures in comparison to low temperatures. This process is complicated, with temperature alterations in the system increasing its efficiency, with other factors such as the transport of ions across the membrane being simultaneously affected. This is due to cells homeostasis depending upon active transport which may be affected at some critical temperatures.In plant cells, chloroplasts may be moved around with the stream, possibly to a position of optimum light absorption for photosynthesis. The rate of motion is usually affected by light exposure, temperature, and pH levels.In reference to pH, because actin and myosin are both proteins, strong dependence on pH is expected. The optimal pH at which cytoplasmic streaming is highest, is achieved at neutral pH and decreases at both low and high pH.The flow of cytoplasm may be stopped by:Adding Lugol's iodine solutionAdding Cytochalasin D (dissolved in dimethyl sulfoxide)↑ ↑ ↑ ↑ ↑ ↑