prokaryotic cells

... Physical Description: flattened discs that contains chlorophyll (a green pigment). Looks like a stack of green pancakes.  Function: use energy from SUNLIGHT to MAKE sugar molecules through photosynthesis  Type of Cell: found in plant/algae cells  Analogy: it is like the solar panels of a factory ...

Diffusion: Molecular Transport across Membranes

... into and out of the cell. Selectively permeable membranes are membranes which allow some substances to cross much more easily than other substances. As you know the process of diffusion moves substances down a concentration gradient, from regions of high concentration to regions of low concentration ...

The Cell

... substances through a cell membrane without using the cell’s energy. • Small molecules, such as oxygen and carbon dioxide, pass through membranes via passive transport. • Passive transport depends on the amount of substance on each side of a membrane. ...

Mouse (monoclonal) anti-β-Catenin [pY86]

... Immunoblotting: 1.0 µg/mL for HRP/ECL detection; ELISA: 0.05 µg/mL. The optimal antibody concentration should be determined empirically for each specific application. ...

Not just another hole in the wall: understanding intercellular protein

... membrane subdomains associated with plasmodesmata. In support of this hypothesis, expression of antisense of LeRab11a in tomato led to plants with reduced apical dominance, determinate growth, branched inflorescences, abnormal floral structure, and ectopic shoot growth on leaves. These pleiotropic e ...

The Cell Membrane

... movement of sucrose into the cell. Sucrose MUST bind to an H+ ion. “Rides” with the H+ as H+ flows INTO the cell through the cotransport channel WITH it’s concentration gradient. Remember, the H+ concentration gradient is maintained by the proton pump The only way that sucrose can enter is if it is ...

Cell Activity - Covington Independent Public Schools

... LS 2.1 Identify, describe, and explain various types of cells and cell processes. LS 2.4 Identify the requirements for living organisms. LS 3.1 Design and conduct life science investigations to answer different kinds of questions. LS 3.3 Apply multiple strategies to problem solving. ...

Cells & Cell Organelles

... protein channels allow substances in & out  specific channels allow specific material in & out  H2O channel, salt channel, sugar channel, etc. ...

doc

... Eukaryotic cells tend to be very complex whereas prokaryotic cells are very simple. Eukaryotic cells have membrane bound organelles that must work together to support the life of the cell and the organism in which the cell is located. Large cell Having a large surface area to volume ratio allows par ...

The Importance of Cell Motility

... The interactions among troponin T, troponin C, tropomyosin, and actin are Ca++ dependent. When Ca++ binds to specific regulatory sites of TnC there is a tighter association among the troponin subunits and a change in the position of tropomyosin on the actin filament. This change in binding of tropom ...

Osmosis

... concentrations of the SOLUTES • The substance that moves to balance the solute concentration is the WATER • The solutes to not “pull” or “suck” the water across the membrane – the water simply diffuses from where it is in high concentration to low concentration ...

Anti-Cytochrome c Mouse mAb (7H8.2C12) Cat. No. AP1029

... and becomes combined with a heme group to form the holocytochrome c protein. Holocytochrome c is a soluble protein located in the intermembrane space of mitochondria, loosely attached to the inner membrane and is an essential component of the mitochondrial respiratory chain. Early studies showed tha ...

A Tour of the Cell

... chloroplasts are most similar to the cytosol of a eukaryotic cell? a) the mitochondrial intermembrane space and the lumen of the thylakoids ...

Tonicity, which is directly related to the osmolarity of a

... solute particles; a solution with high osmolarity has fewer water molecules with respect to solute particles. In a situation in which solutions of two different osmolarities are separated by a membranepermeable to water, though not to the solute, water will move from the side of the membrane with lo ...

Chapter 7 Membrane Structure and Function

... may not be very concentrated in the extracellular fluid. Embedded in the membrane are proteins with specific receptor sites exposed to the extracellular fluid. The receptor proteins are usually already clustered in regions of the membrane called coated pits, which are lined on their cytoplasmic side ...

Chapter 3 The Basic Structure of a Cell

... • Cells are the basic units of function in all living things. • Cells in animals and plants have unique forms that allow each to take part in processes that are necessary for the cell and or/living thing to survive. Let’s take a closer look at the similarities and differences between animal and pla ...

Slide 1

... phosphorylation changes the activity of the pump by altering its shape Na+ is expelled out of the cell – against its concentration gradient 2 K+ ions then bind the pump and causes the release of the P group another shape change by the pump - releases the K+ into the cell ...

Ch_49

... removed by active transport into SR after action potential ends. ...

A-level Biology B Question paper Unit 1 - Core Principles

... own sugar. They have thin walls and large vacuoles. The vacuoles contain a solution with a very low (very negative) water potential. These cells support the stem, keeping it upright. (i) Using the information given above, suggest how the cells of the cortex maintain a very low water potential. ...

AP Biology Chapter Questions – Campbell 7th Edition

... 5. Distinguish between peripheral and integral membrane proteins. 6. List six major functions of membrane proteins. 7. Explain the role of membrane carbohydrates in cell-cell recognition. 8. Explain how hydrophobic molecules cross cell membranes. 9. Distinguish between channel proteins and carrier p ...

06_Lecture_Presentation_PC

... • Cristae present a large surface area for enzymes that synthesize ATP ...

PLANT CELLS

... which posses a distinctive DNA. Those containing chlorophyll are called chloroplasts. There may be one, several or many per cell. Chloroplasts are relatively large compared to mitochondria. They are the main source of energy of photosynthetic cells in the light with the production of oxygen. ...

Solute transport - ASAB-NUST

... • Ion concentrations in cytosol and vacuole are controlled by passive (dashed) and active (solid) transport processes • In most plant cells vacuole takes up 90% of the cell volume – Contains bulk of cells solutes ...

Lesson-Plans-Unit-1-Cells-and-Microbiology

... cell, cytoplasm, prokaryote, eukaryote, organism, organelle, cell membrane, nucleus, mitochondrion, ribosome, cell wall, vacuole, chloroplast ...

Solute transport - Lectures For UG-5

... • Ion concentrations in cytosol and vacuole are controlled by passive (dashed) and active (solid) transport processes • In most plant cells vacuole takes up 90% of the cell volume – Contains bulk of cells solutes ...

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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)↑ ↑ ↑ ↑ ↑ ↑

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Cytoplasmic streaming