Metabolism. Defining Energy  Potential energy is the capacity to do work.  Kinetic energy is the energy of motion.  ATP is the cell’s energy source.

Slides:

Advertisements

Similar presentations

Ground Rules of Metabolism

Advertisements

Cellular Transport.

Chapter 5 – The Working Cell

Introduction to Metabolism Chapter 6. Metabolism - sum of organism’s chemical processes. Enzymes start processes. Catabolic pathways release energy (breaks.

Homeostasis and Transport

Cell Theory O Three Parts O All living things are made up of one or more cells O Cells are the basic units of structure and function O All cells arise.

Table 5-1, p. 80. Energy In, Energy Out Chemical reactions –Reactants (molecules in) –Products (molecules out) Endergonic reactions (energy-requiring)

Copyright © 2003 Pearson Education, Inc. publishing as Benjamin Cummings Chapter 5 The Working Cell.

Diffusion and Osmosis. Diffusion Solute molecules moving from an area of high concentration to an area of low concentration –Random motion drives diffusion.

Chapter 4 How Cells Work. Energy Energy is central to life –Universal relationship between energy and work Ultimate energy source = SUN –Plants transform.

How Cells Work Chapter 5. Energy Laws Energy is the capacity to do work The total amount of energy in the universe is constant (1 st law) Energy is flowing.

Cellular Transport Or- How do I get in and out of here?

Homeostasis and Transport

THE WORKING CELL.

Cells and Their Environment

HOMEOSTASIS AND TRANSPORT

maintaining homeostasis

maintaining homeostasis

CHAPTER 5 The Working Cell Energy and ATP, Transport, and Enzymes.

Sample questions 1) Those cells which have a nucleus are classified as? a) prokaryotes b) eukaryotes 2) Name two organelles, other than a nucleus?

Energy Energy (E)– the ability to perform work Potential E (E P )- stored energy Kinetic E (E K )– energy of motion Heat – kinetic energy of molecules.

Chapter 5: The Working Cell. All chemical reactions involve the transfer of energy Metabolism – All chemical reactions of a cell Energy has two forms:

CHAPTER FIVE About 75% of the energy generated by a car’s engine is lost as heat You’d have to run 14 miles to burn the calories from one large pepperoni.

CH 5 - P HOMEOSTASIS AND CELL TRANSPORT. OBJECTIVES 1. Explain how an equilibrium is established as a result of diffusion. 2. Distinguish between.

Facilitated Diffusion Active Transport

Chapter 3. Passive Transport  Diffusion – molecules move spontaneously (no energy used) from an area of high concentration to an area of low concentration.

What is energy? Energy: capacity to do work – Potential energy (Example: chemical bonds) – Kinetic energy (Energy of motion)

Ground Rules of Metabolism

Types of Transport Review. The movement of particles against the direction of diffusion requiring cell energy. ACTIVE TRANSPORT.

CHAPTER 5 The Working Cell Overview: Energy Def Laws Chemical Reactions ATP Enzymes Def Activity Membrane Structure Function Transport (passive, active,

Transportation and the Cell. Transportation is the movement of materials in and out of the cell by way of the cell membrane, or around the cell by way.

Ground Rules of Metabolism Chapter What Is Energy? Capacity to do work Forms of energy –Potential energy –Kinetic energy –Chemical energy.

Chapter 2 Lesson 3 Moving Cellular Materials. Cell Membrane The cell membrane is selectively permeable ◦ It allows certain things into the cell while.

Osmosis, Diffusion, Active Transport

Cycling of Matter in Living Systems 2.2 The Role of Cell Membrane in Transport.

Cells, Cells, Cells Active Transport and Passive Transport.

Chapter 7.3: Moving Materials Into and Out of Cells.

Bell Work! 1. Why are vacuoles important to PLANTS?

KEY CONCEPT Materials move across membranes because of concentration differences. 3.4 Diffusion and Osmosis.

Diffusion And Osmosis. Homeostasis Homeostasis: A stable internal environment. *In a cell, factors such as pH and the concentrations of other substances.

Chapter 7-3 in textbook Cell Transport maintaining homeostasis.

Energy, Enzymes, and Chemical Reactions. Defining Energy Potential energy is the capacity to do work. Kinetic energy is the energy of motion.

Cellular Transport. Lesson Objectives Explain the processes of diffusion, facilitated diffusion, and active transport Predict the effect of a hypotonic,

Cycling of Matter in Living Systems 2.2 The Role of Cell Membrane in Transport.

Cell Transport The Basic Unit of Life. Structure of the Cell Membrane 1C1Cell Membrane 2P2Proteins 3L3Lipid Bilayer 4C4Carbohydrates 5T5Transport Proteins.

Cell Transport Moving things into and out of the cell through the cell membrane to maintain balance ( homeostasis ) Passive: –Doesn’t take any energy from.

Cell Transport Crossing the Plasma Membrane. Plasma Membrane Phospholipid bilayer with proteins and cholesterol molecules scattered throughout Selectively.

How Cells Work Chapter 5. What Is Energy? Capacity to do work Forms of energy –Potential energy –Kinetic energy –Chemical energy.

Cellular Levels of Organization and Cellular Transport

Cellular Transport Across the Membrane

Notes: Cellular Transport

maintaining homeostasis

Cell Transport.

The Cell Membrane Lipids Proteins Also called the plasma membrane.

Structure of the Cell Membrane

Cellular Transport.

Chapter 5 The Working Cell.

Movement Through the Cell Membrane

Cell Transport.

Membrane Transport.

Passive transport movement of molecules across the cell membrane without an input of energy by the cell Diffusion movement of molecules from an area of.

Metabolism Ch 5.

Cellular Transport 7.4.

Cell Transport Different Methods used by Cells to Move Molecules into or out of the Cell.

Cell Transport.

Cell transport: Diffusion and Osmosis

How things get in and out of cells.

Movement Across Membranes

Energy Energy (E)– the ability to perform work

The Working Cell Energy and ATP, Transport, and Enzymes

Presentation transcript:

Metabolism

Defining Energy  Potential energy is the capacity to do work.  Kinetic energy is the energy of motion.  ATP is the cell’s energy source

 Potential energy of molecules is known as chemical energy.  Energy that is not given off as kinetic energy is given off as thermal (heat) energy. Heat energy is considered “wasted energy”

Laws of Thermodynamics  First law –Energy is not created or destroyed only transferred between forms.  The total amount of energy in the universe remains constant.

 Second law -- No energy conversion can ever be 100% efficient.  Energy always flows from more useful forms of energy to forms that are less useful.

Endergonic reaction  Uphill reaction  Energy is put into the reaction  For example: Glycolysis

Exergonic reaction  Downhill reaction  Energy is released during the reaction Example: The Kreb’s cycle and electron transport system

ATP  Adenosine Triphosphate  Consists of a 5 carbon sugar and 3 phosphate groups.  It is the cell’s energy source  To release energy, it will break a bond between phosphates

Enzyme Structure & Function  Enzymes – speed up the rate of a reaction.  Also called a catalyst  Equilibrium - when a reaction is running at the same rate forward as well as in reverse.

Four shared features 1. Enzymes do not make anything happen that could not happen on its own, it just makes it happen faster. 2. Reactions do not permanently change or use up an enzyme

3. The same type of enzyme usually works whether the reaction is occurring in a forward or reverse motion 4. Each type of enzyme is very picky

Enzyme-Substrate interactions  Activation energy - the energy that must be provided in order for the reaction to begin.  Enzymes lower the amount of activation needed to begin a reaction.

Enzymes have one or more active sites  At these places, enzymes interact with their substrate.

Active Site  A specific shape that will only fit a specific substrate. (Like a lock & Key).  When the substrate locks into the active site, the reaction can begin with a lower activation energy because bonds are weakened within the molecule.

Factors influencing Enzyme Activity 1. Temperature – enzymes only work in a certain temperature range 2. pH – measure of amount of acid or base in the solution

3. Salinity – measure of salt content in the solution 4. Feedback Inhibition – mechanism where a cellular change that resulted from an activity stops the activity that caused the change

Working with and against a concentration gradient  A concentration gradient is the difference in the number of molecules of a given substance in two adjoining regions.

 In the absence of an opposing force, molecules move from an area of high concentration to an area of low concentration

Diffusion  The net movement of like molecules from high concentration to low concentration (also called down the gradient)

Passive Transport  Requires no extra energy in order to occur.  The flow of dissolved material across a membrane through transport proteins following the concentration gradient.  If allowed to, this movement would occur until both areas had equal concentration of the solutes.

Osmosis  The diffusion of water molecules across a semi-permeable membrane.

Hypotonic solution  When too much water is moving into the cell and not enough water is leaving the cell

Hypertonic solution  When too much water is leaving the cell and not enough is entering.  Water tends to diffuse from hypotonic solution to hypertonic solutions

Isotonic solutions  Water is moving equally into and out of the cell.  Cell is in a state of equilibrium

Active Transport  Movement across the membrane against the concentration gradient.  This movement requires energy.  ATP provides the energy.

Vesicle Formation  Molecules too large to be transported by carrier proteins are moved into or out of the cell by vesicle formation.

Exocytosis  A vesicle fuses with the membrane and secretion occurs.

Endocytosis  Cells take in substances by vesicle formation.

Phagocytosis  When the material taken in is large and usually a “food”

Pinocytosis  Occurs when the particles taken in are a liquid.

Works Cited  ages/tonicity1.jpeg ages/tonicity1.jpeg  mages_potential_kinetic_energy/potential_kinet ic.jpg mages_potential_kinetic_energy/potential_kinet ic.jpg  meostasis/lockkey.gif meostasis/lockkey.gif  /sharris-deptofentropy.gif /sharris-deptofentropy.gif