Cell Membranes: Osmosis and Diffusion - PowerPoint PPT Presentation

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Cell Membranes: Osmosis and Diffusion

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Title: Cell Membranes: Osmosis and Diffusion


1
Cell MembranesOsmosis and Diffusion
2
Membrane Functions
  • 1. Protect cell
  • 2. Guard incoming and outgoing substances
  • 3. Maintain ion concentrations of various
    substances
  • Selectively permeable
  • Allows some molecules in
  • Others are kept out

3
Lipid Bilayer
  • Main component of cell membranes
  • Gives the membrane its fluid properties
  • Two layers of phospholipids

4
Phospholipid Bilayer
5
Fluid Mosaic Model
6
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7
Membrane Proteins
  • Transport proteins
  • Receptor proteins
  • Recognition proteins
  • Adhesion proteins

8
Solutions
  • Solutions are made of solute and a solvent
  • Solvent - the liquid into which the solute is
    poured and dissolved
  • Solute - substance that is dissolved or put into
    the solvent. Salt and sucrose are solutes

9
Membrane Transport
  • Diffusion
  • Passive transport
  • No energy expended
  • Osmosis
  • Passive transport
  • Water across membrane

10
Diffusion
  • Movement of molecules from one side of a membrane
    to the other
  • Occurs from a region of high concentration of
    substance to a region of lower concentration

11
Di f fus ion
12
Osmosis
13
Turgor Pressure
  • Hypotonic Solution
  • Inside has higher salt concentration
  • Hypertonic Solution
  • Inside has lower salt concentration
  • Isotonic Solution
  • Both solutions have same concentrations of solute

14
Plant and Animal Cells in Various Solutions
15
Membrane Transport
  • Facilitated Diffusion
  • Passive transport
  • Use of proteins to carry polar molecules or ions
    across
  • Active Transport
  • Requires energy to transport molecules against a
    concentration gradient
  • Energy is in the form of ATP

16
Active Transport
  • Movement against a concentration gradient (from
    low to high concentration)
  • Requires added energy (ATP) and a specific
    membrane carrier (pump)

17
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18
Endocytosis
  • Ingestion of large molecules or particles
  • Cell surrounds and envelops substance forming a
    vesicle which fuses with lysosome
  • Phagocytosis
  • Endocytosis of organism
  • Pinocytosis
  • Endocytosis of large, soluble molecules

19
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20
Exocytosis
  • Cell secretes material
  • Package in a vesicle
  • Moves in vesicle to cell surface
  • Vesicle membrane fuses with cell membrane
  • Contents are secreted out
  • Specialized animal cells produce and secrete
    digestive enzymes and hormones

21
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23
Cell Structure and Function
24
Early Discoveries
  • Mid 1600s - Robert Hooke observed and described
    cells in cork
  • Late 1600s - Antony van Leeuwenhoek observed
    sperm, microorganisms
  • 1820s - Robert Brown observed and named nucleus
    in plant cells

25
Cell Theory
  • Matthias Schleiden
  • Theodor Schwann
  • Rudolf Virchow

26
Cell Theory
  • 1) Every organism is composed of one or more
    cells
  • 2) Cell is smallest unit of life
  • 3) Cells arise from pre-existing cells

27
Cell
  • Smallest unit of life
  • Can survive on its own or has potential to do so
  • Is highly organized for metabolism
  • Senses and responds to environment
  • Has potential to reproduce

28
Cells are Microscopic
  • Why arent cells larger?
  • Animal cells range from 7-50 µm, some are much
    larger
  • Nerve cells
  • Algae
  • Eggs
  • Plant cells are generally larger

29
Why arent Cells Larger?
  • As cells grow larger, volume increases faster
    than surface area
  • Large cells do not have sufficient surface area
    for efficient diffusion of nutrients and wastes
  • Nuclei control activities of smaller cells more
    easily

30
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31
Structure of Cells
  • Must Have
  • Plasma membrane
  • DNA Region
  • Cytoplasm
  • Two types
  • Prokaryotic
  • Eukaryotic
  • Plant
  • Animal

32
Structure of Cells
  • The plasma membrane and internal cell membranes
    consist of lipids and proteins. The lipids are
    organized as two adjacent layersas bi-layer.

33
Fluid Mosaic Model
  • Membrane is a mosaic of
  • Phospholipids
  • Glycolipids
  • Sterols
  • Proteins
  • Most phospholipids and some proteins can drift
    through membrane

34
Why Are Cells So Small?
  • Surface-to-volume ratio
  • The bigger a cell is, the less surface area there
    is per unit volume
  • Above a certain size, material cannot be moved in
    or out of cell fast enough

35
Microscopes
  • Create detailed images of something that is
    otherwise too small to see
  • Light microscopes
  • Simple or compound
  • Electron microscopes
  • Transmission EM or Scanning EM

36
Light Microscope Limitations
  • If a structure is less than one-half of a
    wavelength long, it will not be visible
  • Light microscopes can resolve objects down to
    about 200 nm in size
  • Can magnify 2000x
  • Our microscopes magnify 400x at best

37
Electron Microscopy
  • Uses streams of accelerated electrons rather than
    light
  • Electrons are focused by magnets rather than
    glass lenses
  • Can resolve structures down to 0.5 nm magnifying
    20,000x-100,00x

38
Eukaryotic Cells
Plant cell
  • Defined as a cell that starts out life with a
    nucleus
  • Have a nucleus and other organelles
  • Eukaryotic organisms
  • Plants
  • Animals
  • Protista
  • Fungi

Animal cell
39
Animal Cell Features
  • Plasma membrane
  • Cytoskeleton
  • Nucleus
  • Ribosomes
  • Endoplasmic reticulum
  • Vesicle
  • Mitochondria
  • Golgi body

40
Plant Cell Features
  • Cell wall
  • Chloroplast
  • Central Vacuole
  • Nucleus
  • Plasma Membrane
  • Ribosomes
  • Endoplasmic reticulum
  • Golgi body
  • Mitochondria

41
Functions of Nucleus
  • Keeps the DNA molecules of eukaryotic cells
    separated from metabolic machinery of cytoplasm
  • Makes it easier to organize DNA and to copy it
    before parent cells divide into daughter cells

42
Components of Nucleus
  • Nuclear envelope - double membrane enclosing the
    nucleus
  • Nucleoplasm - fluid portion of the nucleus
  • Nucleolus - where other organelles are
    constructed
  • Chromosome made of chromatin
  • Chromatin - DNA with all associated protein

43
Nuclear Envelope
  • Two outer membranes (lipid bi-layers)
  • Innermost surface has DNA attachment sites
  • Pores span bi-layer

44
Nucleolus
  • Dense mass of material in nucleus
  • May be one or more
  • Cluster of DNA and proteins
  • Puts together ribosomal subunits

45
Chromatin
  • Cells collection of DNA and associated proteins
  • Chromosome is one DNA molecule and its
    associated proteins
  • Appearance changes as cell divides

46
Cytomembrane System
  • Group of related organelles in which lipids are
    assembled and new polypeptide chains are modified
  • Products are sorted and shipped to various
    destinations

47
Cyto-membrane System
  • Endoplasmic reticulum
  • Golgi bodies
  • Vesicles

48
Endoplasmic Reticulum
  • In animal cells, continuous with nuclear membrane
  • Extends throughout cytoplasm
  • Two regions - rough and smooth

49
Rough ER
  • Arranged into flattened sacs
  • Ribosomes on surface give it a rough appearance
  • Some polypeptide chains enter rough ER and are
    modified
  • Cells that specialize in secreting proteins have
    lots of rough ER

50
Smooth ER
  • A series of interconnected tubules
  • No ribosomes on surface
  • Lipids assembled inside tubules
  • Smooth ER of liver inactivates wastes, drugs

51
Golgi Bodies
  • Put finishing touches on proteins and lipids that
    arrive from ER
  • Package finished material for shipment to final
    destinations
  • Material arrives and leaves in vesicles

52
Vesicles
  • Membranous sacs that move through the cytoplasm
  • Lysosomes
  • Peroxisomes

53
Mitochondria
  • ATP-producing powerhouses
  • Double-membrane system
  • Carry out most efficient energy-releasing
    reactions that require oxygen

54
Mitochondrial Structure
  • Outer membrane faces cytoplasm
  • Inner membrane folds back on itself
  • Membranes form two distinct compartments
  • ATP-making machinery is embedded in the inner
    mitochondrial membrane

55
Mitochondrial Origins
  • Mitochondria resemble bacteria
  • Have own DNA, ribosomes
  • Divide on their own
  • May have evolved from ancient bacteria that were
    engulfed but not digested

56
Plant Organelles
  • Plastids organelles that specialize in
    photosynthesis
  • Central Vacuole store amino acids, sugars, ions
    and toxic wastes.

57
Chloroplasts
  • Convert sunlight energy to ATP through
    photosynthesis

58
Photosynthesis
  • First stage
  • Occurs at thylakoid membrane
  • Light energy is trapped by pigments and stored as
    ATP
  • Second stage
  • Inside stroma, ATP energy is used to make sugars,
    then other carbohydrates

59
Central Vacuole
  • Fluid-filled organelle
  • Stores amino acids, sugars, wastes
  • As cell grows, expansion of vacuole as a result
    of pressure that forces end cell walls to expand
  • In mature cell, central vacuole takes up 50-90
    percent of cell interior

60
Cytoskeleton
  • Present in all eukaryotic cells
  • Basis for cell shape and internal organization
  • Allows organelle movement within cells and, in
    some cases, cell motility

61
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62
Flagella and Cilia
  • Structures for cell motility

63
Cell Wall
Plasma membrane
  • Structural component that wraps around the plasma
    membrane
  • Occurs in plants, some fungi, some protista

64
Prokaryotic Cells
  • Archaebacteria and Eubacteria
  • DNA is NOT enclosed in nucleus
  • Generally the smallest, simplest cells
  • No organelles

65
Prokaryotic Structure
pilus
cytoplasm with ribosomes
DNA
flagellum
capsule
cell wall
plasma membrane
66
Things to know
  • The first cell seen under a microscope was cork.
  • One portion of the cell theory states that all
    living organisms are made up of cells.
  • The cell theory was proposed by Theodor Schwann
    and Matthias Schleiden.
  • The idea that all living cells come from
    pre-existing living cells was proposed by Rudolf
    Virchow.

67
Things to know
  • The phospholipid molecules of most membranes have
    a hydrophilic head and two hydrophobic tails.
  • Hydrophobic reactions of phospholipids may
    produce clusters of their fatty acid tails, which
    form a lipid bilayer.

68
Things to know
  • The relative impermeability of membranes to
    water-soluble molecules is a result of the
    presence of phospholipids in the lipid bilayer.
  • Membranes have holes due to proteins that extend
    through the membrane.
  • Some membranes have proteins with channels or
    pores that allow for the passage of hydrophilic
    substances.

69
Things to know
  • The current concept of a membrane can be best
    summarized by the fluid mosaic model.
  • The lipid bilayer serves as a hydrophobic barrier
    between two fluid regions.
  • Receptor proteins are responsible for binding
    hormones that can switch on a cell.
  • There are 1,000,000,000 nanometers in a meter.

70
Things to know
  • The maximum power of magnification of a light
    microscope is 4,000.
  • The highest magnification generally used to study
    cells is provided by the transmission electron
    microscope.
  • The transmission electron microscope has the
    highest magnification.
  • The ribosomes are made of two subunits of RNA and
    protein.

71
Things to know
  • Organelles composed of a system of canals, tubes
    and sacs that transport molecules inside the
    cytoplasm are endoplasmic reticula.
  • Mitochondria are the primary cellular sites for
    the recapture of energy from carbohydrates.
  • Golgi bodies are the primary structures for the
    packaging of cellular secretions for export from
    the cell.

72
Things to know
  • The cell part responsible for maintaining cell
    shape, internal organization, and cell movement
    is the cytoskeleton.
  • The cell wall is found in plant cells but not in
    animal cells.
  • The nucleolus is found in the nucleus.
  • The nuclear envelope has two lipid layers there
    are pores in the membrane ribosomal subunits can
    pass out of the nucleus protein filaments are
    attached to inner surface.

73
Things to know
  • Scientists use the word chromosome to describe
    an individual DNA molecule.
  • Endoplasmic reticula are sometimes referred to as
    rough or smooth.
  • Ribosomes are the primary cellular sites for the
    production of protein.
  • The Golgi body has been likened to a stack of
    pancakes.

74
Things to know
  • The lysosomes contain enzymes and are the main
    organelles of intracellular digestion.
  • Animal cells dismantle and dispose of waste
    materials by several lysosomes fusing with a sac
    that encloses the wastes.
  • A tadpoles tail disappears when it changes into
    an adult frog by action of lysosomes.

75
Things to know
  • The nuclei and mitochondria contain DNA.
  • Mitochondria contain enzymes used in the
    breakdown of glucose and generation of ATP.
  • Energy stored in carbon compounds is converted by
    mitochondria to a form usable by the cell.
  • There are two membranes surrounding the
    mitochondrion.

76
Things to know
  • The inner membranes of mitochondria are called
    cristae.
  • Fluid-filled sacs that may store food or water in
    cells are called vacuoles.
  • Plastids in plant cells function in
    photosynthesis or storage.
  • Stroma and grana are portions of chloroplasts.

77
Things to know
  • Vacuoles dramatically increase the cell size and
    surface area.
  • Flagellum is compared to a whip and used for
    mobility.
  • Bacteria are examples of prokaryotes.
  • Prokaryotic cells do NOT have membrane bound
    nucleus.
  • Prokaryotes have DNA regions are unicellular
    have cell walls and are bacteria.

78
Bibliography
  1. http//filebox.vt.edu/users/malsaghi/ 6 Dec 2004,
    Mohannad AL-Saghir, Biology Department, Virginia
    Tech
  2. http//pls.atu.edu/biology/, 6 Dec 2004, Arkansas
    Tech University, Biology Department, Beck,
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