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A TOUR OF THE CELL

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CHAPTER 7 A TOUR OF THE CELL Fluorescent stain of cell CELL TO CELL ADHESION 1) Intercellular matrix (ECMs of adjacent cells) a) Collagen- the most abundant ... – PowerPoint PPT presentation

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Title: A TOUR OF THE CELL


1
CHAPTER 7
  • A TOUR OF THE CELL

Fluorescent stain of cell
2
Cell Biology1. The fundamental life processes of
plants and animals depend on a variety of
chemical reactions that occur in specialized
areas of the organisms cells. As a basis for
understanding this concept, Students know
  • a. cells are enclosed within semipermeable
    membranes that regulate their interaction with
    their surroundings.
  • b. enzymes are proteins that catalyze biochemical
    reactions without altering the reaction
    equilibrium and the activities of enzymes depend
    on the temperature, ionic conditions, and the pH
    of the surroundings.
  • c. how prokaryotic cells, eukaryotic cells
    (including those from plants and animals), and
    viruses differ in complexity and general
    structure.
  • d. the central dogma of molecular biology
    outlines the flow of information from
    transcription of ribonucleic acid (RNA) in the
    nucleus to translation of proteins on ribosomes
    in the cytoplasm.
  • e. the role of the endoplasmic reticulum and
    Golgi apparatus in the secretion of proteins.
  • f. usable energy is captured from sunlight by
    chloroplasts and is stored through the synthesis
    of sugar from carbon dioxide.
  • g. the role of the mitochondria in making stored
    chemical-bond energy available to cells by
    completing the breakdown of glucose to carbon
    dioxide.
  • h. Students know most macromolecules
    (polysaccharides, nucleic acids, proteins,
    lipids) in cells and organisms are synthesized
    from a small collection of simple precursors.
  • i. how chemiosmotic gradients in the
    mitochondria and chloroplast store energy for ATP
    production.
  • j Students know how eukaryotic cells are given
    shape and internal organization by a cytoskeleton
    or cell wall or both.

3
Organisms must exchange matter with the
environment to grow, reproduce and maintain
organization. Growth, reproduction and
maintenance of the organization of living systems
require free energy and matter.
  • Molecules and atoms from the environment are
    necessary to build new molecules.
  • 1. Carbon moves from the environment to organisms
    where it is used to build carbohydrates,
    proteins, lipids or nucleic acids. Carbon is used
    in storage compounds and cell formation in all
    organisms.
  • 2. Nitrogen moves from the environment to
    organisms where it is used in building proteins
    and nucleic acids.
  • 3. Phosphorus moves from the environment to
    organisms where it is used in nucleic acids and
    certain lipids.

4
why are cells microscopic in size?
  • http//www.youtube.com/watch?vxuG4ZZ1GbzI

5
Geometric relationships explain why most cells
are microscopic
The smaller the object, the greater Its ratio of
surface area to volume. Metabolic requirements
depend on passage of oxygen, nutrients and
Carbon dioxide other metabolic Waste through
the plasma membrane.
6
why are cells microscopic in size?
  • Cell size is limited by the surface to volume
    ratio.
  • As cells get larger the volume increases at a
    greater rate compared to surface area.
  • Large cells can not get enough materials inside
    to stay alive.

7
b. Surface area-to-volume ratios affect a
biological systems ability to obtain necessary
resources or eliminate waste products.
  • 1. As cells increase in volume, the relative
    surface area decreases and demand for material
    resources increases more cellular structures are
    necessary to adequately exchange materials and
    energy with the environment. These limitations
    restrict cell size.
  • Ex. root hairs, cells of the alveoli, cells of
    the villi
  • 2. The surface area of the plasma membrane
    must be large enough to adequately exchange
    materials smaller cells have a more favorable
    surface area-to-volume ratio for exchange of
    materials with the environment.

8
  • villi cells within the small intestine
  • root hair cells of plants
  • cells of the alveoli within lungs
  • All shaped and arranged in ways that increase
    surface area to volume ratio and maximize
    diffusion.

9
what types of microscopes are used to view cells?
  • Light (2,000x)
  • Transmission Electron TEM (2,000,000x)
  • Scanning Electron
  • SEM (3-D)

10
Rabbit trachea (windpipe) cell
Transmission electron microscope
(SEM)
(TEM)
Scanning electron microscope creates 3-D image of
the surface of the same cell.
11
  • 1665 1st Microscope
  • Robert Hooke discovered cells-cork
  • 1950s Electron Microscope
  • Revealed the geography of the cell
  • ORGANELLES
  • Subcellular structures specialized
  • for various specific functions.
  • tiny organ
  • compartments or rooms
  • each contains specific enzymes

12
The plasma membrane
13
What is the difference between prokaryotic and
eukaryotic cells?
  • THINGS IN COMMON
  • DIFFERENCES

14
Overview of a prokaryotic cell
Overview of a plant cell
Overview of an eukaryotic animal cell
15
Prokaryotic Vs. Eukaryotic
  • Both have
  • Plasma membrane
  • Cytosol- semifluid substance in which organelles
    are found.
  • Chromosomes/genes
  • Ribosomes (tiny organelles that make proteins
    according to instructions from the genes)
  • Only eukaryotic cells
  • Have chromosomes inside a membrane bound
    organelle- the nucleus.
  • eu true
  • karyon kernel
  • Are large -10x bigger than bacteria.
  • Have other membrane-bound organelles.

16
FYI CELL FRACTIONATION Technique used to
determine the function of organelles. ORGANELLES
are sub cellular structures that perform specific
sets of chemical reactions for the cell within
Eukaryotic Cells.
17
Eukaryotic cells maintain internal membranes that
partition the cell into specialized regions.
  • a. Internal membranes facilitate cellular
    processes by minimizing competing interactions
    and by increasing surface area where reactions
    can occur.
  • b. Membranes and membrane-bound organelles in
    eukaryotic cells localize (compartmentalize)
    intracellular metabolic processes and specific
    enzymatic reactions.
  • For example Endoplasmic Reticulum
    Chloroplasts / Mitochondrion Golgi Nuclear
    envelope

18
  • CHARACTERISTICS
  • OF THE NUCLEUS
  • Contains most of the genes
  • Most conspicuous (big)
  • part of the cell
  • STRUCTURES of
  • THE NUCLEUS (out to in)
  • Nuclear envelope (double
  • membrane system- 2plbls)
  • 2) Pores (protein tunnels)
  • Lamina (protein fiber
  • scaffolding- network)
  • 4) Chromatin (DNA protein)
  • 5) Nucleolus (makes ribosomes)

Chloroplasts and Mitochondria have their own DNA
19
Chromosomes are thick coiled chromatin fibers
that condense when the cell is ready to divide.
  • Nucleosome subunit of a chromosome
  • DNA wrapped around 8 histone proteins.

20
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21
Nuclei and F-actin in BPAEC cells
22
Big Idea 4 Biological systems interact, and
these systems and their interactions possess
complex properties.
  • The structure and function of subcellular
    components, and their interactions, provide
    essential cellular processes.

23
Figure 7.10 Ribosomes
  • RIBOSOMES are small universal structures (proks
    euks)
  • made of ribosomal RNA (rRNA) and protein
  • carry out protein synthesis in 2 areas
  • free- suspended in the cytosol
  • bound- attached to the outside of the endoplasmic
  • reticulum or nuclear envelope.
  • Ex. PANCREAS CELLS have a few million ribosomes
  • (synthesize pancreatic juices, insulin, glucagon)

24
The Endoplasmic Reticulum
  • within the cytoplasm little net
  • Labyrinth of membrane tubes and sacs
  • gt 1/2 the total membrane of the cell
  • Connected to the nucleus
  • FUNCTIONS
  • Occurs in 2 forms rough smooth
  • rough ER provides site-specific protein synthesis
    with membrane-bound ribosomes
  • plays a role in intracellular transport
    endomembrane system.
  • smooth ER synthesizes lipids.

25
Smooth ER vs. Rough ER
  • Smooth ER
  • Lacks ribosomes
  • Functions
  • Synthesis of lipids
  • sex hormones, oils, phospholipids
  • 2) Metabolism of carbohydrates
  • Detoxification of drugs/poisons
  • LIVER CELLS
  • MUSCLE CELLS (store Ca)
  • Rough ER
  • Ribosomes attached to the cytoplasmic surface
  • Functions
  • Protein synthesis on ribosomes, protein enters
    cisternal space to fold into native conformation.
  • Secretory Glycoproteins
  • Phospholipid membrane production (factory)

? Specific functions of smooth ER in specialized
cells are beyond the scope of the course and the
AP Exam.
26
Golgi Complex AKA golgi apparatus, golgi bodies
  • STRUCTURE membrane-bound, consists of a series of
    flattened membrane sacs (cisternae).
  • Looks like a smaller version of the ER but
    totally separate from nucleus)
  • FUNCTIONS include synthesis and packaging of
    materials (small molecules) for transport
    production of lysosomes.
  • Receives ships via transport vesicles- bags of
    membrane.

27
Golgi sorts, modifies, and exports
cis receiving
trans shipping
28
The formation and functions of lysosomes
  • Lysosomes are membrane-enclosed sacs that contain
    hydrolytic enzymes, which are important in
  • intracellular digestion
  • The recycling of a cells organic materials and
  • programmed cell death (apoptosis)

29
lysosomes
  • Made by rough ER, finished in the Golgi
  • Contain hydrolytic enzymes that function at low
    pH
  • Pumps hydrogen ions from cytosol into lysosome to
    maintain acidic pH
  • Targets of primary lysosomes are
  • 1) food vacuoles (formed via phagocytosis)
  • ex. Amoeba (protist)
    Macrophages (white blood cells)
  • 2) organelles or cytosol (autophagy- recycle
    materials)
  • 3) Apoptosis programmed destruction of cells
  • ex. tadpole tail, human hand
    development- webbing
  • EX. Tay-Sachs genetic disorder is caused by
    missing/inactive lipid digesting enzyme which
    results in lipid accumulation in brain cells.

30
Review relationships among organelles of the
endomembrane system 
Endomembrane System Organelles that share
membrane Components with each other. Nuclear
Envelope, ER, Golgi, Lysosome, Vacuoles, and
Plasma Membrane How? Transport Vesicles-
little bag of Membrane.
31
Endomembrane System
  • Rough ER
  • vesicle
  • Golgi Apparatus
  • vesicle
  • Plasma Membrane

32
The Golgi apparatus stack of pita bread insides
cisternae
33
lysosome formation
34
VACUOLES
  • Larger than vesicles
  • Food vacuoles (formed by phagocytosis)
  • Contractile vacuoles- pump excess water out of
    the cell (freshwater protists)
  • Central vacuole- large vacuole in mature plant
    cells (membrane tonoplast)
  • - contains reserves of important compounds
  • ie. pigments (petals), metabolic by-products
    (waste), poisons (repel predators), water,
    proteins and lipids (seeds)

35
The plant cell vacuole 
Which cells have the larger vacuoles- animal or
plant?
plant cells
36
Mitochondrion / mitochondria (pl)
  • Energy conversion organelle
  • Site of cellular respiration
  • (x,y,z--gtATP)
  • Mitochondrial membrane proteins made by free
    ribosomes in the cytosol
  • Contain ribosomes and own DNA
  • Double membrane system
  • - outer membrane smooth
  • - inner membrane convoluted (cristaefolds) w/
    proteins increases surface area for rxns.
  • Two spaces
  • 1) mitochondrial matrix
  • (inner most area)
  • 2) inter membrane space- between the two
    membranes.

37
PLASTIDS
  • Family of closely related plant organelles.
  • Four kinds
  • Chromoplasts- contain pigments that give fruits
    and vegetables their orange and yellow hues.
  • Leukoplasts- store starch, protein, oil
  • Amyloplasts- store starch (amylose) in roots and
    tubers.
  • Chloroplasts- contain green pigment chlorophyll
    enzymes related to photosynthesis.

38
CHLOROPLAST STRUCTURE
  • Double membrane system
  • Pancakes in a to-go box
  • Thylakoids flattened sacs (inside called
    thylakoid space
  • Grana stacks of thylakoids
  • Stroma area outside thylakoids and outer
    membrane contains ribosomes, enzymes, and
    chloroplast DNA.

39
The chloroplast, site of photosynthesis
note chloroplasts are larger than mitochondria.
40
PEROXISOMES
  • Specialized, one membrane, metabolic compartment
    that detoxifies substances.
  • Transfers hydrogen from substrates to oxygen-
    makes H2O2
  • ie. detoxify alcohol or
  • use oxygen to break fatty acids into small
    molecules to be used as fuel for the
    mitochondria.
  • Contains catalase to convert H2O2 to water and
    Oxygen.
  • Liver cells have many.

41
The process of evolution drives the diversity and
unity of life.
  • Organisms are linked by lines of descent from
    common ancestry. Organisms share many conserved
    core processes and features that evolved and are
    widely distributed among organisms today.
  • Structural evidence supports the relatedness of
    all eukaryotes.
  • Cytoskeleton (a network of structural proteins
    that facilitate cell movement, morphological
    integrity and organelle transport)
  • Membrane-bound organelles (mitochondria and/or
    chloroplasts)
  • Linear chromosomes
  • Endomembrane systems, including the nuclear
    envelope

42
THE CYTOSKELETON
plays a major role in organizing the structures
and activities of the cell
made of 1.microtubules 2.microfilaments 3.interme
diate filaments
43
Table 7.2 The structure and function of the
cytoskeleton
44
microtubules
  • structrure
  • hollow fibers of tubulin protein that makes
    microtubules
  • - 2 types alpha beta (tubulin)
  • functions
  • 1) shape support cell- compression resisting
  • 2) tracks to move organelles
  • equipped w/motor molecules.
  • 3) assist in cell division
  • (moving chromosomes)
  • ex. Spindle fibers
  • 4) motion for the cell-
  • cilia/flagella

45
Figure 7.21 Motor molecules and the cytoskeleton
46
MICROTUBUELES grow out of a centrosome (plant
cells) 2 centrioles w/in the centrosome in
(animal cells) centriole structure 9
microtubule triplets in a ring
47
cilia flagellaspecialized microtubular
structures
  • basal bodies (same structure as centrioles)
    anchor cilia and flagella to the cell membrane
  • flagella long tails (few) 10-200 micrometers
  • cilia short hairs (many) 2-20 micrometers
    (10-6)
  • structure of both nine pairs of tubules arranged
    around 2 central tubules (9 2 pattern in
    Euks)
  • Dynein motor molecule (protein) attached to
    tubules, uses energy from ATP to move cilia.
  • Dynein walking like a cat climbing a tree.

48
Figure 7.23 A comparison of the beating of
flagella and cilia
49
cilia in action (paramecium)
50
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51
microfilaments
  • threads of protein
  • actin helix shape
  • twisted double chain of actin subunits
  • present in all Eukaryotic cells
  • bear tension used for structure movement.
  • myosin involved in movement when interacting
    with actin.
  • MA! myosin pulls actin

52
muscles use actin and myosin for
contractionmyosin pulls actinmyosin acts
as the motor molecule by extending armsthat
walk along actin.
53
Cell division uses microfilaments to pull the
cell membrane apartcontracting band of
microfilaments cleavage furrow
54
amoeboid movement via pseudopodia
  • pseudopod false foot
  • cytoplasmic extensions
  • localized contraction of actin myosin move the
    cell membrane
  • reversible actin subunit assembly
  • squeezing toothpaste tube
  • ex. Amoeba white blood cells

55
cytoplasmic streaming
  • in plant cells occurs similarly to the movement
    of pseudopods.

56
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57
microfilament recap
58
intermediate filaments(named for intermediate
diameter)
  • Built from a family of proteins called keratins
  • Form permanent cellular lattice(framework)
  • cell to cell junctions

59
Figure 7.x4 Actin and keratin
60
THE CELL WALL
  • 1) of PLANT CELLS made of cellulose
  • Primary wall 1st wall to form
  • Middle lamella space between two plant cells
  • pectin is a polysaccharide that fills the middle
    lamella. As fruit ripens, pectin dissolves, cells
    loosen and fruit ripens
  • c) Secondary wall develops in woody plants
  • lignin is a molecule that strengthens the
    secondary wall.
  • 2) of FUNGI made of chitin
  • 3) of BACTERIA made of organic molecules
    (polysaccharides protein)

61
THE CELL WALL
  • 1) of PLANT CELLS made of cellulose
  • Primary wall 1st wall to form
  • Middle lamella space between two plant cells
  • pectin is a polysaccharide that fills the middle
    lamella.
  • As fruit ripens, pectin dissolves, cells loosen
    and fruit ripens
  • c) Secondary wall develops in woody plants
  • lignin is a molecule that strengthens the
    secondary wall.
  • 2) of FUNGI made of chitin
  • 3) of BACTERIA made of organic molecules
    (polysaccharides protein)

62
Figure 7.28 Plant cell walls
63
CELL COATING
  • Animal cell membranes have short chains of
    carbohydrates bound to
  • proteins (glycoproteins/proteoglycans)
  • ie. collagen, fibronectins, integrins
  • or lipids (glycolipids)
  • Called glycocalyx or extracellular matrix (ECM)
  • FUNCTIONS OF THE glycocalyx / ECM
  • recognition sites (cell to cell for tissue
    formation)
  • identification markers (ie. A or B on blood cell)
  • communication (hormone messenger receptors)

64
cell coating/ extracellular matrix
Collagen Proteoglycan Polysaccharide microfilament
s
65
how are cells connected?
  1. Intercellular matrix
  2. Cell junctions

66
CELL TO CELL ADHESION
  • 1) Intercellular matrix (ECMs of adjacent cells)
  • a) Collagen- the most abundant glycoprotein,
    protein fibers that bind cells together
  • b) Elastin- also protein fiber that binds cells
    together
  • Cell junctions (permanent connections)
  • a) desmosomes anchoring junctions (plaques
    fibers) rivets, fasten cells together in strong
    sheets (keratin- intermediate filament)
  • b) tight junctions proteins that tie cells
    together, leaving no space between the cells-
    cells fused (ie. intestines)
  • c) communication junctions (2 kinds) allow flow
    of salt ions, sugars, amino acids- cytoplasmic
    channels between adjacent cells. (ie. heart
    muscle cells, cells of embryo)
  • gap junction (animal cells) membrane channels
    that allow passage of material between cells.
  • Plasmodesmata (plant cells) openings in the cell
    wall where adjacent membranes contact each other.

67
desmosome (anchoring junction)
  • (plaques fibers) rivets
  • fasten cells together in strong sheets.
  • keratin- intermediate filament.

68
tight junction
  • tight junctions proteins that tie cells
    together, leaving no space between the cells-
    cells fused (ie. intestines)

69
Gap (communicating junction)
  • communication junctions
  • (2 kinds)
  • allow flow of salt ions, sugars, amino acids-
    cytoplasmic channels between adjacent cells.
  • ie. heart muscle cells, cells of embryo
  • gap junction (animal cells) membrane channels
    that allow passage of material between cells.
  • Plasmodesmata (plant cells) openings in the cell
    wall where adjacent membranes contact each other.

70
Figure 7.30 Intercellular junctions in animal
tissues
71
The End
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