1. Chapter 3 Lecture PowerPoint
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2. 2401 Anatomy and Physiology I Chapter 3
Paris Junior College
2401 Anatomy and Physiology I Chapter 3
Susan Gossett
Department of Biology

3. Hole’s Human Anatomy and Physiology Twelfth Edition Shier w Butler w Lewis
Chapter 3
Cells
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4. 3.1: Introduction
The basic organizational structure of the human body is the cell.
There are trillion cells in the human body.
Differentiation is when cells specialize.
As a result of differentiation, cells vary in size and shape due to their unique function.

5. 3.2: A Composite Cell Also called a ‘typical’ cell
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Also called a ‘typical’
cell
Major parts include:
Nucleus
Cytoplasm
Cell membrane
Phospholipid bilayer
Flagellum
Nucleus
Nuclear envelope
Chromatin
Nucleolus
Ribosomes
Microtubules
Basal body
Cell membrane
Centrioles
Rough
Endoplasmic
reticulum
Mitochondrion
Smooth
Endoplasmic
reticulum
Microvilli
Secretory
vesicles
Cilia
Golgi
apparatus
Microtubule
Microtubules L
ysosomes

6. Cell Membrane (aka Plasma Membrane)
Outer limit of the cell
Controls what moves in and out of the cell
Selectively permeable
Phospholipid bilayer
Water-soluble “heads” form surfaces (hydrophilic)
Water-insoluble “tails” form interior (hydrophobic)
Permeable to lipid-soluble substances
Cholesterol stabilizes the membrane
Proteins:
Receptors
Pores, channels and carriers
Enzymes
CAMS
Self-markers

7. a: © Biophoto Associates/Photo Researchers, Inc.
Cell Membrane
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Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Extracellular side
of membrane
Glycolipid
Carbohydrate
Fibrous protein
Glycoprotein
Cell membrane
(b)
“Heads” of
phospholipid
Double
layer of
Phospholipid
molecules
“Tails” of
phospholipid
Cholesterol
molecules
Globular
protein
Hydrophobic
fatty acid
“tail”
(a)
a: © Biophoto Associates/Photo Researchers, Inc.
Cytoplasmic side
of membrane
Hydrophilic
Phosphate
“head”

8. Cytoplasm Cytosol = water Organelles = solids
Cytoplasm is really like a Jello fruit salad where the Jello is the cytosol and the fruits (oranges, grapes, bananas, maybe walnuts, etc.) are the organelles.

9. Organelles Endoplasmic Reticulum (ER)
Connected, membrane-bound sacs, canals, and vesicles
Transport system
Rough ER
Studded with ribosomes
Smooth ER
Lipid synthesis
Added to proteins arriving from rough ER
Break down of drugs
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Membranes
Membranes
Ribosomes
(b)
(c)
Ribosomes
Free floating or connected to ER
Provide structural support and enzyme activity to amino acids to form protein

10. a: © Bill Longcore/Photo Researchers, Inc.
Organelles
Golgi apparatus
Stack of flattened, membranous sacs
Modifies, packages and delivers proteins
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Vesicles
Membranous sacs
Store substances
Inner membrane
Cristae
Mitochondria
Membranous sacs with inner partitions
Generate energy
Outer membrane
(a)
(b)
a: © Bill Longcore/Photo Researchers, Inc.

11. a: © Don W. Fawcett/Visuals Unlimited
Organelles
Lysosomes
Enzyme-containing sacs
Digest worn out cell parts or unwanted substances
Centrosome
Two rod-like centrioles
Used to produce cilia and flagella
Distributes chromosomes during cell division
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Peroxisomes
Enzyme-containing sacs
Break down organic molecules
Centriole
(cross-section)
Centriole
(longitudinal section)
(a)
a: © Don W. Fawcett/Visuals Unlimited
(b)

12. Organelles Cilia Short hair-like projections
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Cilia
Short hair-like projections
Propel substances on cell surface
Flagellum
Long tail-like projection
Provides motility to sperm
a: © Oliver Meckes/Photo Researchers, Inc.
© Colin Anderson/Brand X/CORBIS

13. © M. Schliwa/Visuals Unlimited
Organelles
Microfilaments and microtubules
Thin rods and tubules
Support cytoplasm
Allows for movement of
organelles
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Microtubules
Inclusions
Temporary nutrients and pigments
Microfilaments
© M. Schliwa/Visuals Unlimited

14. Cell Nucleus Control center of the cell Nuclear envelope Nucleolus
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Nuclear envelope
Porous double membrane
Separates nucleoplasm from cytoplasm
Nucleolus
Dense collection of RNA and proteins
Site of ribosome production
Nucleus
Nuclear
envelope
Nucleolus
Chromatin
Fibers of DNA and proteins
Stores information for synthesis of proteins
Chromatin
Nuclear
pores
(a)

15. 3.3: Movements Into and Out of the Cell
Passive (Physical) Processes
Require no cellular energy and include:
Simple diffusion
Facilitated diffusion
Osmosis
Filtration
Active (Physiological) Processes
Require cellular energy and include:
Active transport
Endocytosis
Exocytosis
Transcytosis

16. Simple Diffusion
Movement of substances from regions of higher concentration to regions of lower concentration
Oxygen, carbon dioxide and lipid-soluble substances
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Permeable membrane
Solute molecule W
ater molecule A B A B A B
(1)
(2)
(3) T
ime

17. Facilitated Diffusion
Diffusion across a membrane with the help of a channel or carrier molecule
Glucose and amino acids
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Region of higher
concentration
Transported
substance
Region of lower
concentration
Protein carrier
molecule
Cell
membrane

18. Osmosis
Movement of water through a selectively permeable membrane from regions of higher concentration to regions of lower concentration
Water moves toward a higher concentration of solutes
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Selectively
permeable
membrane
Protein molecule W
ater molecule A A B B
(1)
(2) T
ime

19. Osmosis and Osmotic Pressure
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Osmotic Pressure – ability of osmosis to generate enough pressure to move a volume of water
Osmotic pressure increases as the concentration of nonpermeable solutes increases
(a)
Isotonic – same osmotic pressure
Hypertonic – higher osmotic pressure (water loss)
Hypotonic – lower osmotic pressure (water gain)
(b)
(c)
© David M. Phillips/Visuals Unlimited

20. Filtration Smaller molecules are forced through porous membranes
Hydrostatic pressure important in the body
Molecules leaving blood capillaries
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Capillary wall
Tissue fluid
Blood
pressure
Blood
flow
Larger molecules
Smaller molecules

21. Active Transport
Carrier molecules transport substances across a membrane from regions of lower concentration to regions of higher concentration
Sugars, amino acids, sodium ions, potassium ions, etc.
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Carrier protein
Binding site
Region of higher
concentration
Cell membrane
Region of lower
concentration
Phospholipid
molecules
Transported
particle
(a)
Carrier protein
with altered shape
Cellular
energy
(b)

22. Active Transport: Sodium-Potassium Pump
Active transport mechanism
Creates balance by “pumping” three (3) sodium (Na+) OUT and two (2) potassium (K+) INTO the cell
3:2 ratio

23. Endocytosis
Cell engulfs a substance by forming a vesicle around the substance
Three types:
Pinocytosis – substance is mostly water
Phagocytosis – substance is a solid
Receptor-mediated endocytosis – requires the substance to bind to a membrane-bound receptor
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Cell
membrane V
esicle
Nucleus
Nucleolus

24. Endocytosis Cell membrane Particle Phagocytized particle Vesicle
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Cell
membrane
Particle
Phagocytized
particle
Vesicle
Nucleus
Nucleolus
Molecules
outside cell
Receptor-ligand
combination V
esicle
Receptor
protein
Cell
membrane
Cell
membrane
indenting
Cytoplasm
(a)
(b)
(c)
(d)

25. Exocytosis Reverse of endocytosis
Substances in a vesicle fuse with cell membrane
Contents released outside the cell
Release of neurotransmitters from nerve cells
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Endoplasmic
reticulum
Golgi
apparatus
Nucleus

26. Receptor-mediated endocytosis
Transcytosis
Endocytosis followed by exocytosis
Transports a substance rapidly through a cell
HIV crossing a cell layer
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HIV-infected
white blood cells
Anal or
vaginal canal V
iruses bud
HIV
Receptor-mediated endocytosis
Lining of anus
or vagina
(epithelial cells)
Exocytosis
Cell
membrane
Receptor-mediated
endocytosis
Virus infects
white blood cells on
other side of lining

27. 3.4: The Cell Cycle
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Series of changes a cell undergoes from the time it forms until the time it divide
Stages:
Interphase
Mitosis
Cytokinesis
G2 phase
Interphase
Prophase
Mitosis
S phase:
genetic
material
replicates
Metaphase
Anaphase
Telophase
G1 phase
cell growth
Cytokinesis
Proceed
to division
Remain
specialized
Restriction
checkpoint
Apoptosis

28. Interphase Very active period Cell grows
Cell maintains routine functions
Cell replicates genetic material to prepare for nuclear division
Cell synthesizes new organelles to prepare for cytoplasmic division
Phases:
G phases – cell grows and synthesizes structures other than DNA
S phase – cell replicates DNA

29. Mitosis Produces two daughter cells from an original somatic cell
Nucleus divides – karyokinesis
Cytoplasm divides – cytokinesis
Phases of nuclear division:
Prophase – chromosomes form; nuclear envelope disappears
Metaphase – chromosomes align midway between centrioles
Anaphase – chromosomes separate and move to centrioles
Telophase – chromatin forms; nuclear envelope forms

30. Mitosis Late Interphase Cell has passed the restriction checkpoint
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Late Interphase
Cell has passed the
restriction checkpoint
and completed DNA
replication, as well as
replication of centrioles
and mitochondria, and
synthesis of extra
membrane.
Early Interphase
of daughter cells—
a time of normal cell
growth and function.
(a)
Restriction
checkpoint
Nuclear
envelope
Chromatin
fibers
Centrioles
Cleavage
furrow
Aster
Prophase
Chromosomes condense and
become visible. Nuclear
envelope and nucleolus
disperse. Spindle apparatus
forms.
Microtubules
(e)
(b)
Centromere
Spindle fiber
Late prophase
Chromosomes
Sister
chromatids
Nuclear
envelopes
Telophase and Cytokinesis
Nuclear envelopes begin to
reassemble around two daughter
nuclei. Chromosomes decondense.
Spindle disappears. Division of
the cytoplasm into two cells.
(d)
(c)
Mitosis
Cytokinesis
G1 phase
Anaphase
Sister chromatids separate to
opposite poles of cell. Events
begin which lead to cytokinesis.
Metaphase
Chromosomes align along
equator, or metaphase plate
of cell.
S phase
Interphase
G2 phase
© Ed Reschke

31. Cytoplasmic Division Also known as cytokinesis Begins during anaphase
Continues through telophase
Contractile ring pinches cytoplasm in half

32. 3.5: Control of Cell Division
Cell division capacities vary greatly among cell types
Skin and blood cells divide often and continually
Neuron cells divide a specific number of times then cease
Chromosome tips (telomeres) that shorten with each mitosis provide a mitotic clock
Cells divide to provide a more favorable surface area to volume relationship
Growth factors and hormones stimulate cell division
Hormones stimulate mitosis of smooth muscle cells in uterus
Epidermal growth factor stimulates growth of new skin
Contact (density dependent) inhibition
Tumors are the consequence of a loss of cell cycle control

33. © Tony Brain/Photo Researchers, Inc.;
Tumors
Two types of tumors:
Benign – usually remains localized
Malignant – invasive and can metastasize; cancerous
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Normal cells
(with hairlike cilia)
Two major types of genes cause cancer:
Oncogenes – activate other genes that increase cell division
Tumor suppressor genes – normally regulate mitosis; if inactivated they are unable to regulate mitosis
Cells are now known as “immortal”
Cancer cells
© Tony Brain/Photo Researchers, Inc.;

34. 3.6: Stem and Progenitor Cells
Stem cell:
Can divide to form two new stem cells
Self-renewal
Can divide to form a stem cell and a progenitor cell
Totipotent – can give rise to every cell type
Pluripotent – can give rise to a restricted number of cell types
Progenitor cell:
Committed cell
Can divide to become any of a restricted number of cells
Pluripotent

35. Stem and Progenitor Cells
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Sperm
Egg
Sebaceous
gland cell
Progenitor
cell
Fertilized
egg
Progenitor cell
Skin cell
Stem cell
Progenitor
cell
Progenitor
cell
Stem cell
Neuron
Progenitor
cell
Progenitor
cell
Progenitor
cell
Astrocyte
Progenitor
cell
Progenitor
cell
Progenitor
cell
Bone cells
one or more steps
Fibroblasts (a connective tissue cells)
produces another stem cell
(self-renewal)
Blood cells and platelets

36. 3.1 From Science to Technology
Therapeutic Stem Cells

37. 3.7: Cell Death Apoptosis: Programmed cell death
Acts as a protective mechanism
Is a continuous process

38. Important Points in Chapter 3: Outcomes to be Assessed
3.1: Introduction
Define cell.
State the range of cell numbers and cells sizes in a human body.
State the term for cell specialization.
3.2: A Composite Cell
List the three major parts of a composite cell.
State the general function of organelles.
Explain how the structure of a cell membrane makes possible its function.
Describe each type of organelle, and explain its function.
Describe the parts of a cell nucleus and their functions.

39. Important Points in Chapter 3: Outcomes to be Assessed
3.3: Movement Into and Out of the Cell
Explain the various ways that substances move through the cell membrane.
Discuss how the mechanisms of crossing cell membranes differ.
3.4: The Cell Cycle
Describe the parts of the cell cycle and identify the major activities during each part.
Explain why regulation of the cell cycle is important to health.
Distinguish between mitosis and cytokinesis.
List the stages of mitosis and describe the events of each stage.

40. Important Points in Chapter 3: Outcomes to be Assessed
3.5: Control of Cell Division
Explain how different types of cells differ in their rate of cells division.
State the range of cell divisions a cell typically undergoes.
Discuss factors that influence whether or not a cell divides.
Explain how cancer arises from too-frequent cell division.
Distinguish the two types of genetic control of cancer.
3.6: Stem and Progenitor Cells
Define differentiation.
Distinguish between a stem cell and a progenitor cell.
Explain how two differentiated cell types can have the same genetic information, but different appearances and functions.

41. Important Points in Chapter 3: Outcomes to be Assessed
3.7: Cell Death
Define apoptosis.
Distinguish apoptosis from necrosis.
List the steps of apoptosis.
Describe the relationship between apoptosis and mitosis.

42. Quiz 3
Complete Quiz 3 now!
Read Chapter 4.