Cells and Tissues Lecture Presentation

Summary

This lecture presentation by Patty Bostwick-Taylor covers Chapter 3 of Essentials of Human Anatomy & Physiology, and provides an overview of cells and tissues. The presentation details the cell theory, the three main regions of a generalized cell (nucleus, cytoplasm, plasma membrane), and the role of the nucleus (including nuclear envelope, nucleolus, and chromatin). It also discusses the fluid mosaic model of the plasma membrane.

Full Transcript

Chapter 3
Cells and Tissues

Lecture Presentation by
Patty Bostwick-Taylor
Florence-Darlington Technical College

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 Part I: Cells

▪ Cells are the structural units of all living things
▪ The human body has 50 to 100 trillion cells

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 Overview of the Cellular Basis of Life

▪ The Cell Theory
1. A cell is the basic structural and functional unit of
living organisms
2. The activity of an organism depends on the collective
activities of its cells
3. According to the principle of complementarity, the
biochemical activities of cells are dictated by their
structure (anatomy) which determines their function
(physiology)
4. Continuity of life has a cellular basis

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 Overview of the Cellular Basis of Life

▪ Most cells are composed of four elements:
1. Carbon
2. Hydrogen
3. Oxygen
4. Nitrogen
▪ Cells are about 60% water

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 Anatomy of a Generalized Cell

▪ In general, a cell has three main regions or parts:
1. Nucleus
2. Cytoplasm
3. Plasma membrane

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Figure 3.1a Anatomy of the generalized animal cell nucleus.

Nucleu
s

Cytoplas
m
Plasma
membran
e
(a) Generalized animal
cell

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 The Nucleus

▪ Control center of the cell
▪ Contains genetic material known as
deoxyribonucleic acid, or DNA
▪ DNA is needed for building proteins
▪ DNA is necessary for cell reproduction
▪ Three regions:
1. Nuclear envelope (membrane)
2. Nucleolus
3. Chromatin

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Figure 3.1b Anatomy of the generalized animal cell nucleus.

Nuclear
envelope
Chromati
n Nucleus
Nucleolu
s
Nuclea
r
pores

(b)
Nucleus
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 The Nucleus

▪ Nuclear envelope (membrane)
▪ Consists of a double membrane that bounds the
nucleus
▪ Contains nuclear pores that allow for exchange of
material with the rest of the cell
▪ Encloses the jellylike fluid called the nucleoplasm

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 The Nucleus

▪ Nucleolus
▪ Nucleus contains one or more dark-staining nucleoli
▪ Sites of ribosome assembly
▪ Ribosomes migrate into the cytoplasm through nuclear
pores to serve as the site of protein synthesis

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 The Nucleus

▪ Chromatin
▪ Composed of DNA wound around histones (proteins)
▪ Scattered throughout the nucleus and present when
the cell is not dividing
▪ Condenses to form dense, rodlike bodies called
chromosomes when the cell divides

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 The Plasma Membrane

▪ Transparent barrier for cell contents
▪ Contains cell contents
▪ Separates cell contents from surrounding
environment

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 The Plasma Membrane

▪ Fluid mosaic model is constructed of:
▪ Two layers of phospholipids arranged “tail to tail”
▪ Cholesterol and proteins scattered among the
phospholipids
▪ Sugar groups may be attached to the phospholipids,
forming glycolipids

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Figure 3.2 Structure of the plasma membrane.

Extracellular fluid Glycoprotein Glycolipid
(watery environment)
Cholesterol

Sugar group

Polar heads of
phospholipid
molecules

Bimolecular
lipid layer
containing
proteins Channel

Nonpolar tails of Proteins Filaments of
phospholipid cytoskeleton Cytoplasm
molecules
(watery environment)

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© 2018 Pearson Education, Ltd.
 The Plasma Membrane

▪ Phospholipid arrangement in the plasma
membrane
▪ Hydrophilic (“water loving”) polar “heads” are oriented
on the inner and outer surfaces of the membrane
▪ Hydrophobic (“water fearing”) nonpolar “tails” form the
center (interior) of the membrane
▪ This interior makes the plasma membrane relatively
impermeable to most water-soluble molecules

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 The Plasma Membrane

▪ Role of proteins
▪ Responsible for specialized membrane functions:
▪ Enzymes
▪ Receptors for hormones or other chemical messengers
▪ Transport as channels or carriers

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 The Plasma Membrane

▪ Role of sugars
▪ Glycoproteins are branched sugars attached to
proteins that abut the extracellular space
▪ Glycocalyx is the fuzzy, sticky, sugar-rich area on the
cell’s surface

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 The Plasma Membrane

▪ Cell membrane junctions
▪ Cells are bound together in three ways:
1. Glycoproteins in the glycocalyx act as an adhesive or
cellular glue
2. Wavy contours of the membranes of adjacent cells fit
together in a tongue-and-groove fashion
3. Special cell membrane junctions are formed, which
vary structurally depending on their roles

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 The Plasma Membrane

▪ Main types of cell junctions
▪ Tight junctions
▪ Impermeable junctions
▪ Bind cells together into leakproof sheets
▪ Plasma membranes fuse like a zipper to prevent
substances from passing through extracellular space
between cells

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 The Plasma Membrane

▪ Main types of cell junctions (continued)
▪ Desmosomes
▪ Anchoring junctions, like rivets, that prevent cells from
being pulled apart as a result of mechanical stress
▪ Created by buttonlike thickenings of adjacent plasma
membranes

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 The Plasma Membrane

▪ Main types of cell junctions (continued)
▪ Gap junctions (communicating junctions)
▪ Allow communication between cells
▪ Hollow cylinders of proteins (connexons) span the width
of the abutting membranes
▪ Molecules can travel directly from one cell to the next
through these channels

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Figure 3.3 Cell junctions.

Microvilli Tight
(impermeable)
junction

Desmosom
e
(anchoring
junction)

Plasma
membranes of
adjacent cells
Connexon

Underlying Extracellular Gap
basement space between (communicating)
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membrane cells junction
 The Cytoplasm

▪ The cellular material outside the nucleus and
inside the plasma membrane
▪ Site of most cellular activities
▪ Includes cytosol, inclusions, and organelles

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 The Cytoplasm

▪ Three major component of the cytoplasm
1. Cytosol: Fluid that suspends other elements and
contains nutrients and electrolytes
2. Inclusions: Chemical substances, such as stored
nutrients or cell products, that float in the cytosol
3. Organelles: Metabolic machinery of the cell that
perform functions for the cell
▪ Many are membrane-bound, allowing for
compartmentalization of their functions

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Figure 3.4 Structure of the generalized cell.

Chromatin Nuclear envelope
Nucleolus Nucleus

Plasma
Smooth endoplasmic
membrane
reticulum
Cytosol

Lysosome

Mitochondrion
Rough
endoplasmic
reticulum
Centrioles
Ribosomes

Golgi apparatus

Secretion being released
Microtubule from cell by exocytosis
Peroxisome

Intermediate
filaments
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 The Cytoplasm

▪ Mitochondria
▪ “Powerhouses” of the cell
▪ Mitochondrial wall consists of a double membrane with
cristae on the inner membrane
▪ Carry out reactions in which oxygen is used to break
down food into ATP molecules

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 The Cytoplasm

▪ Ribosomes
▪ Made of protein and ribosomal RNA
▪ Sites of protein synthesis in the cell
▪ Found at two locations:
▪ Free in the cytoplasm
▪ As part of the rough endoplasmic reticulum

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 The Cytoplasm

▪ Endoplasmic reticulum (ER)
▪ Fluid-filled tunnels (or canals) that carry substances
within the cell
▪ Continuous with the nuclear membrane
▪ Two types:
▪ Rough ER
▪ Smooth ER

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 The Cytoplasm

▪ Endoplasmic reticulum (ER) (continued)
▪ Rough endoplasmic reticulum
▪ Studded with ribosomes
▪ Synthesizes proteins
▪ Transport vesicles move proteins within cell
▪ Abundant in cells that make and export proteins

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Figure 3.5 Synthesis and export of a protein by the rough ER. Slide 1

Ribosome
mRNA
1 As the protein is synthesized on the ribosome,
Rough ER it migrates into the rough ER tunnel system.

2
1 3 2 In the tunnel, the protein folds into its
functional shape. Short sugar chains may be
attached to the protein (forming a glycoprotein).
Protei
n
3 The protein is packaged in a tiny
membranous sac called a transport vesicle.
Transport 4
vesicle buds
off 4 The transport vesicle buds from the rough ER
and travels to the Golgi apparatus for further
processing.

Protein inside
transport vesicle

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Figure 3.5 Synthesis and export of a protein by the rough ER. Slide 2

Ribosome
mRNA
1 As the protein is synthesized on the ribosome,
Rough ER it migrates into the rough ER tunnel system.

1

Protei
n

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Figure 3.5 Synthesis and export of a protein by the rough ER. Slide 3

Ribosome
mRNA
1 As the protein is synthesized on the ribosome,
Rough ER it migrates into the rough ER tunnel system.

2
1 2 In the tunnel, the protein folds into its
functional shape. Short sugar chains may be
attached to the protein (forming a glycoprotein).
Protei
n

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Figure 3.5 Synthesis and export of a protein by the rough ER. Slide 4

Ribosome
mRNA
1 As the protein is synthesized on the ribosome,
Rough ER it migrates into the rough ER tunnel system.

2
1 3 2 In the tunnel, the protein folds into its
functional shape. Short sugar chains may be
attached to the protein (forming a glycoprotein).
Protei
n
3 The protein is packaged in a tiny
membranous sac called a transport vesicle.
Transport
vesicle buds
off

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Figure 3.5 Synthesis and export of a protein by the rough ER. Slide 5

Ribosome
mRNA
1 As the protein is synthesized on the ribosome,
Rough ER it migrates into the rough ER tunnel system.

2
1 3 2 In the tunnel, the protein folds into its
functional shape. Short sugar chains may be
attached to the protein (forming a glycoprotein).
Protei
n
3 The protein is packaged in a tiny
membranous sac called a transport vesicle.
Transport 4
vesicle buds
off 4 The transport vesicle buds from the rough ER
and travels to the Golgi apparatus for further
processing.

Protein inside
transport vesicle

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 The Cytoplasm

▪ Endoplasmic reticulum (ER) (continued)
▪ Smooth endoplasmic reticulum
▪ Lacks ribosomes
▪ Functions in lipid metabolism
▪ Detoxification of drugs and pesticides

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 The Cytoplasm

▪ Golgi apparatus
▪ Appears as a stack of flattened membranes associated
with tiny vesicles
▪ Modifies and packages proteins arriving from the
rough ER via transport vesicles
▪ Produces different types of packages
▪ Secretory vesicles (pathway 1)
▪ In-house proteins and lipids (pathway 2)
▪ Lysosomes (pathway 3)

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Figure 3.6 Role of the Golgi apparatus in packaging the products of the rough ER.

Rough ER Tunnels Proteins in tunnels

Membrane Lysosome fuses with
ingested substances.
Transport
vesicle

Golgi vesicle containing
digestive enzymes
becomes a lysosome.
Pathway
3

Pathway Golgi vesicle containing
Golgi
2 membrane components
apparatus
Secretory vesicles fuses with the plasma
Pathway
membrane and is
1 Proteins
Golgi vesicle containing incorporated into it.
proteins to be secreted Plasma membrane
becomes a secretory Secretion by
vesicle. exocytosis Extracellular fluid

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 The Cytoplasm

▪ Lysosomes
▪ Membranous “bags” that contain digestive enzymes
▪ Enzymes can digest worn-out or nonusable cell
structures
▪ House phagocytes that dispose of bacteria and cell
debris

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 The Cytoplasm

▪ Peroxisomes
▪ Membranous sacs of oxidase enzymes
▪ Detoxify harmful substances such as alcohol and
formaldehyde
▪ Break down free radicals (highly reactive chemicals)
▪ Free radicals are converted to hydrogen peroxide and
then to water
▪ Replicate by pinching in half or budding from the ER

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 The Cytoplasm

▪ Cytoskeleton
▪ Network of protein structures that extend throughout
the cytoplasm
▪ Provides the cell with an internal framework that
determines cell shape, supports organelles, and
provides the machinery for intracellular transport
▪ Three different types of elements form the
cytoskeleton:
1. Microfilaments (largest)
2. Intermediate filaments
3. Microtubules (smallest)

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Figure 3.7 Cytoskeletal elements support the cell and help to generate movement.

(a) (b) Intermediate (c)
Microfilaments filaments Microtubules
Tubulin subunits
Fibrous subunits
Actin subunit

7 nm 10 nm 25 nm

Microfilaments form the blue Intermediate filaments form Microtubules appear as gold
batlike network. the purple network surrounding networks surrounding the cells’
the pink nucleus. pink nuclei.

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 The Cytoplasm

▪ Centrioles
▪ Rod-shaped bodies made of nine triplets of
microtubules
▪ Generate microtubules
▪ Direct the formation of mitotic spindle during cell
division

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Table 3.1 Parts of the Cell: Structure and Function (1 of 5)

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Table 3.1 Parts of the Cell: Structure and Function (2 of 5)

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Table 3.1 Parts of the Cell: Structure and Function (3 of 5)

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Table 3.1 Parts of the Cell: Structure and Function (4 of 5)

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Table 3.1 Parts of the Cell: Structure and Function (5 of 5)

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 Cell Extensions

▪ Surface extensions found in some cells
▪ Cilia move materials across the cell surface
▪ Located in the respiratory system to move mucus
▪ Flagella propel the cell
▪ The only flagellated cell in the human body is sperm
▪ Microvilli are tiny, fingerlike extensions of the plasma
membrane
▪ Increase surface area for absorption

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Figure 3.8g Cell diversity.

Nucleus Flagellum

Sper
m
(g) Cell of
reproduction

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 Cell Diversity

▪ The human body houses over 200 different cell
types
▪ Cells vary in size, shape, and function
▪ Cells vary in length from 1/12,000 of an inch to over
1 yard (nerve cells)
▪ Cell shape reflects its specialized function

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 Cell Diversity

▪ Cells that connect body parts
▪ Fibroblast
▪ Secretes cable-like fibers
▪ Erythrocyte (red blood cell)
▪ Carries oxygen in the bloodstream

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Figure 3.8a Cell diversity.

Fibroblast Rough ER and
s Golgi apparatus
No organelles
Secreted
fibers

Nucleus
Erythrocyte
(a) Cells that connect body s
parts

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 Cell Diversity

▪ Cells that cover and line body organs
▪ Epithelial cell
▪ Packs together in sheets
▪ Intermediate fibers resist tearing during rubbing or
pulling

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Figure 3.8b Cell diversity.

Epithelia Nucleus
l Intermediate
cells filaments

(b) Cells that cover and line body
organs

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 Cell Diversity

▪ Cells that move organs and body parts
▪ Skeletal muscle and smooth muscle cells
▪ Contractile filaments allow cells to shorten forcefully

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Figure 3.8c Cell diversity.

Skeletal
Nuclei
muscle
cell
Contractile
Smooth
filaments
muscle
cells

(c) Cells that move organs and body
parts

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 Cell Diversity

▪ Cell that stores nutrients
▪ Fat cells
▪ Lipid droplets stored in cytoplasm

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Figure 3.8d Cell diversity.

Fat Lipid droplet
cell

Nucleus

(d) Cell that stores
nutrients

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 Cell Diversity

▪ Cell that fights disease
▪ White blood cells, such as the macrophage (a
phagocytic cell)
▪ Digests infectious microorganisms

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Figure 3.8e Cell diversity.

Lysosomes
Macrophag
e
Pseudopods

(e) Cell that fights
disease

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 Cell Diversity

▪ Cell that gathers information and controls body
functions
▪ Nerve cell (neuron)
▪ Receives and transmits messages to other body
structures

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Figure 3.8f Cell diversity.

Processes
Rough ER

Nerve
cell
Nucleus

(f) Cell that gathers information
and
controls body functions

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 Cell Diversity

▪ Cells of reproduction
▪ Oocyte (female)
▪ Largest cell in the body
▪ Divides to become an embryo upon fertilization
▪ Sperm (male)
▪ Built for swimming to the egg for fertilization
▪ Flagellum acts as a motile whip

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Figure 3.8g Cell diversity.

Nucleus Flagellum

Sper
m
(g) Cell of
reproduction

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 Cell Physiology

▪ Cells have the ability to:
▪ Metabolize
▪ Digest food
▪ Dispose of wastes
▪ Reproduce
▪ Grow
▪ Move
▪ Respond to a stimulus

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 Membrane Transport

▪ Solution—homogeneous mixture of two or more
components
▪ Solvent—dissolving medium present in the larger
quantity; the body’s main solvent is water
▪ Solutes—components in smaller quantities within a
solution

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 Membrane Transport

▪ Intracellular fluid
▪ Nucleoplasm and cytosol
▪ Solution containing gases, nutrients, and salts
dissolved in water
▪ Extracellular fluid (interstitial fluid)
▪ Fluid on the exterior of the cell
▪ Contains thousands of ingredients, such as nutrients,
hormones, neurotransmitters, salts, waste products

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 Membrane Transport

▪ The plasma membrane is a selectively permeable
barrier
▪ Some materials can pass through, while others are
excluded
▪ For example:
▪ Nutrients can enter the cell
▪ Undesirable substances are kept out

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 Membrane Transport

▪ Two basic methods of transport
▪ Passive processes: substances are transported across
the membrane without any input from the cell
▪ Active processes: the cell provides the metabolic
energy (ATP) to drive the transport process

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 A&P FlixTM: Membrane Transport

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 Membrane Transport

▪ Passive processes: diffusion and filtration
▪ Diffusion
▪ Molecule movement is from high concentration to low
concentration, down a concentration gradient
▪ Particles tend to distribute themselves evenly within a
solution
▪ Kinetic energy (energy of motion) causes the molecules
to move about randomly
▪ Size of the molecule and temperature affect the speed
of diffusion

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Figure 3.9 Diffusion.

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 Membrane Transport

▪ Molecules will move by diffusion if any of the
following applies:
▪ The molecules are small enough to pass through
the membrane’s pores (channels formed by
membrane proteins)
▪ The molecules are lipid-soluble
▪ The molecules are assisted by a membrane
carrier

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 Membrane Transport

▪ Types of diffusion
▪ Simple diffusion
▪ An unassisted process
▪ Solutes are lipid-soluble or small enough to pass
through membrane pores

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Figure 3.10a Diffusion through the plasma membrane.

Extracellular fluid
Lipid-
soluble
solutes

Cytoplasm

(a) Simple
diffusion
of lipid-soluble
solutes directly
through the
phospholipid
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bilayer
 Membrane Transport

▪ Types of diffusion (continued)
▪ Osmosis—simple diffusion of water across a
selectively permeable membrane
▪ Highly polar water molecules easily cross the plasma
membrane through aquaporins
▪ Water moves down its concentration gradient

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Figure 3.10b Diffusion through the plasma membrane.

Water
molecules

(b) Osmosis,
diffusion of water
through a specific
channel protein
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 Membrane Transport

▪ Osmosis—A Closer Look
▪ Isotonic solutions have the same solute and water
concentrations as cells and cause no visible changes
in the cell
▪ Hypertonic solutions contain more solutes than the
cells do; the cells will begin to shrink
▪ Hypotonic solutions contain fewer solutes (more water)
than the cells do; cells will plump

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A Closer Look 3.1 IV Therapy and Cellular “Tonics.”

(a) RBC in isotonic (b) RBC in hypertonic (c) RBC in hypotonic
solution solution solution

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 Membrane Transport

▪ Types of diffusion (continued)
▪ Facilitated diffusion
▪ Transports lipid-insoluble and large substances
▪ Glucose is transported via facilitated diffusion
▪ Protein membrane channels or protein molecules that
act as carriers are used

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Figure 3.10cd Diffusion through the plasma membrane.

Small lipid- Lipid-
insoluble insoluble
solutes solutes

Lipid
bilayer

(c) Facilitated (d) Facilitated diffusion via
diffusion protein carrier specific for one
through chemical; binding of substrate
a channel protein; causes shape change in
mostly ions, transport protein
selected on basis
of size and charge

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 Membrane Transport

▪ Passive processes
▪ Filtration
▪ Water and solutes are forced through a membrane by
fluid, or hydrostatic, pressure
▪ A pressure gradient must exist that pushes
solute-containing fluid (filtrate) from a high-pressure
area to a lower-pressure area
▪ Filtration is critical for the kidneys to work properly

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 Membrane Transport

▪ Active processes
▪ ATP is used to move substances across a membrane
▪ Active processes are used when:
▪ Substances are too large to travel through membrane
channels
▪ The membrane may lack special protein carriers for the
transport of certain substances
▪ Substances may not be lipid-soluble
▪ Substances may have to move against a concentration
gradient

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 Membrane Transport

▪ Active processes (continued)
▪ Active transport and vesicular transport
▪ Active transport
▪ Amino acids, some sugars, and ions are transported by
protein carriers known as solute pumps
▪ ATP energizes solute pumps
▪ In most cases, substances are moved against
concentration (or electrical) gradients

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 Membrane Transport

▪ Active transport example: sodium-potassium
pump
▪ Necessary for nerve impulses
▪ Sodium is transported out of the cell
▪ Potassium is transported into the cell

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Figure 3.11 Operation of the sodium-potassium pump, a solute pump. Slide 1

Extracellular fluid
Na+
+
Na K+

Na+-K+ pump Na+

Na+

Na+
K+

Pi

Pi
Na+ K+
+
Na
AT
1 2 3 K+
P
AD
P

1 Binding of cytoplasmic Na+ 2 The shape change expels 3 Loss of phosphate restores
to the pump protein stimulates Na+ to the outside. Extracellular the original shape of the pump
phosphorylation by ATP, which K+ binds, causing release of the protein. K+ is released to the
causes the pump protein to inorganic phosphate group. cytoplasm, and Na+ sites are
change its shape. ready to bind Na+ again; the
cycle repeats.
Cytoplasm

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Figure 3.11 Operation of the sodium-potassium pump, a solute pump. Slide 2

Extracellular fluid

Na+-K+ pump

Na+

Na+

Pi

Na+
AT
1
P
AD
P

1 Binding of cytoplasmic Na+
to the pump protein stimulates
phosphorylation by ATP, which
causes the pump protein to
change its shape.

Cytoplasm

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Figure 3.11 Operation of the sodium-potassium pump, a solute pump. Slide 3

Extracellular fluid
Na+
+
Na K+

Na+-K+ pump Na+

Na+

Na+
K+

Pi

Pi
+
Na
AT
1 2
P
AD
P

1 Binding of cytoplasmic Na+ 2 The shape change expels
to the pump protein stimulates Na+ to the outside. Extracellular
phosphorylation by ATP, which K+ binds, causing release of the
causes the pump protein to inorganic phosphate group.
change its shape.

Cytoplasm

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Figure 3.11 Operation of the sodium-potassium pump, a solute pump. Slide 4

Extracellular fluid
Na+
+
Na K+

Na+-K+ pump Na+

Na+

Na+
K+

Pi

Pi
Na+ K+
+
Na
AT
1 2 3 K+
P
AD
P

1 Binding of cytoplasmic Na+ 2 The shape change expels 3 Loss of phosphate restores
to the pump protein stimulates Na+ to the outside. Extracellular the original shape of the pump
phosphorylation by ATP, which K+ binds, causing release of the protein. K+ is released to the
causes the pump protein to inorganic phosphate group. cytoplasm, and Na+ sites are
change its shape. ready to bind Na+ again; the
cycle repeats.
Cytoplasm

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 Membrane Transport

▪ Active processes (continued)
▪ Vesicular transport: substances are moved across the
membrane “in bulk” without actually crossing the
plasma membrane
▪ Types of vesicular transport
▪ Exocytosis
▪ Endocytosis
▪ Phagocytosis
▪ Pinocytosis

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 Membrane Transport

▪ Exocytosis
▪ Mechanism cells use to actively secrete hormones,
mucus, and other products
▪ Material is carried in a membranous sac called a
vesicle that migrates to and combines with the plasma
membrane
▪ Contents of vesicle are emptied to the outside
▪ Refer to pathway 1 in Figure 3.6

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Figure 3.6 Role of the Golgi apparatus in packaging the products of the rough ER.

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 Membrane Transport

▪ Exocytosis (continued)
▪ Exocytosis docking process
▪ Docking proteins on the vesicles recognize plasma
membrane proteins and bind with them
▪ Membranes corkscrew and fuse together

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Figure 3.12a Exocytosis.

Extracellular Plasma
fluid membrane
docking
protein

1 The membrane-
Vesicle bound vesicle
docking migrates to the
protein plasma membrane.
Molecule
to be
Secretory secreted
vesicle Cytoplasm

Fusion pore formed
2 There, docking
proteins on the
vesicle and plasma
membrane bind, the
vesicle and
Fused
membrane fuse, and
docking
a pore opens up.
proteins

3 Vesicle contents
are released to the
cell exterior.

(a) The process of
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exocytosis
Figure 3.12b Exocytosis.

(b) Electron micrograph of
a
secretory vesicle in
exocytosis (190,000 ×)

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 Membrane Transport

▪ Endocytosis
▪ Extracellular substances are enclosed (engulfed) in a
membranous vesicle
▪ Vesicle detaches from the plasma membrane and
moves into the cell
▪ Once in the cell, the vesicle typically fuses with a
lysosome
▪ Contents are digested by lysosomal enzymes
▪ In some cases, the vesicle is released by exocytosis
on the opposite side of the cell

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Figure 3.13a Events and types of endocytosis. Slide 1

Extracellular
fluid Cytoplasm Plasma
membrane
Vesicle
Lysosome
1 Vesicle
forms and fuses
Release of
with lysosome
2 contents to
for digestion. A
cytosol
2 Transport to plasma
membrane and exocytosis
of vesicle contents
Detached vesicle
2
Ingested B
substance

3 Membranes and receptors
(if present) recycled to
Pit plasma membrane

(a) Endocytosis
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Figure 3.13a Events and types of endocytosis. Slide 2

Extracellular
fluid Plasma
membrane
1 Vesicle
forms and fuses
with lysosome
for digestion.

(a) Endocytosis
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Figure 3.13a Events and types of endocytosis. Slide 3

Extracellular
fluid Cytoplasm Plasma
membrane
Vesicle
Lysosome
1 Vesicle
forms and fuses
with lysosome
for digestion.
2 Transport to plasma
membrane and exocytosis
of vesicle contents
Detached vesicle

(a) Endocytosis
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Figure 3.13a Events and types of endocytosis. Slide 4

Extracellular
fluid Cytoplasm Plasma
membrane
Vesicle
Lysosome
1 Vesicle
forms and fuses
Release of
with lysosome
2 contents to
for digestion. A
cytosol
2 Transport to plasma
membrane and exocytosis
of vesicle contents
Detached vesicle

(a) Endocytosis
© 2018 Pearson Education, Ltd.
Figure 3.13a Events and types of endocytosis. Slide 5

Extracellular
fluid Cytoplasm Plasma
membrane
Vesicle
Lysosome
1 Vesicle
forms and fuses
Release of
with lysosome
2 contents to
for digestion. A
cytosol
2 Transport to plasma
membrane and exocytosis
of vesicle contents
Detached vesicle
2
B

(a) Endocytosis
© 2018 Pearson Education, Ltd.
Figure 3.13a Events and types of endocytosis. Slide 6

Extracellular
fluid Cytoplasm Plasma
membrane
Vesicle
Lysosome
1 Vesicle
forms and fuses
Release of
with lysosome
2 contents to
for digestion. A
cytosol
2 Transport to plasma
membrane and exocytosis
of vesicle contents
Detached vesicle
2
Ingested B
substance

3 Membranes and receptors
(if present) recycled to
Pit plasma membrane

(a) Endocytosis
© 2018 Pearson Education, Ltd.
 Membrane Transport

▪ Types of endocytosis
1. Phagocytosis—“cell eating”
▪ Cell engulfs large particles such as bacteria or dead
body cells
▪ Pseudopods are cytoplasmic extensions that separate
substances (such as bacteria or dead body cells) from
external environment
▪ Phagocytosis is a protective mechanism, not a means of
getting nutrients

© 2018 Pearson Education, Ltd.
Figure 3.13b Events and types of endocytosis.

Cytoplasm
Extracellular
fluid Bacterium
or other
particle

Pseudopod
(b)
Phagocytosis

© 2018 Pearson Education, Ltd.
 Membrane Transport

▪ Types of endocytosis (continued)
2. Pinocytosis—“cell drinking”
▪ Cell “gulps” droplets of extracellular fluid containing
dissolved proteins or fats
▪ Plasma membrane forms a pit, and edges fuse around
droplet of fluid
▪ Routine activity for most cells, such as those involved in
absorption (small intestine)

© 2018 Pearson Education, Ltd.
Figure 3.13a Events and types of endocytosis.

Extracellular
fluid Cytoplasm Plasma
membrane
Vesicle
Lysosome
1 Vesicle
forms and fuses
Release of
with lysosome
2 contents to
for digestion. A
cytosol
2 Transport to plasma
membrane and exocytosis
of vesicle contents
Detached vesicle
2
Ingested B
substance

3 Membranes and receptors
(if present) recycled to
Pit plasma membrane

(a) Endocytosis
© 2018 Pearson Education, Ltd.
 Membrane Transport

▪ Types of endocytosis (continued)
3. Receptor-mediated endocytosis
▪ Method for taking up specific target molecules
▪ Receptor proteins on the membrane surface bind
only certain substances
▪ Highly selective process of taking in substances
such as enzymes, some hormones, cholesterol,
and iron

© 2018 Pearson Education, Ltd.
Figure 3.13c Events and types of endocytosis.

Membrane
receptor

Target molecule

(c)
Receptor-mediate
d
endocytosis

© 2018 Pearson Education, Ltd.
 Cell Division

▪ Cell life cycle is a series of changes the cell
experiences from the time it is formed until it
divides
▪ Cell life cycle has two major periods
1. Interphase (metabolic phase)
▪ Cell grows and carries on metabolic processes
▪ Longer phase of the cell cycle
2. Cell division
▪ Cell reproduces itself

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 Cell Division

▪ Preparations: DNA Replication
▪ Genetic material is duplicated and readies a cell for
division into two cells
▪ Occurs toward the end of interphase

© 2018 Pearson Education, Ltd.
© 2018 Pearson Education, Ltd.
 Cell Division

▪ Process of DNA replication
▪ DNA uncoils into two nucleotide chains, and each side
serves as a template
▪ Nucleotides are complementary
▪ Adenine (A) always bonds with thymine (T)
▪ Guanine (G) always bonds with cytosine (C)
▪ For example, TACTGC bonds with new nucleotides in
the order ATGACG

© 2018 Pearson Education, Ltd.
Figure 3.14 Replication of the DNA molecule at the end of interphase.

KEY
: Adenine
Thymine
Cytosine
Guanine

New
Old Newly
strand Old (template)
(template) synthesized
forming strand
strand strand
DNA of one sister chromatid
© 2018 Pearson Education, Ltd.
 Cell Division

▪ Events of cell division
▪ Mitosis—division of the nucleus
▪ Results in the formation of two daughter nuclei
▪ Cytokinesis—division of the cytoplasm
▪ Begins when mitosis is near completion
▪ Results in the formation of two daughter cells

© 2018 Pearson Education, Ltd.
 A&P Flix™: Mitosis

© 2018 Pearson Education, Ltd.
 Cell Division

▪ Events of mitosis: prophase
▪ Chromatin coils into chromosomes; identical strands
called chromatids are held together by a centromere
▪ Centrioles direct the assembly of a mitotic spindle
▪ Nuclear envelope and nucleoli have broken down

© 2018 Pearson Education, Ltd.
 Cell Division

▪ Events of mitosis: metaphase
▪ Chromosomes are aligned in the center of the cell on
the metaphase plate (center of the spindle midway
between the centrioles)
▪ Straight line of chromosomes is now seen

© 2018 Pearson Education, Ltd.
 Cell Division

▪ Events of mitosis: anaphase
▪ Centromere splits
▪ Chromatids move slowly apart and toward the opposite
ends of the cell
▪ Anaphase is over when the chromosomes stop moving

© 2018 Pearson Education, Ltd.
 Cell Division

▪ Events of mitosis: telophase
▪ Reverse of prophase
▪ Chromosomes uncoil to become chromatin
▪ Spindles break down and disappear
▪ Nuclear envelope re-forms around chromatin
▪ Nucleoli appear in each of the daughter nuclei

© 2018 Pearson Education, Ltd.
 Cell Division

▪ Cytokinesis
▪ Division of the cytoplasm
▪ Begins during late anaphase and completes during
telophase
▪ A cleavage furrow (contractile ring of microfilaments)
forms to pinch the cells into two parts
▪ Two daughter cells exist

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 Cell Division

▪ In most cases, mitosis and cytokinesis occur
together
▪ In some cases, the cytoplasm is not divided
▪ Binucleate or multinucleate cells result
▪ Common in the liver and skeletal muscle

© 2018 Pearson Education, Ltd.
Figure 3.15 Stages of mitosis. Slide 1
Centrioles Chromatin Centrioles Spindle Centromere
microtubules
Forming
mitotic
spindle
Centromere

Plasma Nuclear Chromosome, Fragments of
membrane envelope consisting of two nuclear envelope
sister chromatids
Nucleolus
Interphas Early Late
e prophase prophase
Metaphase Nucleolus
plate forming

Cleavage
furrow

Nuclear
Mitotic Sister Daughter envelope
spindle chromatids chromosomes forming
Metaphas Anaphas Telophase and
© 2018 Pearson
e Education, Ltd. e cytokinesis
Figure 3.15 Stages of mitosis (1 of 6). Slide 2

Centrioles Chromatin

Plasma Nuclear
membrane envelope
Nucleolus

Interphas
e
© 2018 Pearson Education, Ltd.
Figure 3.15 Stages of mitosis (2 of 6). Slide 3

Centrioles

Forming
mitotic
spindle
Centromere

Chromosome,
consisting of two
sister chromatids

Early
prophase
© 2018 Pearson Education, Ltd.
Figure 3.15 Stages of mitosis (3 of 6). Slide 4

Spindle Centromere
microtubules

Fragments of
nuclear envelope

Late
prophase
© 2018 Pearson Education, Ltd.
Figure 3.15 Stages of mitosis (4 of 6). Slide 5

Metaphase
plate

Mitotic Sister
spindle chromatids

Metaphas
e
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Figure 3.15 Stages of mitosis (5 of 6). Slide 6

Daughter
chromosomes

Anaphas
e

© 2018 Pearson Education, Ltd.
Figure 3.15 Stages of mitosis (6 of 6). Slide 7

Nucleolus
forming

Cleavage
furrow

Nuclear
envelope
forming
Telophase and
cytokinesis
© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ DNA serves as a blueprint for making proteins
▪ Gene: DNA segment that carries a blueprint for
building one protein or polypeptide chain
▪ Proteins have many functions
▪ Fibrous (structural) proteins are the building materials
for cells
▪ Globular (functional) proteins can act as enzymes
(biological catalysts)

© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ DNA information is coded into a sequence of
bases
▪ A sequence of three bases (triplet) codes for an
amino acid
▪ For example, a DNA sequence of AAA specifies
the amino acid phenylalanine

© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ The role of DNA
▪ Most ribosomes, the manufacturing sites of proteins,
are located in the cytoplasm
▪ DNA never leaves the nucleus in interphase cells
▪ DNA requires a decoder and a messenger to carry
instructions to build proteins to ribosomes
▪ Both the decoder and messenger functions are carried
out by RNA (ribonucleic acid)

© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ How does RNA differ from DNA?
▪ RNA is single-stranded
▪ RNA contains ribose sugar instead of deoxyribose
▪ RNA contains uracil (U) base instead of thymine (T)

© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ Three varieties of RNA
▪ Transfer RNA (tRNA): Transfers appropriate amino
acids to the ribosome for building the protein
▪ Ribosomal RNA (rRNA): Helps form the ribosomes
where proteins are built
▪ Messenger RNA (mRNA): Carries the instructions for
building a protein from the nucleus to the ribosome

© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ Protein synthesis involves two major phases:
▪ Transcription
▪ Translation
▪ We will detail these two phases next

© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ Transcription
▪ Transfer of information from DNA’s base sequence to
the complementary base sequence of mRNA
▪ DNA is the template for transcription; mRNA is the
product
▪ Each DNA triplet corresponds to an mRNA codon
▪ If DNA sequence is AAT-CGT-TCG, then the mRNA
corresponding codons are UUA-GCA-AGC

© 2018 Pearson Education, Ltd.
Figure 3.16a Protein synthesis (1 of 2).

Nucleus DNA Cytoplasm
(site of transcription) gene (site of translation)

1 mRNA specifying
one polypeptide is
made from a gene on
the DNA template by an
enzyme (not shown).

2 mRNA leaves nucleus
Amino and attaches to ribosome,
mRNA
acids and translation begins.
Nuclear pore

Nuclear membrane Correct amino
acid attached to Synthetase
each type of enzyme
tRNA by an
enzyme

© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ Translation
▪ Base sequence of nucleic acid is translated to an
amino acid sequence; amino acids are the building
blocks of proteins
▪ Occurs in the cytoplasm and involves three major
varieties of RNA

© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ Translation (continued)
▪ Steps correspond to Figure 3.16 (step 1 covers
transcription)
▪ Step 2: mRNA leaves nucleus and attaches to
ribosome, and translation begins
▪ Step 3: incoming tRNA recognizes a complementary
mRNA codon calling for its amino acid by temporarily
binding its anticodon to the codon

© 2018 Pearson Education, Ltd.
Figure 3.16 Protein synthesis. Slide 1

Nucleus DNA Cytoplasm
(site of transcription) gene (site of translation)

1 mRNA specifying
one polypeptide is
made from a gene on
the DNA template by an
enzyme (not shown).

2 mRNA leaves nucleus
Amino and attaches to ribosome,
mRNA acids
and translation begins.
Nuclear pore

Nuclear membrane Correct amino
acid attached to Synthetase
each type of enzyme
tRNA by an
enzyme

IIe 3 Incoming tRNA
recognizes a complementary
Growing
mRNA codon calling for its
Met polypeptide
chain amino acid by temporarily
Gly
4 As the ribosome moves binding its anticodon to the
along the mRNA, a new amino Ser codon.
tRNA “head”
acid is added to the growing Phe
bearing anticodon
protein chain. Ala
Peptide bond

5 Released tRNA
reenters the cytoplasmic
Large ribosomal subunit
pool, ready to be recharged
with a new amino acid.

Codon
Direction of ribosome
Small ribosomal subunit reading; ribosome
Portion of
moves the mRNA strand
mRNA already
along sequentially
translated
as each codon is read.

© 2018 Pearson Education, Ltd.
Figure 3.16 Protein synthesis (1 of 2). Slide 2

Nucleus DNA Cytoplasm
(site of transcription) gene (site of translation)

1 mRNA specifying
one polypeptide is
made from a gene on
the DNA template by an
enzyme (not shown).

Amino
mRNA
acids

Nuclear pore

Nuclear membrane Correct amino
acid attached to Synthetase
each type of enzyme
tRNA by an
enzyme

© 2018 Pearson Education, Ltd.
Figure 3.16 Protein synthesis (1 of 2). Slide 3

Nucleus DNA Cytoplasm
(site of transcription) gene (site of translation)

1 mRNA specifying
one polypeptide is
made from a gene on
the DNA template by an
enzyme (not shown).

2 mRNA leaves
Amino nucleus and attaches to
mRNA
acids ribosome, and
Nuclear pore translation begins.

Nuclear membrane Correct amino
acid attached to Synthetase
each type of enzyme
tRNA by an
enzyme

© 2018 Pearson Education, Ltd.
Figure 3.16 Protein synthesis (2 of 2). Slide 4

IIe 3 Incoming tRNA
recognizes a complementary
mRNA codon calling for its
amino acid by temporarily
binding its anticodon to the
codon.
tRNA “head”
bearing anticodon

Large ribosomal subunit

Codon
Direction of ribosome
Small ribosomal subunit reading; ribosome
Portion of
moves the mRNA strand
mRNA already
along sequentially
translated
as each codon is read.

© 2018 Pearson Education, Ltd.
 Protein Synthesis

▪ Translation (continued)
▪ Steps correspond to Figure 3.16
▪ Step 4: as the ribosome moves along the mRNA, a new
amino acid is added to the growing protein chain
▪ Step 5: released tRNA reenters the cytoplasmic pool,
ready to be recharged with a new amino acid

© 2018 Pearson Education, Ltd.
Figure 3.16 Protein synthesis (2 of 2). Slide 5

IIe 3 Incoming tRNA
recognizes a complementary
Growing
mRNA codon calling for its
Met polypeptide
amino acid by temporarily
chain
4 As the ribosome moves alongGly binding its anticodon to the
codon.
the mRNA, a new amino acid is Ser
tRNA “head”
added to the growing protein Phe bearing anticodon
chain. Ala
Peptide bond

Large ribosomal subunit

Codon
Direction of ribosome
Small ribosomal subunit reading; ribosome
Portion of
moves the mRNA strand
mRNA already
along sequentially
translated
as each codon is read.

© 2018 Pearson Education, Ltd.
Figure 3.16 Protein synthesis (2 of 2). Slide 6

IIe 3 Incoming tRNA
recognizes a complementary
Growing
mRNA codon calling for its
Met polypeptide
amino acid by temporarily
chain
4 As the ribosome moves alongGly binding its anticodon to the
codon.
the mRNA, a new amino acid is Ser
tRNA “head”
added to the growing protein Phe bearing anticodon
chain. Ala
Peptide bond

5 Released tRNA
reenters the cytoplasmic
Large ribosomal subunit
pool, ready to be recharged
with a new amino acid.

Codon
Direction of ribosome
Small ribosomal subunit reading; ribosome
Portion of
moves the mRNA strand
mRNA already
along sequentially
translated
as each codon is read.

© 2018 Pearson Education, Ltd.
Figure 3.16 Protein synthesis. Slide 7

Nucleus DNA Cytoplasm
(site of transcription) gene (site of translation)

1 mRNA specifying
one polypeptide is
made from a gene on
the DNA template by an
enzyme (not shown).

2 mRNA leaves nucleus
Amino and attaches to ribosome,
mRNA acids
and translation begins.
Nuclear pore

Nuclear membrane Correct amino
acid attached to Synthetase
each type of enzyme
tRNA by an
enzyme

IIe 3 Incoming tRNA
recognizes a complementary
Growing
mRNA codon calling for its
Met polypeptide
chain amino acid by temporarily
Gly
4 As the ribosome moves binding its anticodon to the
along the mRNA, a new amino Ser codon.
tRNA “head”
acid is added to the growing Phe
bearing anticodon
protein chain. Ala
Peptide bond

5 Released tRNA
reenters the cytoplasmic
Large ribosomal subunit
pool, ready to be recharged
with a new amino acid.

Codon
Direction of ribosome
Small ribosomal subunit reading; ribosome
Portion of
moves the mRNA strand
mRNA already
along sequentially
translated
as each codon is read.

© 2018 Pearson Education, Ltd.
© 2018 Pearson Education, Ltd.
 Part II: Body Tissues

▪ Tissues
▪ Groups of cells with similar structure and function
▪ Four primary types:
1. Epithelial tissue (epithelium)
2. Connective tissue
3. Muscle tissue
4. Nervous tissue

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 Epithelial Tissue

▪ Locations:
▪ Body coverings
▪ Body linings
▪ Glandular tissue
▪ Functions:
▪ Protection
▪ Absorption
▪ Filtration
▪ Secretion

© 2018 Pearson Education, Ltd.
 Epithelial Tissue

▪ Hallmarks of epithelial tissues:
▪ Cover and line body surfaces
▪ Often form sheets with one free surface, the apical
surface, and an anchored surface, the basement
membrane
▪ Avascular (no blood supply)
▪ Regenerate easily if well nourished

© 2018 Pearson Education, Ltd.
 Epithelial Tissue

▪ Classification of epithelia
▪ Number of cell layers
▪ Simple—one layer
▪ Stratified—more than one layer
▪ Shape of cells
▪ Squamous?