Postlab Cell and Cell Transport Mechanisms PDF

Summary

This document is a description of cell and cell transport mechanisms. The document contains information on different parts of a cell like the membrane, nucleus, ER, and ribosomes, as well as an explanation of processes like diffusion, osmosis, endocytosis, exocytosis and active transport.

Full Transcript

Lab Activity 3

Human Transport
Cheek Cell Mechanism
 Human Cheek Cell

cytoplasm

nucleus

Cell membrane

Human cheek cells (unstained) Human cheek cells (stained)
 Cell
The basic structural and functional unit of
every organism

Types of cells (based on the presence or
absence of true nucleus)
– Eukaryotic
– Prokaryotic
A eukaryotic
ANIMAL cell
Major Parts of the Cell (Eukaryotic)
Plasma membrane (or cell membrane)
– Plants, fungi, and some protists have cell
wall
Nucleus
Cytoplasm
– Endoplasmic reticulum
– Ribosomes
– Golgi bodies (or golgi apparatus)
– Mitochondria
– Peroxisomes
– Cytoskeleton
 Plasma membrane
the outermost component of a cell

encloses the cytoplasm and forms the boundary between
material inside the cell and materials outside it, hence it is
called the “gatekeeper of the cell”

Selectively permeable which regulates the exchange of
essential substances between the cell’s contents and the
external environment
 Nucleus
the most distinct (usually the largest) organelle in a
eukaryotic cell
averaging about 5 um in diameter

usually situated at the center
of the cell, bounded by a
double membrane (nuclear
membrane)
contains most of the genes in
the eukaryotic cell (some
genes are located in
mitochondria and
chloroplasts).
 Three distinct parts of nucleus
Nuclear envelope/ membrane
– Double membrane that encloses the nucleus separating its
contents from the cytoplasm
– isolates the nucleus from the rest of the cell and allows
selective exchange of materials
– perforated with tiny membrane-lined channels called nuclear
pores.
Nucleolus
diffuse body with no
surrounding membrane
that is found at the center
of the nucleus
Functions: Ribosomal RNA
(rRNA) synthesis and Site
of ribosome assembly
Chromatin
 Three distinct parts of nucleus
Nuclear envelope/
membrane
Nucleolus
Chromatin materials
– Within the nucleus, the
DNA is organized into
discrete units called
chromosomes,
structures that carry the
genetic information.
– Each chromosome is
made up of a material
called chromatin, a
complex of proteins and
DNA.
Note: The cytoplasm of the nucleus is
referred to as nucleoplasm or
karyoplasm.
 Functions of nucleus
Controls and regulates
the functions of other
organelles, thus called
the “governor or the
control center of the
cell”
Information central
 Cytoplasm
consists of all materials inside the plasma membrane and
outside the nucleus
Has semifluid, jellylike substance called cytosol
the most active region of the cell because most of the cell’s
metabolic activities---the biochemical reactions that support
life--- occur in cell cytoplasm
Contains the different organelles of the cell
– Organelles are physiologically active, permanent sub-
cellular structures performing metabolic functions
 Ribosomes
spherical bodies that may be attached to the Endoplasmic
Reticulum or nuclear envelope (Bound ribosomes) or free in
the cytoplasm (Free ribosomes).
– The two types of ribosomes are structurally identical
aggregates of rRNA and protein
Function: site of protein synthesis in the cell
Proteins synthesized from free
ribosomes function within the
cytosol (e.g. enzymes)
Proteins from bound
ribosomes are used for:
membrane components
export from the cell or for
secretion
 Endoplasmic reticulum (ER)
Endoplasmic means "within
the cytoplasm”, and
reticulum is Latin for "little
net”
network of membranous
tubules and sacs called
cisternae
accounts for more than half
the total membrane in many
eukaryotic cells
the ER membrane is
continuous with the
nuclear membrane
 Two types of Endoplasmic Reticulum
Smooth ER- without
ribosomes
Functions:
– synthesis of lipids (oils,
phospholipids, and steroids)
– metabolism of
carbohydrates
– detoxification of drugs and
poisons
– Store calcium ions
– Transport by vesicle
formation
– Abundant in liver and
muscle cells
 Two types of Endoplasmic Reticulum
Rough ER- with ribosomes
Function
– The ribosomes on the outside
of rough ER are used to
synthesize both secretory
proteins and phospholipids
– Membrane factory of the cell
(grows in place by adding
membrane proteins and
phospholipids to its own
membrane)
– Transport by vesicle formation
 Golgi apparatus/ Golgi complex
named for the Italian physician and cell biologist Camilo Golgi,
who discovered in the late 1800s
membrane-bound vesicles of flattened sacs and stacks (cisternae)
parallel to each other
– Unlike in ER, the cisternae of Golgi appartus are not physically connected
derived from endoplasmic reticulum
Golgi apparatus/ Golgi complex
§ Entry or cis face (convex)
§ a cisterna that faces the
rough ER

§ Exit or trans face (concave)
§ a cisterna that faces the
plasma membrane

§ Medial cisternae
§ Sacs between the entry
and exit faces.
 Functions of Golgi complex
§ Modifies, sorts, packages, and
transports proteins received from
the rough ER.

§ Forms secretory vesicles that
discharge processed proteins via
exocytosis into extracellular fluid

§ Forms membrane vesicles that
ferry new molecules to the plasma
membrane

§ Forms transport vesicles that carry
molecules to other organelles,
such as lysosomes
 Golgi apparatus/ Golgi complex
Functions
separates (sorts) proteins and lipids
received from the ER according to their
destinations

modifies some molecules
– For instance, it adds sugars to
proteins to make glycoproteins

manufactures certains molecules
(polysaccharides)

‘Shipping and
receiving center’ of the packages these materials into vesicles
that are then transported to other parts
cell
of the cell or to the plasma membrane
for export
Three general destinations for proteins that leave
the Golgi complex
Secreted from the cell by exocytosis
Incorporated into the plasma membrane
Occupy storage vesicles that become lysosomes
 Endomembrane system
Includes the:
– Nuclear membrane/ envelope
– Endoplasmic reticulum
– Golgi appratus
– Lysosomes (found only in animal cell)
– Various kinds of vacuoles (lysosomes in plants)
– Plasma membrane (not actually an endomembrane in physical
location, but nevertheless related to the endoplasmic reticulum and
other internal membranes)

The membranes of this system are related either through direct
physical continuity or by the transfer of membrane segments as
tiny vesicles (sacs made of membrane).
 Peroxisomes
are small, single membrane-bound
vesicle containing enzymes that
break down fatty acids, amino
acids, and hydrogen peroxide
(H2O2)
Hydrogen peroxide is a by-product
of fatty acid and amino acid
breakdown and can be toxic to a
cell.
The enzymes in peroxisomes break
down hydrogen peroxide to water
and oxygen.
§ Peroxisomes in the liver detoxify
alcohol and other harmful
compounds by transferring
hydrogen from the poisons to
oxygen.
 Mitochondria
Singular: ‘mitochondrion’ Pair of membranes
double-membrane organelle, enclosing two fluid
smooth outer membrane and compartments:
folded inner membrane the intermembrane
(cristae) found in almost all compartment
living cells between the outer
and inner
membrane
matrix within the
inner membrane
 Mitochondria
Abundant in liver cells
Also contain ribosomes
Have their own DNA (capable of self-replication).

Functions:
– Site of cellular aerobic respiration (convert energy
stored in sugar to ATP)
– major site of ATP synthesis
– “powerhouse of the cell”
– found in large number of metabolically active cells
 Cytoskeleton
network of protein fibers that
support the cell, hold
organelles in place, and
enable the cell to change to
shape

Functions:
– Cell support
– Cell shape
– Cell and organelle motility
(movement)
– Cell division
 Types of cytoskeleton
1.thin microfilaments- small fibrils formed
from protein subunits
– Cell shape
– Cell motility (movement)
– Cell division
2.medium-sized intermediate filaments-
provide mechanical support to the cell
and maintenance of cell shape
3.thick microtubules- hollow structures
formed from protein subunits
– Cell shape
– Cell motility (movement)
– Chromosome movements in cell
division
– Organelle movements
– Forming essential components of
certain organelles, such as cilia and
flagella (in animal cells)
Structures Present in Animal Cell
but not in plant cell
Lysosomes
– Central vacuole in plants
Centrosomes and Centrioles
Flagella
Cilia
 Lysosomes
membrane-enclosed vesicles formed from Golgi apparatus containing
numerous digestive enzymes
– Hydrolytic enzymes and lysosomal membrane are made by rough ER
and then transferred to the Golgi apparatus for further processing. At
least some lysosomes probably arise by budding from the trans face of
the Golgi apparatus.
Main function:
Intracellular digestion
– Lysosomes contain digetsive enzymes called hydrolases, which
catalyse the digestion of proteins, nucleic acids, some carbohydrates
and fats into their component subunits
– Digest food particles, which range from individual proteins to
complete microorganisms
Also digest excess cellular membranes and defective and malfunctioning
organelles
– Serve as the cell’s digestive system and known as the “suicide
bags”
Vesicles formed by endocytosis may fuse with lysosomes. The enzymes within
the lysosomes break down the materials in the endocytotic vesicle.

Lysosomes digest food in a process known as phagocytosis or cell
eating.
Lysosomes also use their hydrolytic enzymes to recycle the cell's own
organic material, a process called autophagy.

Phagocytic white blood cell (macrophage) is best for studying
lysosomes.
 Note: About lysosomes
Lysosomal enzymes work best in the acidic environment found
in lysosomes.
If a lysosome breaks open or leaks its contents, the released
enzymes are not very active because the cytosol has a neutral
pH. However, excessive leakage from a large number of
lysosomes can destroy a cell by autodigestion.
 Centrosomes
a region that is often located
near the nucleus
Function:
– “microtubule-organizing
center” in animal cells
Where microtubules grow out
from
Within the centrosome are a pair
of centrioles
 Centrioles
short barrel-shaped ring consisting of nine
microtubule triplets, with no microtubules in the
center (9+0 arrangement).

Functions:
– Cell division
– move to the plasma membrane and
provides a center for the formation of
cilia or flagella (formation of basal
body)

Before an animal cell divides, the centrioles replicate.
Although centrosomes with centrioles may help
organize microtubule assembly in animal cells, they
are not essential for this function in all eukaryotes;
yeast cells and plant cells lack centrosomes with
centrioles but have well-organized microtubules.
 Cilia and flagella
Singular- cilium; flagellum
slender extensions of the plasma
membrane
consists of microtubules arising from the
basal body
Each cilium and flagellum contain
microtubules arranged in an outer ring of
nine fused pairs of microtubules
surrounding a central unfused pair (9+2
arrangement).

Function: for locomotion (movement)
 Difference between cilia and flagella

Cilia Flagella
Length Shorter Longer

Number on cell surface Numerous usually limited to just one
or a few per cell
Beating patterns Alternating power and Undulating motion that
recovery strokes generates force in
generating force in a the same direction as the
direction perpendicular flagellum's axis.
to the cilium’s axis, much
as the oars of a crew boat
extend outward at right
angles to the boat's
forward movement.
Beating patterns and direction of movement of cilia and flagella
Transport Across the Plasma Membrane
Types of Transport Mechanism
PASSIVE TRANSPORT ACTIVE PROCESSES
§ Simple diffusion § Active transport
§ Transport in vesicles (Bulk
§ Facilitated diffusion
Transport)
§ Osmosis § Endocytosis
§ Phagocytosis
§ Pinocytosis
§ Exocytosis
 Passive transport
§ A substance moves down its concentration or
electrical gradient (from higher concentration to
lower concentration) to cross the membrane using
only its own kinetic energy (energy of motion).
§ Kinetic energy is intrinsic to the particles that are
moving.
Requires NO expenditure of energy
EXAMPLES OF PASSIVE TRANSPORT
 The Principle of Diffusion
§ Diffusion is a passive
process in which the
random mixing of
particles in a solution
occurs because of the
particles’ kinetic
energy.
§ Both the solutes and the
solvent undergo
diffusion.
§ They move down
their concentration
gradient
 Simple diffusion
§ Movement of solute molecules from an area of higher
concentration to an area of a lower concentration of that
solute in solution
§ results from the constant random motion of all solutes in a
solution
§ A passive process in which
substances move freely
through the lipid bilayer of
the plasma membranes of
cells without the help of
membrane transport
proteins
 Diffusion within a liquid

Solutes diffuse faster
in hot water.
 Brownian Motion
§ The constant movement
of all particles of
matter

§ Discovered by Scotish
scientist Robert Brown

§ Brownian motion drives
passive transport process
(diffusion)
Diffusion through a membrane

The cornstarch solution turned purple-black in color
Iodine diffuses from the outside (greater
concentration) to the inside (lesser concentration)
 Diffusion through a membrane

The color change indicates that the iodine reacts with starch
Starch molecules did not pass through the membrane
because of their large size.
The cellophane serves as semipermeable membrane
 Simple diffusion
§ Nonpolar, hydrophobic § Small, uncharged polar
molecules molecules such as:
§ Such molecules include: § water,
§ oxygen, § urea
§ carbon dioxide § small alcohols
§ and nitrogen gases
§ fatty acids
§ steroids
§ fat-soluble vitamins (A,
D, E, and K)
 Factors affecting diffusion
§ Steepness of the concentration gradient.
§ The greater the difference in concentration between
the two sides of the membrane, the higher is the rate
of diffusion
§ Temperature.
§ The higher the temperature, the faster the rate of
diffusion
§ Mass of the diffusing substance.
§ The larger the mass of the diffusing particle, the
slower its diffusion rate
 Factors affecting diffusion
§ Surface area.
§ The larger the membrane surface area
available for diffusion, the faster is the
diffusion rate

§ Diffusion distance.
§ The greater the distance over which diffusion
must occur, the longer it takes
 Osmosis
§ A type of diffusion in
which there is net
movement of a solvent
through a selectively
permeable membrane.

§ In living systems, the
solvent is water, which
moves by osmosis across
plasma membranes from
an area of higher water Water moves through a selectively
concentration to an area permeable membrane from an area of
of lower water lower solute concentration to an area
concentration of higher solute concentration
 Requirements: Osmosis

Osmosis occurs only
when:
1. Difference in
concentration of water
between two sides of
the membrane

2. A membrane is
permeable to water
NOT permeable to
certain solutes
 Tonicity
§ A measure of the solution’s ability to change the
volume of cells by altering their water content.

§ Three types of solution
§ Isotonic solution
§ Hypotonic solution
§ Hypertonic solution
 Isotonic solution
§ “having the same strength”
§ Solution whose concentration
of water and solute inside the
cell (intracellular fluid) is THE
SAME as the concentration
outside the cell (extracellular
fluid)
§ Example: 0.9% NaCl (normal
physiologic saline solution)
 Hypotonic solution
§ “having lesser strength”

§ Solution that has a LOWER
concentration of solute and
higher concentration of water
than does a cell cytoplasm

§ It will cause water to enter the
cell, and thus the cell will swell or
even burst (lysis)

§ Example: pure water
 Hypertonic solution
§ “having greater strength”

§ Solution that has a HIGHER
concentration of solute and a
lower concentration of water than
does a cell cytoplasm

§ It will cause water to leave the cell
will shrink or crenate (crenation)

§ Example: 2% NaCl solution
 2.Active transport
uses CELLULAR ENERGY to move molecules across the plasma
membrane, often “uphill”AGAINST a concentration gradient (from
lower concentration to higher concentration gradient)
Example: Na+K+ pump
 2.Active transport
also a carrier-mediated processàuses active transport-proteins
which span the width of the membrane and have two active sites:
 3.Bulk transport
particles are transported in large amounts or in bulk
without actually passing or crossing the membrane
Uses cellular energy

Examples: endocytosis and exocytosis
 Endocytosis
particles are transported in large amounts or in bulk “into the cell”
uptake of material through the cell membrane by formation of vesicle
the cell membrane invaginates to form a vesicle containing the material
to be taken by the cell. The vesicle then moves into the cytoplasm

Three types:
Ø Pinocytosis
Ø Receptor-mediated endocytosis
Ø Phagocytosis
 Three types of Endocytosis
Pinocytosis (“cell-drinking”)
– the particle to be engulfed is in liquid form or a droplet of extracellular fluid
Receptor-mediated endocytosis
– selectively concentrate specific molecules inside a cell
– Plasma membranes bear many receptor proteins on their outside surfaces,
each with a binding site for a particular molecule
– Example: cholesterol and growth factors
Phagocytosis (“cell-eating”)
– the particle to be engulfed is in solid form or chunks of matter.
– Example: WBC and some other cell types phagocytize bacteria, cell debris, and
foreign particles
 Exocytosis
particles are transported in large
amounts or in bulk “out of the cell”

A membrane-enclosed vesicle carrying material
to be expelled moves to the cell surface, where
the vesicle’s membrane fuses with the cell’s
plasma membrane. The vesicle then opens to
the extracellular fluid, and its contents diffuse
out
used to dispose of unwanted materials such as
products of digestion
 Transport Needs carrier
Movement Requires energy?
Mechanism molecule?
Simple Diffusion Higher to lower
concentration of No No
solute
Osmosis Higher to lower
concentration of No No
water (solvent)
Facilitated Higher to lower
diffusion concentration of Yes No
molecules
Active transport Lower to higher
concentration of Yes Yes
substance
Endocytosis “into the cell”
No Yes

Exocytosis “out of the cell”
No Yes
 Summary
Types of Transport
Mechanisms across plasma
membrane Carrier-mediated
transport
1. Passive Transport
Facilitated diffusion
Diffusion Active transport
Osmosis
Facilitated Diffusion Energy-requiring transport
2. Active Transport Active transport
Bulk transport
3. Bulk Transport
Endocytosis
Exocytosis