BIOL1000-2024-Lecture3-2 PDF - Cell Biology Lecture 3

Summary

This document is a lecture on cell biology, introducing cell anatomy, functions, and osmosis. The document details the basic unit of life and explains its organization. It touches on the different types of cells and their various components.

Full Transcript

Content – Cell Biology - Lecture 3

Introduction to cells
Anatomy of a cell
Membranes
Osmoregulation
Membrane transport

Video 1 1
 Basic concepts in cells
Internal membranes compartmentalize functions
Nucleus containing genetic instructions
Metabolic functions: Endomembrane system regulates
protein traffic and performs metabolic functions in the
cell
Energy: Mitochondria change energy
Organization: The cytoskeleton is a network of fibers
organizing structures and activities of the cell
Communications: Extracellular components and
connections between cells help coordinate cellular
activities

Video 1 2
 The cell
Basic structural and functional unit of every organism
Two types:
– Prokaryotic – Bacteria and Archaea
– Eukaryotic – fungi, animals, plants etc.

Electron microscopy

Super-
Light microscopy
resolution
microscopy
Unaided eye
Length
of some
nerve Nucleus
Most Smallest
and Plant and Most Small
bacteria Proteins
muscle animal bacteria Viruses molecules
Human
cells cells Ribo-
Human Chicken Frog egg Mitochondrion
height egg egg somes Lipids Atoms

10 m 1m 0.1 m 1 cm 1 mm 100 μm 10 μm 1 μm 100 nm 10 nm 1 nm 0.1 nm

Video 1 3
 Basic features of all cells
ENDOPLASMIC

Plasma membrane RETICULUM (ER)

Semifluid substance Rough ER Smooth ER Nuclear
envelope

called cytosol Flagellum
Nucleolus
Chromatin
NUCLEUS

Chromosomes (carry Centrosome

genes) Plasma
membrane

Ribosomes (make CYTOSKELETON:

proteins)
Microfilaments
Intermediate filaments
Microtubules
Ribosomes
Microvilli

Golgi apparatus
Peroxisome
Lysosome
Mitochondrion

Video 1 4
Why are cells so small?

Metabolic requirements of cell set upper limit on
size

Small cells have a greater surface area to volume
ratio – more surface to allow passage of materials
in and out of cell

Video 1 5
High surface area to volume ratio

Larger organisms
are not made of
larger cells, just
more cells
Maintains high
surface area-to-
volume ratio

Video 1 6
 Prokaryotic cells

No membrane-bound organelles
Cytoplasm bound by plasma
membrane

No nucleus
DNA in an unbound region
called nucleoid

Video 1 7
 Eukaryotic cells

Membrane-bound organelles
DNA in a nucleus bounded by a
membranous nuclear envelope

GENERALLY MUCH LARGER THAN
PROKARYOTIC CELLS

Video 1 8
Video of cell biology

9
Eukaryotic cell

Video 1 10
Tour of an animal cell

Video 1 11
Nucleus: Information centre

Nucleus is usually
most conspicuous
organelle
Nuclear membrane
is a double layer
(outer and inner
membrane)
– Each membrane is a lipid
bilayer

Video 2 12
Nucleus: Pore complex

Pores in membrane
regulate entry and
exit of molecules
from nucleus
– lined by a pore
complex of proteins
Shape of the nucleus
is maintained by
nuclear lamina
– composed of protein

Video 2 13
 Nucleus:
Information centre
In nucleus, DNA is organized into
discrete units called chromosomes
A chromosome is composed of a
single DNA molecule associated
with proteins
DNA and proteins of chromosome
together are called chromatin (diffuse
mass when not dividing)
Nucleolus within nucleus is the site
of ribosomal RNA (rRNA) synthesis,
and construction of small and large
subunits of ribosomes

Video 2 14
 Ribosomes: Protein Factories
Ribosomes are particles made of
ribosomal RNA and protein
Ribosomes carry out protein
synthesis
– In the cytosol (free ribosomes)
– On the outside of endoplasmic
reticulum (bound ribosomes)

Video 2 15
 Endomembrane system

Regulates protein traffic and
performs metabolic functions
– Nuclear envelope
– Endoplasmic reticulum
– Golgi apparatus
– Lysosomes
– Vacuoles
– Plasma membrane

Video 2 16
 Endoplasmic reticulum:
Biosynthetic factory
ER accounts for more than
half of total membrane in
many eukaryotic cells
ER membrane is
continuous with nuclear
envelope
Components are either
continuous or connected
via transfer by vesicles
Video 2 17
Endoplasmic reticulum:
Biosynthetic factory

Two distinct regions of
ER
– Smooth ER, which
lacks ribosomes
– Rough ER, surface is
studded with
ribosomes

Video 2 18
 Smooth ER
Synthesizes lipids (oils, phospholipids,
steroids/hormones)
– Testes, ovaries rich in smooth ER
Metabolizes carbohydrates
Detoxifies drugs and poisons
– Liver cells rich in smooth ER
– Some drugs induce proliferation of
more smooth ER, leading to drug
tolerance
Stores calcium ions

Video 2 19
 Rough ER

Has bound ribosomes which
synthesize many secretory
proteins
Most are glycoproteins (proteins
covalently bonded to carbohydrates)
Transports proteins via transport vesicles
– Proteins wrapped in membrane

Is a membrane factory for the cell

Video 2 20
Video: Staining of Endoplasmic Reticulum

Video 2 21
 Golgi apparatus:
Shipping and receiving

Modifies ER products
Manufactures certain
molecules
– Polysaccharides, pectins
Sorts and packages materials
into transport vesicles
Consists of flattened
membranous sacs called
cisternae
Video 2 22
Video: Golgi Complex in 3-D

Video 2 23
 Lysosomes:
Digestive compartments

Membranous sac of hydrolytic enzymes that
can digest macromolecules
Lysosomal enzymes can hydrolyze proteins,
fats, polysaccharides, and nucleic acids
Lysosomal enzymes work best in acidic
environment inside lysosome

Video 3 24
 Lysosomes:
Digestive compartments
Some cells can
engulf another cell
by phagocytosis;
forming a food
vacuole
A lysosome fuses
with food vacuole
and digests the
molecules

Video 3 25
Animation: Lysosome Formation

Video 3 26
 Lysosomes:
Digestive compartments

Lysosomes also
recycle cell’s own
organelles and
macromolecules,
a process called
autophagy

Video 3 27
Video: Phagocytosis in Action

Video 3 28
 Evolutionary of
eukaryotic cells
Mitochondria and chloroplasts
have similarities with bacteria
(prokaryotes)
– Enveloped by a double membrane
– Contain free ribosomes and circular
DNA molecules
– Grow and reproduce somewhat
independently in cells

Video 3 29
 Endosymbiont
Theory

Prokaryotic
ancestor of
eukaryotic cells
engulfed energy
producing
prokaryotes

Video 3 30
 Mitochondria:
Chemical energy conversion
Have a smooth outer
membrane and an inner
membrane folded into
cristae
Inner membrane creates
two compartments:
intermembrane space
and mitochondrial
matrix

Video 3 31
 Mitochondria:
Chemical energy conversion
Mitochondria are in nearly all
eukaryotic cells
Some metabolic steps of
cellular respiration are
catalyzed in the mitochondrial
matrix
Cristae present a large surface
area for enzymes that
synthesize ATP
Video 3 32
Video: Mitochondria in 3-D

Video 3 33
 Cytoskeleton organizes
structures and activities in cells

Network of fibres
extending
throughout
cytoplasm
It organizes the
cell’s structures
and activities,
anchoring many
organelles
Video 4 34
 Cytoskeleton organizes
structures and activities in cells

The cytoskeleton composed of
three types of molecular
structures
– Microtubules (thickest)
– Microfilaments (thinnest)
– Intermediate filaments
(intermediate..)

It helps to support the cell and
maintain its shape
Video 4 35
 Cytoskeleton:
Support and motility
Cytoskeleton interacts
with motor proteins to
produce motility

Inside the cell, vesicles
can travel along
“monorails” (microtubules
or microfilaments)

Video 4 36
Video: The Cytoskeleton in Neuron Growth Cone

Video 4 37
 Cytoskeleton:
Microtubules
Hollow tube made of
globular protein called
tubulin
Tubulin dimer made of 2
subunits: α-tubulin, β-
tubulin
– Serve as tracks for motor
proteins
– Guide vesicles from ER to
Golgi to plasma
membrane
– Cell division
Video 4 38
Video: Interphase Microtubule Dynamics

Video 4 39
 Microtubules and
Centrosomes
Important microtubule function
is chromosome separation
during cell division
In many cells, microtubules
grow out from a centrosome
near the nucleus
Centrosome is “microtubule-
organizing centre”
Video 4 40
 Centrosome containing a
pair of centrioles

In animal cells,
centrosome has a
pair of centrioles,
each with nine
triplets of
microtubules
arranged in a ring

Video 4 41
 Cilia and flagella

Microtubules control the
beating of cilia and flagella,
locomotor appendages of
some cells
Cilia and flagella share a
common structure
“ 9 + 2” microtubules

Video 5 42
 Cilia and Flagella

Move by dynein “walking”
Dynein arms alternately grab,
move, and release outer
microtubules
– Protein cross-links limit sliding
– Forces exerted by dynein arms
cause doublets to curve, bending
cilium or flagellum

Video 5 43
Video: Movement of Organelles In Vitro

Video 5 44
 Cytoskeleton:
Microfilaments

Twisted double chain of
actin subunits – SOLID ROD
Bear tension, resist pulling
forces
Form a 3-D network called
cortex just inside the
plasma membrane to help
support the cell’s shape
Video 5 45
Microfilaments (Actin
filaments)

 Bundles make up core of microvilli of
intestinal cells

Video 5 46
Microfilaments (Actin filaments)
Microfilaments that function in cellular motility
contain the protein myosin in addition to actin
Thicker myosin filaments walk along thinner
actin fibres to pull them together, contracting
muscle cells

Video 5 47
 Cytoskeleton:
Intermediate filaments
Range in diameter
from 8–12 nm, larger
than microfilaments
but smaller than
microtubules
Support cell shape and
fix organelles in place
Intermediate filaments
are more permanent
cytoskeleton fixtures
Video 5 48
 Extracellular components

Connect and coordinate cellular
activities
Most cells synthesize and secrete
materials external to plasma
membrane
These extracellular structures
include
– Cell walls of plants
– Extracellular matrix (ECM) of animal
cells
– Intercellular junctions

Video 6 49
 Extracellular matrix (ECM)
of animal cells
Animal cells lack cell walls but
have an elaborate extracellular
matrix (ECM)
Functions of the ECM
– Support
– Adhesion
– Movement
– Regulation

Video 6 50
 Extracellular matrix (ECM)
of animal cells
Made of glycoproteins such as collagen,
proteoglycans, and fibronectin
Polysaccharide
Collagen

Fibronectin
Integrins
Cell Proteoglycans
membrane Proteoglycan
Microfilaments Complex

ECM proteins bind to receptor proteins in
plasma membrane Video
called
6 integrins 51
Extracellular matrix (ECM)
Collagen!
Tonkotsu Ramen…pork bone broth

52
 Cell junctions

Neighboring cells in tissues,
organs, or organ systems often
adhere, interact, and
communicate through direct
physical contact
Intercellular junctions facilitate
this contact

Video 6 53
 Cell junctions

There are several types of
intercellular junctions

– Plasmodesmata (Plants)

– Tight junctions
– Desmosomes
– Gap junctions

Video 6 54
Tight junctions in
animal cells

At tight junctions, membranes of
neighboring cells are pressed
together, preventing leakage of
extracellular fluid
Video 6 55
Desmosomes in
animal cells

Desmosomes (anchoring
junctions) fasten cells together
into strong sheets

Video 6 56
Gap junctions in animal cells

Gap junctions (communicating
junctions) provide cytoplasmic
channels between adjacent cells

Video 6 57
Cellular membrane

Selective barrier
Allows passage of
oxygen, nutrients,
waste
General structure:
phospholipid layer
– hydrophilic
exterior
– hydrophobic
interior

Video 7 58
Transport through cellular
membranes

Cellular membranes are fluid mosaics of
lipids and proteins
Membrane structure results in selective
permeability
Passive transport is diffusion of a substance
across a membrane with no energy
investment
Active transport uses energy to move solutes
against their gradients
Bulk transport across the plasma membrane
occurs by exocytosis and endocytosis

Video 7 59
 Cellular membranes:
fluid mosaics of lipids and proteins
Phospholipids are the most
abundant lipid in the
plasma membrane
Phospholipids are
amphipathic molecules,
containing hydrophobic
and hydrophilic regions

Video 7 60
 Fluid mosaic model
a membrane is a fluid structure with a “mosaic” of
proteins embedded in it

Video 7 61
 Membrane fluidity

Phospholipids in plasma
membrane can move within
bilayer
Most lipids and some proteins
drift laterally
Rarely a molecule flip-flops
transversely

Video 7 62
 Membrane fluidity

As temperatures cool, membranes go from a fluid
state to a solid state
Temperature when membrane solidifies depends
on types of lipids
Membranes must be fluid to work properly; they
are usually about as fluid as salad oil

Video 7 63
 Membrane fluidity

Membranes rich in unsaturated
fatty acids are more fluid than
those rich in saturated fatty acids

Video 7 64
 Membrane fluidity and
Cholesterol

Cholesterol has different effects
on membrane fluidity at
different temperatures
At warm temperatures, it
restrains movement of
phospholipids
At cool temperatures, it
maintains fluidity by preventing
tight packing
Video 7 65
 Membrane proteins

Membrane is a collage of different proteins,
often grouped together, embedded in fluid
matrix of lipid bilayer
Proteins determine most of membrane’s
specific functions
– Peripheral proteins are bound to the surface of
the membrane
– Integral proteins penetrate the hydrophobic
core

Video 7 66
Membrane proteins

Integral proteins that span membrane
are called transmembrane proteins
Hydrophobic regions of an integral
protein consist of one or more
stretches of nonpolar amino acids,
often coiled into alpha helices
Video 7 67
 Membrane proteins

Six major functions of membrane
proteins
– Transport
– Enzymatic activity
– Signal transduction
– Cell-cell recognition
– Intercellular joining
– Attachment to the cytoskeleton
and extracellular matrix (ECM)

Video 7 68
Membrane proteins

Video 7 69
Membrane proteins

Video 7 70
IMPACT: HIV

HIV requires CD4 receptor AND CCR5 co-
receptor to enter cells
Immune patients lack the CCR5 co-receptor
Drugs then target CCR5 as CD4 has too
many other roles
Video 7 71
 Synthesis and sidedness
of membranes
Membranes have distinct inside and
outside faces
Asymmetrical distribution of plasma
membrane components determined when
membrane is built by ER and Golgi
apparatus

Video 7 72
Synthesis and sidedness of membranes

Video 7 73
 Membrane structure and
selective permeability
Cells must exchange materials with
surroundings, a process controlled
by plasma membrane
Plasma membranes are selectively
permeable, regulating the cell’s
molecular traffic
– Hydrophobic (non-polar) molecules
can dissolve in lipid bilayer and pass
through membrane rapidly
– Polar (hydrophilic) molecules do not
cross membrane easily – need help

Video 7 74
 Transport proteins

Transport proteins allow
hydrophilic substances to pass
across membrane
Some have hydrophilic
channel that certain molecules
or ions can use as a tunnel
Channel proteins called
aquaporins facilitate passage
of water
Video 8 75
 Transport proteins

Others bind to
molecules and change
shape to shuttle them
across membrane
A transport protein is
specific for the
substance it moves

Video 8 76
 Passive transport: diffusion of
substances across membranes
Diffusion- tendency for
molecules to spread out
evenly into available space
Each molecule moves
randomly, but diffusion of a
population of molecules may
be directional
Dynamic equilibrium- as
many molecules cross
membrane in one direction as
in the other

Video 8 77
Diffusion of one solute

Video 8 78
Diffusion of two solutes

Video 8 79
 Passive transport

Substances diffuse down their
concentration gradient
Diffusion is a spontaneous
process
Diffusion of a substance across
a biological membrane is
passive transport; no energy is
expended by the cell to make it
happen
Video 8 80
Osmosis and water balance
Osmosis- diffusion of water across a
selectively permeable membrane

Video 8 81
 Water balance of cells
Tonicity is ability of surrounding solution to
cause cells to gain or lose water

Video 8 82
 Osmoregulation

Hypertonic or hypotonic
environments create osmotic
problems for organisms
Osmoregulation, control of
solute concentrations and
water balance, is a necessary
adaptation for life in such
environments

Video 8 83
 Osmoregulation
Paramecium, which is hypertonic to its
pond water environment, has a
contractile vacuole (acts as a pump)

Video 8 84
Facilitated diffusion: passive
transport aided by proteins
Facilitated diffusion, transport proteins aid passive
movement of molecules across plasma membrane
Channel proteins provide corridors that allow a
specific molecule or ion to cross
Channel proteins include
– Aquaporins, facilitated diffusion of water
– Ion channels open or close in response to a
stimulus (gated channels)

Video 8 85
 Facilitated diffusion:
passive transport aided by proteins
Carrier proteins undergo a subtle change
in shape that translocates the solute-
binding site across the membrane

Video 8 86
Active transport uses energy to
move solutes against gradients
Facilitated diffusion-
the solute moves
down its
concentration
gradient, and
transport requires no
energy
Some transport
proteins, however,
can move solutes
against their
concentration
gradients

Video 9 87
 Energy in active transport

Active transport moves substances
against their concentration
gradients
Active transport requires energy,
usually in the form of ATP
Active transport is performed by
specific proteins embedded in
membranes
Active transport allows cells to
maintain concentration gradients
that differ from their surroundings

Video 9 88
 Sodium-potassium pump
Cytoplasmic Na+ binds to the sodium-
potassium pump
Affinity for Na+ is high when the protein has
this shape

Video 9 89
 Sodium-potassium pump
Na+ binding stimulates
phosphorylation by ATP

Video 9 90
Sodium-potassium pump
Phosphorylation leads to a change in
protein shape reducing affinity for Na+

Video 9 91
 Sodium-potassium pump

New shape has high
affinity for K+
K+ binds and triggers
release of phosphate
group

Video 9 92
 Sodium-potassium pump

Loss of phosphate
changes shape
resulting in low
affinity for K+

Video 9 93
 Sodium-potassium pump

K+ is released
Affinity for Na+ is
restored
Cycle starts again

Video 9 94
Review: passive and active
transport

Video 9 95
 How ion pumps maintain
membrane potential

Membrane potential is the voltage difference
across a membrane
Voltage is created by differences in the
distribution of positive (outer) and negative
(inner) ions across a membrane
Two combined forces, collectively called
electrochemical gradient, drive diffusion of
ions across a membrane
– A chemical force (the ion’s concentration gradient)
– An electrical force (effect of membrane potential on
ion’s movement)
Video 9 96
 How ion pumps maintain
membrane potential

An electrogenic pump is a
transport protein that generates
voltage across a membrane
The sodium-potassium pump is
the major electrogenic pump of
animal cells

Video 9 97
 Bulk transport
across a membrane
Small molecules and water
enter or leave cell through lipid
bilayer or via transport proteins
Large molecules, such as
polysaccharides and proteins,
cross membrane via vesicles
(Bulk transport)
Bulk transport requires energy
Video 9 98
 Exocytosis

In exocytosis, transport vesicles
migrate to the membrane, fuse
with it, and release their
contents
Many secretory cells use
exocytosis to export their
products

Video 9 99
 Endocytosis
In endocytosis, the cell takes in
macromolecules by forming vesicles
from the plasma membrane
Endocytosis is a reversal of
exocytosis, involving different
proteins
There are three types of endocytosis
– Phagocytosis (“cellular eating”)
– Pinocytosis (“cellular drinking”)
– Receptor-mediated endocytosis

Video 9 100
 Phagocytosis

 Phagocytosis cell engulfs
a particle in vacuole
 Vacuole fuses with
lysosome to digest
particle

Video 9 101
 Pinocytosis

Pinocytosis,
extracellular fluid is
“gulped” into tiny
vesicles (drinking)

Video 9 102
 Receptor-mediated
endocytosis

Receptor-mediated
endocytosis, binding
of ligands to receptors
triggers vesicle
formation

Video 9 103
Summary – Membrane transport

Video 9 104