A Tour of the Cell - Avon Community School Corporation
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Transcript A Tour of the Cell - Avon Community School Corporation
Chapter 6:
A Tour of the
Cell
Essential Knowledge
2.a.2 – Organisms capture and store free energy for use
in biological processes (6.2).
2.b.3 – Eukaryotic cells maintain internal membranes
that partition the cell into specialized regions (6.2-6.5).
4.a.2 – The structure and function of subcellular
components, and their interactions, provide essential
cellular processes (6.2-6.5).
4.b.2 – Cooperative interactions within organisms
promote efficiency in the use of energy and matter
(6.4).
Light Microscope - LM
Uses visible light to illuminate the object
Relatively inexpensive type of microscope
Can examine live or dead objects
Light passes through specimen and then
through various lenses
Lenses refract/bend light to magnify
Light Microscope
Occular Lens
Objective Lens
Stage with specimen
Light Source
Limitations - LM
Miss many cell structures that are beyond
the magnification of the light microscope
◦ Ex: lysosomes, centrioles
Need other ways to make the
observations
Electron Microscopes
Use beams of electrons instead of light
Invented in 1939, but not used much until
after WWII
Advantages:
◦ Much higher magnifications
◦ Magnifications of 50,000X or higher are
possible.
◦ Can get down to atomic level in some cases
Disadvantages of EM
Need a vacuum
Specimen must stop the electrons
High cost of equipment
Specimen preparation
Other Types of Microscopes
Transmission Electron Microscope TEM
◦ Sends electrons through thinly sliced and stained
specimens
◦ Gives high magnification of interior views. Many
cells structures are now visible
Scanning Electron Microscopes – SEM
◦ Excellent views of surfaces
◦ Produces 3-D views
◦ Live specimens possible
Limitations to EM
TEM:
◦ Specimen dead; specimen prep is difficult
SEM:
◦ Lower magnifications than the TEM; only see
surface of specimen
TEM - interior
SEM - surface
Cell Biology or Cytology
Cyto = cell - ology = study of
Should use observations from several
types of microscopes to make a total
picture of how a cell is put together
Directly related to biochemistry
Tools for Cytology
Cell Fractionation
Chromatography
Electrophoresis
Cell Fractionation
Disrupt cells
Separate parts (organelles and
membrane) by centrifugation at different
speeds
◦ Separates by size and density of the various
structures
Result - pure samples of cell structures
for study
Cell Fractionation
Chromatography
Technique for separating mixtures of
chemicals
Separates chemicals by size or degree of
attraction to the materials in the medium
Ex - paper, gas, column, thin-layer
Electrophoresis
Separates mixtures of chemicals by their
movement in an electrical field
Used for proteins and DNA
Cell History
See alternate Ppt
History of Cells
Robert Hooke - Observed cells in cork
Coined the term "cells” in 1665
◦ Came from “jail cells” and/or monastery cells
Cells:
◦ Al life is made of cells!!!
◦ Cells are the simplest form of life
History of Cells
1833 - Robert Brown, discovered the
nucleus
1838 - M.J. Schleiden, all plants are
made of cells
1839 - T. Schwann, all animals are made
of cells.
1840 - J.E. Purkinje, coined the term
“protoplasm”
Late 1800s – Rudolf Virchow (“Omnis
cellula e cellula” - All cells are from
other cells)
Cell Theory: 3 Parts
1.
2.
3.
All living matter is composed of one or
more cells.
The cell is the structural and functional
unit of life.
Cells come only from existing cells.
Two Types of Cells
1) Prokaryotic - lack a nucleus and other
membrane-bound structures.
2) Eukaryotic - have a nucleus and other
membrane-bound structures.
Examples
Nucleus
Organelles
Prok
Bacteria, blue-green
algae, Archaebacteria
No
Some (ribosomes,
cell mem,
cytoplasm)
Euk
Animal, plants, fungi
Yes
Most (depends on
whether
plant/animal)
DNA
Complexity
# of cells
Prok
Circular, singlestranded, in
cytoplasm
Less
One/Uni,
smaller in size
Euk
Helical, doublestranded, in
nucleus
More
Several/Multi,
larger in size
Eukaryotic
Prokaryotic
Cell diversity
Most cells are between 5-50 micrometers
Mycoplasmas - bacteria that are .1 to 1.0 mm.
(1/10 the size of regular bacteria)
# of cells: uni- and multicellular
Why Are Cells So Small?
Cell volume to surface area ratios favor
small size
Nucleus to cytoplasm consideration
(control)
Metabolic requirements
Surface area v.Volume
Vol and SA are proportionate (if one
increases, the other increases)
Vol increases more than surface area (as
cell grows)
◦ Smaller objects have a greater ratio of sa to
vol
Structure/Function:
◦ Villi in intestinal cells – inc sa so cells can
absorb more materials from food
Basic Cell Organization
Membrane*
Nucleus
Cytoplasm*
Organelles
DNA/RNA*
*EVERY cell has these 3 parts
Animal
Cell
Plant
Cell
Cell Membrane
Separates the cell from the environment
Boundary layer for regulating the
movement of materials in/out of a cell
Often called plasma membrane
Bilayer of phospholipids
Allows oxygen, nutrients, wastes to pass
through a series of processes:
Diffusion
Osmosis
Active transport
Cytoplasm
Cell substance between the cell membrane
and the nucleus
The “fluid” part of a cell.
Neutral pH (serves as a natural buffer)
Exists in two forms:
◦ gel - thick
◦ sol - fluid
Organelles
Term means "small organ”
Formed body in a cell with a specialized
function
Important in organizational structure of
cells
More prominent/numerous in eukaryotic
cells
Ex: Mitochondria, Endoplasmic reticulum,
lysosomes
Nucleus
Most obvious organelle
Usually spherical, but can be lobed or irregular
in shape
Contains genetic info
Found ONLY in euk cells
Function/s:
◦ Control center for the cell
◦ Contains the genetic instructions
◦ Controls protein synthesis by making mRNA and
rRNA (from DNA)
Structure of Nucleus
Nuclear membrane
Nuclear pores
Nucleolus
Chromatin
Nuclear Membrane
Otherwise known as Nuclear Envelope
Double membrane (lipid bilayer) separated
by a 20-40 nm space
Inner membrane supported by a protein
matrix (nuclear lamina) which gives the
shape to the nucleus
Separates nuclear contents from cytoplasm
Dissolves during cell division
Nuclear Pores
Regular “holes” through both membranes
100 nm in diameter
Protein complex gives shape
◦ Lines every nuclear pore
Allows materials, such as
macromolecules, in/out of nucleus
Nucleolus
Dark staining area in the nucleus
0 - 4 per nucleus
Storage area for ribosomes
rRNA made here (from DNA)
No membrane encloses it??? (Research
about nucleolus continues!!!)
Chromatin
Chrom: colored
- tin: threads
DNA and protein in a “loose” format
Will form the chromosomes during
Interphase of cell division (Chromosomes
more condensed)
Each eukary cell has
specific #
Ribosomes
Structure: 2
subunits made of protein and
rRNA
No membrane
Function: protein synthesis
◦ The more occurrences of protein synthesis,
the more ribosomes
◦ Ex: Pancreatic cells have over 1.2 million
ribosomes
Ribosome structure
2 Subunits:
◦ 1) Large
45 proteins, 3 rRNA molecules
◦ 2) Small
23 proteins, 1 rRNA molecule
2 Locations:
◦ 1) Free in the cytoplasm - make proteins for
use in cytosol
◦ 2) Membrane bound - make proteins that are
exported from the cell (Attached to rough
ER)
Endomembrane System
Series of membranes connected by direct
physical continuity or by transfer of
membrane segments called vesicles
Includes: ER, Golgi, vesicles
Function: protein synthesis, transport of
proteins, move lipids, detoxify proteins
Works closely with: nucleus, lysosomes,
ribosomes, plasma membrane
Endomembrane System
Endoplasmic Reticulum
Often referred to as ER
Makes up to 1/2 of the total membrane in
cells
Often continuous with the nuclear
membrane/pores
◦ All cisternae (inner portion) are connected
Structure:
◦ Folded sheets or tubes of membranes
◦ Very “fluid” in structure with the
membranes constantly changing size and
shape.
2 Types of ER
1) Smooth ER: no ribosomes
◦ Used for lipid synthesis, carbohydrate storage,
detoxification of poisons
◦ Ex: store calcium ions, sex hormones contain LOADS
of these (lipid synthesis)
2) Rough ER: with ribosomes
◦ Makes secretory protein and lipid parts of cell
membrane
◦ Ex: liver cells (add water to detoxify proteins to
secrete), insulin (secretory protein)
◦ Most proteins are called glycoproteins (contain
protein and carb parts)
Golgi Apparatus or
Dictyosomes
Structure: parallel array of flattened
cisternae (looks like a stack of Pita bread)
3 to 20 per cell
Likely an outgrowth of the ER system
Think of the UPS man
2 Faces of Golgi
1) Cis face - side toward the nucleus
Receiving side
◦ Located near ER
2) Trans face - side away from the nucleus.
Shipping side
◦ Gives rise to vesicles
Both contain varying polarity
Function of Golgi
Processing - modification of ER products
Distribution - packaging of ER products for
transport
Sorting and Shipping
UPS man/organelle!!!
Found in large #s in secretory cells
Ever-changing organelle
Transport Vesicles
Secretory proteins in transit from one
organelle to another
Two kinds:
◦ 1) From ER to Golgi
◦ 2) From Golgi to ?
Otherwise known as Golgi vesicles
Golgi Vesicles
Small
sacs of membranes that bud off the
Golgi Body
Transportation vehicle for the modified
ER products
◦ May become polypeptide chains or amino
acids
Contain
identifiers to help determine
where destination is
Lysosome
Single membrane – made by rough ER
Made from the Trans face of the Golgi
apparatus
Functions:
◦ Breakdown and degradation of cellular materials
Carry out intracellular digestion
◦ Digest cell’s own materials
Called autophagy
Digest old, non-repairable items
◦ Contains hydrolytic enzymes to breakdown fats,
proteins, polysaccs, and nucleic acids
Lysosome Function, cont.
Important in cell death (apoptosis)
Missing enzymes may cause various
genetic enzyme diseases
◦ Examples:
Tay-Sachs, Pompe’s Disease
Tay-Sachs: Can’t break down lipid in brain
(accumulates and causes nervous system disorders)
Vacuoles
Structure - single membrane, usually larger than
the Golgi vesicles
Function - depends on the organism (most
control hydrolysis and store materials)
Types - Food, contractile, central
Function:
◦ Water regulation - hydrolysis
◦ Storage of ions
◦ Storage of hydrophilic pigments (e.g. red and blues in
flower petals)
Helps attract pollinators
Protist vacuoles
Contractile vacuoles - pump out excess
water.
Food vacuoles - store newly ingested
food until the lysosomes can digest it
Plant vacuoles
Large single vacuole in mature (making up
to 90% of the cell's volume)
Tonoplast - vacuole membrane
◦ Regulatory (Semi-permeable)
Function:
◦ Used to enlarge cells and create turgor
pressure
Absorb water
◦ Store enzymes (various types)
◦ Store toxins
◦ Coloration (may contain pigment)
Microbody
Contain
specialized enzymes for specific
reactions
Peroxisomes: use up H peroxide
◦ Some break down fatty acids, detoxify
poisons
Glyoxysomes: lipid
digestion
◦ Found in plant seeds (used for energy
storage)
Enzymes in a
crystal
Energy Transforming
Organelles
1) Mitochondria
◦ Found in ALL cells (plant, animal, etc)
2) Chloroplasts
◦ Found only in plant, plant-like cells
Considered to be energy transforming
organelles
◦ Mitochondria – food ATP
◦ Chloroplast – sun/water/CO2 food
Mitochondria
2 membranes:
◦ Inner and outer (each is phospholipid bilayer)
◦ The inner membrane has more surface area
than the outer membrane.
Matrix: inner space
Intermembrane space: area between the
membranes
Mitochondria
Have ribosomes
Have their own DNA
Can reproduce themselves
May have been independent cells
Found in nearly ALL eukaryotic cells
Function:
◦ Site for cell respiration - the release of energy
from food.
◦ Major location of ATP generation
◦ “Powerhouse” of the cell
Inner Membrane of Mito
Folded into cristae
Amount of folding depends on the level of
cell activity
Contains many enzymes
◦ Serve as catalysts for cellular respiration
ATP generated here
Chloroplasts
Function: performs photosynthesis
Structure
◦ Two outer membranes
◦ Complex internal membrane
◦ Fluid-like stroma is around the internal
membranes
3 components/parts:
◦ 1) Stroma
◦ 2) Thylakoid OR Grana
◦ 3) Intermembrane space
Chloroplasts
Contain ribosomes
Contain DNA
Can reproduce themselves
Often contain starch
May have been independent cells at one
time
Inner/Thylakoid
Membranes of Chloroplast
Arranged into flattened sacs called
thylakoids
Some regions stacked into layers called
grana
Contain the green pigment chlorophyll
Cytoskeleton
Network of rods and filaments in the
cytoplasm
Components:
◦ 1) Microtubules
◦ 2) Microfilaments
◦ 3) Intermediate Filaments
Cytoskeleton Functions
Cell structure and shape
Cell movement
Movement of organelles
Cell division - helps build cell walls and
move the chromosomes apart
VERY important to animal cells
◦ Why? Because animal cells lack the extra
support of cell wall
Microtubules
Structure - small hollow tubes made of
repeating units of a protein dimer
Size - 25 nm diameter with a 15 nm
lumen; can be 200 nm to 25 mm in length
Thickest of three components
Contains protein called tubulin
Microtubules
Regulate cell shape
Coordinate direction of cellulose fibers
in cell wall formation
Tracks for motor molecules
◦ Ex: Guide vesicles from Golgi
Form cilia and flagella
Internal cellular movement
Make up centrioles, basal bodies and
spindle fibers
Cilia and Flagella
Cilia - short, but numerous
◦ Hair-like
Flagella - long, but few
◦ Tail-like
Functions –
◦ Flight/Movement/Locomotion, reproductive
processes, filter water
Structure - arrangement of microtubules,
covered by the cell membrane
Dynein - motor protein that connects the
tubules
Dynein Protein
A contractile/motor protein
Uses ATP
Creates a twisting motion between the
microtubules causing the structure to
bend or move
Made of several polypeptide chains
◦ Quaternary structured protein
Centrioles
Usually one pair per cell, located close to
the nucleus
Found in animal cells
9 sets of triplet microtubules
Help in cell division
Microfilaments
5 to 7 nm in diameter
Structure - two intertwined strands of
actin protein
Solid rods of
linear filaments
Functions of Microfilaments
Muscle contraction
Cytoplasmic streaming
Pseudopodia (ex: amoeba)
Cleavage furrow formation (ex: cell
division)
Maintenance and changes in cell shape
Intermediate Filaments
Fibrous proteins that are super coiled
into thicker cables and filaments
8 - 12 nm in diameter
Made from several different types of
protein
Functions:
◦ Maintenance of cell shape
◦ Hold organelles in place
Cell Wall
Nonliving jacket that surrounds some
cells
Function as the cell's exoskeleton for
support and protection
Found in:
◦
◦
◦
◦
Plants
Prokaryotes
Fungi
Some Protists
Plant: Primary Cell Wall
Thin and flexible
Cellulose fibers placed at right angles to
expansion
Placement of fibers guided by
microtubules
Plant: Secondary Cell
Wall
Thick and rigid
Added between the cell membrane and
the primary cell wall in laminated layers
May cover only part of the cell; giving
spirals
Makes up "wood”
Cell wall: Middle Lamella
Thin layer rich in pectin found between
adjacent plant cells
Glues cells together
The Inner Life of the Cell - Harvard
University
Intercellular Junctions
Plants - Plasmodesmata
◦ Channels between cells through adjacent cell
walls
◦ Allows communication between cells
◦ Also allows viruses to travel rapidly between
cells
Intercellular Junctions
Animals:
◦ Tight junctions
◦ Desmosomes
◦ Gap junctions
Tight Junctions
Very tight fusion of the membranes of
adjacent cells
Seals off areas between the cells
Prevents movement of materials around
cells
Desmosomes
Bundles of filaments which anchor
junctions between cells
Does not close off the area between
adjacent cells
Coordination of movement between
groups of cells
Gap Junctions
Open channels between cells, similar to
plasmodesmata
Allows “communication” between cells
Summary
Recognize the types and uses of
microscopes in the study of cells.
Recognize the limitations on cell size.
Recognize why cells must have internal
compartmentalization.
Identify the structures and functions of cell
organelles.
Identify the structures and functions of the
cytoskeleton.
Recognize the surface features and intercellular connections of plant and animal cells.