The Cell: An Overview Chapter 2 PDF

Summary

This chapter provides a comprehensive overview of cells, including their importance, structure, and function. It covers cell theory, different types of microscopy, and basic cell features. The information is useful for understanding the fundamental concepts of biology.

Full Transcript

Image Source: https://www.behance.net/gallery/15570899/Cell-Collage

The Cell: An Overview Chapter 2
 Key concepts

1. All organisms are made up of cells
2. The cell is the basic unit of function and structure
3. All cells share some common structures/characteristics
4. There are some differences between cells within and between different
organisms

Image Source: https://www.proprofs.com/flashcards/upload/q4753561.png
 Why are cells important?

Vital in understanding various aspects of biology but also
in agriculture, biotechnology, and many aspects of
health and disease

Image Source: https://unsplash.com/s/photos/biotechnology
Image Source: https://www.sciencefocus.com/science/what-is-lab-grown-meat-a-scientist-explains-the-taste-production-and-safety-of-artificial-foods
Image Source: https://cals.ncsu.edu/news/crispr-plants-new-non-gmo-method-to-edit-plants/
 The first look

Robert Hooke 1655
Small rooms used by monks - cella
 Cell theory

Mid-19th century, microscopic observations had yielded three generalizations
= cell theory

All organisms are
composed of one
or more cells The cell is the basic
structural and
functional unit of
Cells arise only all living organisms
from the division Schleiden – plants
of preexisting cells Schwann – animals Image Source: Screen capture from the TED Ed
Virchow saw cells video, “The Wacky History of Cell Theory.”

divide under
microscope
 Basic features of cell structure and function

Basic structural and functional Essential processes of life
unit

Image Source: https://biologywise.com/plant-animal-cell-similarities

Contain genetic information Use energy, respond to changes in
environment, reproduce, and pass on
hereditary information
 Many kinds of cells

Unicellular organisms
Functional independent organism – carry out all necessary activities

Multicellular organisms (plants and animals)
Activities of life divided with specialized cells
 Sizes of cells

Most cells are microscopic

Size of cell not related to body size

Related to function

Image Source: https://www.toppr.com/ask/content/story/amp/cell-and-its-
discovery-123264/
 Why are cells so small?

Cell size limited by surface area-to-volume ratio

As cell gets larger there comes a time when its surface area is not large
enough to meet the demands of the cell volume
Cell will stop growing
 How can we look at cells?

Microscopy
Visualization of cells and microorganisms by magnifying their images to
make them larger

Image Source: https://micro.magnet.fsu.edu/primer/museum/hooke.html
 Magnification

The number of times larger an image is
than the real size of the object

M = I/A
I = observed size of the image
A = actual size Low magnification

Its like zooming in

See less but in more detail

High magnification
Depends on lens system Image Source: https://www.slideshare.net/1slid/3-microscope-lab-thursday-91213
 Resolution

Minimum distance that two points in specimen can be separated and
still be seen as two points

The higher the resolution, the
greater the detail we can see

Affects sharpness of object

Higher magnification increases
resolution

Depends on wavelength of
light used Image Source: https://slidetodoc.com/microscopes-magnifications-resolutions-and-calculations-
light-microscope-uses/
Magnification vs Resolution

Image Source: https://open.oregonstate.education/cellbiology/chapter/microscopy/
 Contrast
Variation of color and shadow

Allows human eye to focus on different aspects of image and
to register depth

Stains and staining
techniques

Method of illumination

Higher contrast gives more
detail, but can’t increase Picture showing low contrast, high contrast and phase
resolution contrast
Image Source: https://player.slideplayer.com/27/9157951/#
 Light microscopy

Use visible light (400-700 nanometers) to illuminate specimen

a. Range of the electromagnetic spectrum
The shortest, most Range of most Range of heat The longest,
energetic radiation reaching the escaping from the lowest-energy
wavelengths surface of Earth surface of Earth wavelengths

Gamma X-rays Ultraviolet Near-infrared Infrared Microwaves Radio
rays radiation radiation radiation waves

Visible light

400 450 500 550 600 650 700
 Light microscopy

Allows magnification of about 1000x

Resolution of about 0.2 μm

Very versatile

Image Source: https://microbenotes.com/light-microscope/
 Light microscopy

Use natural color or add stain

Developing seed coat of the
model plant Arabidopsis
thaliana stained with toluidine
blue

Epithelial cells of a human gall
bladder, stained with
hematoxylin and eosin (H&E)

Image Source: https://open.oregonstate.education/cellbiology/chapter/microscopy/
 Light microscopy

Subtypes of light microscopy

Types of light that you are
viewing when you look at an
image

Transmitted light microscopy
Sample between light source and
eyepiece
Light passes through sample

Image Source: https://open.oregonstate.education/cellbiology/chapter/microscopy/
 Light microscopy

Subtypes of light microscopy

Types of light that you are
viewing when you look at an
image

Emitted light microscopy
Light source off to the side
Molecules in sample get excited
Release own photons
Light come from samples
themselves
Image Source: https://open.oregonstate.education/cellbiology/chapter/microscopy/
 Fluorescence

Property of some molecules

Absorbs energy of a photon

Gets excited/moved to higher energy
state

Electron returns to ground state (less
excited)

Releases a less energetic / longer
wavelength photon

Fluorescence emission
 Fluorescence microscopy

Uses much higher intensity
light source (like UV light)

Excites a fluorescent species
in a sample of interest

Fluorescent species in turn
emits a lower energy light of
a longer wavelength that
can be detected Image Source: https://www.en.silicann.com/blog/post/what-is-fluorescence/
 Fluorescence microscopy

Label (or tag) specific macromolecules / cell structure so that we can
track them within the cell

Tag structures using fluorescent
molecules (called fluorochromes or
fluorophores)

blue = nucleus
red = actin
green = microtubules
Mouse fibroblasts, Green: F-Actin, FITC, Red: Tubulin, Cy5, Blue:
Nuclei, DAPI. Courtesy of: Dr. Günter Giese, Max Planck Institute for
Medical Research, Heidelberg, Germany.

Image Source: https://www.leica-microsystems.com/science-lab/life-science/fluorescent-dyes//
 Electron microscopy

Use electrons to illuminate specimen
Shorter wavelength than visible light
Higher resolution images

Image Source: https://ib.bioninja.com.au/standard-level/topic-1-cell-biology/11-introduction-to-cells/microscopes.html
 Electron microscopy

Use electrons to illuminate specimen
Shorter wavelength than visible light Electron microscope Light microscope
Higher resolution images
(Ability to distinguish separate
and distinct objects)

1nm 400nm
Image Source: https://quizlet.com/gb/760892366/lecture-8-the-electron-microscopehistory-principles-applications-flash-cards/
 Transmission Electron Microscopy

Pass electrons through specimen
to generate a cross-section

Very thin slices of tissue using an
ultramicrotome

Chemically preserved / fixed and
dehydrated

Stained with heavy metal (lead) Cotton phloem tissue. Sieve element (top
cell) and a companion cell (bottom cell), TEM
x8,000. Photo by J. Thorsch.
Image Source: https://www.ccber.ucsb.edu/ucsb-natural-history-collections-
botanical-plant-anatomy/transmission-electron-microscope
 Scanning Electron Microscopy

Scatter electrons over a
surface to differentiate depth
and map in 3D

Chemically preserved / fixed
and dehydrated

Coated/Stained with heavy
metal (gold / palladium /
Butterfly wing under scanning electron
platinum / silver) microscopy. Image Credit:
ClaudiaSEM/Shutterstock.com
Image Source: https://www.azolifesciences.com/article/Scanning-Electron-Microscopy-
%28SEM%29-An-Overview.aspx
 Comparison

Light Microscopy Electron Microscopy
Glass lenses Electromagnetic “lenses”
Live or dead cells Only dead cells
Stained with coloured dye Coated with heavy metals
Less resolution (0.25 to 0.3 More resolution (0.001 µm)
µm)
Less magnification (500 to More magnification (more
1500x) than 10 000x)
Colour images B/W images*
 What is common to all cells?

What features are shared by all cells (prokaryotic cells and eukaryotic cells)?
 The outer boundary

All cells are surrounded by plasma Cell 1
membrane
Cell 2
Bilayer
Lipids with embedded protein
molecules

Hydrophobic barrier to water-soluble
substances
 The outer boundary

Selected substances can penetrate Cell 1
cell membranes - transport protein
channels Cell 2

Selective transport of ions and water-
soluble molecules

Maintains specialized internal
environments
 Inside the cell

Plasma membrane

Cytoplasm (organelles and
Cytoskeleton
cytosol and cytoskeleton)
Protein based
Cytosol network of
Aqueous solution filamentous structures
containing ions, various Central region of all Maintains cell shape
organic molecules, and cells (DNA molecules - Plays key roles in cell
organelles store hereditary division and
information (genes) chromosome
segregation
 Inside the cell

Plasma membrane

Cytoplasm (organelles and
cytosol and cytoskeleton)
Makes molecules
Receives signals
for growth and
from exterior and
reproduction and
carries out
conversion of Central region of all chemical
chemical and light cells (DNA molecules - reactions in
energy store hereditary response
information (genes)
 How do prokaryotic and eukaryotic cells differ?

Extensive membrane systems Varying internal membranes
that form organelles

Bacteria and Archaea

Nucleoid region with no boundary
Eukaryotes
membrane

Membrane-bound compartment nucleus
 Prokaryotic cells

Image Source: https://letstalkscience.ca/educational-resources/backgrounders/introduction-bacteria
 Prokaryotic cells

Nucleoid
Single, circular molecule
(prokaryotic chromosome)

DNA used to make Messenger RNA
(mRNA) molecules

Carried to ribosomes (in cytoplasm) -
assemble amino acids into proteins

Ribosomes = rRNA + protein
 Prokaryotic cells

Plasma membrane

Transport in and out of cell
Site of metabolic reactions
Cellular respiration
Photosynthesis
 Prokaryotic cells
Cytoskeleton
Maintain cell shape and functions in cell division

Movement
Bacterial flagellum rotates in socket and pushes cell through liquid
medium

Attachment
Hairlike pili attach cell to
surfaces or other cells

Sex pilus joins bacteria during
mating (conjugation)
Image Source: https://byjus.com/question-answer/what-is-the-main-difference-
between-flagella-and-pili/
 Prokaryotic cells

Rigid external cell wall.

Often coated with external
polysaccharide layer (glycocalyx)

Glycocalyx loosely associated with cells
= slime layer
Glycocalyx firmly attached = capsule

Protection and attachment
Image Source: https://www2.nau.edu/~fpm/bio205/Sp-10/Chapter-04.pdf
 Eukaryotic cells

Image Source: https://animalcellstructure.blogspot.com/2014/03/plant-cells-and-animal-cells.html
 Eukaryotic cells
Nucleus
Membrane-bound compartment

Cytoplasm
Membranous organelles
Specialized functions

Cytoskeleton
supports and moves cell structures

Cytosol
Supports energy metabolism and intracellular traffic
 Plasma membrane and Cell wall

Plasma membrane with embedded Supportive cell wall surrounds plasma
proteins membrane (plant, fungi, some protists)

Image Source: https://www.earthslab.com/physiology/cell-membrane-plasma-membrane-structure-function-composition/
 The nucleus

Nuclear envelope
Consists of two membranes (layered)
Selectively permeable

Nuclear pore complex
Embedded in nuclear envelope
Nucleoporins
Regulates transport of proteins and RNA molecules between nucleus and
cytoplasm

Nuclear pore
Channel through nuclear pore complex
The nuclear envelope
 The nucleus

Chromatin
Combination of DNA and proteins
that fills space inside nucleus
Uncondensed / Unwound

Nucleolus (pl. nucleoli)
Small masses - protein,
RNA and DNA
Form around genes coding for rRNA
molecules (rDNA)
Ribosome biogenesis
Image Source: https://www.britannica.com/science/nucleolus
One or more in nucleus
 The nucleus

Chromosome Eukaryotic chromosome
Condensed chromatin One complete DNA molecule and its
Found only during cell division associated proteins

Image Source: https://micro.magnet.fsu.edu/cells/nucleus/chromatin.html
 Eukaryotic ribosomes

Consists of a large and a small
subunit
Comprises RNA and proteins

Formed in nucleoli and exit nucleus
through nuclear pore complexes
In cytoplasm, they join on mRNAs to
form ribosomes

Expression of genes (translation)
 Eukaryotic ribosomes

Image Source: https://www.open.edu/openlearn/science-maths-technology/a-tour-
the-cell/content-section-4.4

Image Source: https://reports.news.ucsc.edu/breakthrough/revealing-the-ribosome/
 Eukaryotic ribosomes

Ribosomes can be freely suspended in the cytosol or attached to
membranes

Free Attached
May remain in cytosol, pass into
Attached to membranes:
nucleus, or become parts of
nuclear envelope or
mitochondria, chloroplasts,
endoplasmic reticulum (ER)
cytoskeleton, or other cytoplasmic
Follow special path to other
structures.
organelles in cell
In nucleus become part of chromatin,
nuclear envelope, or remain in solution