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Intro to Cell Biology
September 4, 2024
Dr. Dana Pape-Zambito
[email protected]
All images from Essential Cell Biology, Fifth Edition
Copyright © 2019 W. W. Norton & Company, unless otherwise noted
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Learning Objectives (1-6 = Chapter 1)
1. Define characteristics of living organisms. Explain the central dogma of biology.
2. Distinguish between prokaryotes and eukaryotes. Give examples of each.
3. Identify cellular organelles/structures in prokaryotic, plant and animal cells and explain
their function within the cell.
4. Describe important components of each structure/organelle and explain why these
structures are necessary for the organelle’s function.
5. Outline the evolution of mitochondria and chloroplasts and cite the evidence for these
origins (i.e. the endosymbiotic theory).
6. Compare and contrast light (conventional and fluorescent) and electron microscopy
including requirements for each technique, which cells/organelles/structures can be
viewed, resolution, and limitations of each technique.
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Learning Objectives (7-10; Chapter 2)
7. Use the periodic table to determine the number of valence electrons in an atom and
explain how valence electrons lead to the chemical reactivity of atoms.
8. Explain the difference between ionic, covalent, and hydrogen bonds, as well as Van
der Waal interactions. Give examples of each.
9. Compare and contrast the terms hydrophilic, hydrophobic, polar, non-polar,
lipophilic, lipophobic, amphipathic. Give examples of each.
10. Recognize the chemical structures and characteristics of the major cellular
macromolecules (carbohydrates, proteins, lipids, and nucleic acids). Identify the
monomer units required to build oligomer or polymer macromolecular structures.
Explain where you would expect to find these macromolecules within prokaryotic and
eukaryotic cells.

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 Chapter 1 - Cells the
Fundamental Units of Life

Image accessed from: 16
https://moosmosis.org/2018/09/01/cornerstones-of-microbiology-robert-hooke-anton-van-leeuwenhoek/
Think, Pair, Share - How do we define life?

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 LO #1

Unity and Diversity of Life

Basic unit of life = cell
Cells are bound by membranes and contain genetic material
Cells can self-replicate
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 LO #1

Central Dogma Required
before cell
division
DNA
↓
mRNA
↓
Protein Required to
perform
cellular
functions 21
 LO #2

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Image from: https://www.sciencefacts.net/prokaryotes-vs-eukaryotes.html
Prokaryote or Eukaryote? Bacteria, Archaea, Plant, Animal, or Protist?
LO #2

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 LO
#1&2
Test your knowledge - True or False?
Prokaryotes are larger than eukaryotes.
False
The hereditary information is passed on through proteins.
False
Protists are prokaryotes.
False
Bacterial DNA is found within the cytoplasm.
True

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Prokaryotes and eukaryotes share all of the following EXCEPT?
A. Ribosomes
B. Cell Membrane
C. DNA
D. RNA
E. Nucleus

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 Activity - Work with your group members to identify the cellular
structures. Indicate the functions of each structure. (8 min)

LO #3 & 4 Image from Campbell Biology,
Pearson publishers
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LO #3 & 4

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 LO #3 & 4

Image from: https://www.earthslab.com/physiology/structure-cell-membrane-cytoplasm-organelles/ 32
Study Guide - Fill out on your own to study LO #3 & 4

Organelle Function Structural What would happen if this
components structure did not function
properly?

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 Mitochondria and
Endosymbiotic Theory - Recap chloroplasts evolved
from the engulfment
of bacteria.

There were 2 separate
engulfment events.

Evidence:
- Size of organelles
similar to size of
prokaryotic cells
- Double membranes
- DNA
- Divide to reproduce

LO #5 35
We can use light and electron microscopes to visualize cells

LO #6

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 LO #6
Light microscopy was used to obtain these images

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 Light Microscopy - uses light, lenses, and dyes to see live and fixed cells

A) Bright field
B) Phase-contrast
C) Interference-contrast

Note: Dye not required

LO #6 38
 Fluorescence microscopy - uses light, filters, and fluorescent dyes to see
live and fixed cells

Top Row = Widefield or standard
fluorescence microscopy

Bottom Row = Confocal
microscopy (more common today)

Note: Dye required

What is difference between the
rows?
Image from:
LO #6 https://www.olympus-lifescience.com/en/microscope-resource/primer/techniques/confocal/confocalintro/ 39
Electron microscopy (EM) - uses an electron beam, lenses, and stains or
resins to see fixed specimens at high magnification

If you were given
an EM image of a
cell, could you
identify the
structures?

Homework 1
will help with
this!
Scanning EM in 3D!!
LO #6 Transmission EM 40
 LO #6

Compare and contrast microscopy techniques
Light Fluorescent Electron

Illumination Source Light Light Electrons

Specimen type Live or Dead (fixed) Live or Dead (fixed) Dead (fixed) only

Dyes or Stains Not required, but can Fluorescent dye Heavy metal dye
be used required, multiple required
colors OK.

Magnification Power 40x - 1000x 12.5x - 1500x 100,000x - 300,000x

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200 µm

200 nm

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If you wanted to see how a single microtubule in a cell changes
when exposed to a drug, which type of microscopy would you use?

A. Light microscopy without any stains or special filters
B. Light microscopy using interference phase contrast filters
C. Confocal fluorescence microscopy
D. Scanning electron microscopy
E. Transmission electron microscopy

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If you wanted to see how a single microtubule in a cell changes
when exposed to a drug, which type of microscopy would you use?

A. Light microscopy without any stains or special filters
B. Light microscopy using interference phase contrast filters
C. Confocal fluorescence microscopy
D. Scanning electron microscopy
E. Transmission electron microscopy

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 Review - Reading the Periodic Table
LO #7

Atomic number determined by # of protons.

Atomic mass = mass of protons + neutrons

Electrically neutral atoms have equal numbers of protons and
electrons.

= mass of protons + neutrons
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 Review - the Periodic Table
LO #7

Chemical reactivity determined by the # of electrons.
Down rows = # of electron shells. First shell = 2 e-, additional shells hold 8 e-.
Across columns = increasing # of electrons.

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 Test your knowledge
LO #7

How many total electrons does Mg have? 12
How many electrons are in Mg’s outer valence shell? 2
How many electrons does Mg need to fill its outer shell? 6

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 LO #7

Isotopes - # of Protons are similar, but neutrons are different
Radioisotopes are powerful scientific tools
C12 and C14 - radioisotope dating
Cancer detection (see right)

Brain, kidney, and bladder take up and
metabolize the radioisotope normally.

Devoogdt et al., 2012. ResearchGate.
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Figure 1
 Understanding chemical bonding and valency
LO #8

Covalent vs. ionic bonds
Covalent bonding - electrons shared

Non-polar covalent bond (a) = equal
sharing of electrons
Polar covalent bond (b) = unequal
sharing of electrons

Ionic bonding (c) - electrons transferred
https://www.youtube.com/watch?v=OTgpN62ou24

Valency video - watch outside of class if you need additional clarification
https://www.youtube.com/watch?v=lVSF2lP4oBA 51
 LO #8
Hydrogen bonding - weak bonds that form between different
molecules
Water
molecule, not
mickey mouse
Hydrogen
bond, dashed
line Polar covalent
bond, solid
line

Hydrogen
bond

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Images from Campbell Biology, Pearson Education Inc.
 LO #8

Van der Waals = Weak Interactions
But can be powerful when many work
together

Image from:
http://www.sci-news.com/othersciences/physicalchemistry/wave-lik
e-nature-van-der-waals-forces-03717.html
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 LO #10

A) Identify the macromolecules shown above (you don’t need to identify the specific molecule, rather
just indicate the type of macromolecule). SUGAR OR CARBOHYDRATE
B) Give an example of this macromolecule that you might expect to find in your body (ex. insulin)
GLUCOSE, GLYCOGEN, (STARCH, CELLULOSE IN PLANTS)
C) Explain how you knew what macromolecule it was. GENERAL MOLECULAR FORMULA =
CN(H2O)N
D) What individual monomers make up the larger oligomer or polymer? MONOSACCHARIDE
E) Identify the individual monomers in these structures. SEE BLUE BOX
F) Describe where you would expect to find these macromolecules in prokaryotic, plant, and animal
cells. CELL WALLS (PROKARYOTES, PLANTS, FUNGI), CREATED IN CHLOROPLAST,
CATABOLIZED IN MITOCHONDRIA, STARCH IN PLANT VACUOLES, GLYCOGEN IN MUSCLES,
MODIFIES PROTEINS AND LIPIDS.

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 LO #10
AMINO
ACID

A) Identify the macromolecules shown above (you don’t need to identify the specific molecule, rather just indicate the
type of macromolecule). PROTEIN - SHOWN ABOVE IS A POLYPEPTIDE.
B) Give an example of this macromolecule that you might expect to find in your body (ex. insulin). INSULIN, GROWTH
HORMONE, ACTIN, MYOSIN, ETC.
C) Explain how you knew what macromolecule it was. CONTAINS -CH + AMINO GROUP (-NH2) + CARBOXYLIC
ACID GROUP (-COOH) + R GROUP (UNIQUE FOR EACH AMINO ACID).
D) What individual monomers make up the larger oligomer or polymer? AMINO ACIDS
E) Identify the individual monomers in these structures. SEE BLUE BOXES ABOVE. NOTE H2O IS LOST FROM -NH2
AND -COOH DURING POLYMERIZATION (condensation reaction for each monomer added).
F) Describe where you would expect to find these macromolecules in prokaryotic, plant, and animal cells.
RECEPTORS, TRANSPORT PROTEINS (IN MEMBRANE), MOTOR PROTEINS (IN CYTOPLASM), CRITICAL
STRUCTURES IN MANY CELL ORGANELLES. 60
 LO #10

Proteins are translated directionally.
They have an N-terminal end and a C-terminal end.
Translation starts at the N-terminal end and proceeds to the
C-terminal end.

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 LO #10

NUCLEOTIDE

A) Identify the macromolecules shown above (you don’t need to identify the specific molecule, rather just indicate the
type of macromolecule). NUCLEIC ACID
B) Give an example of this macromolecule that you might expect to find in your body (ex. insulin). DNA OR RNA
C) Explain how you knew what macromolecule it was. CONTAINS A SUGAR + PHOSPHATE BACKBONE, AND
NITROGENOUS BASE.
D) What individual monomers make up the larger oligomer or polymer? NUCLEOTIDES.
E) Identify the individual monomers in these structures. SEE BLUE BOX.
F) Describe where you would expect to find these macromolecules in prokaryotic, plant, and animal cells. IN
PROKARYOTES - IN THE CYTOPLASM IN THE NUCLEOID REGION, DNA IN NUCLEUS OF EUKARYOTES, RNA
IN NUCLEUS OR CYTOPLASM. 63
 LO #10
FATTY ACID TAIL

A) Identify the macromolecules shown above (you don’t need to identify the specific molecule, rather just indicate the
type of macromolecule). LIPID - THIS IS A PHOSPHOLIPID
B) Give an example of this macromolecule that you might expect to find in your body (ex. insulin). PHOSPHOLIPIDS,
TRIGLYCERIDE, STEROID HORMONES ARE ALL LIPID MACROMOLECULES.
C) Explain how you knew what macromolecule it was. 2 HYDROCARBON TAILS WITH PHOSPHATE HEAD
(PHOSPHOLIPID). ALL LIPIDS HAVE HYDROCARBON PORTIONS THAT ARE HYDROPHOBIC.
D) What individual monomers make up the larger oligomer or polymer? PHOSPHOLIPIDS AND TRIGLYCERIDES
HAVE FATTY ACID TAILS, BUT STEROIDS DO NOT. SO THERE IS NOT A SINGLE MONOMER.
E) Identify the individual monomers in these structures. SEE ANSWER TO D) ABOVE.
F) Describe where you would expect to find these macromolecules in prokaryotic, plant, and animal cells. CELL
MEMBRANE, MEMBRANE BOUND ORGANELLES.
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 LO #10

Imagine you are a scientist who needs to distinguish between a
protein and a nucleic acid.
Which element would you use an isotope for if you wanted to label and trace a nucleic
acid (vs. a protein). Explain why.
PHOSPHOROUS - B/C NUCLEIC ACIDS HAVE PHOSPHATE GROUPS, BUT
PROTEINS DO NOT.
Which element would you use an isotope for if you wanted to label and trace a protein
(vs. nucleic acid). Explain why.
SULFUR - B/C PROTEINS HAVE SULFUR (AMINO ACIDS CYSTEINE AND
METHIONINE) THAT STABILIZE SECONDARY, TERTIARY, AND QUATERNARY
STRUCTURE. NUCLEIC ACIDS DO NOT CONTAIN SULFUR.

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