BIO 201 Set 1 Notes - A Preview of Cell Biology PDF

Summary

These are notes for BIO 201 - Set 1, that provides a preview of cell biology topics, including microscopes, biochemistry, and genetics. There are many figures, diagrams and questions in the notes. The notes cover topics like the scientific method, and describe the contributions of key scientists to understanding cells, which is a topic vital to biology studies.

Full Transcript

BIO 201
Set 1 Notes
A Preview of Cell Biology
 Contents
(1.1) – Ye Olde Microscopes: Robert Hooke & Antonie
Van Leeuwenhoek
(1.2) – Compound Microscopes: Robert Brown and
Theodor Schwann
(1.3) – Rudolf Virchow
(1.4) – The 3 Strands of Modern Cell Biology
(1.5) – Cytology: Microscopes
(1.6) – Biochemistry: The Chemistry of Biological
Structures/Functions
(1.7) – Genetics: Information Flow in the Cell
(1.8) – Review: The Scientific Method
 1.1 – Ye Olde Microscopes: Robert Hooke & Antonie Van Leeuwenhoek

Robert Hooke built a microscope in 1665 that examined dead
cells from an oak tree (called cork cells).
He discovered that the cork cells looked like tiny little boxes,
which he called “cells”, the place where monks stayed in a
Monastery.

Latin: cellula = “little room”

Q1. Why was Hooke not actually looking at real “cells”?

Q2. When have you previously looked at a microscope with 30X Cork Cells (30X)
magnification?

Tube full of lenses
Hooke’s microscope was only able to magnify objects up to 30X
total magnification and he was therefore, unable to see the
details of any cellular structures.
Hooke was interested in many of the branches of sciences and
even got into disputes with Sir Isaac Newton, claiming that
Newton’s ideas were influenced by him (Hooke).

FYI: Hooke discovered the “Law of Elasticity”
Hooke’s constant = k

[Know Robert Hooke’s Scientific Contributions] Hooke’s Microscope
 1.1 – Ye Olde Microscopes: Robert Hooke & Antonie Van Leeuwenhoek
Nobody actually knows what Robert
Hooke looked like as any self-portraits of
Newton
Hooke were destroyed (perhaps by
Newton)! Hooke?

Image of Robert Hooke??

Image from “The wacky history of
the cell theory”
https://www.youtube.com/watch?v=4OpBylwH9DU

Antonie van Leeuwenhoek was a Dutch textile merchant.

He was also interested in microscopes and produced a microscope
made of small lenses, which could magnify objects ~300X their size.

Q3. Which microscope have you previously used in BIO 111/112 lab
that can magnify objects up to 300X?

[Know van Leeuwenhoek’s Scientific Contributions]
 1.1 – Ye Olde Microscopes: Robert Hooke & Antonie Van Leeuwenhoek

Antonie van Leeuwenhoek’s
microscopes were not very large and
about the size of a lens (found on glasses).

Van Leeuwenhoek’s microscopes on
display at Boerhaave (Dutch national
museum history of science)

Van Leeuwenhoek became the first person to view:
1. Blood cells.
2. Single-celled organisms (algae and protists).
3. Sperm cells.
4. Bacteria (looked at dental scrapings from other
people).

[Know van Leeuwenhoek’s Scientific Contributions]
 1.1 – Ye Olde Microscopes: Robert Hooke & Antonie Van Leeuwenhoek

Antonie van Leeuwenhoek didn’t call the
single-celled organisms when he
witnessed bacteria or protists, but coined
the term “animalcules because they
looked like little animals.

All of the microscopes produced in the
1600’s-1700’s were limited by their
resolution (resolving power).
Resolution = The shortest distance between
two points on a specimen that can still be
distinguished by the observer as 2 separate
entities.
Poor resolution – Image is magnified, but the
objects are not distinguishable as separate entities.

Good resolution – Image is magnified, and the
objects are distinguishable as separate entities.
 1.2 – Compound Microscopes: Robert Brown and Theodor Schwann

Compound Microscope (1831)
Today’s Compound Microscope
By the 1830’s compound microscopes were used. This greatly increased the
magnification of objects and the resolving power of the microscope.

The compound microscope included 2 lenses: Q4. How does one calculate the total
magnification on a compound microscope?
Objective Lens and Ocular Lens

The limitation however was that structures only 1 μm in size could be seen.
 1.2 – Compound Microscopes: Robert Brown and Theodor Schwann

~1831, Robert Brown used a compound
microscope and discovered the plant
nucleus found from the epidermis of an
orchid.

Brown named the rounded structure the
Robert Brown “nucleus” which is derived from the
Plant cell nucleus from an orchid Latin word kernel.

In 1838, Matthias Schleiden came up
with the conclusion that all plant tissues
are composed of CELLS.

He also came to the conclusion that an
embryonic plant always arises from a
single cell.

Plant cells! Schleiden is a CO-FOUNDER of the
Matthias Schleiden
German Professor of CELL THEORY.
Botany [Know Brown’s and Schleiden’s Scientific Contributions]
 1.2 – Compound Microscopes: Robert Brown and Theodor Schwann

In 1839, Theodor Schwann came to the
conclusion that all animal tissues are
composed of CELLS.

It was more difficult to come to this
conclusion because plant cells have cell
Theodor walls, which easily show boundaries
Schwann Animal Cells
between each cell.

Schwann had to look at animal cells from
Q5. What other discovery was made by cartilage to see boundaries between each
Theodor Schwann regarding neurons? cell, because there was thick deposits of
collagen fibers between them.

Q6. In 1839, Schwann postulated 2 basic
principles of the cell theory. What are these 2
basic principles?

[Know Schwann’s Scientific Contributions]
 1.3 – Rudolf Virchow

In 1855, Rudolf Virchow began to
observe cell division, and
contributed the 3rd principle of the
modern cell theory:

Rudolf 3. All cells arise only from pre-
Virchow existing cells.

Advancements in microscopy has
allowed us to see the large physical
differences between different cells.

Top-Left: Filamentous fungi
Bottom-Left: Villi found in small
intestine
Bottom-Right: Neuron

Does cell structure relate to function?

[Know Virchow’s Scientific Contributions]
1.4 – The 3 Strands of Modern Cell Biology
DO NOT MEMORIZE THIS DIAGRAM!
3 historical strands are woven together
to form the concept of modern cell
biology. Each strand is important
because it gives us a better understanding
of cells.

1. CYTOLOGY: Focuses mainly on
structure and emphasizes optical
techniques. Observation of cell
physiology.

2. BIOCHEMISTRY: The strand that
focuses mainly on cellular function
(especially at the molecular level) –
Krebs’ cycle, Glycolysis, etc.

3. GENETICS: The strand that
focuses on information flow and
heredity. DNA sequencing,
chromosomal inheritance, etc.
 1.5 – Cytology: Microscopes

1. CYTOLOGY: Focuses mainly on cell structure
and emphasizes optical techniques.

LIGHT MICROSCOPE: Earliest tool used
by cytologists. Allows for identification of
membrane-bound organelles within cells as
well.
Q7. What is the smallest organism
you have been able to see clearly (in a
light microscope) in first-year BIO at
UFV?

Q8. Why is the light microscope used
in the UFV lab known as a
“brightfield’ microscope?

Slides that are used for the light microscope
are prepared using a microtome.
 1.5 – Cytology: Microscopes

Microtome

MICROTOME: First started to be used in
the mid 1800’s. A device used to create very
thin sections of a specimen. These thin slices
are called “sections”.

When creating sections, it is often useful to
use dyes and stains in order to distinguish
different parts of the cell.
 1.5 – Cytology: Microscopes

It is must easier to see details in the stained
specimen vs. the unstained specimen. Later
on in the course, you will be performing
staining of various slides.

Staining improves the limit of resolution
of the microscope.

Limit of resolution = How far apart
objects must be to appear distinct.

Q9. What is the ‘limit of resolution’ of a
typical light (compound) microscope that we
use in the Bio 111/112 lab?
The smaller the limit of resolution a
microscope, the greater its resolving power
(higher resolution).

Q10. What is a major disadvantage in using
stained specimens in a brightfield microscope?
1.5 – Cytology: Microscopes
Phase Contrast Microscope and
Differential Interference Contrast
When light passes through the specimen,
some wavelengths of light pass through
the specimen more slowly. This is called
a phase shift.

The human eye can not detect this, but a
phase contrast microscope can exploit
these differences and create different
brightness patterns, resulting in a better
defined 3D object.

Brightfield Phase-Contrast
Microscope Microscope
(unstained) (unstained)
 1.5 – Cytology: Microscopes
Fluorescence Microscope:

Detects fluorescence dyes or labels and
shows the locations of substances or
structures inside a cell.

Liposomes (lipid-based
drugs) that contain a
fluorescent label show
up as RED. Cell nuclei
(Hoescht) labeled in
BLUE.

This was how I
demonstrated that my
liposomes accumulated
in the tumor.

Lee et al. (2012)
 1.5 – Cytology: Microscopes
Fluorescence Microscope:

Antibodies that target certain
proteins (such as microtubules) can
be added to cell/tissue samples.
The antibodies have strong
binding and specifically bind to
these proteins.

A fluorescent secondary antibody
can be added and will attach to the
first (primary antibody) that you
added to your sample. GREEN = Microtubules
BLUE = Nuclei
Your sample can then be taken to a
fluorescent microscope where
images can be taken highlighting
specifically labeled sections of the
Q11. Draw a diagram of how fluorescent
cell. microscopy works with primary and
secondary fluorescent antibodies.
 1.5 – Cytology: Microscopes
Confocal Microscope: Similar to fluorescent microscopy except that only
a single plane of a fluorescently labeled specimen is visualized.

Software can be used to compile all of the images of
each single plane to create a complete 3D image.

This can be especially useful for fluorescently labeled
drugs and can determine how far the drugs can
penetrate into a tumor site for example.
 1.5 – Cytology: Microscopes
The Electron Microscope: The electron
microscope uses a beam of electrons rather
than light. It was a major breakthrough for
cell biology!

- The limit of resolution of an electron
microscope is around 0.1-0.2 nm.
- Electron microscopes can magnify images
up to 100,000X.

Transmission Electron Microscopy (TEM):
Electrons are transmitted through the
specimen.

Scanning Electron Microscopy (SEM): The
surface of the specimen is scanned. Electrons A SEM produced images in (a) and (b)
are deflected from the outer surface of the Note only the surface is seen!
specimen.
A TEM produced images in (c) and (d)
Note internal structure can be seen!
 1.5 – Cytology: Microscopes
Electron microscopes can help visualize cell
structures that are too small to be seen with a
light microscope:

- Ribosomes
- Membranes
- Microtubules (fine structure)
- Microfilaments
- DNA double-helix!
 1.6 – Biochemistry: The Chemistry of Biological
Structures/Functions
Biochemistry is the study of looking at the chemical processes occurring in
living organisms. It is vital in understanding how cells work!

Much of Biochemistry dates back to the work of Fredrich Wohler* (1828),
who demonstrated that urea could be synthesized in a laboratory setting.
Note: When amino acids are catabolized (broken down) in the
body, ammonia is released. To prevent any toxic effects of
ammonia on the blood (i.e. causes pH to increase), your body
uses a series of enzymes to convert the ammonia into a non-
Molecule of Urea toxic end product called urea that is excreted in the urine.

Louis Pasteur* (1860’s) demonstrated that living
yeast cells could ferment sugar into alcohol.

[Do not need to know scientist’s names
beyond this point i.e. slide 21 or later]
 1.6 – Biochemistry: The Chemistry of Biological
Structures/Functions
Eduard and Hans Buchner* (1897) discovered that isolated
yeast extracts (not live yeast) could also perform
fermentation of sugar into ethanol.

Q12. Why would yeast extracts be able to perform
fermentation?
Eduard Buchner* was awarded the Nobel prize in Chemistry
(1907) for his work on fermentation. His work helped to
initiate the discoveries of biochemical pathways, which
utilize enzymes.

Gustav Embden* and Otto Meyerhof* described the
metabolic pathway of GLYCOLYSIS in the early 1930’s.
We will study this process in detail in Ch 9. Hans Krebs*
discovered the metabolic cycle known as the Krebs’
Cycle/TCA Cycle/Citric Acid Cycle shortly after. We will
study this process in detail in Ch 9 as well!

Q13. What are glycolysis and the Krebs’ Cycle important
for in the cell?
 1.6 – Biochemistry: The Chemistry of Biological
Structures/Functions
Other advancements in Biochemistry:

Radioactive isotopes: 3H, 14C and 32P can be
used to trace where atoms and molecules end up
when molecules are transformed by enzymes in
the cell. Examples will be given later in the
course.

Subcellular Fractionation: Centrifugation
(shown to the right) spins test tubes at a high
speed causing more dense organelles/cell
structures to sediment to the bottom of the test
tube and less dense organelles/cell structures to
stay near the top of the test tube. Covered in
Lab #3.
 1.6 – Biochemistry: The Chemistry of Biological
Structures/Functions
Other advancements in Biochemistry:

Chromatography: Biochemical technique to
separate molecules based on size, charge, or
different chemical properties (like polarity)
Recall Thin-Layered Chromatography (TLC) in
BIO 111??

Electrophoresis: Uses an electrical field to
move proteins, DNA or RNA molecules
through a medium based on size/charge.
Covered in BIO 202, not BIO 201!

Mass Spectrometry: To determine the size and
composition of individual proteins. Covered in
BIO 320, not BIO 201!

The main point is that Biochemistry is
needed in order to understand how a cell
functions at the molecular level!
 1.7 – Genetics: Information Flow in the Cell
The last “strand” of cell biology incorporates genetics,
which is the study of genes, heredity of genes and the
variation of inherited characteristics.

BIO 220 (genetics) and BIO 202 (cell signaling and
regulation of gene expression) cover most of the this
“strand” of cell biology, which is why it will only be
covered briefly in BIO 201.

Gregor Mendel’s experiments with peas (1866) laid the
foundation for understanding the passage of “hereditary
factors” (now known as genes) from parents to offspring.

Walther Flemming* (1880) saw threadlike bodies in the
nucleus that he called chromosomes. Also coined the term
mitosis for the process of cell division.

Wilhelm Roux* (1883) and August Weisman* suggested
that chromosomes carried the genetic material.
 1.7 – Genetics: Information Flow in the Cell
Other advancements in Genetics:

1953: Watson and Crick proposed the double helix
model for DNA

1960s: Understanding of DNA replication, transcription
and the genetic code (codon table).

Nucleic acid hybridization: A variety of techniques that
use the ability of nucleic acid bases to bind to each
other. Covered in BIO 202.

Recombinant DNA technology: Using restriction
enzymes to cut DNA at specific places allowing
scientists to create recombinant DNA molecules with
DNA with different sources. i.e. GMO’s. covered in
BIO 202.
 1.7 – Genetics: Information Flow in the Cell
Other advancements in Genetics:

DNA sequencing: Methods for rapidly determining the
base sequences of DNA molecules. i.e. The human
genome project. Covered in BIO 202.

Bioinformatics: Merges computer science with biology
to organize and interpret enormous amounts of
information (DNA sequencing, proteomes, etc.) i.e. You
can find the DNA sequence or amino acid sequence of a
specific protein simply by doing a search! Covered in
BIO 202.
 1.8 – Review: The Scientific Method
The scientific method is used to assess new information found in cell biology (just
like in any field of other science as well!) This should be review from first-year
Biology.

- Scientists make observations about the world around them. They formulate a
question/problem.

- Scientists formulate a hypothesis (tentative explanation or model that can be
tested).

- Data are collected and interpreted.

- Hypothesis is accepted or rejected.

- The experiment is normally modified and repeated numerous times to better
understand the question/problem at hand.