Week 1 Cohort 1 Cell Structure and Function PDF

Summary

This document is an outline for a course on science and technology for healthcare. It includes topics such as course introduction, stem cells, and cell structure and organization.

Full Transcript

10.019
Science and Technology
for Healthcare
Week 1 Cohort 1:
Course Introduction
Introduction to Stem Cells
Cell Structure and Organization
 A Warm Welcome to 10.019!

Dr. Chandrima Dr. Hendrikje Werner- Dr. Lou Xuanming
Dr. Tan Mei Xuan
Chatterjee Saerbeck Lecturer, SMT
Senior Lecturer, SMT
Senior Lecturer, SMT Adjunct Fellow, SUTD (Ph.D., Mechanobiology)
(Ph.D., Integrative
(Ph.D., Biophysical (Ph.D., Molecular Sciences & Engineering)
Chemistry) Biotechnology)

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 Course Aims and Expectations
Why Study Biology?
1. As Creators of biomedical technology
2. Towards healthtech or medtech Careers
3. As Collaborators with clinicians and biologists
4. As Citizens who use biology in health decision-making
5. As Consumers who apply their biology knowledge to
making better product choices
6. As Critics of the misuse of biology
7. As Connoisseurs who enrich their lives with science

Copyrights Adapted from Robin Millar, Uni of York 3
 Course Aims and Expectations

Our Personal Goal For You
“SCIENCE LITERACY”
To be curious about human biology and health and
appreciate that living systems are complex but fascinating
To be able to make hypotheses and design appropriate
solutions to healthcare problems
To understand that biology is also about problem solving
and applying information, and not just memorizing facts

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 What will you learn in this course?

10.019 Science and Technology for Healthcare (ST4H)
(greater emphasis on molecular and cell biology fundamentals
which form the the basis of human health and disease)

Copyrights Silverthorn, Human Physiology, Fig. 1.1 5
 Course Learning Objectives
This course is for students who would like a better
understanding of leading chronic diseases and the limitations
in their diagnosis and treatment. At the end of the course,
students will be able to apply fundamental biology knowledge
to better appreciate current technologies and pressing
challenges in healthcare.

Overall Learning Objectives

1. Apply fundamental concepts in molecular biology (DNA and
genes), cell biology and human physiology to compare and
contrast function and regulation in the healthy versus
diseased states.

2. Apply fundamental concepts of classical and modern
genetics towards the understanding of the patterns of human
inheritance and clinical manifestations of genetic diseases.

3. Interpret and analyze common experimental data (both
qualitative and quantitative) derived from molecular biology
and genetic tests.

4. Research and discuss factors that need to be considered
in the prevention, early detection, and treatment of cancer.

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 Course Format
Two 2.5h cohort class sessions
Mini-lectures, group discussions, and hands-on activities
In-class worksheets

Pre-class Video + Weekly MCQ (Flipped; on eDimension)
Weekly MCQs must be submitted by Monday at 9:00am, before the cohort lesson that week
Essential content for cohort class will not be retaught in cohort; pre-class content will be tested
Weeks 1, 2, 3, 5, 8, 10, and 11

To further support your learning:
Midterm Quizzes and Finals
Quiz 1 (Week 4)
Progressive Learning Sessions (PLS)
Quiz 2 (Week 9)
When: Weekly on Fridays @ 2 – 4 pm
Final Exam (Week 14)
Where: Cohort Classroom 14 (2.507)
What: Weekly summary notes +
Group Projects practice problems + consultation
1D Lab (Week 4)
2D Project (Week 12) Instructor Consultations
Week 13 Presentations Email for appointment

Weekly Homework
Due Wednesdays 5pm (online Gradescope submission)
6 homework assignments (3% each)
No submission for Week 3 and Week 8 (due to quiz in following week), and Week 11 Homework

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 Monday Schedule (2 pm – 3 pm)
Week(s) Description Location Details

Weekly Pre-Class (Flipped): Videos and MCQ released one week before
1, 2, 3, 5, Self-study
Pre-class Videos E.g., Week 3 videos and MCQ released in Week 2, and
8, 10, 11 (own place and time)
MCQ Quiz (eDimension) due on Monday 9am at the start of Week 3

Oct 21: Diabetes
Distinguished Clinician Lecture In-person Dec 2: Infectious Disease
6, 12, 13
(CGH Guest Lectures) LT2 (1.203) Dec 9: Cancer
Attendance is mandatory and will be recorded;

Respective cohort
4, 9 Midterm Quizzes 1 and 2 Oct 7, Nov 11; Quiz will begin promptly at 2pm
classrooms

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 Course Assessments
Midterm Quiz 1 (10%) – Week 4
Physical venue: Cohort classrooms
Content from Weeks 1, 2, 3
Bring your own laptops; Closed book; Multiple-choice questions (MCQ)

Midterm Quiz 2 (10%) – Week 9
Physical venue: Cohort classrooms
Content from Weeks 5, 6, 8, but may require concepts learned earlier in the course
Bring your own laptops; Closed book; Multiple-choice questions (MCQ)

Final Exam (25%) – Week 14
Physical venue: TBD (centralized)
Content from Weeks 8, 9, 10, 11, but may require concepts learned earlier in the course
Hardcopy exam; 1 A4 double-sided cheat sheet;
Both Multiple-choice AND Structured questions

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 Weekly Homework

Homework for Weeks 1, 2, 3*, 5, 6, 8*, 9, 10, 11*
(Week 3, 8, 11 not collected – due to midterm and 2D)

Total 6 graded homework

Submit online through Gradescope by Wednesday 5pm
of following week

Please contact your cohort instructors if there are any
issues

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 Overall Grade Breakdown
Assessments Grade
Final Exam 25%
Midterm Quizzes x 2 20%
Weekly Assignments (25%)
Homework x 6 18%
Pre-Class MCQ x 7 7%
Class Participation (10%)
Week 13 Group Presentation 5%
Guest Lecture Attendance 3%
End-term course evaluation survey 2%
1D Project 10%
2D Project 10%
TOTAL 100%

Late penalty: Grade of 50% if within 24h and 0% if > 24h from due date
Please notify instructor of any absences ahead of time (with documentation)

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 Course Textbooks
Alberts et al., Essential Cell Biology, 4th
edition, Garland Science, 2014

Main course text; available at SUTD library and in
cohort classroom.
Provides a very nice conceptual understanding of
the most essential principles; uses simplified,
stripped-down illustration

Campbell et al., Biology: A Global Approach,
10th edition, Pearson, 2014

Main course text; available at SUTD library and in
cohort classroom
Highly detailed and comprehensive text densely
packed with information. Figures are very detailed
and clear with informative captions.
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 Supplementary Text
Pre-class Reading:

In order to get maximum benefit from the lessons, you are strongly encouraged to
complete the assigned textbook reading before class. Even a superficial first
reading the night before will improve your comprehension and retention of the material
covered in class and allow for more active engagement in the classroom activities.

Clark et al., Biology 2e, OpenStax, 2018

Supplementary, optional resource; free access at
https://openstax.org/books/biology-2e/pages/1-
introduction

Comprehensive but suitable for all levels with
simple, straightforward figures and illustrations

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 Questions?

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 Week 1: Pre-Class Material
Part 1: Cells – The Basic Unit of Life

Part 2: Cells and the Chemistry of Life

Complete Pre-Class MCQ (eDimension)
Due Monday @ 9am

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 Week 1 Pre-Class Summary
Organisms are living entities comprised of one or more cells
Cell is the basic structural, functional, and biological unit of life
Cells are varied in appearance and function but share fundamental chemical
characteristics
The human body has different levels of organization, from simple to complex, small
to large
Cells are highly complex chemical systems with shared fundamental characteristics
Cells are mainly composed of four classes of macromolecules – carbohydrates,
lipids, proteins, and nucleic acids
Macromolecules are formed and broken down via dehydration and hydrolysis
reactions, respectively
Cells are very small and composed of complex structures and molecules that can be
visualized under the microscope
Cellular dysfunction can result in disease Questions on the
pre-class material?
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 What do you see here?
How many different cell types
are seen here?

Which cell(s) belong to a
unicellular organism?

Which cell(s) belong to a
multicellular organism?

What are the cells doing?
Credit: David Rogers, Vanderbilt University

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 How many cells in the human body? (FYI)
There are roughly ___________ cells in the human body.

A. 3 million (106)
B. 30 million (107)
C. 30 billion (1010)
D. 30 trillion (1013)
E. Similar to the number of atoms in the universe (~1080)

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 Recap: The Cell is the Basic Unit of Life
The cell is the basic structural, functional, and biological unit (i.e., “building block”) of all
known organisms
Cells come in very diverse shapes and sizes but share fundamental characteristics in their
components
Fig. 4.1 OpenStax Biology 2e.

From L to R: Human nasal sinus
cells (viewed with light microscope),
onion cells (viewed with light
microscope, and Vibrio
tasmaniansis bacterial cells (viewed
with scanning electron microscope).

The human body is composed of more than 30 trillion cells, with >200 different cell types,
each specialized for a specific function

Specialized
cells of the
human body:

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 Recap: Levels of Organization of the Body
(E.g., Cardiovascular System)

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 Lesson Outline
Introduction to Stem Cells

Cell structure and organization
– Prokaryotic vs. Eukaryotic cells

Mini-Activities:
– Visualizing Cells under the Light Microscope
– Build a Virtual Eukaryotic Cell (Animal vs. Plant Cell)

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 Learning Objectives
At the end of the lesson, you will be able to:

Describe the various types of stem cells and their varying ability to differentiate into
the different cell types of the body
Discuss the potential use of stem cells in clinical medicine
Explain the difference between eukaryotic and prokaryotic cells
Identify the various eukaryotic organelles and briefly describe their normal cellular
function
Distinguish between an animal and plant cell

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 Relevant Readings
Alberts et al. Essential Cell Biology, 4th Edition, Garland Science, 2014.
Ch 20 Pg. 705 - 712.

Lippincott Illustrated Reviews: Cell and Molecular Biology, 2nd Ed, Wolters
Kluwer, 2019, Ch 1

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 From Cell to Organism

(Credit: Texas Fertility Clinic)

Repeated rounds of division of a fertilized egg This newborn baby is composed of more than
(zygote) in the early development stage of a 30 trillion cells, with >200 different cell
multicellular organism; IVF = in vitro fertilization types, each specialized for a specific function

How do we get from the single cell (zygote) to the complex and highly-organized multicellular organism?

Cell proliferation = grow + divide
Precursor cell Human body with >30 trillion
“Stem cell” Cell differentiation = specialize cells with >200 cell types

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 Stem cells give rise to the specialized cells of the body
Stem cells are undifferentiated or partially differentiated cells
that can develop into other specialized cell types

Stem cells generate a continuous supply of differentiated cells
When a stem cell
divides, each daughter
cell can either remain a
stem cell or go on to
become terminally
differentiated (i.e., fully
specialized; unable to
develop any further)

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 Cell differentiation (i.e., specialization)
– When a cell becomes more specialized in structure and function
– This happens through a process of selective gene expression,
i.e., turning ON or OFF of specific genes (units of DNA which contains genetic information that relates to an
organisms’ traits)

Each cell type expresses a different
subset of genes, giving rise to specialized
cell structure, behavior, and function

Only a small subset of all human genes are
expressed in each fully differentiated cell

A housekeeping gene is a gene required
to maintain basic cellular function and so is
typically expressed in all cell types of an
organism

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 Clicker Question
In which organ would you expect to find the greatest number of stem cells?

Skin - largest organ in the body
A. Brain Skin cells are constantly shed
and need constant renewal
B. Heart
C. Skin
D. Kidney

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 Stem cells play an important role in tissue renewal
Example: stem cells in the basal layer of the epidermis continually divide and
differentiate into new skin cells to replace those that shed from the top layer

Figure 20.37 Essential Cell Biology
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 Video – Stem Cells and their Applications

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 Clicker Question
Which of the following stem cells would show the greatest
capacity to differentiate into other cell types?

A. Stem cell from the early embryo
B. Stem cell from a newborn baby
C. Stem cell from a child
D. Stem cell from an adult

Plasticity = capacity of stem cell to differentiate into other cell types

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 Stem cells have different levels of plasticity
Plasticity = capacity of stem cell to differentiate into other cell types

Capacity to develop
into a total organism

Capacity to give rise to all
cell types in the body, but
not supporting structures,
such as the placenta
Embryonic stem cells (ESCs)
isolated from the blastocyst
inner cell mass are pluripotent
Capacity to give rise
to multiple different
cell types Adult stem cells are found
in small numbers in various
tissues in the body. They
are multipotent or unipotent

Capacity to give rise Unipotent
to only one cell type

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 Clicker Question
From which type of stem cells
might it be possible to obtain
tissue to regenerate brain
function in a patient suffering
effects of a severe stroke?

Select ALL possible options:
A. ESCs from inner cell mass
B. Hematopoietic SCs
C. Neural SCs
D. Mesenchymal SCs

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 Multipotent stem cells differentiate within a specific lineage

Example: a hematopoietic stem cell (HSC)
divides to generate more HSCs, as well as
precursor cells that proliferate and differentiate
into all the various cells of the blood.

HSCs are unable to differentiate down a
different lineage i.e., cannot become muscle
cell

Figure 20.39 Essential Cell Biology
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 Clinical Application: Blood Stem Cell Transplants
Technically a hematopoietic stem cell transplant (HSCT)
3 different types, based on cell source:
– Bone marrow transplant  HSCs from bone marrow
– Peripheral blood transplant  HSCs from whole blood
– Cord blood transplant  HSCs from placenta and umbilical cord

Credit: Cordlife

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 The Promise of Embryonic Stem Cells (ESCs)

Pluripotent ESCs could serve as
a renewable source of
replacement cells and tissues
to treat several diseases and
conditions, including:
Type 1 diabetes, where the beta
+ appropriate cells of the pancreas are
chemical and destroyed
physical cues
Stroke, where a blood clot
causes oxygen deprivation and
loss of brain tissue.
Spinal cord injuries, leading to
paralysis of skeletal muscles.
Other conditions such as burns
or heart disease, osteoarthritis

What are some concerns about Human clinical trials are ongoing
across several countries
the use of embryonic stem cells?

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 The Embryonic Stem Cell Debate (FYI)
Medical or scientific issues
- Are ESCs the best stem cells for
regeneration and repair?
- Are there any medical risks inherent
in the use of ESCs?

Ethical issues
- What is the source of embryos?
- When is an embryo or fetus
considered a living person?
- What legal status, if any, does an
embryo have?
- Who has the right to use the
harvested stem cells?

There are many laws and acts which researchers are legally bound by.
Must have special license to carry out research on embryos
Can only use “excess” embryos (e.g., leftover from IVF)
Must have written permission from individual responsible for embryo
Embryos cannot be created for research purposes

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 If not human embryos…
then what are some alternative sources
of pluripotent stem cells?

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 Alternative Sources of Pluripotent Stem Cells
1) Therapeutic cloning (i.e., somatic cell nuclear transfer)
Essential Cell Biology, 4th ed

2) Induced pluripotent stem cells (iPS cells)

four

Beating heart muscle cells
derived from iPS cells
Copyrights Credit: Zhen Ma et al., Nature Communications
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 Video – Making Induced Pluripotent Stem Cells (iPSCs)

https://www.youtube.com/watch?v=2zoLUmZyxLk
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 Clicker Question
Induced pluripotent stem cells (or iPSCs) involve the:

A. Activation of stemness in embryonic stem cells
B. Generation of cells from the inner cell mass of blastocysts
C. Conversion of a totipotent cell to pluripotency
D. Reprogramming of unipotent cells to be pluripotent

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 Clinical Applications: Cell Source for Tissue Engineering (FYI)
Modified from Anaïs
Chalard, 2019

or iPSCs
Tissue
Engineering
Approach

Tissue graft
(injectable or
transplantable)
Appligraf is a bovine type I collagen
matrix cultured with allogeneic male
neonatal fibroblasts and keratinocytes

Multiple cell types and
supporting structures needed for
Copyrights a fully functional skin substitute Metcalfe A., J. Royal Society Interface 2006
Simon Myers et al. Tissue Engineering, 2014
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 Summary: Introduction to Stem Cells
Stem cells are undifferentiated or partially differentiated cells that can develop into
other specialized cell types
Stem cells exist in embryos and in adult tissues
Differentiation involves the turning on/off of specific genes
Plasticity refers to the ability of a cell to differentiate into different cell types
Stem cells have varying extents of plasticity (totipotent, pluripotent, multipotent,
unipotent)
Pluripotent SCs can give rise to all cell types and show great potential for use in
regenerative medicine
Induced pluripotent stem cells (iPSCs) generated from adult somatic cells are a
promising source of stem cells

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 Lesson Outline
Introduction to Stem Cells

Cell structure and organization
– Prokaryotic vs. Eukaryotic cells

Mini-Activities:
– Visualizing Cells under the Light Microscope
– Build a Virtual Eukaryotic Cell (Animal vs. Plant Cell)

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 The Microscopic World of Cells (FYI)
Fig. 4.6 OpenStax Biology 2e.

Try me! Cell size and scale:
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 Visualizing Cells

Cells are very small (micron-scale) and
composed of complex structures and
molecules as visualized under the (A) light
microscope, (B) fluorescence microscope,
and (C) electron microscope

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 E.g., Transmission Electron Microscope (FYI)
Prokaryotic cell

Eukaryotic cell

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 Mini-Activity: Visualizing Cells w/ Light Microscope
Make your way to the microscopes to view the following three types of cells:

Human buccal epithelial Onion root tip cells Human Blood Smear
(cheek) cells Carolina Biological Supply Red Blood Cells (RBC)
http://www.olympusmicro.com White Blood Cells (WBC)
Carolina Biological Supply

How do these cells differ from each other?
How are they similar?

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 Classifying Life: Prokaryotes vs. Eukaryotes
Living organisms can be briefly classified as Prokaryotes or Eukaryotes
Prokaryotes comprise of simple unicellular organisms such as bacteria
Eukaryotes include the more complex unicellular or multicellular organisms that we are familiar with,
such as plants, animals, and fungi
Prokaryotes

Unicellular
organisms
(single-celled)

Eukaryotes

Multicellular
organisms
(multiple cells)

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Credit: Archaebacteria: NASA; Bacteria: De Wood and Chris Pooley/Agricultural Research Service, USDA; Protist:
Image copyright MichaelTaylor, 2014; Fungus: Tony Hisgett; Plant: Mauro Guanandi; Animal: úlfhams_víkingur
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 Prokaryotic vs. Eukaryotic Cells
Lumen Learning

Prokaryotic cell (“before nucleus”): a Eukaryotic cell (“true nucleus”): a type of
type of cell lacking a nucleus and other cell with a nucleus and many membrane-
membrane-bound organelles. bound organelles (“little organ”).

Organisms with prokaryotic cells are Organisms with eukaryotic cells are called
unicellular and called prokaryotes. eukaryotes. (e.g., animals and plants)
(e.g., bacteria)
Larger in size (10 – 100 µm)
Smaller in size (0.1 – 5 µm)

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 Four Common Cellular Components
Prokaryotic cell Which components are present in BOTH
prokaryotic and eukaryotic cells?

Eukaryotic cell

1

2

3

4
DNA (genetic material)
rsscience.com

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 Eukaryotic cells contain many organelles
Organelles are sub-
cellular structures
with specialized
cellular functions

Many organelles are
membrane-bound
to form a separate
compartment within
the cytosol for
specific compounds
and reactions

Organelles support
complex functions
of a eukaryotic cell
(e.g., movement,
protein synthesis)
Lippincott Molecular and Cell Biology

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Eukaryotic Organelles and their Functions

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 Mini-Activity: Build a Eukaryotic Cell
http://sepuplhs.org/high/sgi/teachers/cell_sim.html
Build a complete animal cell and plant cell (eukaryotic)
Hover over each organelle for more details about its function.

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 Solution: Animal vs. Plant Cell

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 Comparing Animal vs. Plant Cells

Lumen Learning

Components of an animal (left) and plant (right) cell

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 Clicker Question
Match the following organelles with their function:
a. ribosomes i. Movement

b. microtubules ii. Photosynthesis

c. mitochondria iii. Protein synthesis

d. chloroplasts iv. Digestion

e. lysosomes v. Cellular respiration

A. a-i, b-ii, c-v, d-iii, e-iv
B. a-iii, b-i, c-v, d-ii, e-iv
C. a-ii, b-v, c-iii, d-i, e-iv
D. a-iii, b-i, c-iv, d-ii, e-v
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 Clicker Question
Which of the following would be a possible process to study in the
bacterium E. coli?

1. how cells decode DNA instructions to make proteins
2. formation of the endoplasmic reticulum
3. trafficking of lysosomes within the cell
4. how mitochondria get distributed to cells during cell division

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 Summary: Cell Structure and Organelles
Prokaryotic cell: Unicellular organisms (e.g., bacteria cell) without a nucleus or
membrane-enclosed organelles
Eukaryotic cell: Plant and animal cells with a nucleus and membrane-enclosed
organelles
Organelles are sub-cellular structures with specialized function
All cells have four common components: 1) plasma membrane, 2) cytoplasm, 3)
genetic material (DNA), and 4) ribosomes
Some cells have specialized structures unique to them
– e.g., cilia in human airway cells, flagella in bacteria and sperm cells
Plant and animal cells have many fundamental similarities, but also some striking
differences
– e.g., cell wall and chloroplasts in plants
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 Mini-Activity: Visualizing Cells w/ Light Microscope
Make your way to the microscopes to view the following three types of cells:

Human buccal epithelial Onion root tip cells Human Blood Smear
(cheek) cells Carolina Biological Supply Red Blood Cells (RBC)
http://www.olympusmicro.com White Blood Cells (WBC)
Carolina Biological Supply

How do these cells differ from each other?
How are they similar?

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