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Announcements
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Assignments
Lecture
Objectives
Why Study
Cells
Web
Resources
Cells
Are the
Basic Unit of Life
Prokaryotic
Cells
Eukaryotic
Cells
Membrane
Structure
and Function
Coordination
Organelle Function
Lecture
Syllabus
IB 100/101 Home
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Text Readings in Life, Lewis et al.
Chapters 4, Cells: Units of Life and 5, the Cell Surface and
Cytoskeleton
The "Reviewing Concepts" boxes are valuable summaries of the
main
ideas in these sections of the text.
You have open access (no log-in or password needed) to
instructional
materials on the Text web site. Select the text chapter you want and
use the links to the e-learning modules or other available materials.
There is also a collection of study materials called the "Essential
Study Partner" that you may find useful.
Web Crossing
You may also ask questions and see answers to your classmates'
questions in Web Crossing in the "Talk to Jim and Ed" discussion.
Objectives:
The content of today's lecture will help you answer
questions 1
and 2 on this assignment:
After studying this material you should be able to:
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Explain how a single cell meets the basic criteria that
differentiate living organisms from nonliving objects or chemical
reactions.
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Draw sketches of prokaryotic and eukaryotic cells (plant
and
animal), pointing out the distinguishing characteristics of each of
these types of cells.
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Describe the basic structure of the membranes in the cells
you have
drawn and describe the roles of these membranes in determining the
organization and functions of cells and their organelles.
Include the following in your description:
| phospholipid bilayer |
transport proteins |
receptor proteins |
sugar molecules |
| diffusion |
osmosis |
facilitated diffusion |
active transport |
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Describe the role of each cell organelle and membrane
system
involved in the production and secretion of milk from a mammary gland
cell. (Read the text section "Organelles Interact to Secrete
Substances"
starting on pg 54 (Chapter 4 of the Life text). Understand the
relationships among the organelles illustrated in figures 4.11, pg.
55)
Include the following in your description:
| Chromosomes |
DNA |
messenger RNA |
nucleus |
| cytoplasm |
endoplasmic reticulum
(rough & smooth) |
ribosomes |
protein |
| vesicles |
Golgi bodies |
fat droplets |
outer cell membrane |
As you study the unit on cells, can you figure out how the
cell
membrane systems, organelles, and other components in the right-hand
side of the table below are involved in maintaining the characteristics
of living organisms in the left-hand side of the table? (Lecture
Objective #1)
| Characteristics of Living Organisms
(From Lecture #1) |
Cell Membrane Systems,
Organelles, and Other Components |
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Life is organized
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Life requires energy
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Living things must maintain an internal constancy
-homeostasis: the ability to maintain chemical constancy (i.e., to stay
the same)
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Living things react to environmental change (i.e.,
their
surroundings)
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Living things reproduce, grow, and develop
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Living things adapt
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| cell wall |
plasma membrane |
| phospholipid bilayer |
membrane proteins |
fluid mosaic
membrane model |
transport proteins |
| nucleus |
nuclear membrane (envelope) |
| nuclear pores |
chromosomes |
| DNA |
nucleolus |
| receptor proteins |
golgi bodies |
| vesicles |
mitochondria |
| chloroplasts |
ribosomes |
| endoplasmic reticulum (ER) |
lysosomes |
| cytoskeleton |
microtubules |
| vacuole |
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Why should we study cells?
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Cells are the basic structures of almost all living
things,
including us. There are maybe 10 to 100 trillion of them in each of our
bodies.
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Cells do all the chemical activity that happens in our
bodies (our
meaning - all types of organisms).
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They process energy, digest our food, capture CO2, release
CO2,
release heat
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When cells get "out of whack" we get sick.
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Stem cells may one day help us recover from inherited and
other
types of illness or injury.
Cell Biology Web Resources
Cells as the "Basic Unit of
Life"
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Cells are common to all organisms from bacteria to fungi,
plants,
and animals.
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Cells were "discovered" as the basic unit of living
organisms in
the nineteenth century.
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Early observations of cells led to the distinction of two major cell types:
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Prokaryotes - cells without membrane-bound nuclei or
other cell
organelles.
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Eukarya - cells with "true" nuclei and membrane-bound
organelles
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Plants, Algae, Fungi, Animals, you and me
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A third cell type - characteristic of another domain of
life was
discovered by Carl Woese wins Crafoord Prize! at the University
of
Illinois in 1977.
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Archaea - cells similar to bacteria in that they do
not
have
membrane-bound nuclei or other cell organelles, BUT they differ
genetically and in other structural characteristics. Many Archaea have
been found in extreme environments (temperature, pressure, salinity).
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Archaea, bacteria, and eukaryotic cells are all thought
to have
evolved from some common ancestor.
Prokaryotic Cells
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Pro = before, karyon = kernal (what nuclei looked like to
those who
first saw them through a microscope)
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Cells WITHOUT ORGANIZED NUCLEI bounded by a nuclear
membrane OR ANY
OTHER MEMBRANE-BOUND ORGANELLES
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Eubacteria (True bacteria) (Text pg. 50, fig. 4.6)
and cyanobacteria (blue-green algae)
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No membrane bound organelles within the bacterial cell
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Nucleoid - the main genetic content of the cell
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Plasmids are small circular pieces of DNA that are
separate from the DNA of the nucleoid.
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Test your knowledge of prokaryote structure.
Eukaryotic Cells
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Eu = true, karyon = kernel (nucleus)
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Cells WITH ORGANIZED NUCLEI bounded by a nuclear membrane
AND OTHER
MEMBRANE BOUND ORGANELLES.
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Plants and animals HAVE EUKARYOTIC CELLS
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Fungi, algae, and most other types of organisms, except
bacteria and
archaea
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All have a cell (plasma) membrane
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Some have cell walls
Membrane Structure and Function
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Membranes are selectively permeable structures
that regulate
the movement of molecules in and out of the cell (bacteria, archaea,
and
eukaryotes) and in and out of compartments within the eukaryote
cell.
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The basic structure is a phospholipid bilayer. Phospholipid
molecules
align to form membranes because part of the molecule is hydrophilic
(the
phosphate end) and part is hydrophobic (the fatty acid chain). (Text pg
67, fig 5.2)
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The Phospholipid bilayer is a constantly moving, fluid
structure.
Proteins and other materials imbedded in it are free to move about.
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Proteins embedded within the membrane perform many
tasks: (Text pg 68, fig. 5.3)
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Receptor proteins: receive and transmit chemical
messages
so that
cells can respond to changes in their environment.
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Cells respond to hormones produced in your body when
hormone
molecules bind to specific receptor proteins in your cell membranes.
(Insulin, growth hormone, sex hormones, thyroid hormones, etc.)
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Antihistamines block the receptor proteins that
normally bind histimines produced when you have an allergic reaction to
something in your environment. (Link from wikipedia.org)
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Cell surface proteins: Important for recognition of self
(in
animals). Your blood type and tissue type are determined by the
proteins
on the surface of your cells. This is especially important to consider
when getting a transfusion or a tissue or organ transplant.
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Transport proteins: move substances across the membrane
How do materials cross membranes?
Eukaryotic cells are thought to have developed from the
symbiotic
relationship of one cell being engulfed by another cell, but not being
digested - the endosymbiotic hypothesis
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