Transcript here
Week 12: The Cell as the Functional
Unit
Characteristics of cells
Metabolism
Reproduction: mitosis and
meiosis (text)
Recapitulation
Hierarchical Nature of Living
Systems
Community
Population
Organism
Organ
Tissue
Cell
Organelles
Macromolecules
Atoms
Structural and Functional
Characteristics of Cells
Cells as the physical infrastructure
Cell membranes: gate keeper of outflow and
inflow of materials
Water: medium of cell’s biochemistry
Compartmentation via organelles: a good thing!
Major types of cells (see text)
Cells as the Physical Infrastructure
Cell theory
All organisms composed of cells
Cells as smallest unit of organization exhibiting all
characteristics of life (e.g., irritability, reproduction, energy)
Structure
Cell Membrane
Organelles
Nucleus
Cytoplasm
Size of Cells Relative to Other
Features in the Sciences
10-10m
10-5m
10+3m
~Five orders of magnitude (105) larger than atoms and visible with light microscope
General Features of a Cell
Size correlated with function
Upper limit: 0.00001 m (1 x 10-5 m)
Distance from interior to exterior: critical
Over 1 x 10-5 m: nonfunctional
Efficacy of transport/diffusion (diffusion … physics
and chemistry again!)
so physics and chemistry determines upper limit of the cell
Structural and Functional
Characteristics of Cells
Cells as the physical infrastructure
Cell membranes: gate keeper of outflow and
inflow of materials – stop … what is a gate?
Water: medium of cell’s biochemistry
Compartmentation via organelles: a good thing!
Major types of cells
Membranes: Structure
Principal structural components (N=2)
Lipid
Phosphate group (PO4)
Phosphate/ Glycerol
(Hydrophilic - polar)
Lipid/Fatty Acid
(Hydrophobic – non-polar)
Lipid bilayer at the molecular level
Functional property: contrasting
chemical characteristics of the two
layers
Hydrophilic (water loving and polar)
Hydrophobic (not water loving or polar)
Hydrophilic (water loving and polar)
Lipid Bilayer
Membranes: Structure
Lipid bilayer: “fluid membrane” with floating
chunks of proteins and carbohydrates (e.g.,
icebergs)
Lipid Bilayer
Protein Chunk
The Cell as the Functional Unit
Characteristics of cells
Start with membranes
Metabolism
Reproduction: mitosis and
meiosis (text)
Recapitulation
Membranes: from Lipid Bilayer
to Functional Properties
Example of hierarchy theory and emergent
properties
“Parts”: lipid, phosphate, proteins, carbohydrates
When combined: unusual/unexpected properties =
emergent properties
Selective permeability (text and lecture)
Active transport (text)
Signaling: cell-to-cell communication (text)
Transport through Membrane:
Selective Permeability
Signaling in/on Membranes
Swine Flu
Cystic Fibrosis
http://www.youtube.com/watch?v=GW0lqf4Fqpg
Allergies
The Cell as the Functional Unit
Characteristics of cells
Water medium
Metabolism
Reproduction: mitosis and
meiosis (text)
Recapitulation
Water: Medium for Biochemistry
(back to chemistry!)
Role of water (H2O)
Liquid medium for cell
Physical properties (e.g., polarity, phases)
Chemical properties (e.g., pH, liquid solution)
Exquisite and unique properties of
H2O
Importance in cell metabolism:
liquid phase chemistry and pH
Imagine a cell’s functioning in a
medium other than liquid water (say
… water in a gas phase or a solid)
The Cell as the Functional Unit
Characteristics of cells
Compartmentation
Metabolism
Reproduction: mitosis and
meiosis (text)
Recapitulation
General Cell Structures:
Compartmentation
Principle of Compartmentation
Cells are compartmentalized
Elaborate and organized infrastructure
Analogy to a dorm
Corridors as endoplasmic reticulum
Rooms as organelles
Consequence of not being compartmentalized
… disorder!
Function of individual organelles (text)
Compartmentation: Animal cell
Question
In the following diagram, which letter identifies
the cytoplasm?
A.
B.
C.
D.
E. None of the above
Question
In the following diagram, which of the arrows
indicates the lipid portion of the membrane?
A.
B.
C.
D.
Structural and Functional
Characteristics of Cells
Cells as the physical infrastructure
Cell membranes: gate keeper of outflow and
inflow of materials
Water: medium of cell’s biochemistry
Compartmentation via organelles: a good thing!
Major types of cells (see text)
Cell Types
Prokaryotes
No nucleus
No mitochondria, chloroplasts,
Golgi or endoplasmic reticulum
DNA, enzymes, metabolize, etc.
Example: bacteria
Eukaryotes
Nucleus and all the organelles
Plant eukaryotes – same except
Chloroplast for photosynthesis
and cell wall
Animal eukaryotes (this is you!)
Prokaryote: Bacteria
Flagella
Information
Capsule
Plasma Membrane
Cytoplasm
Cell Wall
Spores
Size of Eukaryote vs. Prokaryote
The Cell as the Functional Unit
Characteristics of cells
Metabolism (all about
carbon-carbon bonds)
Reproduction: mitosis and
meiosis
Recapitulation
Energy Utilization
Three related activities: acquisition,
utilization, and storage
Energy Acquisition
Energy utilization
Energy capture (autotrophs; heterotrophs)
First law of Thermodynamics
Laws of Thermodynamics (1st and 2nd laws)
ATP (adenosine triphosphate) and ADP
(adenosine diphosphate)
Energy storage
Chemical bonds (C-C covalent bonds)
Carbohydrates, glycogen and lipids
In humans and other animals, storage as _____?
The Cell’s Energy Currency:
Analogy to Legos!
Adenosine triphosphate (ATP … high energy)
Adenosine diphosphate (ADP … low energy)
Structure
3 or 2 phosphate groups
Sugar molecule
Function
Removal of phosphate group
source
of energy
Currency analogy in economy
Last 5 seconds in your body: trillions of ATP to
ADP conversions and back again and again and again …!
Cell’s Energy Currency
Biosynthesis = construction of high energy carbon molecules
Catabolism = deconstruction of high energy carbon molecules
ADP
Biosynthesis/
Anabolism
Catabolism
ATP
Remember the analogy to Legos!
Photosynthesis
Photosynthesis
Convert sunlight to chemical energy (1st Law of
Thermodynamics)
Process (building high energy carbon molecules)
Energy + CO2 + H2O Carbohydrate + O2
Carbon - Carbon
Now the Granola Bar
Energy and the Granola Bar
First Law of Thermodynamics
Second Law of Thermodynamics (think ecology)
Chemistry of bonds (energy stored – First law of
Thermodynamics)
Uniqueness of carbon atom’s bonding (covalent)
Immediate energy currency in cells via ATP and ADP
Release of some energy as heat (Second Law of
Thermodynamics)
Universality of Reproduction:
How the Cell Achieves this Feat
Reproduction: regenerative process of
making new organisms (not necessarily
copies)
Methods
Sexual
Asexual (microbes; cell division/mitosis)
Examples
Siblings
Geranium plants
Dolly (the sheep)
Reproduction: Mitosis (Text)
Reproduction in general
Cell to cell reproduction
Information copying
(DNA)
The Cell as the Functional Unit
Characteristics of cells
Metabolism
Reproduction: mitosis
Recapitulation
Question
Energy is a commodity in all living systems. The
principles governing the use of energy in plants,
animals and microbes are consistent with ____.
A.
B.
C.
D.
The Law of energy efficacy
Biochemical Law of energy transfer
First and second laws of thermodynamics
All of the above
Question
The carbohydrate (CH2O) is the energy rich product of
photosynthesis in plants. The “energy richness’ is
simply another way of stating that ___.
A.
B.
C.
D.
Energy transductions in plants conform to the 2nd
Law of Thermodynamics
Energy is stored in the covalent bonds between
carbon atoms
Energy is the sole product of photosynthesis
Energy is the ATP commodity in all cellular
biochemistry
Question
Mitosis and meiosis are two dissimilar processes in plants
and animals and yet they share the same underlying
characteristic of living systems which is one of _____.
A.
B.
C.
D.
E.
Information copying
Energy utilization
Gender identification
A and B above
B and C above