1. 1.2 – Ultrastructure of cells
(with special thanks to Stephen Taylors “Draw the Core” and topic 2 presentations)

2. Look at that resolution!
The invention of electron microscopes led to greater understanding of cell structure
Look at that resolution!

3. All organisms can be divided into two groups according to their cell structure.
Prokaryotes
Eukaryotes
Cell wall with peptidoglycan
Cell wall with cellulose (plants), chitin (fungi), or no cell wall (animals)
70s ribosomes
80s ribosomes
Cell membrane on inside of cell wall – no organelles
Cell membrane on inside of cell wall and all throughout cell surrounding organelles

4. Prokaryotes have a simple cell structure without compartmentalization and divide by binary fission.

5. Drawing of the ultrastructure of prokaryotic cells based on electron micrographs: cell wall, pili and flagella, and plasma membrane enclosing cytoplasm that contains 70S ribosomes and a nucleoid with naked DNA.

6. A Terrible Drawing…
Draw the Core

7. A Terrible Drawing… Too light Unlabeled Messy Tiny Draw the Core
Draw the Core

8. A Rubbish Drawing…
Draw the Core

9. A Rubbish Drawing… Criss-crossed label lines Wiggly label lines
Where are these labels pointing?
The arrow heads are unnecessary
Unclear labels
Messy shading
Outside the scanning box
Draw the Core

10. Drawing of the ultrastructure of prokaryotic cells based on electron micrographs: cell wall, pili and flagella, and plasma membrane enclosing cytoplasm that contains 70S ribosomes and a nucleoid with naked DNA.

11. A Good Drawing…
Draw the Core

12. A Good Drawing… Good use of space Clear strong lines
Label lines are straight
Labels clearly written
Scale bar if appropriate
Lines touch the labeled structure
No unnecessary shading or colouring
Draw the Core

13. cell wall plasma membrane Flagellum Movement Pili Nucleoid Contains:
Protects cell, holds structure
plasma membrane
Controls what goes in and out of the cell
Flagellum
Movement
Pili
Attachment,
Exchange of
DNA
Nucleoid
Contains:
70S ribosomes
Protein synthesis
Plasmids/ Loops of DNA
Genetic information
Cytoplasm
Contains solutes, enzymes for metabolic reactions
1µm
Draw the Core

14. Drawing of the ultrastructure of eukaryotic cells based on electron micrographs: plasma membrane enclosing cytoplasm that contains 80S ribosomes and a nucleus, mitochondria and other membrane-bound organelles are present in the cytoplasm. Some eukaryotic cells have a cell wall.

15. 10µm
Draw the Core

16. Rough Endoplasmic Reticulum
Plasma membrane
Mitochondria
Free 80S ribosomes
Lysosomes
Cytoplasm
Nucleus
Golgi apparatus
Rough Endoplasmic Reticulum
10µm
Draw the Core

19. Rough Endoplasmic Reticulum
Plasma membrane
Controls what enters and leaves the cell
Mitochondria
Cell respiration
Free 80S ribosomes
Protein synthesis for use within the cell
Lysosomes
Contain enzymes for intracellular digestion
Cytoplasm
Solutes and enzymes for metabolic pathways
Nucleus
Contains DNA in the form of chromosomes
Golgi apparatus
Modifies and packages proteins for export from the cell. Produces vesicles for exocytosis
Rough Endoplasmic Reticulum
Attached 80S ribosomes produce proteins for export from the cell
10µm
Draw the Core

20. Structure and function of organelles within exocrine gland cells of the pancreas and within palisade mesophyll cells of the leaf.

21. Structure and function of organelles within exocrine gland cells of the pancreas and within palisade mesophyll cells of the leaf.
What is its function?

22. Structure and function of organelles within exocrine gland cells of the pancreas and within palisade mesophyll cells of the leaf.

23. Structure and function of organelles within exocrine gland cells of the pancreas and within palisade mesophyll cells of the leaf.

24. Interpretation of electron micrographs to identify organelles and deduce the function of specialized cells.

25. Red Blood Cell Small and flexible to fit through tiny tubes.
NO nucleus to make more room for
more oxygen

26. Nerve Cell
Long and branching arms to send messages quickly from any part of the body to the brain.

27. Muscle Cell Long and skinny to contract and extend for movement.
Lots of nuclei to help large cell communicate.
Lots of mitochondria because cells need lots of energy.

28. White Blood Cell
Can change shape to fit between tissues to find and fight infections.

29. Form
Function
DNA is replicated only a few pieces at time.
What DNA structure regulates the replication?
DNA has sections that signal for the beginning of a coding sequence as well as a DNA section that signals for the ending of a coding sequence. The possibility of damage to the DNA is minimized by having only small sections opened up at any time.

30. Form
Function
Hummingbirds often feed from flowers that do not have a place for them to perch.
How do hummingbirds access their food?
Hummingbirds can beat their wings fast enough to hover in midair and they have long bills and tongues which allow them to drink from the nectar of flowers.

31. Form
Function
In vertebrate organisms, the nervous system must establish an effective system of communication.
Muscle tissue responds to electrical charges which causes them to contract, resulting in movement.
Chlorophyll and other pigments needs isolation from the cytosol in order to perform its function.
What structure of nerve cells (neurons) allows for communication throughout the body?
How does skeletal muscle respond to the nervous signals to result in movement?
What organelle isolates these pigments?

32. Form
Function
The cell membrane must be flexible enough for transport, but sturdy enough to withstand the impact of external factors.
Hemoglobin is a globular protein that carries multiple oxygen molecules throughout the blood stream.
Proper cell function requires the ability to digest old organelles/metabolic wastes that take up space, waste valuable resources, and may be toxic to the cell.
Most fungi do not have a system of transport for water and food.
What component of the cell membrane provides stability?
How does the structure of hemoglobin allow it to carry oxygen?
What organelles perform this function and what specific toxin do they eliminate?
As heterotrophic organisms, how do fungi “find” their food?

33. Form
Function
Some proteins are destined to stay in the cell while others are destined to leave the cell (secretion).
ER, Golgi body and other membrane bound organelles often work together to produce a finished functional product.
Cellular respiration (specifically the electron transport chain) requires a very specific proton concentration in order to allow production of ATP.
Amoeba is a unicellular protozoan that would not survive if it were to feed only by diffusion.
Are these two types of proteins produced in loose ribosomes? Explain.
What structure connects them?
What feature of the mitochondrion allows isolation of the proton gradient?
What type of cellular transport do they use for large molecules? What features of the cell membrane permit it?

34. Form
Function
Eukaryotic cells have a small surface area to volume ratio compared to prokaryotic cells.
The evolution of plants from aquatic environments to land resulted in adaptations for vertical growth and to store water.
Some cells depend on the ability to move in order to survive.
What compensates for that? How do land plants gain stability without the buoyancy of water to keep them upright? What do they use for such movement?