1. Cell Structure and Function
Chapter 4
Cell Structure and Function

2. 4.1 What Features Are Shared By All Cells?
Cells are the smallest unit of life.
Cells are enclosed by a plasma membrane.
Cells use DNA as a hereditary blueprint.
Cells contain cytoplasm, which is all the material inside the plasma membrane and outside the DNA-containing region.
Cells obtain energy and nutrients from their environment.

3. 4.1 What Features Are Shared By All Cells?

4. 4.1 What Features Are Shared By All Cells?
Diameter
Relative sizes
100 m
tallest trees
10 m
adult human
1 m
visible with unaided
human eye
10 cm
chicken egg
1 cm
1 mm
frog embryo
100 m
light microscope
visible with
most eukaryotic cells
10 m
mitochondrion
1 m
most bacteria
visible with conventional
electron microscope
100 nm
virus
10 nm
Units of measurement:
special electron
visible with
microscopes
proteins
1 meter (m) = inches
diameter of DNA double helix
1 centimeter (cm) = 1/100 m
1 nm
1 millimeter (mm) = 1/1,000 m
1 micrometer (mm) = 1/1,000,000 m
atoms
1 nanometer (nm) = 1/1,000,000,000 m
0.1 nm
Fig. 4-1

5. 4.1 What Features Are Shared By All Cells?
Cell function limits cell size.
Diffusion of molecules across cell membranes limits the diameter of cells.
As cells get bigger, their nutrient and waste elimination needs grow faster than the membrane area to accommodate them.

6. 4.1 What Features Are Shared By All Cells?
The volume of cytoplasm grows faster than the plasma membrane area.
Fig. 4-2

7. 4.2 How Do Prokaryotic And Eukaryotic Cells Differ?
There are two kinds of cells.
Prokaryotic cells
Are found only in two groups of single-celled organisms—the bacteria and archaea
Eukaryotic cells
Are structurally more complex cells
Possess a membrane-enclosed nucleus
Probably arose from prokaryotic cells

8. 4.2 How Do Prokaryotic And Eukaryotic Cells Differ?
PLAY
Animation—Cell Structure

9. 4.3 What Are The Main Features Of Eukaryotic Cells?
Eukaryotic cells differ from prokaryotic cells because the former possess a number of membrane-enclosed organelles that perform specific cell functions.
Nucleus: contains DNA
Mitochondria: produce energy
Endoplasmic reticulum: synthesizes membrane components and lipids
Golgi apparatus: molecule sorting center
Lysosomes: digest cellular membranes or defective organelles
Microtubules: make up the cytoskeleton

10. 4.3 What Are The Main Features Of Eukaryotic Cells?
A generalized animal cell
nuclear pore
chromatin (DNA)
nucleus
nucleolus
nuclear envelope
flagellum
centriole
intermediate
filaments
cytoplasm
plasma
membrane
rough endoplasmic
reticulum
ribosome
lysosome
Golgi
apparatus
microtubules
vesicle
free ribosome
smooth
endoplasmic
reticulum
vesicle
mitochondrion
Fig. 4-3

11. Suggested Media Enhancement: Tour of an Animal Cell
To access this animation go to folder C_Animations_and_Video_Files and open the BioFlix folder.

12. 4.3 What Are The Main Features Of Eukaryotic Cells?
A generalized plant cell
microtubules
(part of cytoskeleton)
mitochondrion
chloroplast
central
vacuole
Golgi
apparatus
plasmodesma
smooth
endoplasmic
reticulum
vesicle
rough
endoplasmic
reticulum
cell wall
plasma
membrane
nucleolus
nuclear pore
chromatin
nuclear
envelope
intermediate
filaments
nucleus
ribosomes
free ribosome
Fig. 4-4

13. Suggested Media Enhancement: Tour of a Plant Cell
To access this animation go to folder C_Animations_and_Video_Files and open the BioFlix folder.

14. 4.4 What Role Does The Nucleus Play?
The nucleus is the largest organelle in the cell.
It is bounded by a nuclear envelope.
It contains granular-looking chromatin.
It contains the nucleolus.

15. 4.4 What Role Does The Nucleus Play?
nuclear
envelope
nucleolus
nuclear
pores
nucleus
nuclear
pores
chromatin
(a) Structure of the nucleus
(b) Yeast cell
Fig. 4-5

16. 4.4 What Role Does The Nucleus Play?
The nuclear envelope is a double membrane.
The membrane is perforated with channels called nuclear pores.
Some smaller materials can move through the pores, while others, such as DNA, are excluded.

17. 4.4 What Role Does The Nucleus Play?
The nucleus contains chromosomes.
DNA and protein are closely associated in the nucleus in chromatin.
Chromatin can become condensed into chromosomes.
chromatin
chromosome
Fig. 4-6

18. 4.4 What Role Does The Nucleus Play?
Ribosomes are composed of RNA and proteins, and serve as a “workbench” for the manufacture of proteins.

19. 4.4 What Role Does The Nucleus Play?
Ribosome components are made at the nucleolus.
A darkly staining region in the nucleus is called a nucleolus.
The nucleolus contains DNA, RNA, proteins, and ribosomes in various stages of construction.
This is the site where components of ribosomes are constructed.
Ribosome components leave the nucleus and are assembled in the cytoplasm.

20. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
The plasma membrane isolates the cell, and alternately, helps it interact with its environment.
The phospholipid bilayer contains globular proteins that regulate the transport of molecules into and out of the cell.
Plant cells also have a rigid structure outside the plasma membrane, called a cell wall, which forms a protective coating.

21. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
The endoplasmic reticulum (ER) forms channels within the cytoplasm.
There are two kinds of ER membranes:
Rough endoplasmic reticulum: is studded with ribosomes
Smooth endoplasmic reticulum: has no ribosomes

22. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
The endoplasmic reticulum
ribosomes
smooth ER
smooth ER
rough ER
rough ER
vesicles
(a)
Endoplasmic reticulum may be rough or smooth
(b)
Smooth and rough ER
Fig. 4-7

23. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
The rough ER is the site where proteins are made.
The smooth ER makes phospholipids and cholesterol.
Together, the rough and smooth ER are the sites of new membrane synthesis for the cell.

24. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
The Golgi apparatus sorts, chemically alters, and packages important molecules.
This organelle looks like a stack of flattened sacs.
Its membranes are derived from the ER.
Vesicles containing preformed molecules from the ER are transferred to the Golgi for further processing.

25. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
The Golgi apparatus
Protein-carrying
vesicles from the
ER merge with the
Golgi apparatus
Golgi
apparatus
Vesicles carrying
modified proteins
leave the Golgi
apparatus
Fig. 4-8

26. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
Once the molecular work of the Golgi has been done, new vesicles bud off and travel elsewhere in the cytoplasm, where they fuse with membranes of other organelles, such as the plasma membrane.
A major role of the Golgi is to add sugar molecules to proteins formed in the ER and to pass them on to other places in the cell.

27. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
We can follow the travels of a secreted protein.
An antibody protein is synthesized on ribosomes of the rough ER.
Formed antibody is packaged into vesicles that travel to the Golgi, where carbohydrates are attached to protein to make an antibody.

28. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
We can follow the travels of a secreted protein (continued).
The vesicle containing antibody leaves the Golgi and goes to the plasma membrane, where it fuses with it.
The antibody inside the vesicle is released to the outside of the cell (to the blood), where it helps defend the body against infection.

29. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
Animation—Membrane Traffic

30. 4.5 What Roles Do Membranes Play In Eukaryotic Cells?
Lysosomes are vesicles that serve as the cell’s digestive system.
They are formed as buds from the Golgi.
Lysosomes contain digestive enzymes that they receive from Golgi during their production.
In the cytoplasm, they digest defective organelles or pieces of membrane into component parts that can be recycled.

31. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
Vacuoles regulate water and store substances.
They are fluid-filled sacs surrounded by a single membrane.
Many plant cells have a large central vacuole.
Vacuoles hold water and help maintain the proper water balance of the cell.
Vacuoles can also serve as dump sites for hazardous waste that can’t be excreted.
They can also store sugars and amino acids, which can be used for energy.

32. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
Mitochondria extract energy from food molecules.
Mitochondria provide the energy needed for all cellular processes.
Energy is obtained from sugar molecules in mitochondria and is stored in ATP molecules.
Once formed, ATP can be used anywhere in the cell where energy is needed.
Mitochondria have a complex set of outer and inner membranes, and both sets are used in the process of energy production.

33. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
Chloroplasts capture solar energy.
Only plant cells contain chloroplasts.
Chloroplasts capture energy from sunlight and store it in sugar molecules.
They are the site of photosynthesis, the process upon which all life depends.
Like mitochondria, chloroplasts contain both outer and inner membranes.

34. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
The cytoskeleton provides shape, support, and movement.
All organelles in the cell do not float about the cytoplasm, but instead, are attached to a network of protein fibers called the cytoskeleton.

35. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
Several type of protein fibers make up the cytoskeleton.
Microfilaments: thin fibers
Intermediate filaments: medium-sized fibers
Microtubules: thick fibers

36. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
The cytoskeleton
plasma
membrane
microfilaments
microtubules (red)
mitochondrion
intermediate
filaments
ribosomes
endoplasmic
reticulum
nucleus
microtubule
vesicle
microfilaments (blue)
(a) Components of the cytoskeleton
(b) Cell with stained cytoskeleton
Fig. 4-9

37. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
Cilia and flagella move the cell or move fluid past the cell.
Cilia and flagella are slender, movable extensions of the plasma membrane.
They contain microtubules that extend along their length.
They may be used to move small animals or particle-containing fluids past a surface.

38. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
Cilia and flagella move the cell or move fluid past the cell (continued).
Differences between cilia and flagella lie in their length, number, and the direction of force generated.
Cilia are shorter and more numerous than flagella.

39. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
Cilia provide force parallel to the plasma membrane, which can be described as a “rowing” motion.
propulsion of fluid
power stroke
return stroke
plasma membrane
cilia lining
the trachea
(a) Cilium
Fig. 4-10a

40. 4.6 What Other Structures Play Key Roles In Eurkaryotic Cells?
Flagella provide a force perpendicular to plasma membrane, like the engine on a motorboat.
direction of locomotion
propulsion of fluid
continuous propulsion
flagellum
of human
sperm
(b) Flagellum
Fig. 4-10b

41. 4.7 What Are The Features Of Prokaryotic Cells?
Prokaryotic cells are much smaller than eukaryotic cells, are more abundant, and are very reproductively successful.
The are very small and have a simple internal structure.
They are surrounded by a stiff cell wall, which provides shape and protection.
Some move with a whiplike flagellum.

42. 4.7 What Are The Features Of Prokaryotic Cells?
A single, circular strand of DNA is attached to the plasma membrane and is concentrated in an area called the nucleoid, which lacks a membrane.
There are no membrane-enclosed organelles.
The cytoplasm contains ribosomes used for protein synthesis.

43. 4.7 What Are The Features Of Prokaryotic Cells?
A generalized prokaryotic cell
chromosome
(nucleoid region)
ribosomes
food granule
prokaryotic
flagellum
cell wall
plasma membrane
cytoplasm
Fig. 4-11