Cell Structure and Function
Pattern #3: Life Needs an Inside and
an Outside
How Small is SmallUnit Outline
• Background• Cell Theory• Prokaryotes vs.
Eukaryotes• Surface Area vs.
Volume• Form vs. Function• Cell Membrane• Cytoplasma• Nucleus
• Endoplasmic Reticulum
• Ribosomes• Golgi Apparatus• Lysosomes• Vacuoles• Mitochondria• Cytoskeleton• Endosymbiosis
First Glimpse of The Cell
• 1665 – Robert Hooke– One of the first microscopists–wrote
Micrographia– Thin slices of cork, completely enclosed
“cells”
• 1677 – Anton Van Leeuwenhoek– First to view living cells – animalcules– Discovered bacteria in the human
mouth
Birth of Cell Theory
• 1831 – Robert Brown– Discovered nucleus in plant cells
• 1838 - Matthias Schleiden– All plants are composed of cells
• 1839 – Theodor Schwann– All animals and tissues are composed
of cells• 1855 – Robert Remak and Rudolf
Virchow– Cells come from other living cells
Cell Theory
1) All organisms are composed of one or more cells.
2) Cells are the smallest living things, the basic units of organization for all organisms.
3) Cells arise only by the division of a previously existing cell.
Prokaryotic Cells
• No true nucleus• Still carry out all life functions• Bacteria, cyanobacteria• Cell membrane and
sometimes cell wall• Few/no organelles
(ribosomes)• Movement by flagella
Eukaryotic Cell
• True nucleus• Membrane bound
organelles• Compartmentalizaiton
Limits to Cell Size
• Communication• Diffusion/Transportation• Surface Area to Volume ratio
– Smaller cells have more surface area per unit volume
– Larger cells must import/export more materials through the cell membrane
– Volume increases at a cubic rate, surface area at a squared rate
The Bigger They Come The Harder to They are
to MaintainCell
Radius
(mm)
Surface
Area(mm2)
Volume
(mm3)
S.A.:Vol
1 6 1 6:1
2 24 8 3:1
3 54 27 2:1
5 150 125 1.2:1
Cell Radiu
s(mm)
Surface
Area(mm2)
Volume
(mm3)
S.A.:Vol
1 12.56 4.18 3:1
2 50.24 33.49 1.5:1
3 113 113 1:1
5 314 523 0.6:1
Cubic Cell
Spherical Cell
Some cells are much larger than others. Given the constraints imposed by the S.A. to volume ratio, how would you expect the level of activity in large cells to compare with that in small cells?
Form Follows Function
• Nerve cells are long and skinny to transmit messages
• Red Blood Cells are close to spherical to maximize S.A. to volume
• Skin cells fit together tightly
Just How Small Are We Talking?
•Micrometer or micron - m•Nanometer – nm•Angstrom – Å•1 Å = 0.1 nm = 10-4 m = 10-8
cm•Most cells < 50 m
Plasma MembraneConsistent from Bacteria to
Mammals
1) Forms a protective outer barrier for the cell
2) Helps maintain a constant internal environment
3) Regulates exchange of substances in and out of the cell
Fluid-Mosaic Model
1972 – Singer and Nicolson
The membrane is made of a phospholipid bilayer that is viscous and free to move. Globular proteins are embedded in the bilayer and move about as well. The Hydrophobic ends of the lipids create a non-polar region within the membrane. This region impedes the passage of all water soluble molecules. Hydrophilic heads exist at the inner and outer surfaces and allow specific chemical interactions to take place.
Membrane Structure
• Lipid bilayer• Transmembrane proteins• Network of supporting fibers
– Shape and structure– scaffolding
• Exterior proteins and glycolipids– “sugar coating” acts as cell identity
markers– Glycoproteins – self recognition– Glycolipids – tissue recognition
CytoplasmThe material within a cell
excluding the nucleus
The cytoplasm of most eukaryotic cells is filled with membranous structures that extend to every nook and cranny of the cell’s interior.
While the membranes of the cytoplasm have the same basic structure, the particular proteins embedded in the lipid bilayer vary and give specialized functions.
The membranes of the cytoplasm form a highly interdependent network within the cell.
The NucleusRoger, Headquarters
• Genetic headquarters• Largest and most easily seen organelle• Repository of genetic information• Discovered by Robert Brown – 1831• Fungi and other groups may have >1
nucleus• Mammalian erythrocytes (RBC) lose
nucleus when mature
Nuclear Structure• Nuclear envelope
– Two phospholipid bilayers– Nuclear pores
• Membranes pinch together, filled w/ proteins that restrict movement
• Proteins moving into the nucleus• RNA and RNA complexes to be exported into the
cytoplasm
• Nucleolus– Site of intensive rRNA synthesis
• Nucleoli– Tiny granules that are precursors to ribosomes
• Nucleoplasm– Semifluid area that organizes the contents and
provides sites of attachment for enzymes in DNA duplication
Nuclear Shots
Liver Cell NucleusNucleus Diagram
Nuclear PoreNucleus with Pores
ChromosomesPackaging DNA
• Stored as thin strands (chromatin) except for cell division– Allows access to genetic information
• During cell division DNA coils around histones in a condensed forms called chromosomes– After cell division chromosomes
uncoil and can’t be seen with a light microscope
Endoplasmic ReticulumER every night of the week
• Located within the cytoplasm – little net• Highway of the cell
– System of passageways that allow materials to be channeled to different locations within the cell
• Cell is organized by endomembrane system• ER – lipid bilayer with embedded proteins• Site of membrane phospholipid synthesis• Highly developed in pancreas and salivary
glandsRough ER
Smooth ER
Rough or Smooth – It’s All ER?
• Rough ER– Studded with ribosomes– Site of protein synthesis and segregation– Proteins can be used within the cell or
exported outside of the cell
• Smooth ER– Found in lesser quantities– May be responsible for synthesis of
steroids– Break down lipids and toxins in the liver
Golgi Apparatus (Bodies)
Delivery System of the Cell• Discovered in 1898 by Camillo Golgi
• Flattened stacks of membranes thought to form from vesicles produced by the RER
• Abundant in glandular cells – secretions• Collection, packaging, and distribution • Proteins from ER are modified
– Short sugar chains are added (glycoproteins and glycolipids)
• Two distinct sides– “cis” end accepts protein packages from ER– “trans” end secretes membrane bound vesicles
to be expelled from the cell (exocytosis)
Cis
Trans
exocytosis
Cisternae
Ribosomes
• Site of protein synthesis• They are not membrane bound
– Eukaryotic ribosomes slightly larger than prokaryotic
• Consists of small and larger subunits– rRNA and about 50 structural proteins
• Cluster on the ER to make protein for export– Free ribosomes make proteins for use within
the cell• Functional only when attached to mRNA in
the cytoplasm• Ribosomal subunits are manufactured in
the nucleolus
Lysosomes and Vesicles• Vesicles transport materials in and out of the
cell– Exocytosis– Endocytosis – phago- (solid) and pino- (liquid)
• Lysosomes – membrane bound digestive vesicles that arise from the golgi bodies
• Lysosomes contain a concentrated mix of digestive enzymes– Catalyze breakdown of protein, NA’s, lipids, carbo’s– Recycle old organelles – mitochondria replaced
every 10 days
• Lysosomes in metabolically inactive eukaryotic cells dissolve cells from the inside out
Vacuoles• Large fluid containing sacs• In plants they may occupy more than 90
percent of the cell’s volume• Bounded by a single membrane• In addition to water the vacuole may
contain gases (O2, N2, and/or CO2), acids, salts, sugars, pigments
• In plants the vacuole keeps toxins separate from the rest of the cell and maintain internal pressure which aids in the support of the plant
MitochondriaPowerhouse of the Cell
• Site of aerobic respiration• Energy released and ATP produced• Inner membrane (cristae) houses the
electron transport system• Mitochondria have their own DNA (mDNA)• Cells do not produce new mitochondria
during cell division– Mitochondria divide and partition
between new cells
Mitochondria(continued)
• Could have been a bacteria-like organism incorporated into another cell 1.5 bya
• Mitochondria are particularly numerous in muscle cells
• All mitochondria of offspring is maternal– Mitochondria of sperm remain
outside fertilized egg– mDNA is inherited maternally
How can maternal mitochondria be useful to scientists?
Mitochondria Structure
Electron Microscope View
CentriolesMicrotubule Assembly
Centers
• Centrioles – help to assemble microtubules• Some centrioles contain DNA which helps
control synthesis of structural proteins• Help assemble spindle fibers which move
and align chromosomes during cell divison
Cytoskeleton• Three main types of components
1) Microtubules – composed of the protein tubulin
2) Microfilaments – contractile protein actin3) Intermediate filaments – variety of
proteins
• Interconnected to form an elaborate network
• Carry out many functions for the cell1) Maintain cell shape2) Anchor organelles within the cytoplasm3) Help in cell movement4) Help to organize the internal contents of
the cell
Cytoskeleton Fibers• Actin filaments
– About 7 nm in diameter– 2 protein chains loosely twined together– Contraction, “pinching”, and cellular
extension
• Microtubules– About 25 nm in diameter– A ring of 13 protein protofilaments– Cell movement, transport of materials witin
the cell
• Intermediate filaments– About 8-10 nm in diameter– The most durable element of the cytoskeleton– Structural stability
Cell Movement
• Cell motion is tied to the movement of actin filaments, microtubules or both
• Actin filaments can form and dissolve very rapidly allowing cells to change shape quickly
• In cells treated with drugs that make microfilaments dissolve all cell locomotion stops
Some Crawl, Some Swim
• Some cells use a pseudopod (false foot)– Cytoplasmic oozing forces a “foot” out in a
certain direction, the cell then drags itself
• Some cells use cilia or flagella to swim– Whip-like flagella and shorter cilia both
have a 9 + 2 structure of microtubules in eukaryotes
– The beating or turning of these structures propels the cell
Endosymbiosis
• Proposes that today’s eukaryotic cells evolved by a symbiosis in which one species of prokaryote was engulfed by and lived inside another species of prokaryote
• Mitochondria and chloroplasts are thought to be two prime examples of this theory– Double membranes– Both contain circular DNA similar to
bacteria– Mitochondria divide by simple fission
Sources
Brum, Gilbert D., L. McKane, and G. Karp. 1994. Biology: Exploring Life, 2d ed. New York: Wiley.
Raven, Peter H. and G.B. Johnson. 1999. Biology, 5th ed. New York: McGraw-Hill.
http://cellsalive.com/
http://gened.emc.maricopa.edu/bio/bio181/BIOBK/BioBookTOC.html
http://www.pbrc.hawaii.edu/~kunkel/gallery
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