Transcript Cell Notes

Cells
The Levels of Organization
2.3 – Introduction to
Biomolecules Organ Systems
Organism
Skin Cells and Stomach cells
How did cells get discovered??
1655 – was the
first to identify
cells, and he
named them.
1674- because
he made
better lenses,
Leeu observed
cells in greater
detail.
1655 – was
the first to
note that
plants are
made of cells.
1839 –
concluded
that all living
things are
made of cells.
1855 –
proposed that
all cells come
from other
cells.
• The Cell Theory has 3 principles:
– All organisms are made of cells.
– The Cell theory has three principles.
• All organisms are made of cells.
• All existing cells are produced by other living cells
– The Cell theory has three principles.
• All organisms are made of cells.
• All existing cells are produced by other living cells.
• The cell is the most basic unit of life.
All cells share certain characteristics.
• Cells tend to be microscopic.
• All cells are enclosed
by a membrane.
• All cells are filled with
cytoplasm.
cell membrane
cytoplasm
Bacterium
(colored SEM; magnification 8800x)
There are two cell types:
EUKARYOTES vs PROKARYOTES
•Eukaryotic
nucleus.
nucleus
cells have a
•Prokaryotes do not
have a nucleus.
EUKARYOTES vs PROKARYOTES
•Eukaryotic
cells
have membrane
bound organelles.
nucleus
organelles
•Prokaryotes do
not have
membrane bound
organelles.
EUKARYOTES vs PROKARYOTES
•Both
Eukaryotic and Prokaryotic cells
have cytoplasm and a cell membrane.
nucleus
organelles
cytoplasm
cell membrane
Living Things Come in All Sizes
• How does the size of a cell in a tadpole
compare to a blue whale??
– Most cells in a whale are similar in size to those in tadpoles
• What makes a whale so
Much larger than a tadpole?
– A whale has far more cells than a
tadpole or the frog it Becomes.
Organelles
• All cells have a cell membrane
– the cell membrane or plasma membrane, forms a
boundary between a cell and the outside environment.
– Controls the passage of materials into and out of cell
– Consists of a double layer of phospholipid molecules.
• Phospholipid- a phosphate group, 2 fatty acids, glycerol.
• Cell Wall ( ONLY IN PLANT CELLS!!!)
– A rigid layer that gives protection, support, and shape to
the cell
– Cell walls can adhere to one another to support an entire
organism
• Example - much of the wood in a tree trunk consists of dead cells
whose cell walls continue to support the entire tree
– Cell wall composition varies and is related to the needs of
each type of organism - tree vs algae
– Even though it is tough, it still has channels to allow water
and other molecules to cross into and out of the cells
survival.
• Cells have an internal structure.
– Cytoskeleton is a network of proteins
(fibers/tubes) that is constantly changing to meet
the needs of cells.
– The cytoskeleton has many functions.
• supports and shapes cell
• helps position and
transport organelles
• provides strength
• assists in cell division
• aids in cell movement
• Components of a Cytoskeleton:
• 2 main types of fibers/tubes that make it up.
– Microtubules
• long hollow tubes give cell its shape
• act as tracks for movement of organelles
• assist in cell division
– Microfilaments
• smallest of the 2
• tiny threads that enable cells to move & divide
• play important role in muscle cells, allow muscle to
contract & relax
• Cytoplasm:
– Clear, gelatinous fluid inside the cell
• Mostly made of cytosol
– Jelly-like material that consists mostly of water
with proteins and carbohydrates
– Organelles are found within the cytoplasm
• Several organelles are involved in making and
processing proteins.
– Nucleus
– Nuclear envelope
– Nuclear pores
– Nucleolus
– Rough Endoplasmic Reticulum
– Ribosomes
– Golgi Apparatus
– Vesicles
• Nucleus
– Control center of the cell because it holds the
genetic information or DNA
– DNA contains the genes that are instructions for
making proteins
2 Major demands on DNA
1. DNA must be carefully protected
2. DNA must be available for use at all times
Solution for these demands:
* Nuclear envelope- a double membrane that
surrounds and protects DNA, with tiny nuclear
pores that allow certain large molecules in and
out.
• Nucleolus
– Tiny dense region within nucleus
– Essential for making ribosomes
• Endoplasmic Reticulum
– A large part of most eukaryotic cells is filled by the
ER.
– Interconnected network of thin folded
membranes
– Numerous processes, including the production of
proteins and lipids, occur on both the surface and
inside the ER
– 2 types of ER:
• Rough Endoplasmic Reticulum
• Smooth Endoplasmic Reticulum
• Rough ER – its surface is dotted with
ribosomes
– Proteins are being made on ribosome and the
rough ER can modify the protein by adding sugar
chains to it which can help it fold into a shape.
• Ribosomes
– Tiny organelles that link amino
acids together to form proteins.
– Both the site of protein synthesis
and actively participates in the
process.
– Ribosomes themselves are made
up of proteins and RNA.
– After ribosomes are made in the
nucleolus, they pass through the
nuclear pores into the cytoplasm
where they can attach to the
rough ER or just float.
– 2 types of ribosomes:
• Attached ( on ER)
• Free ( floats in cytoplasm)
• Golgi Apparatus
– Closely layered stacks of membrane-enclosed
spaces that process, sort, and deliver proteins.
– Its membranes contain enzymes that make
additional changes to proteins
– Packages proteins and stored for later use
– Transports proteins to other organelles
– Transports proteins to membrane where they are
secreted outside the cell.
• Vesicles
– Small membrane-bound sacs that divide some materials
from the rest of the cytoplasm
– Transport these materials from place to place within the
cell
– Generally short-lived and are formed and recycled as
needed.
• **after proteins have been made, part of the ER pinches off to
form a vesicle surround it.
• **the protein can then be safely transported to the golgi
apparatus.
• ** After being modified in Golgi,
Vesicles form ( pinch off) to take
proteins out
of cell.
Overview of Protein Synthesis:
• Ribosomes are made in nucleolus
•Ribosomes leave through the Nuclear pores on the nuclear
membrane
•Some attach to ER, while others remain free floating
•Ribosomes begin attaching Amino Acids together to form proteins
•Proteins enter into Rough ER to be modified and folded (shaped)
into structures
Overview of Protein Synthesis:
•Vesicles form from Rough ER and carry proteins to Golgi
apparatus
•There proteins are packaged, sorted and/ or stored in Golgi
•Once the proteins are ready to leave, vesicles form to transport
proteins throughout the cell and to other cells.
• Other organelles have various functions
– Smooth Endoplasmic Reticulum
– Mitochondria
– Lysosomes
– Centriole
– Vacuole
– Chloroplasts
• Other type of ER:
• Smooth ER – its surface does not contain
ribosomes
– Makes lipids
– Breaks down drugs and alcohol (liver cells)
– Calcium storage (muscle cells)
• Mitochondria (powerhouse)
– Supplies energy to the cell
– chemical reactions take place within the inner
folds and convert molecules from the food you
eat into usable energy
– Unlike most organelles, mitochondria have
their own ribosomes and DNA. This suggests
that they were originally free-living
prokaryotes that were taken in.
– Found in cells that
are very active
(muscle cells)
• Lysosomes (garbage disposal)
– Membrane-bound organelle that contain enzymes
to break down worn-out cell parts and debris.
– They also defend a cell from invading bacteria and
viruses
– They are numerous in animal cells and their
presence is still questioned by scientists in plant
cells.
• Centriole
– Are cylinder-shaped organelles made of short
microtubules arranged in a circle.
– Located in a small region in the cytoplasm called
the centrosome that produces these microtubules.
– Both Plant and Animal cells have a centrosome
region, but only Animal cells form centrioles.
– Help divide DNA during cell
division
– Help form cilia (little hairs)
and flagella (whip/tail) for
cells.
• Vacuole
– A fluid-filled sac used for storage of materials
needed by a cell.
– These materials include water, food molecules,
inorganic ions and enzymes
– Most animal cells contain small vacuoles
– All plant cells have a large central vacuole that
strengthens the cell and helps to support the
entire plant.
• When a plant wilts, its leaves shrivel because there is
not enough water in the vacuole to support its
normal structure
• A plants vacuole may also contain substance that are
toxic to harm predators, waste products, and
pigments that give color to cells – such as those in
the petals of flowers.
Milkweed
• Chloroplasts
– Organelles that carry out photosynthesis
– Like mitochondria, they have their own ribosomes
and DNA so scientist believe they too were taken
in by larger cells
– ONLY IN PLANT CELLS!!!
Nuclear Pores
Nucleolus
Lysosome Cytoskeleton
Nucleus
Centriole
Centrosome
Golgi
Appratus
Vesicle
Small
Vacuole
Rough ER
Cytoplasm
Mitochondria
Smooth ER
Cell
Membrane
Ribosome (attached)
Chloroplast
Cytoskeleton
Vesicle
Vacuole
Cell Wall
Nuclear Pores
Nucleus
Centrosome
Nucleolus
Rough ER
Ribosomes
Mitochondria
Golgi
Appratus
Smooth ER
Cell
Membrane
Venn Diagrams
Prokaryotes
Eukaryotes
No Nucleus
Genetic
material not in
nucleus
No membrane
bound
organelles
Cell membrane
Ribosomes
Genetic Material
Cytoplasm
Nucleus
ER
Golgi apparatus
Vesicles
Lysosomes (animal)
Vacuoles
Mitochondria
Cytoskeleton
Chloroplast (plant)
Venn Diagrams
Plant Cells
Animal Cells
Lysosomes
centrioles
Cell membrane
Ribosomes
Nucleus
Nucleolus
ER
Vesicle
Golgi apparatus
Vacuoles
Mitochondria
Cytoskeleton
Cytoplasm
centrosome
Cell Wall
Chloroplasts