• Folded membrane that forms compartments where newly synthesized proteins are processed (cut, joined, folded into their final shape)

• Ribosomes bind to rough ER when they start to synthesize proteins that are intended to be exported from the cell – the proteins enter the ER directly from the ribosome

Components found only in Eukaryotic Cells

Rough Endoplasmic Reticulum (ER)

• Synthesis of lipids and steroids

• Metabolism of carbohydrates and steroids

• Regulation of calcium concentration

• Drug/toxin detoxification

• Attachment of receptors on cell membrane

Components found only in Eukaryotic Cells

Smooth Endoplasmic Reticulum (ER)

• Folded membranes form compartments that each contain different enzymes which selectively modify the contents depending on where they are destined to end up

• Processes and packages macromolecules produced by the cell (e.g. proteins and lipids) – sent out as excretory vesicles “labeled” for their destination

Components found only in Eukaryotic Cells

Golgi Apparatus

• Network of long protein fibers (microtubules, actin filaments, and intermediate filaments)

• Helps support cell shape and movement

• transport organelles and vesicles throughout the cytoplasm to other areas within the cell

The cytoskeleton is stained green in this image (the nucleus is stained blue and the cell membrane is stained red)

Components found only in Eukaryotic Cells

Cytoskeleton

Store nutrients such as starch, glycogen, or fat Take up most of space in many plant cells, full of water

Components found only in Eukaryotic Cells

Vacuoles

Peroxisomes

Lysosomes

Membranous Sacs

In animal cells – full of enzymes that oxidize amino acids In plant cells – full of enzymes that oxidize fat In plant and animal cells – convert hydrogen peroxide to water

Contain digestive enzymes Fuse with vesicles and vacuoles containing food, cell refuse, captured

bacteria, etc

Carry products of protein synthesis to parts of the cell or to membrane to be excreted via exocytosis

Excretory Vesicles

• Form centrosome and initiate formation of the mitotic spindle during cellular replication

• Found in animal cells and some plant cells – not in higher plants or fungi

• Composed of microtubules (like those in the cytoskeleton)

Components found only in Eukaryotic Cells

Centrioles

• Brakes down glucose (sugar) using oxygen to produce energy for the cell = cellular respiration

• Many cells have only a single mitochondrion, whereas others can contain several thousand

• Have own DNA and ribosomes

Components found only in Eukaryotic Cells

Mitochondrion (plural – Mitochondria)

• Use light energy to convert atoms in water and CO2 (from air) into sugars and starches

• Have double membrane (inner and outer)

• Have own DNA and ribosomes

• Grana (stacks of thylakoids) – where light energy is captured by chlorophyll and converted into chemical energy = photosynthesis

• Stroma – fluid inside chloroplasts

• Chlorophyll – light-absorbing pigment in thylakoids

Photosynthetic OrganellesChloroplasts (plant cells and photosynthetic protists)

Endosymbiotic Theory• Concept that mitochondria and chloroplasts are the result of years of

evolution initiated by the endocytosis of bacteria and blue-green algae which, instead of becoming digested, became symbiotic

Endosymbiotic Theory• Concept that mitochondria and chloroplasts are the result of years of

evolution initiated by the endocytosis of bacteria and blue-green algae which, instead of becoming digested, became symbiotic Have their own DNA which resembles bacterial DNA Have their own 70s ribosomes and produce their own proteins Double membrane indicates they entered cell via endocytosis Membrane composition strongly resembles Gram-negative bacteria Divide within eukaryotic cell via binary fission (the way of bacteria) Similar symbiotic relationships exist between organisms that are still

distinct species from one another

• Some evidence indicates that eukaryotic flagella and cilia may have originated as symbiotic bacteria as well

Evolution of Eukaryotes

Some protists lack mitonchondria which indicates that the eukaryote lineage evolved before the ancestral bacterial of mitochondria established a symbiotic relationship with early protists

Cell Walls• Tough, rigid wall around cell membrane

Most prokaryotes Eukaryotes: plants, algae and fungi only

• Functions: Prevents over-expansion when water

enters the cell via osmosis Structural support

(otherwise cells would be spherical) Protection

• Composed of cellulose and/or chitin in eukaryotes (only plant and fungi cells

have cell walls in eukaryotes)

Cell Walls

• Flagella Creates movement in prokaryotes by rotating like a propeller Whip-like movement in eukaryotes Larger and more complex in eukaryotes

- common in protozoa, found in some algae- only spermatozoa cells in humans

Positive chemotaxis – cell moves up concentration gradient Negative chemotaxis – cell moves down concentration gradient Phototaxis – cell moves towards (positive)

or away from (negative) light

Other External Structures

• Cilia (eukaryotes only) Numerous on surface of cell Beat in a coordinated pattern creating

a wave of movement Mostly occur in protozoa, but some

human cells too (like those lining the respiratory tract)

• Pili (prokaryotes only)

also known as fimbria

Hair-like appendage on bacteria thathelp the bacteria connect to other cells in order to exchange plasmids (DNA)

Other External Structures