A Tour of the Cell Chapter 6.

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A Tour of the Cell Chapter 6

You Must Know Three differences between prokaryotic and eukaryotic cells. The structure and function of organelles common to plant and animal cells. The structure and function of organelles found only in plant cells or only in animal cells.

How We Study Cells Biologists use microscopes and the tools of biochemistry to study cells

Size range of cells Note that light microscopes can not magnify as well as electron microscopes

Light Microscopy (LM) vs. Electron Microscopy (EM)

Comparisons of Scopes Light Electron Visible light passes through specimen Refracts light so specimen is magnified Magnify up to 1000X Specimen can be alive/moving Color Focuses a beam of electrons through/onto specimen Magnify up to 1,000,000 times Specimen non-living and in vacuum Black and white

Electron Microscopy Transmission (TEM) Scanning (SEM) 2-D 4/21/2017 Electron Microscopy Transmission (TEM) Scanning (SEM) 2-D Creates a flat image with extreme detail Can enhance contrast by staining atoms with heavy metal dyes 3-D Used for detailed study of surface of specimen Gives great field of depth

Studying cell structure & function Cell fractionation - take apart cells, separate major organelles Ultracentrifuge - applies force 1 million times the force of gravity to separate further the cell organelles with the most dense at the bottom

2 Types of Cells: Prokaryotes: Domain Bacteria & Archaea Eukaryotes (Domain Eukarya): Protists, Fungi, Plants, Animals

A Prokaryotic Cell (bacteria)

Prokaryote Vs. Eukaryote “before” “kernel” No nucleus DNA in a nucleoid Cytosol No organelles other than ribosomes Small size Primitive i.e. Bacteria & Archaea “true” “kernel” Has nucleus and nuclear envelope Cytosol Membrane-bound organelles with specialized structure/function Much larger in size More complex i.e. plant/animal cell

Cells must be small to maintain a large surface area to volume ratio Large S.A. allows  rates of chemical exchange between cell and environment

Surface Area Example (Animal): Small Intestine: highly folded surface to increase absorption of nutrients Villi: finger-like projections on SI wall Microvilli: projections on each cell

Folds  Villi  Microvilli

Surface Area Example (Plant): Root hairs: extensions of root epidermal cells; increase surface area for absorbing water and minerals

Nucleus Continuous with the rough ER Function: control center of cell Contains DNA Surrounded by double membrane (nuclear envelope) Continuous with the rough ER Nuclear pores: control what enters/leaves nucleus Chromatin: complex of DNA + proteins; makes up chromosomes Nucleolus: region where ribosomal subunits are formed

Nucleus Continuous with the rough ER Contains DNA Function: control center of cell Surrounded by double membrane (nuclear envelope) Continuous with the rough ER Nuclear pores: control what enters/leaves nucleus Chromatin: complex of DNA + proteins; makes up chromosomes Nucleolus: region where ribosomal subunits are formed

Ribosomes Function: protein synthesis Composed of rRNA + protein Large subunit + small subunit Types: Free ribosomes: float in cytosol, produce proteins used within cell Bound ribosomes: attached to ER, make proteins for export from cell

Regulates protein traffic & performs metabolic functions Endomembrane System:

Endoplasmic Reticulum (ER) Network of membranes and sacs Types: Rough ER: ribosomes on surface Function: package proteins for secretion, send transport vesicles to Golgi, make replacement membrane Smooth ER: no ribosomes on surface Function: synthesize lipids, metabolize carbs, detox drugs & poisons, store Ca2+

Endoplasmic Reticulum (ER)

Golgi Apparatus Cis face: receives vesicles Trans face: ships vesicles Function: synthesis & packaging of materials (small molecules) for transport (in vesicles); produce lysosomes Series of flattened membrane sacs (cisternae) Cis face: receives vesicles Trans face: ships vesicles

Lysosomes Function: intracellular digestion; recycle cell’s materials; programmed cell death (apoptosis) Contains hydrolytic enzymes

Vacuoles Function: storage of materials (food, water, minerals, pigments, poisons) Membrane-bound vesicles Eg. food vacuoles, contractile vacuoles Plants: large central vacuole -- stores water, ions

Parts of plant & animal cell p 108-109

Mitochondria Function: site of cellular respiration Double membrane: outer and inner membrane Cristae: folds of inner membrane; contains enzymes for ATP production; increased surface area to  ATP made Matrix: fluid-filled inner compartment

Chloroplasts Function: site of photosynthesis Double membrane Thylakoid disks in stacks (grana); stroma (fluid) Contains chlorophylls (pigments) for capturing sunlight energy

Endosymbiont theory Double-membrane structure Have own ribosomes & DNA Mitochondria & chloroplasts share similar origin Prokaryotic cells engulfed by ancestors of eukaryotic cells Evidence: Double-membrane structure Have own ribosomes & DNA Reproduce independently within cell

Peroxisomes Functions: break down fatty acids; detox alcohol Involves production of hydrogen peroxide (H2O2)

Cytoskeleton: network of protein fibers Function: support, motility, regulate biochemical activities

3 Types of Cytoskeleton Fibers: Microtubules Microfilaments Intermediate Filaments Protein = tubulin Largest fibers Shape/support cell Track for organelle movement Forms spindle for mitosis/meiosis Component of cilia/flagella Protein = actin Smallest fibers Support cell on smaller scale Cell movement Eg. ameboid movement, cytoplasmic streaming, muscle cell contraction Intermediate size Permanent fixtures Maintain shape of cell Fix position of organelles

Also called microtubule organizing center Centrosomes: region from which microtubules grow Also called microtubule organizing center Animal cells contain centrioles

Cilia & Flagella Flagella: long and few; propel through water Cilia: short and numerous; locomotion or move fluids Have “9+2 pattern” of microtubules

Extracellular Matrix (ECM) Outside plasma membrane Composed of glycoproteins (ex. collagen) Function: Strengthens tissues and transmits external signals to cell

Intercellular Junctions (Animal cells) Tight junctions: 2 cells are fused to form watertight seal Desmosomes: “rivets” that fasten cells into strong sheets Gap junctions: channels through which ions, sugar, small molecules can pass

Plant Cells Composed of cellulose Cell wall: protect plant, maintain shape Composed of cellulose Plasmodesmata: channels between cells to allow passage of molecules