Cell Biology Overview II. Membranes – How Things Get in and Out of Cells A. Membrane Structure

Cell Biology • Overview • II. Membranes – How Things Get in and Out of Cells • A. Membrane Structure • 1. phospholipids POLAR END (react with water) NON-POLAR END (hyrophobic)

Cell Biology • Overview • II. Membranes – How Things Get in and Out of Cells • A. Membrane Structure • 2. proteins and carbohydrates

Cell Biology • Overview • II. Membranes – How Things Get in and Out of Cells • A. Membrane Structure • B. Membrane Function • 1. semi-permeable barrier Aqueous Solution (outside cell) dissolved ions dissolved polar molecules suspended non-polar (lipid soluble) Aqueous Solution (inside cell) dissolved ions dissolved polar molecules suspended non-polar (lipid soluble)

Cell Biology • Overview • II. Membranes – How Things Get in and Out of Cells • A. Membrane Structure • B. Membrane Function • 1. semi-permeable barrier • 2. transport Net diffusion Net diffusion equilibrium

Cell Biology • Overview • II. Membranes – How Things Get in and Out of Cells • A. Membrane Structure • B. Membrane Function • 1. semi-permeable barrier • 2. transport – facilitated diffusion

Cell Biology • Overview • II. Membranes – How Things Get in and Out of Cells • A. Membrane Structure • B. Membrane Function • 1. semi-permeable barrier • 2. transport - osmosis

Cell Biology • Overview • II. Membranes – How Things Get in and Out of Cells • A. Membrane Structure • B. Membrane Function • 1. semi-permeable barrier • 2. transport – active transport

Cell Biology • Overview • II. Membranes – How Things Get in and Out of Cells • A. Membrane Structure • B. Membrane Function • 1. semi-permeable barrier • 2. transport • 3. metabolism (enzymes nested in membrane) • 4. signal transduction

Cell Biology • Overview • II. Membranes – How Things Get in and Out of Cells • A. Membrane Structure • B. Membrane Function • 1. semi-permeable barrier • 2. transport • 3. metabolism (enzymes nested in membrane) • 4. signal transduction • 5. cell-cell binding • 6. cell recognition • 7. cytoskeleton attachment

Cellular Respiration

III. Cellular Respiration Overview: Proteins, Carbohydrates, Fats, Nucleic Acids Organic Molecules: C—C—C—C Break C—C bonds release E Some trapped in bonds between ADP + P ATP NAD + H+ NADH Some E lost (heat) C C C C (These are CO2 molecules)

III. Cellular Respiration Overview: Proteins, Carbohydrates, Fats, Nucleic Acids Organic Molecules: C—C—C—C Break C—C bonds release E Some trapped in bonds between ADP + P ATP NAD + H+ NADH Some E lost (heat) C C C C (These are CO2 molecules) Break NADH ADP + P Make ATP NAD, H+

III. Cellular Respiration Overview: Focus on core process… Glucose metabolism GLYCOLYSIS

III. Cellular Respiration Overview: 1. Glycolysis: - All cells do this! (very primitive pathway) - Occurs in the cytoplasm of all cells - Occurs in presence OR absence of oxygen gas. Glucose C6H12O6 2 pyruvate 2 C3

III. Cellular Respiration Overview: 1. Glycolysis: - Energy in 2 ATP is used to ‘activate’/start reaction 2 ATP 2 ADP + P Glucose C6H12O6 2 pyruvate 2 C3

III. Cellular Respiration Overview: 1. Glycolysis: - Energy in 2 ATP is used to ‘activate’/start reaction - breaking the C-C bond in glucose releases e- /Energy - electrons accepted by NAD NAD- +H+ NADH NAD NADH 2 ATP 2 ADP + P Glucose C6H12O6 2 pyruvate 2 C3 4 ADP + P 4 ATP

III. Cellular Respiration Overview: GLYCOLYSIS PYRUVATE METABOLISM Oxygen Absent? Oxygen Present? Anaerobic Respiration Or Fermentation Aerobic Respiration MORE ATP SOME ATP

III. Cellular Respiration • Overview: • Glycolysis • Anaerobic Respiration C3 C2-CoA + CO2 Pyruvate Acetyl-CoA NAD NADH

III. Cellular Respiration • Overview: • Glycolysis • Anaerobic Respiration C3 C2-CoA + CO2 CoA NAD NADH NAD NADH C6 C4 Incomplete Citric Acid Cycle C5 + CO2

2. Anaerobic Respiration Electron Transport Chain across a membrane to convert energy harvested in NADH into bonds in ATP. OUTER Intermembrane (periplasmic) space INNER e- NADH NAD + H+ STEP 1: NADH gives up electron to an electron acceptor protein in the membrane, splitting into NAD and H+ ions. NAD is RECYCLED at this step, so GLYCOLYSIS can continue!

2. Anaerobic Respiration Electron Transport Chain across a membrane to convert energy harvested in NADH into bonds in ATP. OUTER Intermembrane (periplasmic) space H+ H+ e- INNER e- NADH NAD + H+ H+ Step 2: The electron is passed from protein to protein, across the inner membrane. This movement of negative charge draws H+ ions across through protein channels… H+ build up in the intermembrane space, creating a CHARGE DIFFERENTIAL.

2. Anaerobic Respiration Electron Transport Chain across a membrane to convert energy harvested in NADH into bonds in ATP. OUTER Intermembrane (periplasmic) space H+ H+ H+ e- INNER ATP synthase e- NADH NAD ADP + P ATP Step 3: The charge differential is electric potential energy. Eventually, the differential is so great that H+ ions flow back through the membrane. The energy in this ‘current’ of charged particles is used to add P + ADP  ATP.

2. Anaerobic Respiration Electron Transport Chain across a membrane to convert energy harvested in NADH into bonds in ATP. OUTER Intermembrane (periplasmic) space e- INNER ADP + P ATP e- NADH NAD S- H2S S H+ H+ Step 4: The electron(s) are accepted by a ‘final electron acceptor’. In anaerobic respiration, this is CO2, NO3, Fe, or S. And the anion formed reacts with H+ ions. THUS, ENERGY IN NADH IS USED TO MAKE BONDS IN ATP.

III. Cellular Respiration • Overview: • Glycolysis • Anaerobic Respiration Ethanol Fermentation: Some bacteria, plants, yeasts Lactate Fermentation: Some bacteria, animals

III. Cellular Respiration Overview: GLYCOLYSIS PYRUVATE METABOLISM Oxygen Absent? Oxygen Present? Anaerobic Respiration Or Fermentation Aerobic Respiration MORE ATP SOME ATP

III. Cellular Respiration • Overview: • Glycolysis • Anaerobic Respiration • Aerobic Respiration Occurs in: Aerobic bacteria Aerobic Archaea All Eukaryotes (in the mitochondria descended from aerobic bacteria!) GLYCOLYSIS OCCURS IN THE CYTOPLASM. THAT’S WHERE THE PYRUVATES ARE PRODUCED.

III. Cellular Respiration • Overview: • Glycolysis • Anaerobic Respiration C3 C2-CoA + CO2 Pyruvate Acetyl-CoA NAD NADH “Gateway Step” In Eukaryotes

REVIEW – ANAEROBIC RESPIRATION Incomplete Citric Acid Cycle CoA CoA – C2 NAD NADH (oxaloacetate) C6 C4 C5 + CO2 NAD NADH NAD FAD FADH2 NADH C4 + CO2 ADP + P ATP

Aerobic Respiration Citric Acid (“Krebs”) Cycle CoA CoA – C2 NAD NADH (oxaloacetate) C6 C4 C5 + CO2 NAD NADH NAD FAD FADH2 NADH C4 + CO2 ADP + P ATP The C5 molecule is recycled into oxaloacetate (C4), with the release of even MORE ENERGY trapped in ATP, NADH, and FADH

2. Aerobic Respiration Electron Transport Chain across a membrane to convert energy harvested in NADH into bonds in ATP. OUTER Intermembrane (periplasmic) space H+ H+ H+ H+ H+ H+ e- INNER e- e- ADP + P ATP NADH NAD + H+ O2 2 O-- 2 H2O FADH FAD + H+ 2H+ 2H+ SAME THING: Electrons transferred, H+ ions pulled across membrane, and flood back across creating ATP. But O2 is the final electron acceptor, making WATER!! MORE electrons transferred, stronger ‘pull’ exerted by oxygen, more ATP made.

P 2 ADP + 2 2 ATP i Glycolysis Glucose LE 9-17a 2 Pyruvate 2 NAD+ 2 NADH CO2 2 + 2 H+ 2 Acetaldehyde 2 Ethanol Alcohol fermentation

P 2 ADP + 2 2 ATP i Glycolysis Glucose LE 9-17b 2 NAD+ 2 NADH + 2 H+ 2 Pyruvate Lactate 2 Lactate Lactic acid fermentation

Cell Biology Overview II. Membranes – How Things Get in and Out of Cells A. Membrane Structure