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What we have to learn to do, we learn by doing Aristole

What we have to learn to do, we learn by doing Aristole. Welcome to Biology: A Molecular Approach Bio 7505 Professors : JM Crisman, PhD EJ Lehning, PhD. www.ccuri.org. Lecture Block- Basic Chemistry. Basics of Quantum Mechanics. Protons, neutrons and electrons.

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What we have to learn to do, we learn by doing Aristole

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  1. What we have to learn to do, we learn by doing Aristole Welcome to Biology: A Molecular Approach Bio 7505 Professors: JM Crisman, PhD EJ Lehning, PhD www.ccuri.org

  2. Lecture Block- Basic Chemistry

  3. Basics of Quantum Mechanics Protons, neutrons and electrons Atomic number- total # of protons Atomic mass- protons + neutrons - dalton is the unit of atomic mass

  4. Potential Energy vs. Kinetic Energy (stored) vs. (released) What do the words “potential” and “kinetic” mean? Kinetic Energy- Energy is released Potential Energy- Energy is Stored For Bonds Use Free nrg (G) Kilocalories (kcals) Calories X miles

  5. Atoms store nrg and release nrg • Movement of electrons between nrg (energy) • levels (e.g. fluorescence) 2) Forming and breaking bonds 3) Radioactive Decay- Nrg is also released when some atoms release subatomic particles

  6. Fig. 2.3

  7. Fig. 2.4 Radioactive Isotopes Decay Radioactive Half-life

  8. electrons occupy different energy levels Nucleus M Highest nrg L K Lowest nrg Nrg = energy

  9. Fig. 2.5

  10. Fig. 2.8

  11. Fig. 2.6 Nrg in nrg levels can be use to create fluorescence

  12. Atoms can absorb energy (potential energy) and release energy (kinetic energy) M Highest nrg L K Lowest nrg An Example Nucleus Release nrg Absorb nrg Nrg = energy

  13. Ionic Bonds- AKA electrovalent bonds - Atoms are in close association and electrons are donated and change the charge of the atom.

  14. Ions: Number of electrons does not equal the number of protons….. So there is a charge Cations- ions with positive charge (e.g. Na+) Anions- ions with negative charge (e.g. Cl-)

  15. Redox Reactions Redox = reduction/oxidation reactions e- can be gained and lost during chemical reactions (rxns). Gain of e- ---reduction Loss of e- ---oxidation LEO SAYS GER Used for energy transfer in biochemical reactions

  16. Bonds and Basic Reactions Atoms interact to form molecules by forming bonds Bonds store energy Covalent bonds- pairs of electrons are shared between atoms Strong bonds that require significant amounts of energy to break

  17. These bonds take tons of nrg to form! • So cells use molecules called enzymes that make reactions • go faster! • Explain the example of making a protein from amino acids • When chemical combine they form an intermediary state called • a transition state….takes a ton of energy to get there…and when • achieved the transition state allows bonds to break and new • bonds to form • Enzymes lower the amount of energy needed to break and reform • New bonds…they hold reactants close together and • move electrons themselves!...usually within their own molecular • structures!

  18. Activation nrg (Ae)- nrg needed to get to the transistion state from reactant nrg level Enzymes are biological catalysts that lower the Ae + reactants products What is an enzyme? Chemical reactions pass through a transition state and enzymes speed-up reactions by lowering the nrg needed to get there Free nrg (G) kcal A + B C Use the example of two amino acids!!!!!!

  19. Besides true bonds, there are other ways atoms interact with each other • Van der Waal forces • Hydrogen bonds (H Bonds) • Hydrophobic interactions Low nrg associations - are like velcro individually these interactions are weak but collectively they are very strong

  20. Van der Waals Interactions Molecules naturally attract each other Within a certain radius atoms attract each other. If they get too close…they repel each other Van der Waal Radius Distance that atoms of a molecule will stably interact individually these interactions are weak but are stronger collectively

  21. H Bonds d- d+ H H O O H H DIPOLE Water (H2O) H O H Polar Molecule O and N can form Hydrogen bonds -very weak individually but collectively strong In fact the DNA double helix is stabilized by these interactions

  22. Hydrophobic Interactions What does “hydro” and “phobic” mean? Hydrophobic molecules (i.e. do not interact with water…and thus tend to interact with each other… to “drive” water out Very important to stabilize many molecular structures (e.g. cell membranes, some protein structure)

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