Part 1b

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Glucose - two forms: B(beta)-form = CELLULOSE
a(alpha)-form = starch

Beta means up position; axial
Alpha means down posit; equatorial
Nucleic acids: Backbone: sugar-phosphate-sugar-phosph..
Differentiation: comes from bases
Lipids: Small, water-insoluble molecules
-Phospholipids form extended bilayers
-Structures include long chain FATTY ACIDS
Years ago Earth was formed: 4.5 Billion
Years ago Microorganisms formed: 3.5 billion
Eukaryotes formed: 2.25 billion yrs ago
Oxygen atmosphere formed: 1.5-2 billion yrs ago
Early steps in Evolution: -Prebiotic Synthesis of Molecules
-Biosynthetic Cycles began
-Energy transformation/collection
-Replication
---CELLULAR LIFE (the RNA world?)
Urey-Miller Experiment: Illustrated that simple, prebiotic conditions can generate amino acid products.
-Reducing Atmsphere of NH3, H2, CH3, H2O
-Spark
-Generated Amino Acid products
Hammerhead Ribozyme: -Discovery suggests that catalytic RNA molecules could have played fundamental roles in evolution of life.
-Makes plausible the idea of an early "RNA WORLD"; lifeforms depended on RNA for heredity, info storage, promotion of specific reactions.
Imino acid: proline
-3 carbon cyclic side chain
-still non-polar
-only amino acid with side chain bonded to amino group.
2 Ways to make a Buffer: Mix an Acid with its salt to get desired pH.

Mix weak acid or base w/ strong base or acid.
Nonpolar amino acids: Glycine, Alanine, valine, leucine, isoleucine, methionine, proline
only non-chiral amino acid: glycine; not L or D
aromatic amino acids: phenylalanine, tyrosine, tryptophan
Special features of Tyrosine/Tryptophan: -kind've polar - Hydroxyl/NH groups.
-Aromatic rings contain delocalized electrons that strongly absorb UV lite.
Allows determination of protein concentration in solution. (Beer's law)
Polar Uncharged Amino acids: Serine, Threonine, Cysteine
Cysteine special features: Side chains S-H oxidize to form disulfide bonds/bridges.
Oxidation: Loss of electrons (H+)
Polar Amino Acids with Basic R chains: Lysine, Arginine, Histidine
Polar Amino Acids with Acidic R chains: Glutamate, Aspartate
Nonpolar Amino Acids additional: Asparagine, Glutamine
Water is a Weak Acid: just know that
% of Other ions, metabolites in -Total cell composition -Dry mass composition: 1%
3%
Major classes of biomolecules: LIPIDS
CARBS
NUCLEIC ACIDS
PROTEINS
WATER
Proteins: -Linear polymers of 20 different amino acids
-Chemically, structurally, functionally diverse
Water: -Very small
-Highly structured intermolecular Hydrogen bonding
Carbohydrates: -Linear or branched chains of SMALL SUGARS
Functions:
-Gives cells STRUCTURE
-STORES ENERGY
ATP SYNTHASE function: -A molecular machine
-Functions as a ROTARY ENGINE, synthesizing ATP as it spins
ATP Synthase Structure: 8 DIFFERENT POLYPEPTIDE CHAINS
22-24 Total Subunits
-1 each: a, y(gamma) delta(d) E(epsl)
-2: B
-3: alpha, beta
-10-12 copies of C
Amino Acids: Building Blocks of Proteins.
Residues hooked together to form long polypeptide chains.
Dominant Amino acid conformation: L-alpha amino acid
other is D
Polypeptide Backbone: NCCNCCNCCNCC...
Nitrogen-Carbon-carbon-....
Number of E.Coli bp: 4.5 x 10e6
Number of Human base pairs: 3 x 10e9
% water in cell composition (total): 70%
% water in dry mass cell composition: 0 obviously, it's dry
% of Protein in -Total cell composition -Dry mass cell composition: Total = 20%
Dry = 66%
% of Lipids in -Total cell composition -Dry mass cell composition: 5%
16% in dry mass
% of Carbohydrates in -total cell composition -dry mass cell composition: 4%
12%
% of Nucleic Acids in -Total Cell composition -Dry mass cell composition: 1%
3%
+ charged ions migrate to... - charged ions migrate to...: Anode - this occurs below the pI
Cathode - occurs above the pI
Native Protein Structure: the particular folded structure of a protein under biological conditions
2 Examples of Fibrous Proteins: Collagin and Keratin
pKr: the acid dissociation constant of a SIDE chain on an amino acid - the r group
Myoglobin: Structural relative of Hemoglobin
-Stores oxygen in muscles
-predominantly alpha helices
-1 single chain.
alpha Keratin: -in hair and nails
-has long coiled helices, fibrous protein, no compact folding.
-an alpha-helical coiled coil - alpha helices intertwined to form long fiber
4 levels of protein structure: Primary
Secondary
Tertiary
Quarternary
Primary Protein Structure: sequence of amino acids
Secondary Protein Structure: regular, local folding of peptide backbone.
tertiary protein structure: compact folding of a single pp chain.
-aka, domain structure.
-Pp chain can have multiple domains.
Quaternary Protein Structure: multiple individually folded chains (subunits) are tightly associated.
Immunoglobulin domain: Only Beta-barrels. No helices.
Formed of 8 pp strands.
Beta clamp: A subunit of DNA polymerase
4 Non-covalent Intermolecular Forces that stabilize Protein Structure:: Hydrogen bonds
Ionic bonds
Van der Waals forces
Hydrophobic Interactions
Hydrogen bond: -bond that forms between a polarized h-bond donor and H-bond acceptor with unshared electrons.
-Length: Donor-hydrogen: 0.9A
Acceptor-Hydrogen: 2.0A
Geometry: 180degrees SP
H-bond length: 2.0 A
-That's between the H and the acceptor.
-Overall = 2.9
-From H-donor is 0.9
Ionic Bonds/Salt bridges: strong interaction between two oppositely charged ionic groups.
-Energy depends on distance btwn molecules, dielectric constant of the solvent.
Van der Waals forces: weak nonspecific interactions from transient charge fluctuations in electron shells.
-criticaly depends on distance between atoms/groups of atoms.
Contact distance: how close 2 atoms can get to each other before their van der waals forces become repulsive.
Hydrophobic interactions: apparent interactions between nonpolar molecules. But not really.
-Really the highly structured H-bonding of water.
Oil-drop effect: To maximize energy of a system of protein and water: water-molecular surface interface is minimized by nonpolar areas aggregating. Reduces entropy, maximizes H2O's freedom to interact.
Linus Pauling: -discovered that peptide bond C-N is PLANAR and ALWAYS TRANS.
-has a PARTIAL DOUBLE BOND due to resonance of the pi electrons of the carboxyl group.
A.A. that is exception to the Always Trans, Always Planar Peptide Bond rule:: PROLINE Energy difference is only small between trans/cis; cis has a little more steric hindrance than trans.
He predicted 3 secondary structures of pp backbones that maximized H-bonding and had correct geometry.: Who is Linus Pauling, 1990-1994?
That is correct.

..Paved the way for double helix..
3 2ndary structures: Alpha helix
Parallel Beta sheet
Antiparallel beta sheet

-All result from Hydrogen bonds
Alpha Helix Features: -Each A.A. is H-bonded to 4th residue in sequence.
-3.6 residues per turn
-5.4 Angstrom Pitch
-R-groups (sidechains) stick out away from axis.
B(A) and B(P) sheets: B(A)=Antiparallel; 2 pp chains running opposite; H-bonds are straight between corresponding residues; every other.
B(P)=Parallel; much longer than anti;
-Both have repeat every 2 residues
Phi angle Psi angle: between Alpha Carbon and Nitrogen
between Alpha Carbon and Carbonyl C
Which is more common: Right or Left-handed helices?: RIGHT. Left is very rare.
Torsional angles determine..: Backbone conformation.
Phi and Psi
Hemoglobin: Structural relative of Myoglobin
-transports oxygen in blood.
-Tetramer - 2 alpha, 2 beta.(4 subunits)
Subunits are structurally similar to myoglobin's 1 unit. (predominantly alpha helices)
X-ray crystallography: 1. Grow crystals
2. Collect data - send X-ray through crystals, diffract, beams go around different e- densities and film picks up remaining rays.
3. Use Diffraction Pattern
4. Get E- density map, fit molecular structure.
What directs tertiary folding? (into globular proteins): Hydrophobic intercations.
Oildrop Model of Globular Proteins: Tertiary Folding; Directed by Hydrophobic interactions. Nonpolar molecules pack densely into protein's interior, polar on exterior. Minimizes surface area btwn water and nonpolar.
Bonding that aids Tertiary folding: H-bonds
Ionic - strong when protected from water (otherwise it hydrates them).
VanderWaals - tight packing interior of protein; atoms rub shoulders.
Porins: membrane proteins that have reversed distribution of polar and nonpolar groups.
-Nonpolar is EXTERIOR - hydrophobic (in contact w/ membrane)
-Polar is INTERIOR - hydrophilic
-creates H2O channel inside protein.
Not only do Myoglobin/Hemoglobin have similar tertiary folding.. also have..: Similar amino acid sequences.. hmm what does that tell us?
-Specific amino acids can predict secondary structure AND tertiary structure.
What types of secondary structures do Glycine/Proline contribute to?: SHARP TURNS.
-They're alpha helix breakers.
ANFINSEN: -Demonstrated spontaneous folding of native protein globular 3ary structure.
-Used ribonuclease A, Urea, B-mercaptoethanol.
Ribonuclease A: A digestive enzyme, synthesized in the pancreas.
-124 residues
-8 Cysteins, with 4 Disulfide bonds.
-Predominantly a B-sheet structure.
Protein Denaturation Reagents (in anfinsen experiment): -Excess B-Mercaptoethanol.
-Urea
B-Mercaptoethanol: -reduces disulfide bonds in proteins.
-used by anfinsen on ribonuclease A
Urea: Disrupts H-bonding and hydrophobic interactions.
-Great h-bond former itself.
-Interrupts Lattice structure of H2O - so it disrupts the hydrophobic effect.
Dialysis: -removes urea from denatured proteins.
-Small molecules (MW<6000) diffuse out of porous tubing. The desired protein stays inside the tubing.
transmissable spongiform encephalopathies: Mad Cow (BSE)
Scrapie (sheep)
Kuru (human, New Guinea)
variant Cruetzfeld-Jakob Disease (human)
-Associated with PRIONS
Prions: -Infectious agents
-Contain no detectable DNA or RNA
-Misfolded cellular proteins in alternate conformation
-Pathalogical
PrPc and PrPsc: two prion structures.
PrPc = normal; 3 alpha helices
PrPsc = pathogenic; 2 alpha helices, one from normal switches to Bparallel sheet that's very stable.
Prion Hypothesis -why pathogenic?: -Association of PrPsc the pathogenic form with PrPc the normal form converts the normal to pathogenic too.
-Result: neurotoxic filaments grow.
-Causes: nerve cell death in CNS.
3 ways to seperate proteins by CHARGE: -Gel Electrophoresis
-Isoelectric Focusing
-Ion-exchange chromatography
3 ways to seperate protein by SIZE: SDS-PAGE electrophoresis
Gel-filtration chromatography
Sedimentation (centrifugation)
2 Ways to seperate proteins by BINDING: -affinity chromatography
-immunochemical methods
Ion exchange chromatography: -Column with beads (either - or +)
-Proteins bind to beads w/ opsit charge
-Proteins with same charge flow through
2 Types Ion Exchange Chromatography: Carboxymethyl:
- charged, binds + proteins.

Diethylaminoethyl:
+ charged, binds - proteins.
Gel Electrophoresis (SDS PAGE): SDS - sodium dodecyl sulfate
PAGE - polyacrylamide gel electrophor.
SDS creates uniform negative charge.
Proteins put at top of acrylamide plate.
Migrate down, according to SIZE.
Smallest go fastest.
SDS: sodium dodecyl sulfate
-in SDSPAGE, completely denatures all noncovalent (hydrogen) bonds in proteins - only primary sequence remains. Mercaptoethanol also reduces disulfide bonds.
Reagents of SDS PAGE: SDS
Betamercaptoethanol
PAGE
Limitation of SDS PAGE: Completely denatures all bonds
Isoelectric Focusing: seperates proteins on basis of charge.
Mixture of AMPHOLYTES - many pI's.
Sets a pH gradient.
Add proteins; seperate as each seeks the pH of its pI.
Horizontal migration
Proteases: Trypsin and Chymotrypsin
-Key reagents in protein analysis
-Specifically cut proteins into fragments.
Trypsin: hydrolizes peptide bonds after ARG LYS

ARG LYS
Chymotrypsin: hydrolyzes peptide bonds after
PHE TYR TRP
WHy use chymotrypsin and trypsin?: Both cleave peptides after different residues; overlapping the cleaved fragments allows identification of similar bonds, to sequence the whole sequence.
PITC: edman's reagent
Edman's Reagent: PITC
-phenyl isothiocyanate
-cleaves individual amino acids from the amino-terminal end.

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