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http://users.wfu.edu/shapiro/Biophysics14/
Regular class times: MWF 10-10:50 AM
Physics 307/607 Biology 307/607
Instructors:
(1) Professor Martin Guthold, Phone: 758-4977, Office: 302 Olin, email: gutholdm@wfu.edu, http://www.wfu.edu/~gutholdm/
(2) Professor Kim-Shapiro, Phone: 758-4993, Office: 208 Olin, email: shapiro@wfu.edu, http://www.wfu.edu/~shapiro/
Office hours: Guthold: M, W, F; 12:00 pm – 1:00 pm, and by appointment.
Kim-Shapiro: M, W; 2:15 pm – 4:00 pm, and by appointment
Texts:
1. Principles of Physical Biochemistry, by K.E. van Holde, W. C. Johnson, and P.S. Ho
2. Neurodynamix, by W.O. Friesen and J.A. Friesen.
3. Supplementary texts on reserve:
1. Biophysical Chemistry Part II, Techniques for the study of biological structure and function, by Charles Cantor and Paul Schimmel (1980).
2. Biochemistry by Lupert Stryer (1988).
3. Additional reading will be assigned in the form of journal articles and handouts
Syllabus
Emphasis in grading will be placed on how each problem is solved. All work showing how the solution was obtained must be shown. An answer with the correct answer but poor method is inferior to one with the wrong answer but good method.
Homework: Problem sets will generally be assigned for each chapter and the students will have one week to complete them. Students may help each other on problem sets but each student must write their own solution to each problem.
TA: Wei Li, Olin 203, liw210@wfu.edu
The project that all students do will be a 5-10 page paper focusing on a particular topic in biophysics. The project could be a service learning project (see instructors for more information on that).
Project topic is due in two weeks (Wednesday, Jan. 29)
Project outline is due before spring break (Friday, March 7)
Complete project due last day of class (Wednesday, April 30)
** Graduate students need to do a 5-10 minutes presentation on one of the journal articles that are part of the reading assignments (see reading list); or another article relevant to a lecture topic.
Graduate Students:2 Midterm exams........................... 30% Project……………………………….10%Presentation of Journal Article.......10% ** Final Exam.....................................30 % Problem Sets.................................20%
Grading:
Undergraduate Students: 2 Midterm exams...........................40% Project………………………………10%Final Exam.....................................30 % Problem Sets..................................20%
Exam Schedule:
Midterm 1: Wednesday, Feb. 26 (in-class)
Midterm 2: Monday, April 21 (in-class)
Final Exam: Friday, May 2, (9:00 am – 12:00 pm)
Miscellaneous:
We will, at times, look at structures that are deposited in the protein data bank (
http://www.rcsb.org/pdb/home/home.do). The data bank contains the
coordinates of all solved protein, DNA, RNA and other bio-molecular structures,
usually to atomic resolution. ~ 97,000 structures (Jan. 2014).
Syllabus
Tentative Syllabus:
Part I Biophysical Methods
1. Introduction (Guthold) (~7 lectures)1.1 Biological Macromolecules; 1.2 Molecular interactions; 1.3 Overview of ThermodynamicsReading: van Holde, chapters 1-4 (partial).
2. X-ray diffraction, DNA Structure (Guthold) (~5 lectures)Fourier Transforms, Scattering, r(x) F(q), A helix , History of Watson and Cricks' discovery and its implications Reading: van Holde chapter 6, Watson and Crick Papers
3. Light Scattering, Sedimenation, Gel Electrophoresis, Higher Order DNA Structure (Kim-Shapiro) (~4 lectures)
Sedimenation, mass spectrometry, Gel electrophoresis (Fick's Law), Light Scattering (Classical, Dynamic, Polarized) DNA Topology (Length, Twist, and Writhe), Chromosome Structure Reading: van Holde, chapters 5 and 7, Polarized Light Scattering
4. Absorption Spectroscopy, Protein Structure (Kim-Shapiro) (~4 lectures)UV, VIS spectroscopy, linear and circular dichroism Protein primary, secondary, tertiary, quaternary structure Reading: van Holde chapters 8-10
Syllabus
Tentative Syllabus (cont.)
5. Emission Spectroscopy (Guthold) (~4 lectures)Reading: van Holde, Chapter 11
6. Single Molecule biophysics (Guthold) (~3 lectures)Reading: van Holde, Chapter 16
7. Electron Paramagnetic Resonance, Protein Function - Hemolgobin (Kim-Shapiro) (~4 lectures)Electron Paramagnetic Resonance, Hemoglobin cooperativity Studies using EPR and time-resolved
absorption spectroscopy Reading: Handout
Part II Membrane Biophysics
8. Biological membranes and Transport (Kim-Shapiro) (~4 lectures)Description of membranes, Diffusion, Facilitated transport, Nernst Equation, Donnan EquilibriumReading: van Holde, chapters 13-14
9. Nerve Excitation (Kim-Shapiro) (~3 lectures)Neurons, Action Potential, Propagation of action potential, measurements in membrane biophysics,Synaptic transmission Reading: Frisens, Sections 1 and 2
Syllabus
Reading: Van Holde, Chapter 1
Van Holde Chapter 3.1 to 3.3
Van Holde Chapter 2
(we’ll go through Chapters 1 and 3 first.)
Homework (due Wednesday, Jan. 29):
1. What is the Central Dogma of Molecular Biology? Describe, sketch in your own words. 2. Van Holde 1.2 (amino acid structure)3. Van Holde 1.7 (DNA structure)4. Protein data bank exercises (see extra handout)5. Protein & DNA structure exercises (see extra handout)
Paper list (for presentations) is posted on web site
http://www.wfu.edu/~shapiro/biophysics14/
Introduction-1Structures of Biological Macromolecules
In this course we will mainly deal with:
• nucleic acids (DNA, RNA), amino acids (proteins), membranes (cell
membrane)
• Look at physical methods to examine the structure and function of these biological molecules
From: Voet & Voet Biochemistry
Introduction-1Structures of Biological Macromolecules
AFM image of l-DNA(Guthold group)
DNA mismatch repair protein MutS(image: Salsbury group)
Bovine pulmonary artery endothelial cells
Image: Justin Sigley, WFU Physics)
Triple stain: DNA (nucleus )– blueActin fibers – redMicrotubules – green
Scale bar: 10 mm
Introduction-1Structures of Biological Macromolecules
Outline
• Nucleic acids, DNA, RNA
• DNA structure, twist, rise, linking number
• Amino acids, proteins
• Protein structure, 1o, 2o, 3o, 4o structure
• Properties of amino acids, (small, large, neutral, charged, hydrophobic, hydrophilic, etc.)
• Protein data bank (PDB)
• Central Dogma, Replication, Transcription, Translation
• Genetic code, DNA/RNA codons
Biological Macromolecules – General Prinicples
- Well-defined stoichiometry & geometry. Not readily broken into tiny pieces
- Monomer is the building block (nucleic acid → DNA/RNA; amino acid → proteins)
(Macro = large. Up to ~ 25 residues = oligomer; >25 = polymer)
• 1° structure: one-dimensional sequence
• 2° structure: local arrangement (a-helices, b-sheets, turns); sometimes super- secondary structures: hairpins, corners, - -a b a motifs, etc.
• 3° structure: 3-D structure (e.g. folded protein), stabilized by H-bond, hydrophobic forces, van-der-Waals, charge-charge, etc.
• 4° structure: Arrangement of subunits (e.g. hemoglobin)
- Configuration vs. Conformation:
• Configuration – Defined by chemical (covalent bonds), must break bond to change configuration (e.g. L-amino acid, D-amino acid)
• Conformation – Spatial arrangement (e.g. an amino acid polymer can have a huge number of different conformations, one of which is the natively folded protein).
http://www.rit.edu/~gtfsbi/IntroBiol/images/CH09/figure-09-07.jpg
Nucleosome
How to compact 2 meters of DNA into 2 mm-sized nucleus?(like folding a 1000 km long long fishing line (1 mm diameter) into 1m sized ball)
The structure of DNA and RNA
• Four monomer building blocks
• RNA has ribose instead of 2’-deoxyribose
• RNA has Uridine instead of Thymidine
Stabilizing factors in double-stranded (ds)-DNA
Later: This is also how DNA and RNA match up (hybridize) in the binding pocket of RNA polymerase during transcription!
Base Base plus ribose sugar Nucleoside (RNA)
Base plus deoxy ribose sugarDeoxy-nucleoside (DNA)
Base plus ribose sugar plus phospate (nucleotide)*
Adenine (A) Adenosine (A) Deoxy-adenosine (dA) Adenosine monophospate (AMP)
Cytosine (C) Cytidine (C) Deoxy-cytidine (dC) Cytidine monophospate (CMP)
Guanine (G) Guanosine (G) Deoxy-guanosine (dG) Guanosine monophospate (GMP)
Thymine (T) (Methyluridine, m5U) Thymidine (dT) m5UMP
Uracil (U) Uridine (U) Deoxy-urdine (dU) Uridine monophosphate(UMP)
A bit of nucleic acid nomenclature
* Can also have two or three phosphates, and de-oxy variety, too
B-DNA (most common): - right-handed
- 0.34 nm rise
- 10.5 bp per turn
- 3.4 nm pitch
- adopted in aqueous
- 2 nm diameter
A-DNA:
- right-handed
- broader than B
- 0.26 nm rise
- 11 bp per turn
- 2.8 nm pitch
- adopted in non-aqueous
- most common form for RNA
- 2.3 nm diameter
- 19o inclination of base pairs
Z-DNA:
- left-handed
- zig-zaggy
- ~12 bp per turn
- adopted sometimes by (CG)n repeats.
- 1.8 nm diameter
cruciform
Triple-strand
The structure of DNA and RNA
Twist, rise and linking number in DNA
L = T + W
L, linking number: Number of times one edge of ribbon linked around other – topological property cannot change w/o cutting. (calculate by L = T + W)
T, twist = winding of Watson around Crick – integrated angle of twist/2p along length, not an integer, necessarily (calculate by T = (number of base pairs/(base pairs/turn))
W, writhe = wrapping of ribbon axis around itself – noninteger, geometric property
Supercoiling (Writhe) important in vivo (most DNA is slightly negatively supercoiled).
s = superhelical density
Note: There are topoisomerases to convert topoisomers. They can ‘remove a knot’ by breaking double-stranded DNA and re-ligating DNA. Mutated topoisomerases cause cancer.
s = W/T
Sample problem
A circular, plectonemic (‘braided’) helix of DNA is in the B
form and has a total of 1155 base pairs.
1. What is the twist of the DNA?
2. The DNA has a superhelical density of -0.273. The DNA
is put into an alcohol solution and it takes the A form.
What is the DW, DT, DL, and Ds?
The structure of proteins1° structure: Amino acid sequence
– Twenty amino acids common to all organisms.
– Each has amino group, carboxyl group, R group and a hydrogen in tetrahedral symmetry. Almost all organisms have “L” chirality, but some virus have the mirror-image “D” chirality. (see board)
– Linked together by peptide bond. Peptide bond can be trans or cis.
– Proteins have prosthetic groups (e.g. heme) and amino acids can get modified (sugars, phosphates, etc).
– Two important angles: Φ: N-Ca bond, Ψ: C-Ca bond Ramachandran plot of allowed angles (dis-allowed due to steric hindrance).
The structure of proteins
– Given N amino acids, there are 20N different sequences. Sequence determines structure. If >20% homologous, probably similar structure. Converse not true: very different sequences can have similar structures.
– Hydrophobicity/hydrophilicity values [or “hydropathy” values, i.e. “strong feeling about”] determines protein folding. In aqueous environment, the core is hydrophobic, the surface is hydrophilic; in the membrane, both are hydrophobic.
– Kyte-Doolittle Scale – measure of hydrophobicity. Hydrophobicity is determined by measuring the energy DGtrans of transferring an amino acid from organic solvent (or vapor) to water (more in introduction-3*).
• If DGtrans is positive – hydrophobic; if negative hydrophilic.
– There are charged and uncharged side chains. Proteins have net charge and pockets of positive and negative charges, salt bridges. Isoelectric point: pH where net charge of protein is 0.
1° structure (primary structure): Amino acid sequence
aq
nonaq
ln , where P , mole fractiontransferG RT P
Kyte-Doolittle scale also uses structural data, in addition to DGtransfer
The structure of proteins
• 1° structure: A polymer with a unique amino acid sequence.
• There are twenty different amino acids
Charged amino acids
Positively charged
Negatively charged
Source: Kyte J & Doolittle, RF; J. Mol. Biol. 157, 110 (1982)
The structure of proteins
• 1° structure: A polymer with a unique amino acid sequence.
• There are twenty different amino acids
Hydrophobic amino acids
Nonpolar (hydrophobic) amino acids, aromatic
Nonpolar (hydrophobic) amino acids, alkyl
Nonpolar (hydrophobic) amino acids
Source: Kyte J & Doolittle, RF; J. Mol. Biol. 157, 110 (1982)
The structure of proteins
• 1° structure: A polymer with a unique amino acid sequence.
• There are twenty different amino acids
Uncharged, polar amino acids
Polar amino acids, aromatic
Polar amino acids, amines
Polar amino acids, disulfide with adjacent Cys
Polar amino acids
Source: Kyte J & Doolittle, RF; J. Mol. Biol. 157, 110 (1982)
The structure of proteins
Alpha helix:- right-handed helix- 0.15 nm translation
(rise)- 100° rotation (twist)- 3.6 residues/turn- Pitch: 0.54 nm - stabilized by H-bonds
between NH and CO group (four residues up).
2° structure (secondary structure): alpha helix
a-helix (© by Irvine Geis)
Biochemistry Voet & Voet
Red – oxygen
Black – carbon
Blue – nitrogen
Purple – R-group
White – Ca
Hydrogen-bonds between C-O of nth
and N-H group of n+4th residue.
The structure of proteins
Beta sheet:- Can have parallel
and anti-parallel- Distance between
residues: 0.35 nm- H-bonds between
NH and CO groups of adjacent strands stabilized structure.
2° structure: beta strand
Note: Color-in atoms for practice
The structure of proteins
Domains: Structurally or functionally defined protein regions, e. g. DNA binding domain
3° Structure (tertiary structure): Overall three dimensional structure of whole protein
4° Structure (quaternary structure): Larger assembly of several proteins or subunits (non-covalently linked or linked by cystines (e. g., hemoglobin 2 2a b)
Higher Order Structure: Super secondary (+2°) structure: b turns, b-Hairpin, Greek Key, -aa, - -b a b, -b barrel
(a) Stick model; (b) van der Waal’s surface model; (c) ribbon model; (d) solvent accessible surface model; (e) caricature of molecule.
Example: Structure of Fibrinogen(look at this structure in Protein Data Bank)
Six polypeptide chains: 2 A a (610 a.a.), 2 B b (461 a.a.), and 2 g (411 a.a.) (human numbering).
Trinodular: 2 external D nodules; central E nodule (N-termini)
Parts not resolved: loopy a-C region stretching back to E nodule (after residue 220), N-terminal of a- and b- chains (fibrinopeptides A and B) and N-terminal of g-chain (2x96 residues), C-terminal of g-chain(2x16 residues).
Dimensions: about 45 nm x 4.5 nm
17 disulfide bonds: within E nodule and braces at ends of the alpha helix coiled coils
E nodule D noduleD nodule
Crystal structure of Chicken Fibrinogen (2x 1364 a.a.) . Z. Yang, J. M. Kollman, L. Pandi, R. F. Doolittle, Biochemistry 40, 12515-12523 (2001)
b-hole
a-hole
Formation of Fibrin Fibers(major structural component of blood clots)
+
thrombin
fibrinogen
fibrin
B
AFibrinogen
b
a
Fibrinopeptides A & B
Thrombin
Fibrin (protofibrils)
Protofibrilformation
Further lateral aggregation
Lateral aggregation and branching
SEM image (Hantgan) of fibrin clot (plus platelets)
10 mm
AFM image (Guthold) of fibrin clot
10 mm
Image: M. Kaga, P. Arnold; Voet & Voet, “Biochemisty”, Wiley & Sons, NewYork, 1990
The protein data bankAn Information Portal to Biological Macromolecular Structures
nearly 100,000 structures (Jan 2014)
Go to:
http://www.rcsb.org/pdb/home/home.do
We’ll do some exercises related to the homework.
• DNA is just a super-long string of four different
bases.
• Proteins do all the work and action in an organism
(structure, catalyze reactions, etc).
How does the information (letter code) contained in
DNA get translated into specific proteins?
?
Central dogma of Molecular Biology
Describes how the genetic information encoded (stored) in the ‘letter sequence’ of DNA is first transcribed and then translated into an amino acid sequence, i.e. into proteins. (Crick, F.H.C. (1958): On Protein Synthesis. Symp. Soc. Exp. Biol. XII, 139-163; Crick, F. H. C. (1970): Central Dogma of Molecular Biology. Nature 227, 561-563.)
(Enzymes catalyze reactions in organism)(Proteins – building blocks of organism)
The genome, or genomic DNA (deoxyribonucleic acids), of an organism consists of a very long sequence of four different nucleotides with bases A, C, G, T. Genomic DNA is a double-stranded helix comprised of two complementary strands, held together by A-T and C-G base pairs. The entire genome is replicated by DNA polymerases (a protein) and passed on to daughter cells during cell division. The genome consists of many (usually thousands) of genes. A gene is a specific, defined nucleic acid sequence that encodes one particular protein. The human genome consists of about 3·109 base pairs and only about 30,000 genes (in higher organisms, large parts the genome (80 – 98%) do not encode any known proteins).
Genomic DNA
Re
plic
atio
n
(DN
A p
oly
me
rase
)
mRNA
Transcription
(RNA polymerase)
Transcription: RNA polymerase (a protein) binds to the beginning of one particular gene and synthesizes an exact mRNA copy of that gene. RNA (ribonucleic acid) consists of nucleotides with bases A, C, G, U. It is single-stranded. Transcription stops at the end of each gene and the RNA chain is released. A gene is on the order of a thousand bases.
Protein
Tran
slat
ion
(Rib
osom
e)
Translation: The RNA is moved to the ribosome. The ribosome reads the RNA sequence (with the help of t-RNA) and synthesizes an amino acid chain (polypeptide). The polypeptide folds into a three-dimensional structure – a protein (or part of a protein). There are 20 different amino acids, thus three RNA letters are needed to code for one amino acid. These triplets of RNA letters are called codons.
Central dogmaPicture in prokaryotic (bacterial) cell and eukaryotic (higher) cell
Eukaryotic cell
The human genome has about 30,000 genes (and lots of non-coding DNA)
Simply speaking: one gene one polypeptide
Prokaryotic cell (no nucleus)
Transcription (making RNA from a DNA template):
RNA polymerase binds at a promoter (beginning of a gene), unwinds DNA, and starts synthesis of an RNA copy of the gene
The sequence of bases in DNA codes for the sequence of amino acids in proteins
First real-time movies of a transcribing RNA polymerase 1,2
1. S. Kasas et al., Biochemistry 36, 461 (1997). (see Fig. 16.6 of book)2. M. Guthold et al., Biophysical Journal 77, 2284 (Oct, 1999). Kasas movie
http://www.youtube.com/watch?v=ZDH8sWiUsAM
http://www.youtube.com/watch?v=YEzRz1jmqNACredit: 8 minute movie of inner workings of a cellBioVisions, Harvard University
Central dogma …continued
Translation: Ribosome is reading codons of mRNA, and with the help of tRNA, synthesizes a polypeptide.
mRNA is translated into polypeptide chain
mRNA … messenger RNA
tRNA … transfer RNA
mRNA
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