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Molecular Biology & Biochemistry 694:407 & 115:511 Protein Structure Sept. 13th, 2005, Lecture. - PowerPoint PPT Presentation
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Molecular Biology & Biochemistry 694:407& 115:511
Protein Structure
Sept. 13th, 2005, Lecture
Special thanks for this lecture goes to Dr. Gabriel Fenteany, Department of Chemistry, University of Illinois at Chicago (www.chem.uic.edu/fenteany/teaching/452), whose slides I liberally borrowed!
3-D Structure of Myoglobin
QuickTime™ and aTIFF (Uncompressed) decompressorare needed to see this picture.
Importance of Proteins
• Main catalysts in biochemistry: enzymes (involved in virtually every biochemical reaction)
• Structural components of cells (both inside and outside of cells in tissues)
• Regulatory functions (if/when a cell divides, which genes are expressed, etc.)
• Carrier and transport functions (ions, small molecules)
Levels of Protein Structure
• Primary Structure - amino acid sequence in a polypeptide
• Secondary Structure - local spatial arrangement of a polypeptide’s backbone atoms without regard to side chain conformation (e. g., -helices and -sheets)
• Tertiary Structure - three-dimensional structure of entire polypeptide
• Quaternary Structure - spatial arrangement of subunits of proteins composed of multiple polypeptides (protein complexes)
Structure of -amino acids
The 20 Amino Acids Found in Proteins
Stereochemistry of -amino acids
Stereoisomers of -amino acids
All amino acids are chiral except glycine.
All amino acids in proteins are L-amino acids.
Properties of Cysteine Side Chain
Side chains with -SH or -OH can ionize, making them more nucleophilic.
Oxidation between pair of cysteine side chains results in disulfide bond formation.
oxidation
reduction
HCH3N+
CH2
COO-
SHHCH3N+
CH2
COO-
SSCH2CH
H3N+ COO-
+ 2H+
+ 2e-
CH
H3N+CH2
COO-
SH
CH
H3N+CH2
COO-
SH
H++
pKa = 8.3
CH
H3N+CH2
COO-
S-
Note: in cells, oxidative disulfide formation normally proceeds via a thiol-disulfide exchange reaction, with (for example) a natural tripeptide such as glutathione:
R’-SH + R”-SH + G-SS-G
R’-SH + R”-SS-G + G-SH
R’-SS-G + R”-SH + G-SH
R’-SS-R” + 2 G-SH
G-SS-G = oxidated glutathioneG-SH = reducted glutathione
Absorption of UV Light by Aromatic Amino Acids
Formation of a Peptide
Planarity of Peptide (Amide) Bond
QuickTime™ and aTIFF (Uncompressed) decompressorare needed to see this picture.
cis and trans Isomers
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QuickTime™ and aTIFF (Uncompressed) decompressorare needed to see this picture.
The trans isomer is generally more stable because of steric crowding of side chains in cis conformation.
“Peptides”• Short polymers of amino acids• Each unit is called a residue• 2 residues - “dipeptide”• 3 residues - “tripeptide”• 12-20 residues - “oligopeptide”• Many residues - “polypeptide”
Examples of Oligopeptides
N- and C-Termini May Be Modified in Proteins
Primary Structure of Bovine InsulinFirst protein to be fully sequenced;Fred Sanger, 1953. For this, he won his first Nobel Prize (his second was for the Sanger dideoxy method of DNA sequencing).
Evolution and Conservation of Protein Sequences
Almost all human genetic diseases involve the disruption of a protein in the body.
Typically, the harmful phenotype(s) of disease-causing lesions in a protein gene are caused by effects on (a) the level of expression of the protein, (b) the activity of the protein, or (c) the folding of the protein.
[Note: Some effects may be different in different tissues for the same mutation! For example, some alpha-1-antitrypsin mutations exert harmful effects in the lungs (emphysema) due to lack of anti-elastase activity, and different harmful effects in the liver (cirrhosis) due to folding/sorting problems.]