09/18/06
From Biolk483
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*R groups interact with water | *R groups interact with water | ||
**Negative interaction (or r-groups not wanting to be near water) is called the hydrophobic effect | **Negative interaction (or r-groups not wanting to be near water) is called the hydrophobic effect | ||
| - | **Positive interaction = | + | **Positive interaction = hydrophilic effect |
<h3>Amino Acids and Protein Structure</h3> | <h3>Amino Acids and Protein Structure</h3> | ||
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*Threonine and tyrosine can be phosphorylated and dephosphorylated. | *Threonine and tyrosine can be phosphorylated and dephosphorylated. | ||
*Serines at specific locations are control points. | *Serines at specific locations are control points. | ||
| - | <h5>Phospholipid Role ( | + | <h5>Phospholipid Role (Phosphatidylserine)</h5> |
| - | *an example of nature using two chemicals it likes in non-primary roles ( | + | *an example of nature using two chemicals it likes in non-primary roles (meaning serine and lipids are being used but not in ways that we would call primary like we would the buiding of proteins and membranes, respectively) |
<h4>Tyrosine</h4> | <h4>Tyrosine</h4> | ||
| Line 53: | Line 53: | ||
**These disulfide bonds give a tight, precise conformation to the protein. They hold the tertiary structure together. | **These disulfide bonds give a tight, precise conformation to the protein. They hold the tertiary structure together. | ||
**Disulfide bonding is reversible. | **Disulfide bonding is reversible. | ||
| - | **Disulfide bonds are '''not''' made by | + | **Disulfide bonds are '''not''' made by hydrolysis! |
**Two cysteine disulfide bonded are called a cystine. | **Two cysteine disulfide bonded are called a cystine. | ||
<h4>Glycine</h4> | <h4>Glycine</h4> | ||
| - | *Can be a neurotransmitter like | + | *Can be a neurotransmitter like acetylcholine (this is done as a monomer, not in a protein or polypeptide form) |
| - | *Glycines are found in tight folding areas of proteins because they do not have an | + | *Glycines are found in tight folding areas of proteins because they do not have an R-group to get in the way. |
| - | *Glycines are found in | + | *Glycines are found in porphyrins, purines and pyrimidines (the latter two from nucleic acids) |
*Nature really likes this molecule. | *Nature really likes this molecule. | ||
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<h5>Lysines Many Bonds</h5> | <h5>Lysines Many Bonds</h5> | ||
<h6>Schiff base</h6> | <h6>Schiff base</h6> | ||
| - | * | + | *Remove water between R1R2C=O and H2N-R3 to make R1R2C=N-R3 |
| - | + | *This shifts the wavelength longer. | |
| - | *This shifts the wavelength longer | + | *So if we find a Schiff base on a lysine on a protein like Rhodopsin. |
| - | *So if we find a | + | *Schiff base = rhodopsin - purple when Schiff base |
| - | *Schiff base = rhodopsin - purple when | + | **Color vision is dependent on formation of Schiff base |
| - | ** | + | *Ex.: Aldolase |
| - | * | + | **an important enzyme in Glycolysis |
| - | **an important enzyme in | + | **Fructose 1,6 bisphosphate (a six-carbon chain) -- (Aldolase --> dihydroxyacetone phosphate (a 3-carbon chain) + glyceraldehyde-3-phosphate (a 3-carbon chain) |
| - | **Fructose 1,6 bisphosphate (a six-carbon chain) -- (Aldolase --> dihydroxyacetone | + | |
| - | <h6> | + | <h6>Amide Linkage</h6> |
*same as asparagine and glutamine | *same as asparagine and glutamine | ||
| - | * | + | *Ex.: pyruvate carboxylase |
**sticks a CO2 group on pyruvate | **sticks a CO2 group on pyruvate | ||
**Biotin is used to get C=) group available for putting on pyruvate | **Biotin is used to get C=) group available for putting on pyruvate | ||
***Note, there are many drawings here. | ***Note, there are many drawings here. | ||
| + | |||
<h6>Salt linkage</h6> | <h6>Salt linkage</h6> | ||
*Brings in anions | *Brings in anions | ||
*Easiest | *Easiest | ||
Current revision as of 16:28, 21 September 2009
Contents |
Amino Acids
- There are 20 coded for in genetic sequences
- A protein is a sequence of amino acids --also called a polypeptide
- All amino acids can form peptide bonds
- R groups interact with water
- Negative interaction (or r-groups not wanting to be near water) is called the hydrophobic effect
- Positive interaction = hydrophilic effect
Amino Acids and Protein Structure
- Primary structure is the sequence of amino acids
- Secondary Structure is the folding caused by r-group interaction with water
- Special structural roles:
- Example of special role: proline stops alpha helices because it is an imino acid with restricted bending.
Class 2 Amino Acids: Uncharged, Polar
- This section continues to detail the categories listed near the end of lecture on 09/13/06.
- This group includes:
- Alcohols: serine, threonine, tyrosine
- Asparagine and Glutamine
- Sulphur amino acids: cystine
Serine
Serine Peptidases: a family of enzymes
- Cleave peptide bonds by adding water
- Serine is at the active site
- We need the serine at the active site so as to end with an O- after an SN2 reaction
- Chymotrypsin is one of these enzymes --used in digestion.
Phosphorylation
- Phosphorylation can cause a fold change in the protein when the phosphate group is added
- This fold change could increase or decrease the protein's reactivity.
- This is a control mechanism for turning proteins on and off.
- Examples:
- Glycogen phosphorilase: increases reaction rate (of something...)
- Pyruvate dehydrogenase (an oxido-reduction reaction): decreases the reaction rate.
- Phosphorylation is reversible.
- Threonine and tyrosine can be phosphorylated and dephosphorylated.
- Serines at specific locations are control points.
Phospholipid Role (Phosphatidylserine)
- an example of nature using two chemicals it likes in non-primary roles (meaning serine and lipids are being used but not in ways that we would call primary like we would the buiding of proteins and membranes, respectively)
Tyrosine
Phosphorylation
- Again, a control mechanism
Planar
- Can lay against another planar molecule to protect the Pi electrons (e-)
Asparagine and Glutamine
- When we sequence we hydrolyse stuff and this process makes these two amino acids look the exact same
- Asparagine has a special role as it is the only amino acid sugars can be attached to so as to make glycoproteins.
Cysteine
- An oxidation reduction reaction makes disulfide bonds between two Cysteines spacially (as opposed to sequentially) near to one another in a protein
- These disulfide bonds give a tight, precise conformation to the protein. They hold the tertiary structure together.
- Disulfide bonding is reversible.
- Disulfide bonds are not made by hydrolysis!
- Two cysteine disulfide bonded are called a cystine.
Glycine
- Can be a neurotransmitter like acetylcholine (this is done as a monomer, not in a protein or polypeptide form)
- Glycines are found in tight folding areas of proteins because they do not have an R-group to get in the way.
- Glycines are found in porphyrins, purines and pyrimidines (the latter two from nucleic acids)
- Nature really likes this molecule.
Class Three Amino Acids: Positively Charged (Cations)
- These have more functions than most other amino acids
- These are the really dynamic amino acids
Lysine
- Lysine likes to hang out in the active site like a fishing hook
- Lysine is called an E-amine (or an Epsilon amine)
Lysines Many Bonds
Schiff base
- Remove water between R1R2C=O and H2N-R3 to make R1R2C=N-R3
- This shifts the wavelength longer.
- So if we find a Schiff base on a lysine on a protein like Rhodopsin.
- Schiff base = rhodopsin - purple when Schiff base
- Color vision is dependent on formation of Schiff base
- Ex.: Aldolase
- an important enzyme in Glycolysis
- Fructose 1,6 bisphosphate (a six-carbon chain) -- (Aldolase --> dihydroxyacetone phosphate (a 3-carbon chain) + glyceraldehyde-3-phosphate (a 3-carbon chain)
Amide Linkage
- same as asparagine and glutamine
- Ex.: pyruvate carboxylase
- sticks a CO2 group on pyruvate
- Biotin is used to get C=) group available for putting on pyruvate
- Note, there are many drawings here.
Salt linkage
- Brings in anions
- Easiest
