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CHM333 LECTURE 8: 9/10/07 FALL 2007 Professor Christine Hrycyna 38 PEPTIDES and PROTEINS - Learned basic chemistry of amino acids – structure and charges - Chemical nature/charges of amino acids is CRUCIAL to the structure and function of proteins - Amino acids can assemble into chains (peptides, polypeptides, proteins) o Can be very short to very long Dipeptide = two amino acids linked Tripeptide = three amino acids linked - Amino acids sometimes called RESIDUES - Identity and function of a protein or peptide is determined by o Amino acid composition o Order of amino acids in the chain o Enormous variety of possible sequences e.g., if you have a protein with 100 aa, there are 1.27 X 10 130 possible sequences! - Amino acids are linked by COVALENT BONDS = PEPTIDE BONDS - Peptide bond is an amide linkage formed by a condensation reaction (loss of water) - Brings together the alpha-carboxyl of one amino acid with the alpha-amino of another - Portion of the AA left in the peptide is termed the amino acid RESIDUE o Amino acids sometimes called RESIDUES - R groups remain UNCHANGED – remain active - N-terminal amino and C-terminal carboxyl are also available for further reaction - Reaction is NOT thermodynamically favorable (not spontaneous) o Need energy and other components and instructions to correctly assemble This is the process of protein translation FORMATION OF THE PEPTIDE BOND

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Page 1: peptides, amino acids

CHM333 LECTURE 8: 9/10/07 FALL 2007 Professor Christine Hrycyna

38

PEPTIDES and PROTEINS

- Learned basic chemistry of amino acids – structure and charges - Chemical nature/charges of amino acids is CRUCIAL to the structure and function

of proteins - Amino acids can assemble into chains (peptides, polypeptides, proteins)

o Can be very short to very long Dipeptide = two amino acids linked Tripeptide = three amino acids linked

- Amino acids sometimes called RESIDUES - Identity and function of a protein or peptide is determined by

o Amino acid composition o Order of amino acids in the chain o Enormous variety of possible sequences

e.g., if you have a protein with 100 aa, there are 1.27 X 10130 possible sequences!

- Amino acids are linked by COVALENT BONDS = PEPTIDE BONDS - Peptide bond is an amide linkage formed by a condensation reaction (loss of water) - Brings together the alpha-carboxyl of one amino acid with the alpha-amino of another - Portion of the AA left in the peptide is termed the amino acid RESIDUE

o Amino acids sometimes called RESIDUES - R groups remain UNCHANGED – remain active - N-terminal amino and C-terminal carboxyl are also available for further reaction - Reaction is NOT thermodynamically favorable (not spontaneous)

o Need energy and other components and instructions to correctly assemble This is the process of protein translation

FORMATION OF THE PEPTIDE

BOND

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Animation of peptide bond formation:

http://www.cat.cc.md.us/courses/bio141/lecguide/unit4/peptide.html http://www.specialedprep.net/MSAT%20SCIENCE/Cellular%20Biology/Proteins1.htm#HOW

- Peptides are always written in the N C direction - Each peptide has ONLY ONE free amino group and ONE free carboxyl group;

others are neutralized by formation of the peptide bond

IMPORTANT FEATURES OF THE PEPTIDE BOND: 1. Peptide bonds have double bond character resulting from resonance stabilization

(C-N bond has 40% double bond character) C-N and C-O have partial double bond character

Animation: http://www.mcphu.edu/netbiochem/movies/peptresn.mov

- Results in the peptide bond being PLANAR

o C, N, H, O are all in the same plane (Cα’s are also in plane) o p orbitals can overlap to form partial double bonds between the nitrogen and

carbon and the carbon and oxygen - Stronger than a normal bond because of the double bond character

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- No tendency to protonate - No significant rotation occurs around the peptide bond itself. - PEPTIDE BACKBONE is made up of these rigid planar units with limited

rotation around the Cα carbons – N- Cα1 (phi) and the Cα2−C (psi) bonds. These bonds link the peptide groups in the peptide chain

o Crucial for protein structure o Rotation can occur at the α−carbons o However, rotation is limited due to steric hindrance (R groups) o These limitations limit the shapes that can be assumed by protein chains

Peptide Rotation Movie: http://cwx.prenhall.com/horton/chapter4/deluxe.html Click on LIVE FIGURES, then Figure 4.8/4.9

These limitations force Cα carbons on either side of the peptide bond to be, with few exceptions, trans to each other (opposite sides of the peptide

bond)

a. Cis configuration is rare; steric hindrance is greater

b. Trans is much more stable (sterically favored)

c. R-groups (on the Cα carbons) also end up on opposite sides of the peptide bond

i. (R-groups away from each other – favored)

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ALMOST EXCLUSIVELY TRANS CONFIGURATION

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SUMMARY: 1. Cα , O, C, N and H atoms are planar 2. No rotation around the peptide bond 3. Cα (with R groups) groups are in trans configuration (i.e. H on the

amide Nitrogen is opposite to the Oxygen of the carbonyl) 4. Peptide backbone is rigid

DRAWING PEPTIDES GIVEN THEIR AMINO ACID SEQUENCE:

- Peptide = ALDS - Left Right = N C-terminus (amino to carboxyl termini) - Want to draw it at pH 5

1) Draw the PEPTIDE BACKBONE fully protonated for as many amino acids as you have. For convenience, convention and ease, put the R groups down and the carbonyls up.

In our case, we have FOUR amino acids:

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2. Add in the side chains onto the Cα carbons – the ones that have the CH group –

in order left to right. Draw side chains fully protonated as well.

3. Determine if groups are ionized at the pH that you are interested in. Remember if pH > pKa, the H+ is OFF (deprotonated) Let’s say pH 5:

- Terminal carboxyl group is DEPROTONATED (5 > 2.21)

- Terminal amino group is NOT DEPROTONATED (5 < 9.69)

- Carboxyl group on Aspartate in DEPROTONATED (5 > 3.9)

Go back to fully protonated figure above and remove 2 protons: One from the terminal carboxyl, and one from the side chain of Asp. Note: In di, tri, or polypeptides, there is only ONE free amino group (N-terminus) and ONE free carboxyl group UNLESS present in R groups. You should be able to write out the full structures of peptides at different pH values.

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Calculate an approximate pI for the peptide Val-Cys-Arg-Phe-His-Asp-Gln. α-carboxyl COOH (pKa 2.2) Asp R-COOH (pKa 3.9) His imidazole + (pKa 6.0) α-amino NH3 + (pKa 9.6) Cys-SH (pKa 8.3) Arg guan. + (pKa 12.5) Sketch out starting with fully protonated and remove protons in order until you get the neutral species. Take the average of the pKa’s surrounding the neutral species. Net charge at low pH = +3, so have to add 3 equivalents of base to get to net charge zero. 3 equiv. base would completely titrate the α-carboxyl, R-carboxyl, and His imidazole, so pI would be halfway between pK of imidazole and pK of α-amino group, i.e. (6.0 + 8.3)/2 so pI = 7.15. You need to be able to do these types of problems! Interesting Peptide in Biological Systems:

1. Glutathione a. Tripeptide of glutamate,

cysteine, glycine b. Regulates

oxidation/reduction reactions in cells

c. Destroys destructive free radicals by scavenging oxidizing agents

2. Oxytocin and Vasopressin a. Pituitary gland peptide

hormones b. Nonapeptides cyclized by disulfide

bond c. Oxytocin stimulates uterine

contractions during childbirth – induces labor

d. Vasopressin stimulates water resorption by kidneys and increases blood pressure (anti-diuretic hormone)

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3. Enkephalins and Endorphins a. Brain and nervous system peptides b. Important in control of pain and emotional

states

4. Insulin – Peptide hormone that regulates carbohydrate metabolism. Acts as signal for “fed” state. Functions to cap glucose levels in blood. Stimulates storage of glucose as glycogen among other effects.

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5. Synthetic Peptide: Nutrasweet or Aspartame a. L-aspartyl-L-phenylalanine methyl ester b. Dipeptide – 200X sweeter than sucrose and only 1 calorie/teaspoon vs. sucrose

that has 16 calories/teaspoon c. Used in diet and low calorie foods and drinks d. Highly profitable e. If amino acids are in the “D” configuration, the peptide is bitter not sweet.

Phenylketonuria:

- Genetic deficiency in phenylalanine hydroxylase, the enzyme that converts Phe Tyr (autosomal recessive)

- Incidence: PKU appears in about 1 in 10,000 births in Caucasian and East Asians. Some are higher: Turks are 1 in 2600, Irish are 1 in 4500, and some are lower - Japanese 1 in 143, 000. Exceedingly rare in Africans.

- In phenylketonurics, tyrosine is essential

– called conditionally essential

- Accumulation of phenylalanine and its derivatives (e.g. phenylpyruvate is found in high levels in urine)

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- If left untreated, severe mental retardation occurs after birth due to accumulation of Phe in brain – poisons neurons

- Testing of all infants in US and most of Europe began in mid 1960’s

- Testing occur about 48 to 72 hours after birth

- Treatment: Low Phe diet and blood monitoring

- In phenylketonurics, Tyr is an essential amino acid

- Reason for warning label on foods containing NutraSweet

- One of the most thoroughly tested and studied food additives the FDA has ever approved – considered safe for the general population

- Aspartame ingestion does produce methanol, formaldehyde and formate, substances that could be considered toxic, but the levels produced are low.

- No “credible evidence” that there is a link between Aspartame and multiple sclerosis, systemic lupus, Alzheimer’s disease or vision problems.

- Beware what you read on the internet! Not always factual or credible!

TESTING OF INFANTS FOR PKU: