AA, peptides, proteins Flashcards
(40 cards)
What are the 5 major classifications for amino acids?1
nonpolar/alphatic, aromatic, polar uncharged, polar and positively charged, polar and negatively charged
Do you remember the 6 nonpolar, aliphatic amino acids?
glycine, alanine, valine, leucine, methionine, isoleucine (listed in increasing hydrophobicity)
Do you remember the three aromatic amino acids?
Tyrosine, tryptophan, phenylalanine (listed in increasing hydrophobilicty
Do you remember the 6 polar uncharged amino acids?
Proline, Glutamine, Asparagine, cysteine, serine, threonine.
Do you remember the 3 polar positively charged amino acids?
Histidine, Lysine, Argenine.
Do you remember the 2 polar negatively charged amino acids?
Aspartate, Glutamate
What is the function of disulphide bonds within a protein?
Under oxidizing conditions disulphide bonds can be made. Disulphide bonds a an important contributor to tertiary protein structure. Examples, RNAase, and insulin molecules.
What are the main post translational modifications that are done to proteins?
(6)
- hydroxyproline,
- gamma carboxy glutamate,
- glycosylation of Ser or Thr or asn
- acetylation or methylation (modification of side chains),
- phosphorylation of dephos. of Ser, Thr, Tyr
- Ubiquitination
What is the medical significance of hydroxyproline modification?
Is very abundant in collogen. Vitamin C is required for the enzyme that hydroxyalates the proline. This is why Vitamin C deficiency causes scruvy
What is the medical significance of the gamma carboxyglutamate
present in proteins involved with blood clotting pathway. The enzyme that does this carboxylation requires Vitamin K so Vitamin K deficiency can lead to bleeding disorders. The drug Warfarin, or coumadin, inhibits this carboxylation, which is why it is considered a blood thinner
What is the medical significance of glycosylation
O-linked added to Ser or Thr, N-linked added to asn
Many secreted or cell surface proteins are glycosylated.
1. This can protect protein stability, (in plasma for example)
2. make it more soluble (it is a charged addition)
3. can also be important for recognition of other factors.
4. Congenital disorder of glycosylation (defect in unglycosylation pathway). (symptoms can include psychomotor retardation, seizures)
What is the medical significance of acetylation and methylation
Acet of lysine, methyl of lysine and argenine.
These AAs are very abundant in histones. Acetylation and methylation of these two AAs, affect txn regulation. When it is deregulated by drugs, you
can cause cells, like cancerous cells to do apoptosis.
What is the medical significance of phosphorylation
of Ser, Thr, Tyr, A major way to transduce signals in cells. For example, Gleevec, a bcr-abl tyrosine kinase inhibitor used to treat chronic myelogenous leukemia (CML)
What is the medical significance of Ubiquitination
adding of ubiquitin (a small protien) added to lysines by ubiquitin ligases. Polyubiquitination of a protein targets this protein for degredation by proteosomes. Bortezomib, used to treat multiple melanoma. inhibits proteosome by targeting this ubiquitin pathway.
What are the three bonds that make up the backbone of a polypeptide chain?
- Bond between AlphaC of residue1 to Carbonyl carbon of residue1
- peptide bond between carbonyl carbon of residue1 and amide nitrogen of residue2
- bond between amide nitrogen of residue2 and alpha carbon on residue2
Of the three bonds that make up a polypeptide chain backbone, which ones can and cannot rotate?
the peptide bond has partial double bond characteristics and cannot rotate. the other two bonds can rotate.
What determines the function of a protein?
the amino acid sequence, because that determines the structure of the protein
What are some examples of proteases and the specific breaking of peptide bonds that have important functions.
Some proteases chew all proteins (trypsin, chymotrypsin, pepsin)
Understand that the amino acid sequence determines the function; mutations in amino acid sequence can cause genetic disease.
sickle cell anemia, and E6V mutation causes the sickle shape, leading to severe anemia. However, there are many proteins that are polymorphic, meaning you can have slightly different AA sequences and still have a perfectly functional protein (if a hydrophobic residue which out any special function is replaced by another hydrophobic residue of approximately the same size, it probably would not affect protein structure, thus its function.
Describe hydrogen bonds and their role in secondary structure formation.
Hydrogen bonds are interactions between hydrogen donors and acceptors (usually N and O in proteins). 1. H bonds between backbones are important in formation of beta sheets.
- Beta turns are also stablized by carbonyl O of 1st residue, and Amide proton of 4th residue
- Alpha helices are stablized by H bonds from CO of residue n and NH of residue n+4.
Describe two major types of protein secondary structures.
- Alpha helices: Right handed helical structure, H bonds between n CO and n+4 NH. Alanine and leucine have higher tendancy to form A.helices, Proline and glycine cannot form them. Example: hemaglobin
- Beta sheets: parallel or antiparallel sheets, H bonds between backbone. Example, immunoglobulins
Side note: circular dichroism is a good way to measure secondary structure of a protein
. What is the difference between a tertiary and Quaternary structure?
Tertiary structure is the overall spacial arrangement of a single polypeptide chain. Quaternary structure is a complex of multiple polypeptide chains, and their interactions and overall spacial arrangement
Explain the role of loops in protein structure and function.
This is how protein backbone changes direction! Glycine and proline are often found in loops.
They also have functional functions. Loops in antibody proteins at the tip of the variable domain, can bind antigens.
Explain how to use Kd to represent binding strength.
For proteins, such as globular proteins, that have to interact with or bind other molecules, Kd, the dissociation constant, is a measure of binding strength. The binding specificity and strength is achieved through the lock and key complementary model or the induced fit model.
Examples: Hemoglobin binds a heme which allows it to bind oxygen. but It has a higher Kd for carbon monoxide, so it preferentially binds to it. different structures of hemoglobin also have different Kds for oxygen. This allows it to transport O2, as opposed to myoglobin which can only store O2, because it lacks the different conformations with different Kds
