WGU 785 Final Exam
Hemophilia Pedigree - Father has hemophilia, mother does not. What is the outcome for their kids? Correct Answer: His daughters
... [Show More] would be carriers. This is x-link recessive.
Autosomal:
Dominant: Correct Answer: Autosomal: males and females equally affected.
Dominant: non-carrier parents
polymerase chain reaction (PCR) Correct Answer: The process of copying DNA in the lab. Uses Template DNA, Nucleotides (dNTPS), DNA Polymerase, and DNA primers.
3 Steps of PCR Correct Answer: 1. Denaturation: DNA is heated to 95C to separate it.
2. Annealing: reaction is cooled to 50C; primers stick to the DNA you want to copy and add DNA polymerase.
3. Elongation: reaction heated to 70C and DNA polymerase, adding nucleotides building a new DNA strand.
Base Excision Repair (BER) Correct Answer: How you repair a mutation. BER is used to repair damage to a base caused by harmful molecules. You remove the base that is damaged and replace it. *BER removes a single nucleotide*
DNA glycolsylase - sees damaged DNA and removes it.
DNA polymerase-puts the right one back in while DNA ligase seals it.
Mismatch repair (MMR) occurs during: Correct Answer: replication. DNA polymerase proofreads but sometimes a mismatch pair gets through. MMR removes a large section of the nucleotides from the new DNA and DNA polymerase tries again. (Ex: C-T instead of C-A)
Mismatch Repair corrects what kind of DNA damage? Correct Answer: When a base is mismatched due to errors in replication. Such as G-T instead of G-C. DNA polymerase comes by and fixes it.
What happens when DNA polymerase binds to DNA to make RNA? Correct Answer: TRANSCRIPTION! DNA polymerase takes the individual nucleotides and matches them to the parental sequences to ensure a correct pair. It must bind with RNA primer to work.
What is needed for DNA replication? Correct Answer: DNA polymerase
Nonsense Mutation Correct Answer: Change in 1 nucleotide produces a STOP codon Stop= nonsense because it is no more.
Silent Mutation Correct Answer: Change in 1 nucleotide but codes for the same amino acid. Silent= the change doesn't change the name of the protein
Missense Mutation Correct Answer: Change in 1 nucleotide leads to a code for a different amino acid. Missense = mistake was made.
What happends during RNA splicing? Correct Answer: During RNA splicing introns are cut out, the remaining exons are joined together.
5'ATG AGT CTC TCT 3'
Find the DNA template strand. Correct Answer: 3'TAC TCA GAG AGA 5'
The DNA template strand is complimentary. So start with the opposite number, then go L-R with the complimentary letter.
5'ATG AGT CTC TCT 3'
What is the corresonding mRNA sequence? Correct Answer: 5'AUG AGU CUC UCU 3'
This sequence is the same as the coding strand except T changes to U because it is RNA. RNA doesn't have T.
How would a mutation from CTC to ATC affect the protein sequence? (CTC/ATC - coding strand, AUC - mRNA strand) Correct Answer: This will make a missense mutation because it changes the name of the protein. (look at the chart provided.) missense = mistake
DNA replication process Correct Answer: DNA ->Transcription -> RNA -> Translation -> Polypeptide
Describe how you would find what ionized Alanine looks like. Correct Answer: This is an amino acid. Look for the "R" group. Alanine is a hydrophobic amino acid that has CH3. It is a weak interaction. An ionized acid will have a + or - charge.
Describe what causes the misfolding of protein in Alzheimer's Disease. Correct Answer: Protein misfolding is caused by intracellular tangles and extracellular plaques (senile plaques) caused by abnormal protein aggregation.
TAU is fibrous material inside cells where the connections are lost. This becomes defective and forms filaments in the neuron.
Amyloid-Beta is a large precursor protein in the cell. Excess amyloid-beta creates senile plaques. This starts in the hippocampus and moves up.
Describe the process of neurodegenerative protein aggregation. Correct Answer: Alzheimer's is the most common neurodegenerative disease. The formation of aggregated amyloid-beta fibers is another characterisitc of Alzheimer's. However, neurodegeneration and memory loss can be detected before amyloid fibers accumulate in the brain.
What are the molecules that help denatured proteins with folding? Correct Answer: Molecular chaperones are protein helpers. They bind to the newly made polypeptide and enable proper folding. Proper protein folding is vital b/c proteins that do not fold properly can lead to a variety of diseases. Normally, the chaperones that help new proteins fold can also help misfolded proteins refold into the correct structure.
Genetic mutations that substitute one amino acid for another can cause incorrect folding.
What are the 4 levels of protein structure? Correct Answer: 1. Primary-chain of amino acids. PEPTIDE bonds form a polypeptide chain. This is a covalent bond (very strong) and does not denature.
2. Secondary-alpha helix and beta sheet. HYDROGEN bonds that contain the carboxyl group and amino groups. Denatured by salt and pH change.
3. Tertiary-side chain interaction (R group). Changes are seen with high temp, salt, change in pH, and reducing agents. (ex: sickle cell, arthritis, hemophilia)
4. Quarternary-more than 1 polypeptide. Change seen with increased temp. (Ex: Hgb)
Hydrogen bonds are formed from Correct Answer: 2 polar amino acids.
(Contains Oxygen and nitrogen-OH, NH, NH2. On exterior surface)
What structure would be unaffected by complete denaturation of its multi-subunit? Correct Answer: PRIMARY. Peptide bonds are strong and covalent. The primary structure is located at the backbone and does not denature.
What is the simplest way to denature a protein? Correct Answer: Heat it up. The tertiary structure is hydrophobic.
The tertiary structure is a protein structure stabilized primarily by the hydrophobic effect.
What is the secondary structure made up of? Correct Answer: Alpha helixes and beta sheets
Describe what is meant by "induced fit" of a substrate and enzyme. Correct Answer: The substrate and active site are somewhat complementary prior to substrate binding. Many enzymes will adjust their active site conformation slightly as the substrate binds to improve the fit. When the molecule is recognized as the substrate, the enzyme will adjust to form itself around the substrate more tightly to facilitate the reaction it catalyzes.
Describe the Substrate-enzyme complex. Correct Answer: Each substrate binds to an active site, producing an enzyme-substrate complex. The geometric and chemical complement between the enzyme and substrate depend on noncovalent forces.
Describe how the substrate and enzyme react with each other. Correct Answer: Substrate- molecule that an enzyme will bind to preferentially to any other molecule. Each enzyme is specific for that substrate. It will not react with molecules that are not its substrate.
Active site- serves as the binding platform on the enzyme for its specific substrate and acts as the site of the chemical reaction.
Competitive vs Non-competitive Enzyme Inhibition Correct Answer: Competitive inhibitor-usually a molecule similar in structure to a substrate that can bind to an enzyme's active site even though the molecule is unable to react.
Non-competitive-attach to the enzyme at an ALLOSTERIC site, which is a site other than the active site.
Feed back inhibition Correct Answer: Non-competitive inhibition. Once the end product builds up, it will bind to the alloteric site on the first enzyme and stop the pathway. It binds to the enzyme, slowing the product.
How would you find which amino acid is non-polar? Correct Answer: It will contain carbons and hydrogens (CH, CH2, CH3) These are weak interactions that tend to aggregate in the middle of the protein. They will be affected by temperature change.
What part of the phospholipid is hydrophobic? Correct Answer: The tail
Describe peptide bonds. Correct Answer: Peptide bonds form between 2 amino acids by a dehydration reaction. During dehydration, a water molecule forms from the oxygen of a carboxyl group and 2 hydrogens from an amino group. As water forms, the carbon atom of the carboxyl group and the nitrogen atom of the amino group become bonded together. It is the bond b/w 2 amino acids.
How does cooperative binding on hemoglobin occur? Correct Answer: The four subunits of hgb work together. When one molecule of oxygen leaves, the other 3 tend to leave too. When one picks up oxygen, the others tend to pick it up also. (Think of the table and chairs.) This is how oxygen is picked up in the lungs and dropped off in the tissues.
Oxygen will bind quicker to hgb when... Correct Answer: there is another oxygen molecule already binding. This is known as Cooperative Binding.
Explain Carbon Monoxide's affinity for hgb. Correct Answer: CO binds to the same group as oxygen, but binds more strongly. If CO is there, it will pick up the O2 but it will not drop it off. This is why CO poisoning is so harmful. The pt will be very pink in color. CO stabilizes the R-state by binding to the same iron in Hgb and changing the heme shape.
Describe fetal 2,3 BPG and oxygen affinity. Correct Answer: The fetus has a higher affinity for oxygen than mom. The mother's 2,3 BPG is higher so their afinity for oxygen is lower. The mom becomes deoxygenated.
Affinity-stickiness for oxygen.
How is a HGB structure affected by the absence of oxygen? Correct Answer: The structure becomes tense. The heme is dome shaped. pH will be lower. This is found in the muscles.
Describe Hemoglobin Correct Answer: 1. Low affinity for oxygen.
2. Transports oxygen to the tissues.
3. Acts as a buffer and controls pH by binding to H+ ions.
4. 4 protein, 4 Iron/Heme, 4 Oxygen
5. Binds to oxygen at high pH and releases at low pH
6. High affinity for CO
7. Quarternary structure
Describe Myoglobin Correct Answer: 1. High affinity for oxygen
2. Stores oxygen in muscle and releases it when oxygen levels get low
3. Not affected by change in pH
4. 1 protein, 1 iron/heme, 1 oxygen
5. Tertiary structure
How does pH influence the oxygen saturation of hemoglobin? Correct Answer: Left shift: increased affinity for oxygen, increased pH (acidic), weak bond
Right shift: decreased affinity for oxygen, decreased pH, strong bond
Bohr Effect: increase in pH->increased affinity for oxygen->increased Hgb saturation->reach 100% sooner. Oxygen will be distributed better, delivering more or less where we need it.
Cholesterol Correct Answer: 1. 4 Ring structure
2. AKA sterols (cholesterol, cortisol, testosterone)
3. Needed for membrane fluidity (expansion)
4. Increases temp to solidify
5. Needed to synthesize Vitamin D in the skin, cholic acid (component of bile), and steroid hormones.
Steroid Hormones Correct Answer: synthesized by cholesterol;
testosterone and estrogen-promote growth and development of sex characteristics;
cortisol-released in response to stress and promotes glucose synthesis in liver.
How could myoglobin indicate an MI? Correct Answer: Myoglobin is a protein with a single subunit containing both heme and iron. While myoglobin is normally contained only in the muscles, it can be released into the bloodstream if there is muscle damage. For this reason, measuring the levels of myoglobin in the blood can provide evidence of rhabdomyolysis, a mild heart attack, or a muscular degenerative disease.
Describe the Anabolic/Anaerobic Pathway. Correct Answer: Occurs when there is no oxygen. The ETC cannot work. Requires energy to synthesize larger molecules.
NAD+ runs out->fermentation regenerates the NADH to NAD+ ->small amounts of ATP and lactate are made->Cori Cycle in liver
*Ends in -GENESIS-*
Describe the Catabolic Pathway. Correct Answer: generates energy by breaking down larger molecules.
*Ends in -LYSIS-*
What do the Anabolic and Catabolic pathways have in common? Correct Answer: They are both required for maintaining the cell's energy balance.
Describe the Cori Cycle. Correct Answer: The Cori Cycle is part of the anabolic pathway. It uses the lactate made by fermentation in the liver and uses gluconeogenesis to convert 2 lactate to glucose. 2 ATP are made with each cycle, but it uses 6. The net loss is -4 ATP.
Describe fermentation. Correct Answer: Fermentation is the formation of lactate by regenerating the NAD+ from NADH that was used during glycolysis to make small amounts of ATP and lactate. It allows glycolysis to continue in the absence of oxygen.
What does the Cori Cycle supply for red blood cells? Correct Answer: The Cori Cycle supplies glucose for RBCs.
The Cori Cycle takes up lactate from the blood and uses the gluconeogenesis pathway to convert 2 molecules of lactate back to glucose. As the byproduct of anaerobic glycolysis, lactate diffuses into the blood and is taken up by the liver where it is converted back into pyruvate by the enzyme dehydrogenase. The newly formed glucose is released into the blood to be used again for energy by the red blood cells and muscles.
Because there is no oxygen present during the Cori Cycle, pyruvate from glycolysis is converted to lactate. What happens to this lactate? Correct Answer: The lactate made from glycolysis is put into the blood. The liver picks up the lactate and uses gluconeogenesis to convert 2 molecules of lactate into glucose.
Which molecule starts the citric acid cycle? Correct Answer: Acetyl-coA.
Describe the Citric Acid Cycle. Correct Answer: AKA Kreb's Cycle.
Takes in Acetyl CoA, NAD, FAD, and GDP.
Puts out CO2, NADH, FADH2, and GTP.
Takes place in mitrochondria.
A defect in this cycle will cause low levels of ATP.
It can be inhibited by increased levels of NADH d/t feedback inhibition.
What is needed in the Citric Acid Cycle to continue aerobic metabolism? Correct Answer: NADH and FADH2
What is the effect of glucagon on carbohydrate metabolism? Correct Answer: Converts glucose into glycogen for later use during hyopoglycemia. Glycogenesis: the formation of glycogen from sugar.
If oxygen is scarce (anaerobic conditions, ie: exercise), what happens to pyruvate? Correct Answer: Pyruvate will be reduced via an anaerobic pathway by the addition of 2 hydrogen atoms to form lactic acid (lactate). This process is known as fermentation. The formation of lactate regenerates the NAD+ that was used during glycolysis, thus allowing glycolysis to continue making small amounts of ATP for the cell.
RBC rely on _______ as their sole pathway for producing ATP. Correct Answer: glycolysis.
This is because they lack mitochondria (and therefore the citric acid cycle and electron transport chain). They are an example of fermentation.
When there is no more NAD+, fermentation________ Correct Answer: takes NADH from glycolysis to make lactate and NAD+ to put the NAD+ back into glycolysis.
How does insulin manage glucose? Correct Answer: It moves Glut 4 to the membrane of the cell allowing glucose into the cell through facilitated diffusion and active transport. [Show Less]