SCT ONE FLASHCARDS

Question 1

Name all 4 staining techniques for chromosomes

Answer 1

G-banding: Proteolysis + Giemsa
R-banding: Heat + Giemsa
C-banding: Barium Hydroxide + Giemsa
Q-banding: Quinacrine

Question 2

Length and composition of a human gene

Answer 2

27 kilo-base-pairs
9 exons
8 introns

Question 3

All 5 types of genetic alteration

Answer 3

1. Insertion/deletion
2. Tandem repeats
3. Duplication
4. Inversion
5. Translocation

Question 4

3 phases of DNA replication

Answer 4

1. Initiation Phase: at G1
2. DNA Synthesis
3. Termination Phase

Question 5

Which enzyme synthesizes DNA?

Answer 5

1. DNA Polymerase α for 20 nucleotides
2. DNA Polymerase δ + DNA Polymerase ε for the rest

Question 6

Which enzyme unwinds DNA?

Answer 6

Helicase

Question 7

Which enzyme places the RNA primer for DNA polymerase?

Answer 7

RNA Polymerase

Question 8

Which enzyme supports DNA Polymerases?

Answer 8

PCNA

Question 9

Which enzyme joins Okazaki fragments with phosphodiester bond?

Answer 9

DNA Ligase

Question 10

Which enzymes solve the supercoil problem?

Answer 10

Topoisomerase Type 1: cuts one DNA strand, rotates the cleaved strand around the uncleaved strand, then ligates the DNA strands

Topoisomerase Type 2: cleaves both DNA strands to allow free rotation, then ligates them

Question 11

Which enzyme is a reverse transcriptase?

Answer 11

Telomerase Enzyme

Question 12

What are the two main types of mutation?

Answer 12

Point mutation: Alteration of a single nucleotide

Insertion/Deletion (Indel): Insertion or Deletion of one or a few nucleotides

Question 13

What is transition in point mutations?

Answer 13

Transition: purine-purine/pyrimidine-pyrimidine changes

Example: Adenine to Guanine
Example: Cytosine to Thymine

Question 14

What is transversion in point mutations?

Answer 14

Transversion: purine-pyrimidine/pyrimidine-purine changes

Example: Adenine to Cytosine
**Example: Guanine to Thymine

Question 15

Deamination of Cytosine produces?

Answer 15

Uracil - Pairs with Adenine

Question 16

Deamination of Adenine produces?

Answer 16

Hypoxanthine - Pairs with Cytosine

Question 17

Deamination of Guanine produces?

Answer 17

Xanthine - Inhibits DNA Polymerase

Question 18

Name all 5 types of Genotoxic Agents

Answer 18

Carcinogen: Causes tumors
Oncogen: Supports proliferation of tumors
Mutagen: Causes mutations
Teratogen: Causes embryonic abnormalities
Clastogen: Causes chromosomal breaks

Question 19

Name all 4 effects of point mutations in the coding DNA region

Answer 19

Synonymous: different codon, encoding the same amino acid
Non-synonymous: different codon, encoding a different amin aocd
Nonsense: the mutation creates a stop codon
Readthrough: the mutation eliminates a stop codon

Question 20

Name all 3 types of DNA repair

Answer 20

Excision repair: damaged nucleotide is excised (cut), and resynthesized correctly

Mismatch repair: mistmatched nucleotide is excised, and resynthesized correctly

Strand break repair: strand breaks are resynthesized or religated

Question 21

Which enzyme recognize damaged nitrogenous bases in excision repair?

Answer 21

DNA Glycosylase

Question 22

Which enzyme excises the affected DNA strand in excision repair?

Answer 22

AP Endonuclease

Question 23

Which enzyme fills the excised gap in excision repair?

Answer 23

DNA Polymerase β

Question 24

Which complex recognizes the mismatched basepairs?

Answer 24

MSH Protein Complex

Question 25

What’s a primary protein structure?

Answer 25

An amino acid sequence

Question 26

What’s a secondary protein structure?

Answer 26

Locally ordered structural elements

Question 27

What’s a protein motif?

Answer 27

Super-secondary structure, that has a particular function & structure

Question 28

What’s a protein domain?

Answer 28

Similar to motifs, has a broader function and is independently folded

Question 29

What’s a tertiary protein structure?

Answer 29

Spatial conformation of a single polypeptide chain

Question 30

What’s a quaternary protein structure?

Answer 30

Structure of a complex consisting of multiple protein chains

Question 31

What type of amino acids are in living organisms?

Answer 31

α-L-Amino acids

Question 32

What is the structure of a peptide bond?

Answer 32

Rigid and planar

Question 33

Name all 4 chaperones

Answer 33

1. Hsp70
2. Hsp60
3. Protein disulfide-isomerase
4. Peptidyl-prolyl-cis/trans-isomerase

Question 34

Define prion proteins

Answer 34

Are misfolded proteins that induce other proteins (mainly in the brain) to misfold too

Question 35

Name the charged amino acids

Answer 35

LAG

Lysine
Arginine
Glutamate

Question 36

Name the polar amino acids

Answer 36

SHTTAG

Serine
Histidine
Threonine
Tyrosine
Asparagine
Glutamine

Question 37

Write the name of 2,3-BPG

Answer 37

2,3-Bisphosphoglycerate

Question 38

What level of Hb(A1c) is diabetic?

Answer 38

greater than or equal to 6.5

Question 39

What can hemoglobin bind to?

Answer 39

1. Glycated Hemoglobin (N-terminal)
2. CO2 (N-terminal)
3. CO (Heme)
4. O2 (Heme)

Question 40

What’s methemoglobin?

Answer 40

Mutated hemoglobin that contains some ferric-iron that is non-functional

Question 41

What’s hemoglobin S?

Answer 41

Sickle Cell Anemia hemoglobin - BCL11A gene

Question 42

What are the three phases of transcription?

Answer 42

1. Initiation
2. Elongation
3. Termination

Question 43

Name the 3 stop codons

Answer 43

UAA
UAG
UGA

Question 44

Name the start codon

Answer 44

AUG - coding for methionine

Question 45

Name all 3 sites of the ribosome

Answer 45

A-site: aminoacyl-tRNA binding site

P-site: peptidyl-tRNA binding site

E-site: exit site

Question 46

List the 4 steps of translational termination

Answer 46

1. Binding to eRF-1
2. Dissociation of polypeptide chain
3. Release of last tRNA
4. Dissociation from ribosome

Question 47

What does the mitochondrial genome code for?

Answer 47

1. 13 mitochondrial proteins
2. 22 tRNA
3. 2 rRNA

Question 48

What’s the mechanism of the antibiotic chloramphenicol

Answer 48

Prevents the formation of the peptide bond by binding to the transfer site

Question 49

What’s the mechanism of the antibiotic puromycin

Answer 49

Inhibits both prokaryotic and eukaryotic translation by binding to the A-site of the ribosome

Question 50

What’s the mechanism of the antibiotic tetracycline

Answer 50

REVERSIBLY binds to the 30S ribosomal subunit and blocks the binding of the charged aminoacyl-tRNA to the acceptor site

Question 51

What’s the mechanism of the antibiotic streptomycin

Answer 51

Belongs to aminoglycosides; it binds to the 30S ribosome and inhibits the formation of initiation complex by preventing the binding of aminoacyl-tRNA to the A-site of the ribosome

Question 52

Name all 6 types of enzyme catalyzed post-translational modifications and their dependencies

Answer 52

1. Phosphorylation (ATP dependent)
2. Acetylation (AcetylCoA dependent)
3. Ubiquitination (Ubiquitine dependent)
4. Methylation (SAM dependent)
5. Palmitoylation (Plamitoyl-CoA dependent)
6. O-glycosylation (UDP-Gal-Nac dependent)

Question 53

Name all 3 types of non-enzymatic post-translational modifications and their metabolites

Answer 53

1. Oxidation (ROS dependent)
2. Succinylation (Succinate dependent)
3. Glycation (Glucose dependent)

Question 54

Name the 4 structural features required for catalysis

Answer 54

1. Catalytic triad
2. Oxyanion hole
3. Primary substrate binding pocket
4. Main chain structure binding

Question 55

What is one unit (U)?

Answer 55

Amount of enzyme activity needed to catalyze 1 micromole of the substrate per minute at STP

Question 56

What is one katal (kat)?

Answer 56

Catalytic activity that will raise the rate of the reaction by 1 mole per second in a specified assay system

Question 57

What gives the Michaelis-Menten equation validity?

Answer 57

1. Second step of the reaction is irreversible
2. Kinetically stable ES complex formed
3. Concentration of substrate doesn’t change
4. No enzyme-product complex made
5. Only one substrate molecule is bound to the active site of the enzyme

K3 is far smaller than K1 and K2

Question 58

What’s the meaning of Km?

Answer 58

Is the substrate concentration when the rate is half of Vmax

Question 59

What happens to Km and Vmax when a competitive inhibitor is brought in?

Answer 59

Km increases
Vmax stays the same

Question 60

What happens to Km and Vmax when a non-competitive inhibitor is brought in?

Answer 60

Km stays the same
Vmax decreases

Question 61

What happens to Km and Vmax when an uncompetitive inhibitor is brought in?

Answer 61

Km decreases
Vmax decreases

Question 62

What are the two types of homotypic ubiquitin modifications?

Answer 62

Homotypic K48
Homotypic K63

Question 63

Name the three components of the ubiquitin proteasome system

Answer 63

E1 - Ubiquitin activating enzyme
E2 - Ubiquitin conjugating enzyme
E3 - Ubiquitin protein ligase

Question 64

Name the three types of autophagy

Answer 64

1. Macroautophagy: Intracellular components aggregate
2. Microautophagy: directly, molecules are internalized into lysosome
3. Chaperone mediated autophagy: special molecules are involved

Question 65

Name all the regulatory agents for macroautophagy

Answer 65

TOR: Inhibits process
Insulin: Inhibits process
PI3K: Starts process
Glucagon: Starts process

Bcl-2: Phosphorylates
Beclin-1: Is released

Question 66

Name the three types of enzyme regulation

Answer 66

Enzyme amount:
gene expression

Enzyme activity:
1- Modulating the substrate conc.
2- Allosteric effectors
3- Product inhibition
4- Covalent modification

Enzyme localization

Question 67

Classify the regulatory process by its speed and duration

Answer 67

Allosteric: Fastest, but short lasting
Covalent: Intermediate and mid lasting
Gene Level: Slowest, but long lasting

Question 68

Explain the three stages of cellular respiration

Answer 68

1. AcetylCoA yield from carbs, fats, and proteins
2. Kreb’s Cycle to yield 1 NADH + 3 FADH2
3. Oxidation of reduced coenzymes to produce electrons

Electrons are then sent to the Electron Transport Chain to yield ATP

Question 69

Name the 5 cofactors involved in the oxidation of Pyrucate to AcetylCoA

Answer 69

1. FAD (Vit. B2: Riboflavin)
2. NAD (Vit. B3: Niacin)
3. TPP (Vit. B1: Thiamin)
4. CoA (Vit. B5: Pantothenic Acid
5. Lipoic acid (fatty acid)

Question 70

Name the three enzymes that make up the pyruvate dehydrogenase complex

Answer 70

E1 - Pyruvate dehydrogenase (most sensitive)
E2 - Dihydrolipoyl transacetylase
E3 - Dihydrolipoyl dehydrogenase

Question 71

What’s the function of E1 in PDH complex?

Answer 71

Pyruvate Dehydrogenase

1. Decarboxylation of pyruvate with the use TPP/vitamin B1 (Thiamine)
2. Transfers acetyl group onto E2

Question 72

What’s the function of E2 in PDH complex?

Answer 72

Dihydrolipoyl Transacetylase

1. Uses Lipoic Acid and CoA/vitamin B5 (Pantothenic Acid) through transesterification to yield AcetylCoA

Question 73

What’s the function of E3 in PDH complex?

Answer 73

Dihydrolipoyl Dehydrogenase

1. Uses FAD/vitamin B2 (Riboflavin) to reduce FAD to FADH2.
2. Uses NAD/vitamin B3 (Niacin) to dehydrogenate FADH2 forming NADH and FAD

Regenerates the reductive power of FAD

Question 74

What are the main products of the PDH complex reaction?

Answer 74

1. AcetylCoA
2. NADH
3. CO2

Question 75

How is the PDH complex regulated

Answer 75

Negative feedback - the products of the complex inhibit the mechanism when there’s an abundance of products

Question 76

How is the PDH complex regulated allosterically?

Answer 76

High levels of AcetylCoA, NADH, ATP, and Fatty Acids provide negative feedback to the PDH complex

High levels of CoA, NAD, AMP, and Ca2+ provide positive feedback to the PDH complex

Question 77

How is the PDH complex regulated covalently?

Answer 77

Insulin & Glucagon dephosphorylate/phosphorylate the mechanism, respectively.

Ca2+ & Mg2+ activate phosphotases which DEphosphorylates the complex (activates)

Question 78

Where else is the PDH complex located?

Answer 78

The nucleus, where it provides AcetylCoA for the modification of histones

Question 79

What are the final products of the TCA cycle?

Answer 79

1. 3 NADH
2. 1 FADH2
3. 1 GTP

Question 80

Name a terminal electron acceptor in the case of hypoxia/stress

Answer 80

Fumarate

Question 81

Which complex houses cytochrome B and cytochrome C1?

Answer 81

Complex III: Ubiquinone-Cytochrome Oxidoreductase

Question 82

Which complex houses cytochrome A and cytochrome A3?

Answer 82

Complex IV: Cytochrome Oxidase

Question 83

What inhibits ADP Synthase?

Answer 83

Oligomycin

Question 84

What inhibits Adenine Nucleotide Translocase (Antiporter)?

Answer 84

Atractylozide

Question 85

What is the mode of action of the inhibitor Retenone?

Answer 85

Prevents the oxidation of NADH for Complex I (NADH Dehydrogenase)

Question 86

What is the mode of action of the inhibitor Malonate?

Answer 86

Binds to the active site of Complex II (Succinate Dehydrogenase)

Question 87

What is the mode of action of the inhibitor Antimycin A?

Answer 87

Blocks Complex III (Ubiquinone-Cytochrome C Oxidoreductase)

Question 88

What is the mode of action of the inhibitors CO and Cyanide?

Answer 88

Block terminal oxidation, O2 cannot be used as a terminal electron acceptor for Complex IV

Question 89

How much ATP do you get from oxidizing one NADH?

Answer 89

2.5-3 ATP

Question 90

How much ATP do you get from oxidizing one FADH2?

Answer 90

1.5-2 ATP

Question 91

Why is mitochondrial DNA more susceptible to genetic mutations than normal DNA?

Answer 91

Because it does not have a repair system

Question 92

What is the normal blood-glucose range?

Answer 92

~5mM (4.4-6.1mM)

Question 93

Name all the important carbohydrate transporters and their function

Answer 93

GLUT5 → Fructose uptake into enterocyte

SGLT → A symporter (2ndry active transporter), Glucose and Galactose enter the enterocyte only with Na+ coming with it

GLUT2 → Fructose, Glucose, and Galactose transporter from the enterocyte into the blood

Question 94

Name the location of all 5 GLUT proteins

Answer 94

GLUT1 → RBC, Brain, Adipose Tissue
GLUT2 → Liver, Pancreatic β-cells, Kidney, GI
GLUT3 → Brain (neurons)
GLUT4 → Muscle, adipose tissue (insulin dependent)
GLUT5 → Fructose transporter

Question 95

What’s the role of GLUT2?

Answer 95

Help regulate blood-glucose levels by being activated at 15-20mM - Liver stores glucose as glycogen, pancreas release insulin, and kidney works harder idk

Question 96

Where does Glycolysis take place?

Answer 96

Cytoplasm

Question 97

What happens to pyruvate (product of glycolysis) in anaerobic conditions?

Answer 97

It is converted to lactate, and forms net 2 ATP only

Question 98

When is glucokinase or hexokinase used?

Answer 98

Hexokinase at low Km of blood-glucose
Glucokinase at high Km of blood-glucose

Question 99

Which steps of glycolysis are regulated?

Answer 99

Step 1: Glucose → Glucose-6-Phosphate (Hexokinase/Glucokinase)
Step 3: Fructose-6-Phosphate → Fructose-1,6-Bisphosphate (Phosphofructo Kinase)
Step 9: Phosphoenolpyruvate → Pyruvate (Pyruvate Kinase)

• Most kinases except Phosphoglycerate Kinase

Question 100

How is step 1 of glycolysis regulated?

Answer 100

Glucose-6-Phosphate grants negative feedback to the reaction, inhibiting Hexokinase

If Glucokinase is used, Fructose-6-Phosphate will grant negative feedback instead.

Question 101

Name the types and location of the aldolases

Answer 101

1. Type A Aldolase: Muscle - Glycolysis
2. Type B Aldolase: Liver - Glycolysis, Gluconeogenesis
3. Type C Aldolase: Brain - Glycolysis

Question 102

Which step is effected by low levels of NAD+ in glycolysis?

Answer 102

Glyceraldehyde-3-Phosphate → 1,3-Bisphosphoglycerate
Glyceraldehyde-3-Phosphate Dehydrogenase

• NAD+ → 2x NADH

Question 103

How can RBCs have a higher affinity to release oxygen into tissue?

Answer 103

By binding to 2,3-Bisphosphoglycerate, 15-20% of glucose in RBCs is converted to this substance, which is a side reaction of the reaction between 1,3-Bisphosphoglycerate and 3-Phosphoglycerate

This forfeits the ATP production