CMB self-study

Question 1

Prokaryotes vs Eukaryotes

Answer 1

Prokaryotes: no membrane enclosed organelles, chromatin in nucleoid Eukaryotes: membrane bound organelles and vesicles, nuclear membrane

Question 2

Purines

Answer 2

Adenine (A) Guanine (G)

Question 3

Pyrimidines

Answer 3

Cytosine (C) Thymine (T) in DNA only Uracil in RNA only

Question 4

Nucleotide bonding

Answer 4

A bonds with T or U (2 bonds) and C bonds with G (3 bonds)

Question 5

Nucleosides

Answer 5

Purines and pyrimidine bases + pentose (deoxyribose or ribose)

Question 6

Nucleotides

Answer 6

Phosphorylated nucleosides (5’ -OH of ribose or deoxyribose is phosphorylated)

Question 7

Oglionucleotides

Answer 7

Short polymers of nucleotides (up to 30)

Question 8

Role of Mg2+ and other cations

Answer 8

Shield phosphate groups from electrostatic intrastrand repulsion (balance the negative charges)

Question 9

Why is circular DNA an advantage?

Answer 9

May provide protection from degredation by exonucleases

Question 10

Active site

Answer 10

Includes substrate-binding site and catalytic site

Question 11

Substrate-binding site

Answer 11

Determines specificity

Question 12

Catalytic site

Answer 12

Contains catalytic residues which act on the substrate

Question 13

-ase usually means

Answer 13

enzyme

Question 14

B-DNA

Answer 14

Conformation primarily found in cells

Question 15

A-DNA

Answer 15

Form taken by DNA-RNA hybrid during transcription

Question 16

Z-DNA

Answer 16

Occurs within DNA sequences that control gene transcription

Question 17

Causes of denaturation

Answer 17

Extreme pH, extreme ionic strength, high temp

Question 18

Type I isomerases

Answer 18

Break only one DNA strand and allow it to rotate about the other to relieve supercoil. Also reseal (ligate) break

Question 19

Type II isomerases

Answer 19

Act as ATPases-Using ATP, break both DNA strands, relax supercoil, reseal DNA

Question 20

What are gyrases?

Answer 20

Topoisomerases which relieve supercoiling from unwinding of DNA. Prevent supercoiling that would be induced by unwinding DNA in DNA synthesis

Question 21

Nalidixic acid

Answer 21

Antibiotic used for antibotic resistant UTIs. Inhibit gyrases and interferes with breaking and rejoining of DNA

Question 22

Novobiocin

Answer 22

Antibiotic which blocks the binding of ATP (which blocks type II isomerases)

Question 23

Cruciforms

Answer 23

Regions of DNA which interchain hydrogen bonds are broken and intrachain bonds form. Function in the control of replication and transcription

Question 24

Triplex DNA functions and bonding

Answer 24

Triple stranded DNA. Usually in regions with string of purine bases. Functions in transcription control, initiation and termination of replication by enhancing stability of chromosome ends called telomeres. Forms hydrogen bonds with major groove of B-DNA with Hoogsteen pairing.

Question 25

What is triple-stranded DNA associated with?

Answer 25

Hereditary persistance of fetal hemoglobin. Mutation prevents the triple stranded DNA from forming and fetal hemoglobin to continues to be transcribed

Question 26

Hoogsteen pairing

Answer 26

Occurs on different faces of DNA than Watson and Crick pairing

Question 27

Quadruplex DNA

Answer 27

Forms in immunoglobin genes that undergo recombination. Responsible for antibody diversity. Also present at the telomeres.

Question 28

Histones (types, function)

Answer 28

Eight proteins (2 each of H2A, H2B, H3, H4) combine to form a histone disk octamer around which DNA supercoils. Interact with highly acidic phosphate residues of DNA in minor groove. H1 is not part of the octamer and functions to stabilize the DNA around the octamer. Histone genes have NO INTRONS.

Question 29

Nucleosomes

Answer 29

1 _ turns of DNA with the histone disk but no H1

Question 30

Chromatosomes

Answer 30

2 full turns of DNA with the histone disk + H1

Question 31

Linker DNA

Answer 31

Between nucleosomes

Question 32

Nucleofilament

Answer 32

Linear arrays of nucleosomes and chromatosomes

Question 33

Heterochromatin vs Euchromatin

Answer 33

Heterochromatin is tightly packed and euchromatin is loose-more accessible and transcriptionally active

Question 34

What do prokaryotes have instead of histones?

Answer 34

HU proteins

Question 35

Prokaryote chromasome structure

Answer 35

One circular double stranded supercoil chromasome

Question 36

Nucleoids

Answer 36

Bacterial chromosomes are compacted into ________ by interaction with HU proteins, cations, polyamines, RNA, and other nonhistone proteins

Question 37

Palindrome

Answer 37

Each DNA strand is self-complimentary within the inverted region that contains the symmetry elements

Question 38

Mirror repeat

Answer 38

Identical base pairs equidistant from center of symmetry within DNA segments

Question 39

Direct repeat

Answer 39

Particular sequence repeated

Question 40

Size of human genome

Answer 40

3.5x109 bp

Question 41

Function of primer

Answer 41

Provides free -OH group to which nucleotides can be added

Question 42

What is released as nucleotides are added to growing DNA strand?

Answer 42

Pyrophosphate (PPi) is released whenever phosphodiester bonds are formed

Question 43

Which end of the strand are nucleotides added to?

Answer 43

3’ end

Question 44

How are primers removed?

Answer 44

Exonuclease activity removes primer nucleotides in 5’ to 3’ direction

Question 45

Helicases

Answer 45

Unwind the DNA strands to allow them to separate

Question 46

Single-stranded binding proteins (SSB)

Answer 46

Bind to DNA to keep the two strands from annealing

Question 47

Types of prokaryotic DNA polymerases and functions

Answer 47

3 types: Pol I, Pol II, Pol III. All have 3’–>5’ exonuclease proofreading activity. Pol I (intermediate processivity) synthesizes lagging strand and only one capable of primer removal (5’–>3’ exonuclease activity). Pol II (low processivity) involved in DNA repair. Pol III (high processivity) synthesizes leading strand.

Question 48

Sliding clamp

Answer 48

Donut shaped protein complex which encircles DNA strands. Prevents Pol III from detaching from the template until replication complete. Reason why Pol III has high processivity.

Question 49

Processivity

Answer 49

Ability of the enzyme to remain on its substrate during synthesis

Question 50

Replisome complex

Answer 50

Includes primosome, SSB proteins, Pol I and Pol III, other molecules needed for DNA replication

Question 51

Primosome

Answer 51

Primases, ligases, helicases, and other proteins that bind to the origin of replication and are necessary for synthesizing the primer

Question 52

Replicons

Answer 52

DNA segments between the origins of replication

Question 53

Differences between prokaryote and eukaryote DNA synthesis

Answer 53

Eukaryotic DNA is much larger, packed into chromatin, and have lower rates of replication fork movement than in prokaryotes

Question 54

Cell cycle order and events

Answer 54

M, G1, S, G2. Mitosis is where cell division occurs. In G1 cell increases in size and makes extra proteins, organelles–G1 checkpoint makes sure cell ready for S phase. In S DNA replication occurs. In G2 rapid cell growth and protein synthesis–G2 checkpoint makes sure cell ready to divide. Also can leave G1 and go into G0 resting phase when the cell has stopped dividing.

Question 55

Cyclin-dependent kinases (CDK)

Answer 55

Controls the cell cycle by initiating cell division and DNA replication

Question 56

Cyclins

Answer 56

Protein substrates of CDKs and activate them

Question 57

Types of eukaryotic DNA polymerases and functions

Answer 57

2 types: _ and _. Polymerase _ (low processivity) synthesizes lagging strand, functions as a primase, and disassembles nucleosome prior to DNA replication. Polymerase _ (high processivity) synthesizes the leading strand, serves as 3’–>5’ exonuclease proofreader.

Question 58

Proliferating cell nuclear antigen (PCNA)

Answer 58

Serves as a clamp to kee the polymerase _ enzyme from dissociating. ::homologous to the sliding clamp in prokaryotes::

Question 59

Replication protein A (RPA)

Answer 59

Bind to DNA to keep the two strands from annealing ::homologous to the SSB proteins in prokaryotes::

Question 60

When does synthesis of histones occur?

Answer 60

During S phase, simultaneous to DNA replication

Question 61

Reverse transcriptases

Answer 61

Enzymes that use RNA as a template for DNA synthesis (RNA dependent DNA polymerase)

Question 62

Telomerase (definition, structure, and function)

Answer 62

Reverse transcriptase that replicates the telomeres. Contains RNA as part of its structure so functions as a template and an enzyme during replication. No proofreading so most error-prone of the DNA polymerases.

Question 63

Retroviruses

Answer 63

Genomes are RNA. During viral infection RNA is copied into DNA and transcribed to produce more viruses.

Question 64

AZT

Answer 64

Inhibits reverse transcriptases. Structural analog of dT, converted to triphosphate and incorporated into viral genome in place of dTTP (AZT competes and has a higher binding affinity than dTTP). Once incorporated into viral DNA, AZT causes premature termination of viral DNA synthesis because it lacks the 3’ -OH site needed for the addition of nucleotides.

Question 65

3 types of recombination

Answer 65

1. Homologous: occurs between homologous DNA on the same chromosome during prophase of meiosis. 2: Conservative site-specific recombination: insertion of bacteriophage DNA into bacterial genome. Homology is not required. Double stranded DNA is inserted at specific sites. 3: Transposition: Jumping genes which move from one site to another within a chromosome. May activate or inactivate gene if inserted into coding sequence. This can make bacteria antibiotic resistant by carrying transposons on plasmids (which can replicate independent of organism’s DNA).

Question 66

Types of RNA modified bases:

Answer 66

1. pseudouridine 2. dihydrouridine 3. methylated bases: methylguanosine, dimethylguanosine, methylinosine 4. ribothymidine

Question 67

Hairpins

Answer 67

Single stranded RNA makes these by base pairing with itself

Question 68

mRNA in prokaryotes

Answer 68

Polycistronic: can code for more than one protein

Question 69

Cistron

Answer 69

Segment of DNA that contains all of the information for production of a single polypeptide

Question 70

mRNA in eukaryotes

Answer 70

Mostly monocistronic: can only code for one polypeptide

Question 71

mRNA half-life

Answer 71

Shortest of the RNAs (mins to several hours). Exceptions: mRNA in unfertilized eggs (dormant until fertilization) and mRNA that codes for hemoglobin in reticulocytes (very stable).

Question 72

Post-translational modifications to mRNA

Answer 72

1. Inverted methylated base 5’ cap: inverted from 5’ phosphate to 5’ phosphate linkage with 1st nucleotide (often methylated purine) instead of usual 3’,5’ phosphodiester bond. 2. Poly A tail: 20-200 adenine nucleotides, length of tail determines stability. Histone mRNA lacks poly A tail.

Question 73

Shine-Dalgarno sequence

Answer 73

Untranslated leader sequence following the 5’ cap in prokaryotic mRNA. There is also a nontranslated sequence following the stop codon.

Question 74

Kozak sequence

Answer 74

Untranslated leader sequence following the 5’ cap in eukaryotic mRNA. There is also a nontranslated sequence following the stop codon.

Question 75

Stop codons

Answer 75

UAA, UAG, UGA

Question 76

Start codon

Answer 76

AUG

Question 77

Amounts of each type of RNA in cells

Answer 77

80% rRNA, 15% tRNA, 1% mRNA, the rest is other RNA

Question 78

tRNA structure

Answer 78

Cloverleaf with 2 active sites: 1. Acceptor stem 3’ -OH terminal CCA where amino acids attach 2. Anticodon loop which recognizes codons on the mRNA.

Question 79

tRNA activation and functions

Answer 79

Needs to be activated (aminoacylated) by aminoacyl-tRNA synthetase. Has 2 functions: 1. Activate the amino acids for protein synthesis which occurs on the ribosome by binding to the acceptor stem 2. Recognize codons to ensure correct amino acid incorporated into the polypeptide chain using the anticodon loop

Question 80

rRNA structure

Answer 80

Two components: large and small particles which are named according to sedimentation coefficient during centrifugation calculated in Svedberg units.

Question 81

Small nuclear RNA (snRNA)

Answer 81

Recognizes introns on mRNA participating in splicing

Question 82

Small cytoplasmic RNA (scRNA)

Answer 82

Involved in selection of proteins for export where it serves as signal recognition particle

Question 83

Mitochondrial RNA (mtRNA)

Answer 83

Include mRNA, tRNA, and rRNA transcribed from mitochondrial DNA. Only one tRNA for each amino acid.

Question 84

Ribonucleoprotein particles (RNP)

Answer 84

Small RNA/protein molecules which function in RNA processing, splicing, transport, control of translation, and protein recognition particles that target proteins for export. The RNA component of the RNP is a ribozyme.

Question 85

Ribozymes

Answer 85

RNA enzymes

Question 86

Ribonuclease P (RNase P)

Answer 86

True enzyme which cleaves pre-tRNA to generate mature 5’ terminus of tRNA

Question 87

RNAi

Answer 87

Control cell’s phenotype by shutting down developmental genes or altering levels of expression. Control cellular differentiation.

Question 88

In what direction is DNA read? What direction are DNA and RNA transcribed?

Answer 88

DNA is read in the 3’–>5’ direction. DNA and RNA are transcribed in the 5’–>3’ direction

Question 89

Pribnow box

Answer 89

Found at the -10 region with the sequence TATAAT. Recognized by the RNA polymerase which attaches before the beginning of transcription.

Question 90

Differences between DNA and RNA polymerases

Answer 90

RNA polymerases requires DNA template but no primers. RNA polymerases have no proofreading ability.

Question 91

Structure of RNA polymerase

Answer 91

Holozyme consists of all 6 subunits: two _, _, _’, _ (omega), _ (sigma). Without _ called the core enzyme.

Question 92

RNA polymerase _ subunit function

Answer 92

Recognizes the promoter and then is released as the RNA polymerase begins to synthesize the RNA

Question 93

Types of RNA polymerases and inhibitor sensitivity

Answer 93

3 nuclear (I,II,III) and 1 mitochondrial type. Distinguished by sensitivity to amanitin (mushroom poison)/rifampicin (antibiotic).

Question 94

RNA polymerase I

Answer 94

Produces rRNA, insensitive to _-amanitin. Synthesizes a single transcript of the rRNA subunits at the same time to form pre-RNA (this ensures equal molar amounts of each subunit).

Question 95

RNA polymerase II

Answer 95

Produces mRNA, very sensitive to _-amanitin. Present in the nucleus.

Question 96

RNA polymerase III

Answer 96

Produces tRNA, sensitive to _-amanitin. Present in the nucleus.

Question 97

Mitochondrial RNA polymerase

Answer 97

Produces all kinds of RNA, insensitive to _-amanitin but sensitive to rifampicin

Question 98

Rifampicin as a drug

Answer 98

Treats Mycobacterium tuberculosis by inhibiting prokaryotic RNA polymerase by binding to the _ subunit.

Question 99

rRNA gene location

Answer 99

Nucleolar organizer region of the nucleolus. Several hundred copies of each rRNA gene separated by spacer sequences.

Question 100

3 general modifications of the RNA primary transcript

Answer 100

1. Removal of external (terminal sequences) and internal (spacer sequence) nucleotides by ribonucleases 2. Base modification 3. Addition of nucleotides

Question 101

Post-translational modifications to tRNA

Answer 101

1. 5’ end removed by ribonuclease P (ribozyme) 2. 3’ end removed and terminal CCA is synthesized 3. Nucleotide bases modified (tRNAs contain the most modified bases of all nucleic acids)

Question 102

Splicing (proteins involved, details, important sequences)

Answer 102

Small nuclear ribonucleoproteins called snRNPs (snurps) remove introns from pre-RNA. Break RNA at the 5’ end of intron and join exons. All introns begin with GU (donor site) and end with AG (acceptor site) but not all GU or AG sequences are splice sites. U1RNA, U2RNA, and snurps discriminate the splice sites.

Question 103

tRNA half-life

Answer 103

about 5 days

Question 104

What makes the genetic code degenerate?

Answer 104

Amino acids have more than one codon except for Met and Trp

Question 105

Which amino acids have only one codon

Answer 105

Met (methionine) and Trp (tryptophan)

Question 106

Why no wobble effect with G at 3’ position?

Answer 106

Makes sure there is no ambiguity coding for the stop codon, Trp, or Met

Question 107

Aminoacyl-tRNA synthetase functions

Answer 107

Catalyze two reactions and has proofreading ability 1. Activation of amino acid with ATP forming the aminoacyl group 2. Transfer of the aminoacyl group to the tRNA

Question 108

Methionyl-tRNAs in prokaryotes

Answer 108

1. Initiator tRNA: fMet-tRNA has formylated Met group and initiates protein synthesis 2. Carries Met for other positions in the protein (not formylated)

Question 109

Methionyl-tRNAs in eukaryotes

Answer 109

No formylation of Met so all methionyl tRNAs are identical

Question 110

Steps of protein synthesis

Answer 110

1. Initiating fMet-tRNA (prokaryotes) moved to P (peptidyl) site of ribosome small subunit 2. Large ribosome subunit joins complex 3. Peptidyltransferase transfers the initiating fMet-tRNA (prokaryotes) to E (exit) site and 2nd amino acid in sequence placed in the A (aminoacyl) site on ribosome 4. Peptide bond forms between amino acids 5. Elongation occurs until stop codon reaches the A site (no aminoacyl-tRNA binds with these codons).

Question 111

Attachments on an amino acid

Answer 111

Carboxylic group (-COOH), Amino group (-NH2), Hydrogen (-H), specific side chain (-R)

Question 112

What isomer of amino acids are in humans?

Answer 112

L amino acids (usually rotate polarized light to the left but not always)

Question 113

Characteristics of peptide bond

Answer 113

Characteristics of a double bond so no rotation about the C-N, but _ carbons can rotate

Question 114

Peptides vs proteins

Answer 114

Peptides are < 50 amino acids, proteins are > 50 amino acids

Question 115

Disulfide bond role

Answer 115

Stabilize protein structure and involved in oxido-reductive reactions

Question 116

Glutathione

Answer 116

Most important agent that fights reactive oxygen species. Composed of Glu-Cys-Gly. When membrane proteins get oxidized, glutathione reduces them.

Question 117

Henderson-Hasselbalch equation

Answer 117

pH=pK + log (A-/HA) In bicarbonate buffer system equation is pH=pK + log (HCO3-/H2CO3) Increase in HCO3- causes pH to rise.

Question 118

Primary protein structure

Answer 118

Order of amino acid residues

Question 119

Secondary protein structure

Answer 119

Local 3D folding of the chain

Question 120

Tertiary protein structure

Answer 120

3D structure of the protein which folds into domains. Hydrophobic side chains are inside away from water and hydrophilic side chains are on the outside and interact with water. Structure stabilized by noncovalent electrostatic, hydrophobic, hydrogen, and disulfide bonds.

Question 121

Quarternary protein structure

Answer 121

non-covalent association of discrete polypeptide subunits into a multi-subunit protein. Subunits are noncovalently attached. ::not all proteins have a quarternary structure::

Question 122

Protein secondary structure types

Answer 122

_-helix, _-pleated sheet, _-turn, random coil. Side chains do not participate in formation of secondary structures.

Question 123

_-helix

Answer 123

L-amino acids form right handed _-helices. Kept together by H-bonds between carbonyl (C=O) groups and imino (N-H) groups directly above or below each other (~every 4th amino acid)

Question 124

_-pleated sheet

Answer 124

Two polypeptide chains are aligned paralell or antiparalell. H-bonds between carbonyl (C=O) groups and imino (N-H) groups between adjacent chains.

Question 125

_-turn

Answer 125

Reverse the direction of the polypeptide chain allowing the chain to form compact globular proteins

Question 126

random coil

Answer 126

Anything that doesn’t fit in the other secondary structure categories. Less ordered structure. Functional and found in binding sites or active centers of proteins.

Question 127

Advantages of quarternary structure

Answer 127

Stability, genetically economical (in homomultimers only one gene needed to code for a complex protein), efficiency (active sites brought in close proximity and substrate channeled from one subunit to the other without diffusion and/or transport), cooperativity

Question 128

Native structure

Answer 128

Final conformation of the protein which is the most stable (disulfide bonds form to help stabilize)

Question 129

Chaperones

Answer 129

Belong to Heat Shock Protein family. Synthesis increases at high temps. Required for refolding proteins as they cross membranes, assembling proteins with multiple polypeptide chains (quarternary structure), and facilitating protein transport into the mitochondria and endoplasmic reticulum

Question 130

4 types of bonds that stabilize proteins

Answer 130

1. Disulfide bonds: covalent linkages between -SH groups in cysteines to produce cystine (called a sulfide bridge) 2. Hydrophobic interactions: hydrophobic groups on inside of protein 3. Hydrogen bonds: between amino acid side chains and stabilize tertiary structure 4. Ionic (electrostatic interactions): salt bridges and can be repulsive or attractive–formed between positively and negatively charged side chains

Question 131

Denaturation

Answer 131

Disrupts all but the primary structure. Occurs due to strong acids, strong bases, heating above 60 degrees C, or by adding denaturants like urea or detergents like SDS or guanidine. In cell leads to enzymatic removal of protein.

Question 132

Alzheimers

Answer 132

Proteins fold in abnormal way and form aggregate long, fibrillar protein assemblies called amyloids

Question 133

Creutzfeldt-Jakob disease

Answer 133

Nervous system dysfunction including ataxia, dementia, and paralysis and almost always fatal. Fibrous amyloid plaques develop in brain and cause degeneration caused by misfolding in the prion protein from soluble to insoluble conformation. Normal protein has 3 alpha helical and 2 small beta strand segments–change results in conversion of 2 alpha helices to beta strand conformations which polymerize.