ch15: genes and how they work

Question 1

the neurospora will only grow if

Answer 1

it can make arginine

Question 2

If the gene mutated was arg H, would the cells grow if
you supplemented the media with Arginosuccinate?

Answer 2

no

Question 3

If the gene mutated was arg E, would the cells grow if
you supplemented the media with Arginosuccinate?

Answer 3

yes

Question 4

one gene/one polypeptide hypothesis

Answer 4

many proteins are made from multiple polypeptide stands (ex. hemoglobin)

Question 5

central dogma

Answer 5

information only flows from DNA to RNA to protein
transcription: DNA to RNA
translation: RNA to protein

Question 6

transcription (3)

Answer 6

• DNA directed synthesis of RNA
• only one strand of the DNA is used (template strand)
• T in DNA replaced by U in RNA

Question 7

translation (3)

Answer 7

• mRNA produced from transcription used to direct synthesis of polypeptides
• takes place at ribosome (RNA protein complex)
• required several kinds of RNA

Question 8

stop codons

Answer 8

three codons (UUA, UGA, UAG) used to terminate translation (dont code for an amino acid)

Question 9

start codon

Answer 9

codon (AUG) used to signify the start of translation; codes for the amino acid methionine as well

Question 10

code is degenerate, meaning that

Answer 10

some amino acids are specified by more than one codon (64 codons, only 20 amino acids)

Question 11

DNA template strand

Answer 11

the template by which the RNA sequence is made

Question 12

DNA coding strand

Answer 12

has the same nucleotide sequence as the RNA sequence (except I instead of T)

Question 13

upstream

Answer 13

closer to the 5’ end of the coding strand than the start site (numbered -1, -2, -3, etc)

Question 14

downstream

Answer 14

closer to the 3’ end of the coding strand than the start site (numbered +2, +3, +4, etc)

Question 15

core enzyme

Answer 15

drives RNA synthesis

Question 16

sigma factor

Answer 16

helps RNA polymerase recognize the beginning of genes

Question 17

only complete core enzyme and sigma factor can

Answer 17

properly initiate RNA synthesis

Question 18

initiation

Answer 18

RNA polymerase finds and binds to promotor region of gene

Question 19

elongation

Answer 19

the RNA transcript is synthesized from the DNA template

Question 20

termination

Answer 20

specific termination sequences cause the RNA polymerase to stall and then stop transcription, releasing the RNA transcription

Question 21

promotor

Answer 21

short sequence upstream of the start site

Question 22

start site

Answer 22

first base transcribed into RNA

Question 23

promotor forms a

Answer 23

recognition and binding site for the RNA polymerase

Question 24

1) prokaryotic initiation of transcription (5)

Answer 24

• -35 sequence binds to sigma subunit
• DNA helix unwinds at TATAAT box (AT rich region)
• RNA polymerase binds to the unwound DNA
• RNA transcription begins at the start site (+1)
• sigma factor released (no longer needed)

Question 25

2. prokaryotic elongation of transcription (3)

Answer 25

• grows in the 5’ to 3’ direction as ribonucleotides are added onto the 3’ end
• transcription bubble: unwound section of DNA template, where RNA transcription occurs
• after transcription bubble passes, the now-transcribed DNA is rewound as it leaves the bubble

Question 26

3) prokaryotic termination of transcription (4)

Answer 26

• signal “stop” to the RNA polymerase
• RNA transcript is released
• RNA polymerase releases DNA
• DNA rewinds back into helix

Question 27

prokaryotic transcription (3)

Answer 27

• single RNA polymerase
• initiation of mRNA synthesis does not require a primer
• requires a transcription unit (promotor, start site, termination site)

Question 28

how is eukaryotic transcription different (3)

Answer 28

1. initiation: requires a series of transcription factors
2. elongation: no difference from prokaryotes
3. termination: termination sites not as well defined; RNA transcript is modified after transcription

Question 29

in eukaryotes, how is the primary transcript modified to become mature mRNA (3)

Answer 29

1. addition of a 5’ cap: protects from degradation; involved in translation initiation
2. addition of a 3’ poly-A tail: created by poly-A polymerase; protection from degradation
3. removal of non-coding sequences (introns): pre-mRNA splicing done by spliceosome

Question 30

introns

Answer 30

non-coding sequences

Question 31

exons

Answer 31

sequences that will be translated

Question 32

primary mRNA need to be processed to get mature mRNA, how is the pre-mRNA processed

Answer 32

by splicing out the introns, making sure that only the exons (coding sequences) will be translated

Question 33

small ribonucleoprotein particles (snRNPs)

Answer 33

a complex of proteins and snRNA that recognizes the intron-exon boundaries

Question 34

introns always begin and end with

Answer 34

the same 2-base sequence (recognition)

Question 35

snRNPs bind to the

Answer 35

beginning of the intron and a branch site within the intron

Question 36

spliceosome

Answer 36

the splicing organelle responsible for removing introns

Question 37

most introns are labeled with a GU at the beginning and an AG at the end. what would that mature mRNA look like if one of these bases were mutated

Answer 37

wherever that mutation is on the mRNA, that intron stays in along with the exons that are supposed to be there

Question 38

alternative splicing

Answer 38

a single primary transcript can be spliced into different mature mRNAs
ex: exons 1,2,3 can splice together and skip 4
ex: exons 1,2,4 can splice together and skip 3

Question 39

tRNA (transfer RNA)

Answer 39

carries amino acids to the ribosome for incorporation into a polypeptide (protein); is an adaptor protein

Question 40

what does aminoacyl-tRNA synthetases do

Answer 40

an amino acid that adds other amino acids to the acceptor stem of tRNA

Question 41

how does tRNA get charged (3)

Answer 41

1) animo acid is activated: ATP provides energy to bring amino acid to enzyme
2) tRNA binds to the enzyme
3) amino acid attaches to tRNA, charged tRNA is then released

Question 42

charged tRNA

Answer 42

has an amino acid added using the energy from ATP

Question 43

ribosomes do not verify amino acid attached to tRNA, so it’s up to aminoacyl-tRNA synthetase to

Answer 43

put the right amino acid on

Question 44

the ribosome has two primary functions:

Answer 44

1) decode the mRNA code: small subunit of ribosome
2) form peptide bonds: peptidyl transferase- enzymatic component of the large subunit of ribosome

Question 45

the ribosome has multiple tRNA binding sites (3):

Answer 45

1) E site: binds the tRNA that carried the last amino acid
2) P site: binds the tRNA attached to the growing peptide chain
3) A site: binds the tRNA carrying the next amino acid

Question 46

three steps of translation

Answer 46

initiation, elongation, termination

Question 47

initiation of prokaryotic translation

Answer 47

• recognizes start codon (AUG)
• initiation complex includes charged tRNA, small ribosomal subunit and mRNA strand
• large subunit now added
• initiator tRNA bound to P site
• A site is empty

Question 48

initiation of eukaryotic translation (similar to prokaryotes except…)

Answer 48

• initiating amino acid is different
• more complicated initiation complex
• lack of an RBS: small subunit recognizes and binds to 5’ cap of mRNA

Question 49

elongation of prokaryotic translation

Answer 49

• elongation factor binds to a charged tRNA and brings it to the empty A site
• peptidyl transferase forms peptide bond
• translocation of ribosome
• addition of successive amino acids occurs as a cycle

Question 50

wobble pairing during translation

Answer 50

wobble pairing allows less stringent pairing between the 3’ base of the codon and the 5’ base of the anticodon so one tRNA can recognize multiple codons (this is why 3rd base of codon can be variable)

Question 51

termination of prokaryotic translation

Answer 51

• elongation continues until the ribosome encounters a stop codon
• stop codons are recognized by release factors which release the polypeptide from the ribosome

Question 52

protein targeting

Answer 52

the mechanism by which a cell transports proteins to the appropriate positions in the cell or outside of it

Question 53

point mutations

Answer 53

alter a single base

Question 54

ase substitution

Answer 54

substitute one base for another

Question 55

silent mutation

Answer 55

one base changes, same amino acid is coded for

Question 56

missense mutation

Answer 56

one base changes, changes amino acid inserted

Question 57

nonsense mutations

Answer 57

changed to stop codon

Question 58

what kind of mutation is sickle cell anemia

Answer 58

missense mutation

Question 59

frameshift mutations (3)

Answer 59

• addition or deletion of a single base
• much more serious consequences
• alter reading frame downstream

Question 60

triplet repeat expansion mutation

Answer 60

• repeat unit is expanded un the disease allele relative to the normal
• caused by “slippage” during DNA replication; replicates the same sequence over and over

ex: huntingtons disease, fragile X syndrome

Question 61

chromosomal mutations: deletion

Answer 61

part of the chromosome is lost; changes the structure of a chromosome

Question 62

chromosomal mutations: duplication

Answer 62

part of the chromosome is copied; change the structure of a chromosome

Question 63

chromosomal mutation: inversion

Answer 63

part of the chromosome is in reverse base-pair order; changes the structure of a chromosome

Question 64

chromosomal mutations: translocation

Answer 64

part of the chromosome is moved to a new location; changes the structure of a chromosome