MIDTERMS, BITCH Flashcards

Question 1

Q

What takes up most of a cells mass except for water

Question 2

Q

What percent of genes are shared between human cells

Question 3

Q

Do you need a primer for transcription

Answer

A

no you idiot

Question 4

Q

What is the abortive transcription

Answer

A

When 10 nucleotides are formed, sigma factor is released. This can happen in eukaryotes but with general transcription factors instead of sigma factor

Question 5

Q

What is a hairpin structure

Answer

A

A looping of mRNA that happens in transcription which causes the RNA polymerase to leave the DNA strand

Question 6

Q

What are gene regulatory proteins or transcription factors? What do they bind to, specifically?

Answer

A

They regulate gene expression by binding to regulatory sequences of DNA called cis factors.

Question 7

Q

What are two types of gene regulatory proteins/transcription factors

Answer

A

Activators and repressors

Question 8

Q

What is an operon

Answer

A

multiple genes transcribed into one RNA molecule

Question 9

Q

What is the Trp operon, how does the trp repressor work

Answer

A

5 genes encode enzymes for tryptophan synthesis, transcription regulated by a single operator. the Trp repressor binds to the operator sequence to prevent RNA polymerase from binding. the trp repressor binds 2 molecules of tryptophan to bind to the helix-turn helix binding motif in the major groove of DNA

Question 10

Q

What is the most common DNA binding motif

Answer

A

the binding of a gene regulatory protein in the major groove of DNA (such as with trp operon)

Question 11

Q

Explain the lac operon in E coli. What does Ecoli prefer

Answer

A

Ecoli uses lactose when there is no glucose. The operon is turned on when using lactose. However, E coli prefers glucose

Question 12

Q

What activates the lac operon, under what condition

Answer

A

Catablite Activator Protein (CAP) which increases when glucose decreases. This increases cAMP which changes CAP conformation, and allows it to bind to DNA. It binds to promoters to help yoink RNA polymerase and get RNA poly. to bind.

Question 13

Q

What represses the lac operon and under what conditions

Answer

A

Lac repressor protein shuts off the operon when there is no lactose. This is because allolactose increases as lactose increases, releasing lac repressor from the operator (conformational change).

Question 14

Q

What does DNA sequencing, DNA microarrays, 2D gel electrophoresis show you

Answer

A

Respectively, info about DNA, RNA, and proteome

Question 15

Q

What is negative and positive regulation in prokaryotic transcriptional regulation

Answer

A

Repressor preventing activity, and activator promoting activity

Question 16

Q

What are the two ways ligands can control gene-regulating proteins

Answer

A

Ligands can yoink regulatory protein from the DNA or yeet the regulatory protien onto it

Question 17

Q

Where can regulatory elements be found

Answer

A

Upstream or downstream of the promoter. Downstream and within genes is common for eukaryotes.

Question 18

Q

What is kissing :3

Answer

A

I’m a visual learner btw (jk its when distant regulatory elements like NRTC loops back allowing NRTC to interact with RNA polymerase at a distance. can happen in both eukaryotes and prokaryotes)

Question 19

Q

Explain how the lambda repressor and cro protein work

Answer

A

The lambda repressor binds to the cro side of the operator, which activates its own synthesis, and most bacteriophage DNA is not transcribed. The cro protein binds to the other side and activates its own synthesis as well. It’s also a repressor. They both essentially prevent transcription from one side

Question 20

Q

Explain the prophage state of lambda DNA after it enters the host

Answer

A

Lambda DNA is put into hist genome after lambda repressor binds to the operator. The cell divides and this leads to lambda DNA dividing with host DNA (it gets a free ride)

Question 21

Q

Explain how a bacteria may switch from prophage to lytic pathway

Answer

A

When the host reacts to DNA damage

Question 22

Q

Explain the lytic pathway after lambda DNA enters host

Answer

A

Cro blocks lambda repressor, and bacterial DNA is extensively transcribed, so theres a shit ton of viral proteins needed for formation of new viruses. Then lambda DNA gets replicated and gets put into viruses. Cell lysis, and the viruses leaves >:) muahahahahah

Question 23

Q

What promotes prophage state in bacteriaphage infected bacteria

Answer

A

If conditions are good for growth and cell division, then lambda repressor turns off cro, maintaining prophage state.

Question 24

Q

What is a transcriptional circuit (simply?)

Answer

A

When A protein is coded for by a certain piece of DNA, and this A protein then goes back and either activates or represses the operator.

Question 25

Q

Explain the flip flop device

Answer

A

One DNA codes for A which stops B synthesis. The B DNA stops A synthesis. Its also known as indirect positive feedback loop

Question 26

Q

Explain feedforward loop

Answer

A

Protein A activates B and Z synthesis. Protein B activates Z synthesis. Z is super duper ultra mega activated >:)

Question 27

Q

Explain cell memory in the context feed forward loops

Answer

A

A cell has a gene, and initial transitent signal turns the gene on. Now you make the protein. The protein facilitates its own creation (positive feedback) so its sons and daughters and children all have the protein and have the gene activated

Question 28

Q

How can feedforward loops be used to measure duration of a signal

Answer

A

Both A and B are needed to activate Z, so the sensitivity of Z is decreased. output of Z is only achieved with prolonged input.

Question 29

Q

What is synthetic biology

Answer

A

Constructing artificial regulatory circuits and examining behavior in cells

Question 30

Q

What is a repressilator, what happens with the protein synthesized IRL

Answer

A

A is expressed, B repressed, C expressed. C then represses A which expresses B, repressing C. It’s like a bunch of people who really want to fuck with everyone else. IRL the protein amount oscillates up and down but overall goes up due to there being more overall bacteria

Question 31

Q

What is transcription attenuation

Answer

A

Present in both eukaryotes and prokaryotes. RNA gets a structure that fucks with RNA polymerase and Regulatory proteins can bind to RNA and interfere with attenuation. Prokaryotes, plants, and some fungi use riboswitches to regulate gene expression.

Question 32

Q

What is a riboswitch

Answer

A

(Someone who isn’t a ribotop or a ribobottom /j) short RNA sequences that change conformation when bound by a small molecule. some do transcription attenuation, some do stuff other than transcription attenuation. an example is when high purine, purine binds to the riboswitch, changing it conformationally, and then RNA polymerase is pried off.

Question 33

Q

What do general transcription factors do, name the 5 needed by RNA polymerase 2

Answer

A

help position eukaryotic RNA polymerases at eykaryotic promoters. The 5 are TFIID, TFIIB, TFIIF, TFIIE, TFIIH.

Question 34

Q

What does RNA polymerase II code for

Answer

A

protein coding genes

Question 35

Q

What does the mediator do

Answer

A

correctly positions TFIIH, influences general transcription proteins

Question 36

Q

What do elongation factors do

Answer

A

Prevent DNA polymerase from dissociating

Question 37

Q

What are coactivators and corepressors

Answer

A

Shit that assemble on gene regulatory proteins but don’t directly bind to DNA

Question 38

Q

What are the two parts of a eukaryotic activator protein, how are they positioned on the DNA

Answer

A

DNA binding domain (DBD) recognizes specific DNA sequence. Activation domain (AD) actually accelerates transcription. DBD is the foot part and AD is the doorknob part

Question 39

Q

How do activator proteins facilitate transcription

Answer

A

Attracting, positioning, modifying general transcription factors, mediators, RNA polymerase II. They either directly act on components like prokaryotic activators (e.g. bind somewhere on DNA and succc the thing it wants close) or by indirectly modifying chromatin structure

Question 40

Q

How many base pairs around neocleosomes, how many times around octamer core, how long is linker DNA (just like get the general range)

Answer

A

Nucleosomes are 147 bp, wound 1 2/3 around octamer, linker DNA 10-80 bp

Question 41

Q

What are the 4 major ways activator proteins activate chromatin

Answer

A

Remodelling nucleosomes use chromatin remodelling complex, using ATP to pull DNA along nucleosome. Histone removal, histone replacement (need histone chaperones), specific patterns of histone modification

Question 42

Q

What is the histone code

Answer

A

Acetylation, methylation, phosphorylation on histone tails. Modifications are dynamic and determined by DNA. code readers provide meaning

Question 43

Q

What termini are histone tails

Answer

A

Histone tails are usually N-termini, C termini can stick out too but its rare

Question 44

Q

How does eukaryotic repression happen

Answer

A

Competitie DNA binding, masking activation (the thing where the doorknobs are fighting), direct interaction with general transcription factors, recruitment of chromatin remodelling complexes, deacetylation by recruitinng deacetylases, methyl transferase recruiting.

Question 45

Q

How do reader writer proteins stabilize chromatin

Answer

A

A reader protein recruits writer which starts domino effect of reader-writers complex. DNA methylase enzyme is attracted by the reader which methylates nearby cytosines, stabilizing chromatin.

Question 46

Q

Methylation of chromatin and blocking of gene expression as a result is an example of what

Answer

A

epigenetic inheritance

Question 47

Q

How does the human interferon gene have regulation

Answer

A

Activator attracts histone acetyltransferase, acetylates H4K8, H4K9, activator protein attracts histone kinase that phosphorylates H4S10, and serine modification signals the acetyltransferase to acetylate H3K14. Remember that there are 2 tails for H3 because there are 2 H3s

Question 48

Q

What is RNA capping

Answer

A

Addition of modified guanine to the 5’ end of pre-mRNA, distinguishing it from other types of RNA. Done by cap binding complex that prevents 5’exonuclease from cutting phosphodiester bonds (it cannot cut the weird guanine)

Question 49

Q

What is splicing done by

Answer

A

The spliceosome

Question 50

Q

What marks proper splicing

Question 51

Q

How is the sex lethal gene regulated

Answer

A

The splice site is blocked, which makes a shit ton more spliced. Like the stuff between two introns are spliced out too

Question 52

Q

How is the transformer gene regulated

Answer

A

Sex lethal makes Sxl protein which blocks the splice site and makes an intron longer

Question 53

Q

How is the doublesex gene regulated

Answer

A

The transformer gene creates a protein that activates a splice site, which prevents the exon from being spliced (best to double check with slides for the drosophila related genes because the diagrams help a lot)

Question 54

Q

What makes a male drosophila

Answer

A

Nonfunctional Sxl, nonfunctional Tra, inactive 3’ splice for doublesex

Question 55

Q

How is eukaryotic transcription terminated

Answer

A

CstF (cleavage stimulating factor) and CPSF (cleavage and polyadenylation specificity factor) are on RNA polymerase tail and transfer onto 3’ processing sequence. RNA get cleaved, poly A polymerase adds a ton of not genome encoded As.

Question 56

Q

What binds RNA processing proteins before they go to RNA

Answer

A

C-terminal domain of RNA polymerase

Question 57

Q

What causes the RNA processing proteins to be yeeted on

Answer

A

Phosphorylation of RNA polymerase

Question 58

Q

What are markers of mature RNA you need to move it out of the nucleus

Answer

A

Cap binding complexes, exon-junction complexes, poly A binding proteins.

Question 59

Q

What can you not have on proteins for export

Answer

A

snRNPs must be lost for export

Question 60

Q

What happens to messed up RNAs that aren’t fit for export? how much RNA leaves the nucleus

Answer

A

1/20 leaves the nucleus. messed up RNA will be degraded in the nucleus by the exosome.

Question 61

Q

How do eukaryotes make sure the mRNA is good quality once it is exported out of the nucleus?

Answer

A

5’ cap bound by elF4E, poly A binding protein bound by elF4G. These 2 recruit small ribosomal complexes to start translation. This makes sure both ends of the RNA are intact

Question 62

Q

What is nonsense mediated mRNA decay? What should happen if the splicing is normal?

Answer

A

Normal conditions will have EJCs displaced by moving ribosome. Stop codon is on the last exon. Abnormal splicing will cause a premature stop codon which leads to EJCs still on RNA. UPF degrades fucky wucky mRNA

Question 63

Q

Where is nonsense mediated mRNA decay important

Answer

A

In the immune system where a lot of DNA rearrangement happens to make antibodies.

Question 64

Q

How do prokaryotes control for mRNA quality

Answer

A

Ribosomes get stuck on broken and incomplete RNAs, and a special tmRNA (好礼貌的rna草) gets yoinked to the A side, and puts alanine onto the chain. The tmRNA acts as the template for the next tRNAs, making an 11 amino acid tag, and proteases will be attracted to shit with the tag and eat it.

Answer 62

A

It is a 3-5 exonuclease. Once the polyA tail is too short, then the 5’ end can be dropped, or 3-5 degradation continues. Or both.

Answer 63

A

cytoplasmic poly-A elongation. some proteins can fuck with this tho

Answer 64

A

yeets iron into the cell

Answer 65

A

mRNA is stabilized by cytosolic aconitase when there is low iron in the cell, allowing the transferrin receptor to be made. when there is high iron, the 3’UTR endonucleolytic side is exposed because the iron sticks to mRNA.

Answer 66

A

synthesized by RNA polymerase II and base pairs with itself. the parts not base paired are cleaved in the nucleus, then the dicer removes single parts in the cytosol. Initially, it has a 5’ cap and poly-A tail. it then yoinks a argonaute to form a RISC (RNA-induced silencing complex)

Answer 67

A

A protein that helps miRNAs find targets. The target is either eaten, or it blocks translation, which takes a while, and then usually degrades the RNA.

Answer 68

A

Double stranded RNA that blocks other RNA in a sequence specific manner, like miRNAs

Answer 69

A

small interfereing RNA. double stranded, can work like miRNA or interact with newly transcribed RNA, recruit chromatin modifying enzymes to compact DNA and then no more translation

Answer 70

A

Bits of viral DNA get into CRISPR locus, then it makes pre-crRNA from the DNA sequences that are acquired from viral DNA. The pre-crRNA is processed and added onto Cas protein (which acts like argonaute). Then the cas protein and crRNA go to destroy complementary viral DNA

Answer 71

A

a sequence upstream of aug start codon (5’UTR). this correctly positions aug in ribosome and provides translational control

Answer 72

A

RNA binnding protein blocks access to it, so no protein made. 2. a stem-loop RNA structure blocks access to the shine-dalgarno sequence 3. riboswitch causes structural rearrangement of DNA, blocking Shine-Dalgarno sequence. 4. antisense RNA made somewhere else base pairs with mRNA, blocking SD. this antisense RNA is not miRNA, siRNA, or crRNA

Answer 73

A

Translational repressors can bind near the initiator AUG and inhibit translation. Like how ferritin binds iron, which yoinks the aconitase off of the RNA, allowing ferritin to be made. When iron is low, there is no iron to yoink it off, meaning no ferritin is made. Repressor proteins can also interfere with 5’cap and 3’ poly A tail, which are both needed for efficient translation.

Answer 74

A

Phosphorylate them. elF2 forms a complex with GTP, recruits methionine tRNA to small ribosomal subunit. When the mthionine carrying tRNA finds AUG, ATP is hydrolysed to ADP. This changes elF2 shape, and yeets it out with a GDP attached. GDP attached elF2 is inactive and needs elF2B to activate it. Phosphorylating elF2 makes elF2 stuck to elF2B, and now elF2B cannot go do its job :( now translation is very slow. not all mRNAs are equally affected by this

Answer 75

A

proteins must fold properly, so you can have covalently modified proteins (sugar, phosphate), proteins interacting with other proteins and small molecules (cofactors). some protein folding begins as soon as they emerge from ribosomes and some after synthesis

Answer 76

A

heat-shock proteins because a shit ton is made when its hot. they are also there when its normally hot

Answer 77

A

they interact with exposed hydrophobic parts of proteins, which is not normal, obviously, and use ATP to fold them in one of 2 chambers. theres a lil cute lid to keep stuff in place and prevent shit from getting mixed up

Answer 78

A

they become a clump of garbage and can be toxic. it causes many inherited human diseases. big protein-destroying strucutres, the proteasome, degrade the incorrect proteins

Answer 79

A

they both have a crush on fucked up proteins with exposed hydrophobic residues. they love it so much, and will compete for it. the longer it takes for a protein to fold, the more likely it is degraded

Answer 80

A

yeah its everyfuckingwhere, in the cytosol and nucleus. It’s a hollow cylinder with caps on either end to prevent randomly eating shit, and a hollow cylinder in the middle. it eats proteins with ubiquitin chains. the longer the chain, the more likely it will be destroyed >:)

Answer 81

A

Using ubiquitin conjugating system bade of E1, E2, E3.

Answer 82

A

ATP dependent ubiquitin activating enzyme that yoinks a ubiquitin and puts it onto itself.

Answer 83

A

Ubiquitin conjugating enzyme that yoinks uniquitin from E1 and works with E3

Answer 84

A

binds to specific degradation sequences (degrons) in substrates. uniquitin is added onto a lysine residue on the target protein. process repeated to get polyubiquitination. ubiquitin does not touch E3.

Answer 85

A

Sometimes E2-E3 are called ubiquitin ligase together, but E3 is the actual ubiquitin ligase.

Answer 86

A

a couple different E1s, about 30 different E2s and 100s of E3s.

Answer 87

A

Monoubiquitination: histone regulation

Answer 88

A

Multiubiquitination: endocytosis (like multiple on different spots)

Answer 89

A

A chain of ubiquitin, linked through lysine 48 or 63 of the ubiquitin. for lysine 48, it causes proteosomal degradation. For lysine 63, it causes DNA repair.

Answer 90

A

Phosphorylating E3 by protein kinase, allosteric transition caused by ligand binding on E3 or protein subunit addition

Answer 91

A

Phosphorylation by protein kinase, unnmasking by protein dissociation, creation of destabilizing N-terminus

Answer 92

A

Make proteins on demand, ligand binding to activate, covalent modifications to activate, addition of subunit to activate, unmasking to activate, stimulation of nuclear entry, release from membrane

Answer 93

A

epinephrine binds to GPCR, activating it, which goes through a g protein to make cAMP, which frees the two catalytic subunits from the regulatory subunits. The regulatory subunits bind to cAMP. the catalytic subunits promote breakdown of glucogen and inhibit glycogen synthesis. pKA promotes glucose release.

Answer 94

A

it goes from the cytosol into the nucleus, which then activates genes with cAMP responsive elements (CRE), which are basically bits of DNA that CRE binding proteins (CREB) bind to. The CREB recruits CBP coactivator, which and the two bind to CRE, which activates the target gene. in the liver, this transcribes the gene glucose-6-phosphatase, which makes more glucose to be released into blood, and inhibits glycogen synthesis

Answer 95

A

In large multi-protein complexes comprised of static and transient interactions.

Answer 96

A

complete collection of protein-protein interactions of an organism

Answer 97

A

an organelle where cell components no longer needed are degraded

Answer 98

A

Proteins going to mitochondria and plasmids go in unfolded, proteins going to nucleus and peroxisomes go in folded

Answer 99

A

Gates transport. The nuclear pore complexes (NPCs) are made of nucleoporins and let small things go freely but not DNA or proteins. The nuclear important receptor binds to nuclear localization signal on the protein, which is rich in lysine and argenine, which then binds to nucleoporins in the NPC.

Answer 100

A

Structurally and evolutionally related.

Answer 101

A

Proteins with nuclear export signals. newly assembled ribosomal subunits and RNA do too (because they all need to go to the cytoplasm!!!!!!!!!)

Answer 102

A

Nuclear import receptor binds cargo in cytosol, then the two go to the nucleus. RAN-GTP binding causes cargo release in the nucleus. Then the empty import receptor and RAN-GTP go to the cytosol.

Answer 103

A

GTP hydrolysis (changing GTP to GDP). Releases import receptor, export receptor, and relesae of cargo. It is in the cytosol

Answer 104

A

Nuclear export receptor binds Ran-GTP and cargo in the nucleus, then the three go to cytosol. Once GAP yeets cargo and export receptor off then the export receptor can go back to the nucleus

Answer 105

A

It is a guanine nucleotide exchange factor in the nucleus, which promotes exchange of GDP for GTP by RAN (does the opposite of GAP)

Answer 106

A

When there is a shit ton of calcium in the cell, protein phosphatase blocks nuclear export signal, which reveals the import one, and the protein goes in and activates gene transcription. This is because you want to get the calcium OUT. When theres little Ca2+ in the cell, ATP+ active protein kinase phosphorylate protein changes conformation to reveal the export signal and hasta la vista baby

Answer 107

A

By associating with Hsp70 chaperones

Answer 108

A

Nterminal amphipathic alpha helix guides proteins in (like the protein has an alpha helix). It binds to the import receptor, with a TOM on the outer membrane and a TIM on the inner membrane. The signal sequence in the membrane is then cleaved

Answer 109

A

Also N terminal amphipathic alpha helix. Signals equence also cleaved. Outside membrane is TOC complex, inside is TIC. Sometimes, chopping off the signal sequence will reveal a hydrophobic thylakoid signal sequence

Answer 110

A

3 amino acid at C terminal (SKL) that is not cleaved. The protein is folded (unlike for mitochondria and chloroplasts), and it is transported across by large translocator complex

Answer 111

A

mRNA and ribosomes go to ER lumen. hydrophobic amino acids at N terminal is the ER signal sequence which first emerges from the ribosome. co-translational translocation occurs.

Answer 112

A

synthesis and modification of proteins, synthesis of lipids

Answer 113

A

soluble proteins, transmembrane proteins, proteins destined for the Golgi, secretion, lysosomes

Answer 114

A

a mix of protein and RNA that binds to the signal sequence with its hinge on the large ribosomal subunit. SRP receptor is on the membrane of the ER. both SRP and SRP receptors have GTP domains (that bind GTP). SRP and ribosome does not bind well to the receptor, you need an ER signal sequence as well

Answer 115

A

signal peptidases

Answer 116

A

it is gated in a second direction

Answer 117

A

The first two are basic, basically positive side faces the cytosol, can be either C or N terminal. The third one is that there is a signal sequence at the very tip of the N terminal which gets cleaved off, and the transmembrane domain is actually a stop transfer signal. COOH has to be in cytosol for this one

Answer 118

A

The first TM domain is the internal start-transfer sequence, then the second TM domain is the stop-transfer sequence.

Answer 119

A

Integral, lipid anchored, and peripheral

Answer 120

A

has a c-terminal hydrophobic domain, which signals for GPI anchor while signal sequence is still in the membrane. The ER enzyme transfer protein to GPI anchor, and GPI anchored protein ends up on ER luminal side and can go to cell exterior

Answer 121

A

In transmembrane and soluble proteins in the ER

Answer 122

A

O-linked glycosylation, glucose on the oxygen of the side chain, which happens 10% of the time. N-linked glycosylation, on asparagine side chain’s nitrogen, which happens 90% of the time.

Answer 123

A

The N-linked oligosaccharide precursor is transferred by an oligosaccharyl transferase to an Asn on a protein being synthesized. This can be Asn-X-Ser or Asn-X-Thr. Proteins are only glysosylated on the ER lumen side.

Answer 124

A

3 glucoses removed, 1 mannose removed, then glycosylated protein is transported via vesicles to the golgi.

Answer 125

A

From closest to furthest from ER: cis golgi network, cis cisterna, medial cisterna, trans cisterna, trans golgi network. Different places mean different modifications

Answer 126

A

To mark where protein folds, to protect proteins on the cell surface from proteases. For cell adhesion, to allow formation of 3D structure.

Answer 127

A

Transmembrane proteins, soluble proteins, some are bound by transmembrane cargo receptors

Answer 128

A

Select cargo, give curvature to vesicle, promote vesicle budding

Answer 129

A

from Golgi to ER, between different Golgi cisternae.

Answer 130

A

from ER to Golgi (the normal direction)

Answer 131

A

from Golgi and plasma membrane to endosome (sandwich)

Answer 132

A

GEF at the site of membrane yeets a gtp onto the Sar1 GTPase, then the Sar-1 GTP recruits coat proteins, which forms vesicle bud (like a little hill) and selects the cargo. The vesicle buds off, then it uncoats. This process for COPI and COPII proteins involve GAPs. Clathrin coated vesicles have a different mechanism. Now the vesicle can go to the target compartment

Answer 133

A

COPI uses ARF. COPII uses Sar1

Answer 134

A

Once they get a GTP attached, they expose an amphipathic alpha helix which interacts with the membrane of the ER

Answer 135

A

The inner layer binds to membrane and selects cargo. Outer layer associates with inner layer to promote formation of the coat. Coat proteins need to select cargo (transmembrane proteins), transmembrane cargo receptors (which bind soluble cargo proteins), and SNAREs.

Answer 136

A

In the inner layer, there are 4 subunits, (β, γ, ζ, and delta)

Answer 137

A

y-COP binds to Arf GAP, which makes Arf-GTP go to Arf-GDP. Arf-GDP then detatches from the membrane

Answer 138

A

Inner: 2 subunits (sec23/sec/24)
Outer: 2 subunits (sec13/sec31)

Answer 139

A

Sec23 has CAP activity, stimulated by sec 13 and sec31. Same GTP hydrolysis as in COPI, and Sar-GDP detaches from the membrane.

Answer 140

A

Inner: different adaptor proteins
Outer: clathrin (6 subunits)

Answer 141

A

Dynamin, which has GTPas activity

Answer 142

A

Hsp70 and auxillin

Answer 143

A

A fundamental unit in clathrin vesicles, which form a curved lattice that pinches off the membrane

Answer 144

A

GTP bound Rab-GTPase (on vesicle) binds Rab effector on target. Dock and tether, bringing vSNARE and tSNARE together. Helical domains coil, squishing out water. Cytosolic leaflets first fuse, leaving lumenal leaflets side by side

Answer 145

A

NSF + adaptor proteins unwrap helical domains of SNAREs

Answer 146

A

Soluble proteins are bound by cargo receptors and transmembrane proteins are bound by COPII coat.

Answer 147

A

No, some are packaged because they are in high concentrations in the ER.

Answer 148

A

they form vesicular tubular clusters, which then go to the golgi

Answer 149

A

COPI does, it brings back escaped ER resident proteins, proteins from ER involved in vesicle budding, these typically have ER retrieval signals. Soluble ER proteins ahve a KDEL signal and are bound by the KDEL receptor

Answer 150

A

it gets lower and lower. At vesicular tubular clusters and golgi, the KDEL receptors will bind KDEL because acidic pH, and KDEL drops off at ER, which has a neutral pH

Answer 151

A

They have different transport rates from ER to golgi and vice versa. Proteins stuck in a certain compartment form big complexes and can’t fit into vesicles.

Answer 152

A

tethering proteins

Answer 153

A

COPII coated vesicles move cargo from one golgi cisterna to the next. COPI return escaped resident ER proteins.

Answer 154

A

Cisternae all get promotions. vesicular tubular cluters fuse to become ER cis golgi network. Existing trans cisterna moves to trans golgi network. Retrograde transport by COPI vesicles

Answer 155

A

a complex network of membranes and vesicles, a major branch point where proteins are sorted into different vesicles.

Answer 156

A

Vesicles with lysosomal hydrolases needed for lysosome function are transported to late endosome which mature into lysosomes.

Answer 157

A

Synthesized in the ER, processed in the Golgi. Degrade macromolecules, active at acidic pH. They starte off with n-linked oligosaccharide in the ER, phosphorylates mannose residue in cis-golgi network to form M6P., which receptors in the trans golgi network find, package and release into late endosome.

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MIDTERMS, BITCH Flashcards

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