C1- Protein Modification
1. N-terminus 2. Lysine
2 different types of acetylation:
1. Farnesyl (geranylgeranyl) transferase binds to CAAX box 2. Proteolysis of AA 3. Carboxy methylation
3 steps in Farnesylation and Geranylgeranylation:
basic enzymatic mechanism
A similarity of the two different acetylation mechanisms is that they both have same _______ on amino groups
Reversible (poly) ADP-ribosylation of Glu/Asp
ADP-ribosylation that is a normal physiological response to DNA damage
ADP-ribosylation
Addition of ADP-ribose to proteins
No
Are farnesylation and geranylgeranylation reversible?
Cholera toxin
Arg modification of Gs (G-protein)
Imatinib (Gleevec)
Bcr-Abl tyrosine kinase inhibitors
overactivate
Both cholera and pertussis toxins ____ adenylate cyclase
Gly X Y X= pro Y= 4-Hydroxyproline (Hyp)
Collagen contains repeats of sequence _____
Pertussis toxin
Cyc modification of Gi (G-protein)
Different enzymes, substrates and effects on proteins
Differences of 2 acetylation mechanisms:
Irreversible (mono) ADP-ribosylation
Diphtheria, Cholera and Pertussis toxins all use this mechanism
Prolyl hydroxylase
Enzyme used to convert a prolyl residue to a 4-hydroxyprolyl residue
1. poly (ADP-ribose) glycohydrolase 2. ADP-ribosyl protein lysase (removes last ADP-ribose)
Enzymes used to remove ADP-riboses
"CAAX box" C=Cys A=aliphatic amino acid X= anything
Farnesyl transferase (and geranylgeranyl transferase) recognizes ______ and forms a stable thioether bond
cysteine residues
Farnesylation and Geranylgeranylation occur at _____
Lipid modifications to proteins
Farnesylation, Geranylgeranylation, Myristoylation and Palmitoylation are examples of _______
SOS
GEF of RAS is _____
Ca2+
Gamma-carboxylation of GLA domain allows ____ binding which facilitates membrane binding
inhibitors
HAT and HDAC ____ are potential therapies
Resveritrol
HDACs- a target of ______
Diphtheria toxin
His modification of EF2
2
How many mechanisms of transfer are there for Ub from E2 to substrate/acceptor?
Negatively
Hypoxia-inducible factor (Hif) is ____ regulated by prolyl-hydroxylation
conserved Gamma carboxyglutamic acid rich (GLA)
In Gamma-carboxylation, the enzyme targets a _____ protein domain
Protein tyrosine kinase (growth factor) receptor (PTKR)
In RAS-RAF1-extracellular signal- regulated kinase (ERK) pathway, ____ is activated by autophosphorylation and allows binding to downstream factors
RAS farnesylation
In RAS-RAF1-extracellular signal- regulated kinase (ERK) pathway, _____ facilitates membrane association
RAF1/MEK/ERK protein kinase cascade
In RAS-RAF1-extracellular signal- regulated kinase (ERK) pathway, ______ causes activation of nuclear transcription factor ELK
Warfarin
Inhibition of clotting with ______
No
Is N-terminus acetylation reversible?
yes
Is Ubiquitylation reversible?
yes
Is acetylation on lysine reversible?
Yes
Is phosphorylation reversible?
Yes
Is poly ADP-ribosylation reversible?
Immune suppression
Kinases and phosphatase are important drug targets for _____
Cancer chronic myelogenous leukemia
Kinases are important drug targets for ______
common and essential
Lipid protein modifications are __ and ____ modifications
Collagen
Major extracellular triple helix protein of Connective tissue
N-terminal methionine
Majority (80%) of proteins are acetylated on their _____
clotting cascade
Many GLA-containing proteins are found in _____
RAS
Many tumors have a mutated ____ that has lost its ability hydrolyze GTP so it is always active
Ubiquitin
Most common member of small protein family
disease
Mutations in kinase/phosphatase genes are associated with _____
fatty acid
Myristoylation and Palmitoylation involve the addition of a _____
N-terminus
Myristoylation occurs at the ______
Co-translational
N-terminal methionine acetylation is a _____ modification
Thioether bond
Palmitoylation involves a ___ bond to cysteine residues
cysteine residues
Palmitoylation occurs at ______
Fk506 (Tacrolimus)
Phosphatase calcineurin inhibitor
activity, location and stability
Phosphorylation can change protein ___,___ and ___
glutamic acid, aspartic acid or C-terminus of protein
Poly ADP-ribosylation targeted to ___, ___ or ____
proteasomal degradation
Poly ubiquitylation (K48 and K11 linkage) is the usual signal for _______
rapamycin (Sirolimus)
Protein Kinase mTOR inhibitor
sumolyation
Protein ___ does not target proteins for degradation but can regulate protein function or localization
functionality
Protein modification exceedingly common to extend the _____ of amino acids
farnesylated
RAS is ____ at C-terminus
GTPase
RAS is a _____
1. Palmitoylation 2. plasma membrane 3. removal from membrane 4. Depalmitoylation 5. golgi membrane
Steps in RAS protein modification: 1. __1__ of farnesylated RAS in golgi 2. Vesicular transport to __2__ 3. Binding to factor required for __3__ 4. __4__ 5. binding to __5__
Nicotinamide adenine dinucleotide (NAD+)
Substrate for ADP-ribosylation
1. amino 2. Ubiquitin
Substrate for E3 may be 1. Protein substrate- ____ group of lysine 2. ____ - amino group of a lysine or a amino group of the N-terminal methionine
C-terminal sequence
Synthese of Ub requires removal of _____ to generate the correct Ub C-terminus
ubiquitin ligase (E3)
Transfer of Ub from charged E2 to substrate/acceptor requires ______
1. Reversible (poly) ADP-ribosylation of Glu/Asp 2. Irreversible (mono) ADP-ribosylation
Two classes of ADP-ribosylation modification:
poly proteins
Ub genes are synthesized as ____ or fusions between Ub and another protein
recycled
Ub is ____ during proteasomal degradation
1. lysine 2. isopeptide bond
Ubiquitin is attached to __1__ residues via __2__
1. Adenylation 2. Thioesterification 3. Trans-thioesterification
Ubiquitin-activating enzyme (E1) carries out three enzymatic functions: 1. __1__ of Ub 2. __2__ of E1 3. __3__ of Ubiquitin-conjugating enzyme (E2)
E1
Ubiquitin-activating enzyme =____
E2
Ubiquitin-conjugating enzyme= _____
topologies
Ubiquitylation has different _______
E1, E2 and E3
Ubiquitylation is carried out by three enzymes:
specific
Unlike poly ADP-ribosylation, monoribosylation by bacteria toxins have very ____ substrates, with specific biochemical influences on those substrates
reductase
Vitamin K is rejuvenated by ____
poly ubiquitylated proteins
When ubiquitin is the substrate for E3, it can lead to _____
Seven lysines and N-terminal methionine
___ and ___ of Ub can be ubiquitylated
Sumo
___ is another member of the ubiquitin family
Cholera
___ toxin acts in the intestinal epithelial cells
Few (1 in yeast, 2 in humans)
____ E1 enzymes in most eukaryotes
GAP
____ can stimulate GTPase activity of RAS (results in loss of effector binding)
Warfarin
____ inhibits reductase
Farnesyl pyrophosphate
____ is intermediate in cholesterol biosynthesis
Hydroxyproline (Hyp)
____ is more abundant in animals than seven "common" amino acid residues
Hydroxyproline (Hyp)
____ is necessary for proper folding and assembly of collagen
lysine acetylation
____ of p53 tumor suppressor is required for activation
chain editing
____ takes place with Ub modified proteins
Ubiquitin
____- ubiquitously expressed small 8.5kDa protein (highly conserved)
De-ubiquitylation enzymes (DUBs)
_____ complete syntheses of new Ub
C-terminus
_____ of RAS genes are divergent
lysine acetylation
_____ stabilizes cytoskeletal microtubules
amino group
acetylation of lysine occurs on its ______
Poly (ADP-ribose) polymerase (PARP)
enzyme for ADP-ribosylation
protein quality control and degradation
function of N-terminus acetylation
Histone acetylation (HATs) and deacetylation (HDACs)
lysine acetylation is used for _______
1. cysteine of E2 to Lysine of substrate 2. Thioesterification
mechanisms of transfer for Ub from E2 to substrate/acceptor: 1. Direct transfer of Ub from active site ___ of E2 to __ of substrate 2. _____ of E3 from charged E2 followed by transfer of Ub from active site cysteine of E3 to lysine of substrate
HRAS, NRAS, and KRAS
three RAS genes:
1. Collagen 2. Hypoxia (low oxygen)- inducible factor
two substrates of prolyl-hydroxylase
