Biochemistry 1/2, First Aid for the USMLE Step 1 Flashcards
DNA charge
Negative
Histone charge
Positive
Negatively charged DNA loops ___ around positively charged histone octamer to form nucleosome “___.”
Twice; beads on a string
Histones are rich in the amino acids ___
Lysine and arginine
___ binds to the nucleosome and to “linker DNA,” thereby stabilizing the chromatin fiber
H1
DNA and histone synthesis occur during ___ phase of the cell cycle
S phase
Condensed chromatin that appears darker on EM
Heterochromatin [Think HeteroChromatin, Highly Condensed]
Less condensed chromatin that appears lighter on EM
Euchromatin
Transcriptionally inactive chromatin, sterically inaccessible
Heterochromatin
Transcriptionally active, sterically accessible
Euchromatin
Inactive X chromosomes
Barr bodies
Heterochromatin vs Euchromatin: Barr bodies
Heterochromatin
Template strand ___ and ___ are methylated in DNA replication, which allows mismatch repair enzymes to distinguish between old and new strands in prokaryotes
Cytosine, adenine
What methylation processes make DNA mute or repress DNA transcription
DNA methylation; histone methylation (repress or activate DNA transcription)
Relaxes DNA coiling, allowing for transcription
Histone acetylation [Think Acetylation = Active]
Purines
Adenine, Guanine [Think PURe As Gold]
Pyrimidines
Cytosine, Uracil, Thymine [Think CUT the PY]
Purines vs Pyrimidines: 2 rings
Purines [Pyrimidines = PYRamids can stand alone = 1 ring]
Which pyrimidine has a methyl
Thymine [ Think THYmine has a meTHYl]
What makes uracil
Deamination of cytosine
Uracil is found in
RNA
Thymine is found in
DNA
Base pair with 2 hydrogen bonds
A-T [Think 2 AToms of hydrogen]
Base pair with a higher melting point
G-C (3 H bonds)
Amino acids necessary for purine synthesis
Glycine, Aspartate, Glutamate [GAG]
Amino acid necessary for pyrimidine synthesis
Aspartate
A nucleoSide is composed of
Base + Sugar (ribose or deoxyribose)
A nucleoTide is made of
Base + Sugar + phosphaTe; linked by 3’-5’ phosphodiester bond
De novo purine synthesis
1) Sugar + phosphate (PRPP) 2) Add base
De novo pyrimidine synthesis
1) Temporary base (orotic acid) 2) Add sugar + phosphate (PRPP) 3) Modify base
Which are synthesised first, ribonucleotides vs deoxyribonucleotides
Ribonucleotides are synthesized first and are converted to deoxyribonucleotides by ribonucleotide reductase
Carbamoyl phosphate is involved in what 2 metabolic pathways
1) De novo pyrimidine synthesis 2) Urea cycle
Inhibits dihydroorotate dehydrogenase (pyrimidine base production)
Leflunomide [dihydrOO leflOO]
Inhibit IMP dehydrogenase (purine base production)
Mycophenolate mofetil and ribavirin
Inhibits ribonucleotide reductase (pyrimidine base production)
Hydroxyurea
Inhibits de novo purine synthesis
6-MP and its prodrug azathioprine
Inhibits thymidilate synthase (dUMP>dTMP; pyrimidine base synthesis)
5-FU
Inhibits DHFR
1) MTX (humans) 2) TMP (bacteria) 3) Pyrimethamine (protozoa)
Inhibited by Allopurinol and Febuxostat in purine salvage pathway
Xanthine oxidase
Xanthine oxidase catalyses what 2 reactions in the purine salvage pathway
1) Hypoxanthine > xanthine 2) Xanthine > uric acid
Promotes excretion of uric acid in urine
Probenecid
Causes excess ATP and dATP > feedback inhibition of ribonucleotide reductase > prevents DNA synthesis > decreases lymphocyte count
Adenosine deaminase deficiency (one of the major causes of SCID)
Defective purine salvage due to absent HGPRT
Lesch-Nyhan syndrome
HGPRT catalyzes
1) Hypoxanthine to IMP 2) Guanine to GMP
Treatment of choice for Lesch-Nyhan
Allopurinol (2nd line: Febuxostat)
Genetic code feature: Each codon specifies only 1 amino acid
Unambiguous
Genetic code feature: Most amino acids are coded by multiple codons
Degenerate/ redundant
Genetic code feature: Read from a fixed starting point as a continuous sequence of bases
Commaless, nonoverlapping
Genetic code feature: Conserved throughout evolution
Universal
Amino acids encoded by only 1 codon each and are exceptions to degenerate/redundance feature of genetic code
1) Methionine 2) Tryptophan
Methionine, codon
AUG
Tryptophan, codon
UGG
Genetic code is universal except
In mitochondria
Y-shaped region along DNA template where leading and lagging strands are synthesized
Replication fork
Unwinds DNA template at replication fork
Helicase
Prevent strands from reannealing
Single-stranded binding proteins
Create a single- or double-stranded break in the helix to add or remove supercoils
DNA topoisomerases
Inhibit prokaryotic enzymes topoisomerase II (DNA gyrase) and topoisomerase IV
Fluoroquinolones
Prokaryotic DNA polymerase that elongates leading strand by adding deoxynucleotides to the 3_ end; has 5>3 synthesis and proofreads with 3>5 exonuclease
DNA polymerase III
Prokaryotic DNA polymerase that degrades RNA primer and replaces it with DNA
DNA polymerase I
Catalyzes the formation of a phosphodiester bond within a strand of double-stranded DNA (i.e., joins Okazaki fragments); SEALS
DNA ligase
An RNA-dependent DNA polymerase that adds DNA to 3_ ends of chromosomes to avoid loss of genetic material with every duplication
Telomerase
T/F Telomerase is found in both prokaryotes and eukaryotes
F, eukaryotes only
Severity of DNA damage from least to greatest
Silent, missense, nonsense, frameshift
Point mutations
1) Silent 2) Missense 3) Nonsense
Point mutation in which purine is replaced by purine or pyrimidine by another pyrimidine
Transition
Point mutation in which purine is replaced by a pyrimidine or pyrimidine by a purine
Transversion
Nucleotide substitution but codes for same (synonymous) amino acid
Silent
Nucleotide substitution resulting in changed amino acid
Missense
Nucleotide substitution resulting in early stop codon
Nonsense [Think STOP the NONSENSE]
Deletion or insertion of a number of nucleotides not divisible by 3, resulting in misreading of all nucleotides downstream, usually resulting in a truncated, nonfunctional protein
Frameshift
Type of mutation in Duchenne muscular dystrophy
Frameshift
Base change in silent mutation is usually at which position
3rd position
What do you call the base change in 3rd position of codon
tRNA wobble
A missense is called “conservative” if
The new amino acid is similar in chemical structure
Sickle cell disease is what type of mutation
Missense (glutamic acid>val)
Single strand DNA repair: Specific endonucleases release the oligonucleotides containing damaged bases; DNA polymerase and ligase fill and reseal the gap, respectively
Nucleotide excision repair
Nucleotide excision repair occurs in what phase of the cell cycle
G1
Single strand DNA repair: Important in repair of spontaneous/toxic deamination; occurs throughout the cell cycle
Base excision repair
What DNA repair mechanism is defective in xeroderma pigmentosum, which prevents repair of pyrimidine dimers because of ultraviolet light exposure
Nucleotide excision repair
What single strand DNA repair mechanism is defective in hereditary nonpolyposis colorectal cancer (HNPCC)
Mismatch repair
Mismatch repair occurs predominantly in which phase of the cell cycle
G2
Double strand DNA repair mechanism: Some DNA may be lost; mutated in ataxia telangiectasia and Fanconi anemia
Nonhomologous end joining
DNA and RNA are both synthesised in what direction
5’>3’
The ___ of the incoming nucleotide bears the triphosphate (energy source for bond)
5_ end
Protein synthesis is ___ to ___
N-terminus, C-terminus
mRNA is read from what end to what end
5’ to 3’
Target of the 3_ hydroxyl attack
Triphosphate bond
Drugs blocking DNA replication often have modified ___, preventing addition of the next nucleotide (“chain termination”)
3_ OH
mRNA start codon
AUG (rarely GUG) [Think inAUGurates protein synthesis]
AUG in eukaryotes codes for what amino acid
Methionine
AUG in prokaryotes codes for
N-formylmethionine (fMet)
Function of fMet
Stimulates neutrophil chemotaxis
mRNA stop codons
UGA, UAA, UAG [Think U Go Away, U Are Away, U Are Gone]
Site in the gene where RNA polymerase II and multiple other transcription factors bind to DNA upstream from gene locus
Promoter
AT-rich upstream sequence with TATA and CAAT boxes
Promoter
Stretch of DNA that alters gene expression by binding transcription factors
Enhancer
Site in the gene where negative regulators (repressors) bind
Silencer
RNA polymerase: Makes rRNA
RNA polymerase I
RNA polymerase: Makes mRNA
RNA polymerase II
RNA polymerase: Makes tRNA
RNA polymerase III
Most numerous RNA
rRNA [Rampant]
Largest RNA
mRNA [Massive]
Smalles RNA
tRNA [Tiny]
RNA polymerase: Opens DNA at promoter site
RNA polymerase II
RNA polymerase II is inhibited by what substance, which causes severe hepatotoxicty if ingested
alpha-amanitin, found in Amanita phalloides (death cap mushrooms)
Drug that inhibits RNA polymerase in prokaryotes
Rifampin
Drug that inhibits RNA polymerase in both prokaryotes and eukaryotes
Actinomycin D
How many RNA polymerases are then in prokaryotes?
Only 1 (makes all 3 kinds of RNA)
Initial RNA transcript in eukaryotes that is subsequently modified and becomes mRNA
Heterogenous nuclear RNA (hnRNA)
3 processes that occur in the nucleus following transcription
1) Capping of 5’ end (7-methylguanosine cap) 2) Polyadenylation of 3’ end 3) Splicing out of introns
Capped, tailed, and spliced RNA transcript is called
mRNA
Where does transcription occur
Nucleus
Where does translation occur
Cytosol
mRNA quality control occurs at
P-bodies in cytoplasm (also the site of mRNA storage)
Polyadenylation signal
AAUAA
Primary transcript combines with ___ and other proteins to form spliceosome
Small nuclear ribonucleoproteins (snRNPs)
Antibodies to snRNPs
Anti-Smith antibodies
Introns vs. exons: Contain the actual genetic information coding for protein
Exons
Introns vs. exons: Intervening noncoding segments of DNA
Introns
Introns vs. exons: Stay in the nucleus
Introns
RNA that assumes a cloverleaf form
tRNA
At which end of the tRNA is the anticodon found
Opposite the 3’ aminoacyl end
Amino acid is covalently bound to which end of tRNA
3’ end
This enzyme scrutinizes amino acid before and after it binds to tRNA, and if incorrect, bod is hydrolyzed
Aminoacyl-tRNA synthetase
T/F Accurate base pairing is usually required only in the first 2 nucleotide positions of an mRNA codon, so codons differing in the 3rd “wobble” position may code for the same tRNA/amino acid
T
Protein synthesis is initiated by
GTP hydrolysis
Ribosome site that receives incoming aminoacyl-tRNA
A site
Ribosome site that accommodates the growing peptide
P site
Ribosome site that holds empty tRNA as it exits
E site
At which ribosome subunit are the A, P, and E sites found
60S
___ catalyzes peptide bond formation and transfers growing polypeptide to amino acid in A site
rRNA (“ribozyme”)
Posttranslational modification of protein: Removal of N- or C-terminal propeptides from zymogen to generate mature protein (e.g., trypsinogen to trypsin)
Trimming
Posttranslational modification of protein: Phosphorylation, glycosylation, hydroxylation, methylation, acetylation, and ubiquitination
Covalent alterations
Intracellular protein involved in facilitating and/or maintaining protein folding, e.g. heat shock proteins
Chaperone protein
Shortest phase of cell cycle
M phase
Constitutive regulator of the cell cycle
CDKs
Regulatory proteins that control cell cycle events; phase specific; activate CDKs
Cyclins
Phosphorylate other proteins to coordinate cell cycle progression; must be activated and inactivated at appropriate times for cell cycle to progress
Cyclin-CDK complexes
Inhibit G1-to-S progression, the mutation of which result in unrestrained cell division
Tumor suppressors, p53 and Rb
Phase of the cell cycle where DNA synthesis occurs
S phase
Phases of the cell cycle
G0 > G1 > S > G2 > M > G0 or G1
Cells that remain in G0, regenerate from stem cells
Permanent cells (neurons, skeletal and cardiac muscle, RBCs)
Cells that enter G1 from G0 when stimulated
Stable (quiescent) (hepatocytes, lymphocytes)
Cells that never go to G0, divide rapidly with a short G1. Most affected by chemotherapy.
Labile cells (bone marrow, gut epithelium, skin, hair follicles, germ cells)
Site of synthesis of secretory (exported) proteins and of N-linked oligosaccharide addition to many proteins
RER
Site of synthesis of cytosolic and organellar proteins
Free ribosomes
Site of steroid synthesis and detoxification of drugs and poisons
SER
SER is rich in
1) Hepatocytes 2) Steroid hormone- producing cells of the adrenal cortex 3) Gonads
Distribution center for proteins and lipids from the ER to the vesicles and plasma membrane
Golgi
Abundant, cytosolic ribonucleoprotein that traffics proteins from the ribosome to the RER; the absence or dysfunction of which causes protein accumulation in the cytosol
Signal recognition particle (SRP)
Vesicular trafficking protein: Golgi > Golgi (retrograde); cis-Golgi > ER
COPI
Vesicular trafficking protein: ER > cis-Golgi (anterograde)
COPII
Trans-Golgi > lysosomes; plasma membrane > endosomes (receptor- mediated endocytosis)
Clathrin
Membrane-enclosed organelle involved in catabolism of very-long-chain fatty acids, branched-chain fatty acids, and amino acids
Peroxisome
Barrel-shaped protein complex that degrades damaged or ubiquitin-tagged proteins
Proteasome
Cell filament: Muscle contraction, cytokinesis
Microfilaments, e.g. actin
Cell filament: Maintain cell structure
Intermediate filaments, e.g. Vimentin, desmin, cytokeratin, lamins, glial fibrillary acid proteins (GFAP), neurofilaments
Cell filament: Movement, cell division
Microtubules, e.g. Cilia, flagella, mitotic spindle, axonal trafficking, centrioles
Immunohistochemical stain: Connective tissue
Vimentin
Immunohistochemical stain: Muscle
Desmin
Immunohistochemical stain: Epithelial cells
Cytokeratin
Immunohistochemical stain: Neuroglia
GFAP
Immunohistochemical stain: Neurons
Neurofilaments
Cylindrical structure composed of a helical array of polymerized heterodimers of _- and _-tubulin
Microtubule
Drugs that act on microtubules
[Microtubules Get Constructed Very Poorly] 1) Mebendazole (antihelminthic) 2) Griseofulvin (anti fungal) 3) Colchicine (anti gout) 4) Vincristine/Vinblastine (anticancer) 5) Paclitaxel (anticancer)
9 + 2 arrangement of microtubule doublets
Cilia
Immotile cilia due to a dynein arm defect; immotility in both men and women (immotile sperm and dysfunctional fallopian tube cilia)
Kartagener syndrome/primary ciliary dyskinesia
Inhibits Na-K ATPase pump by binding to K+ site
Ouabain
Drugs that directly inhibit the Na+-K+ ATPase, which leads to indirect inhibition of Na+/Ca2+ exchange > increase in [Ca2+]i > increase in cardiac contractility
Cardiac glycosides (digoxin and digitoxin)
Most abundant protein in the human body
Collagen
MC type of collagen (90%)
Type I
Synthesizes type I collagen in bone
Osteoblasts
Sites of type I collagen
Bone (made by osteoblasts), Skin, Tendon, dentin, fascia, cornea, late wound repair
Sites of type II collagen
Cartilage (including hyaline), vitreous body, nucleus pulposus
Sites of type III collagen
Reticulin—skin, blood vessels, uterus, fetal tissue, granulation tissue
Sites of type IV collagen
Basement membrane, basal lamina, lens
Collagen type: Decreased production in osteogenesis imperfecta type I
I
Collagen type: Deficient in the uncommon, vascular
type of Ehlers-Danlos syndrome
III
Collagen type: Defective in Alport syndrome
IV
Collagen type: Targeted by autoantibodies in Goodpasture syndrome
IV
In what cells is collagen synthesized
Fibroblasts
In what organelle is collagen synthesized
RER
Steps in collagen synthesis that take place in fibroblasts
1) Synthesis (preprocollagen) 2) Hydroxylation of proline and lysine residues 3) Glycosylation and formation of procollagen
Steps in collagen synthesis that take place outside fibroblasts
1) Proteolytic processing (formation of tropocollagen by cleavage of disulfide-rich regions of procollagen) 2) Cross-linking
Structure of preprocollagen (collagen alpha chains)
Gly-X-Y (Gly is glycine; X and Y are proline or lysine)
Best reflects collagen synthesis
Glycine
Collagen is 1/3 ___ (amino acid)
Glycine
What step in collagen synthesis requires Vitamin C?
Hydroxylation of specific proline and lysine residues
Problems forming triple helix of 3 collagen _ chains (glycosylation and formation of procollagen)
Osteogenesis imperfecta
Problems with collagen cross-linking lead to
1) Ehler-Danlos 2) Menkes disease
AKA Brittle bone disease
Osteogenesis imperfecta
Why is there hearing loss in osteogenesis imperfecta
Abnormal ossicles
Faulty collagen synthesis causing hyperextensible skin, tendency to bleed (easy bruising), and hypermobile joints
Ehlers-Danlos syndrome
MC type of Ehlers-Danlos syndrome
Hypermobility type
Classical type of Ehlers-Danlos is due to mutation of what collagen type
V
Vascular type (vascular and organ rupture) of Ehlers-Danlos is due to deficiency of
Type III collagen
X-linked recessive connective tissue disease caused by impaired copper absorption and transport due to defective ATP7A
Menkes disease
Menkes disease is associated with decreased activity of what enzyme
Lysyl oxidase (copper is a necessary cofactor)
Elastin is rich in what amino acids
1) Proline 2) Glycine 3) Lysine
