USMLE step 1 genetics: Difference between revisions

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==First==
==DNA synthesis==
 
Histone → Contain lysine and arginine
Histone → Contain lysine and arginine
DNA is negatively charged because of the negatively charged phosphate groups
DNA is negatively charged because of the negatively charged phosphate groups
Cytosine minus aminogroup = Uracil (Deamination)
Cytosine minus aminogroup = Uracil (Deamination)
G-C : 3 Hydrogen bonds. Higher melting points
G-C : 3 Hydrogen bonds. Higher melting points
A-T: 2 Bonds
A-T: 2 Bonds


Purine synthesis:
=== Purine synthesis: ===
You need glycine, glutamine and aspartate + tetrahydrofolate (Folic acid) + CO2
* You need glycine, glutamine and aspartate + tetrahydrofolate (Folic acid) + CO2
Rate limiting step : Glutamine PRPP amidotransferase
* Rate limiting step : Glutamine PRPP amidotransferase
Carbon sources:
* Carbon sources:
CO2, glycine, tetrahydrofolate
** CO2, glycine, tetrahydrofolate
Nitrogen sources
* Nitrogen sources
Aspartate + Glutamine
** Aspartate + Glutamine
Pyrimidines: Aspartate + carbamoyl phosphate (1 carbon and 1 nitrogen [glutamine]) + ATP
 
Carbamoyl phosphate → Has 1 carbon and 1 nitrogen
=== Pyrimidines: ===
You need aspartate + CO2 + glutamine + ATP (Last 3 come from carbamoyl phosphate)
Aspartate + carbamoyl phosphate (1 carbon and 1 nitrogen [glutamine]) + '''ATP'''
Carbamoyl phosphate synthetase 2 (RATE LIMITING STEP)
* Carbamoyl phosphate → Has 1 carbon and 1 nitrogen
Start with orotic acid then add a base
* You need aspartate + CO2 + glutamine + ATP (Last 3 come from carbamoyl phosphate)
Carbon sources:  
* Carbamoyl phosphate synthetase 2 (RATE LIMITING STEP)
Aspartate
* Start with orotic acid then add a base
CO2
* Carbon sources:
Glutamine → Gives nitrogen
** Aspartate
** CO2
* Glutamine → Gives nitrogen
CPS 1 + CPS 2
CPS 1 + CPS 2
CPS 1  
* CPS 1
Mitochondria
** Mitochondria
Urea cycle
** Urea cycle
Use nitrogen from ammonia
** Use nitrogen from ammonia
CPS 2
* CPS 2
Cytosol
** Cytosol
Pyrimidine synthesis
** Pyrimidine synthesis
Use nitrogen from glutamine
** Use nitrogen from glutamine
Orotic aciduria
 
Deficiency of UMP synthase
==== Orotic aciduria ====
AR
* Deficiency of UMP synthase
Elevated oritic acid
* AR
Megaloblastic anemia
* Elevated oritic acid
Not corrected with B12 or folic acid
* Megaloblastic anemia
No hyperammonemia
** Not corrected with B12 or folic acid
Treat with uridine
* No hyperammonemia
Ornithine Transcarbomylase Deficiency
* Treat with uridine
Causes hyperammonemia
 
Elevated orotic acid
==== Ornithine Transcarbomylase Deficiency ====
Problem with urea cycle
* Causes hyperammonemia
Dantrolene → Prevents release of calcium from SR of skeletal muscle
* Elevated orotic acid
Inhibit reuptake of norepinephrine:
* Problem with urea cycle
Cocaine
TCA
Ribosomes are synthesized in the nucleus and transported into the cytoplasm.
Ribosomes are synthesized in the nucleus and transported into the cytoplasm.
Ribosomes are made of proteins and rRNA
Eukaryotes → 60 and 40s = 80s
Prokaryotes → 50 s and 30 s = 70 s
Have 23s in 50s
Translation
Initiation
IF1, IF2, If3
Assist in assembly of smaller ribosomal subunit to first trna molecule
Methionine is always the start
f-Methionine in prokaryotes
IF-2 first binds to 30s and then to methionine tRNA. Then when 50s comes along, it hydrolyzes GTP on IF2 and allows 50s to attach to 30s
A site → Incoming aminoacyl TRNA binds
P site → Polypeptide binds (Growing chain)
First tRNA binds here
E site → Free tRNA (exit)
Elongation
Incoming charged aminoacyl TRNA binds to A site
Elongation factor help incoming trna to bind to A site (Uses GTP)
50s has peptidyl transferase transfers AA from p site to A site
In prokaryotes, activity is in 23s subunit of 50s rRNA
Translocation
Ribosome complex moves 3 nucleotides
tRNA + Peptide is moved from A site to P site
Newly uncharged tRNA from P side to E side
EF-G  → Eukaryotes
EF-2 in eukaryotes
Diptheria and exotoxin (Pseudomonas) inhibit this
Termination
Stop codons
UGA, UAA and UAG
Signal to STOP
No new TRNA coming
Release factor binds to MRNA and hydrolyzes GTP and new polypeptide is released.
Antibiotics
Aminoglycosides → Inhibit 30s subunit before initiation (No pairing with TRNA)
Linezolid → Inhibits initiation by binding to 50s subunit
Tetracycline
Bind to 30s subunit
Prevent aminoacyl TRNA from binding to A site
Chloramphenicol
Inhibits peptidyl transferase
Binds to 50s
Macrolides
Inhibits translocation by binding to 50s subunit
Clindamycin
Same as macrolides
Lincamycin
Bind to 50s and inhibit translocation
Streptrogranin
Bind to 50s and inhibit translocation
Buy AT 30 ,CCELL at 50
Post translational modification
Trim terminals
Covalent modification
Glycosylation, hydroxylation, phosphorylation
Collagen → Hydroxylation of proline and lysine
Disulfide bonds
Protein folding
Primary structure → Chain
Secondary structure → Beta and alpha pleated
Tertiary structure

Latest revision as of 22:31, 26 September 2018


Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1] Mahshid Mir, M.D. [2]

DNA synthesis

Histone → Contain lysine and arginine

DNA is negatively charged because of the negatively charged phosphate groups

Cytosine minus aminogroup = Uracil (Deamination)

G-C : 3 Hydrogen bonds. Higher melting points

A-T: 2 Bonds

Purine synthesis:

  • You need glycine, glutamine and aspartate + tetrahydrofolate (Folic acid) + CO2
  • Rate limiting step : Glutamine PRPP amidotransferase
  • Carbon sources:
    • CO2, glycine, tetrahydrofolate
  • Nitrogen sources
    • Aspartate + Glutamine

Pyrimidines:

Aspartate + carbamoyl phosphate (1 carbon and 1 nitrogen [glutamine]) + ATP

  • Carbamoyl phosphate → Has 1 carbon and 1 nitrogen
  • You need aspartate + CO2 + glutamine + ATP (Last 3 come from carbamoyl phosphate)
  • Carbamoyl phosphate synthetase 2 (RATE LIMITING STEP)
  • Start with orotic acid then add a base
  • Carbon sources:
    • Aspartate
    • CO2
  • Glutamine → Gives nitrogen

CPS 1 + CPS 2

  • CPS 1
    • Mitochondria
    • Urea cycle
    • Use nitrogen from ammonia
  • CPS 2
    • Cytosol
    • Pyrimidine synthesis
    • Use nitrogen from glutamine

Orotic aciduria

  • Deficiency of UMP synthase
  • AR
  • Elevated oritic acid
  • Megaloblastic anemia
    • Not corrected with B12 or folic acid
  • No hyperammonemia
  • Treat with uridine

Ornithine Transcarbomylase Deficiency

  • Causes hyperammonemia
  • Elevated orotic acid
  • Problem with urea cycle

Ribosomes are synthesized in the nucleus and transported into the cytoplasm.

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