Part 1. Amino Acid Degradation and Urea Cycle Flashcards
What is the amino acid pool?
Inputs and utilization
Protein turnover (defective damaged, not needed proteins), dietary proteins, and amino acid biosynthesis are the input
The utilization of amino acid pool is synthesis of proteins, synthesis of nitrogenous molecules (purines, pyrimidines), and degradation of amino acids carbon skeleton
If a molecule can be converted to acetyl CoA, then ketone bodies, fatty acids, and steroids can be made
Slide 3 mar 8
How are dietary proteins digested?
Proteins are too large generally to be absorbed intact so are digested into amino acids and di and tri peptides
Proteolysis- hydrolysis cleavage of proteins by proteases in stomach and intestine
Slide 5 Mar 8
What are the steps of protein digestion?
- The mouth sets the path for the beginning of digestion, chewing causes neural effects that stimulate gastric juice production and release of peptide hormone production
- True digestion begins in the stomach (more protein added, more gastric juice pH 1.5-3)
Pepsin used to break up proteins - Small intestine is where protein digestion is completed, bicarbonate is major component as base buffer between the gastric juice and other compounds
Proteases act upon the broken down molecules to digest them (need denatured proteins) - Then amino acids absorbed to epithelial cells and moved to blood by portal vein
What is the gastroesophageal reflux disease (GERD)?
Heartburn!
Medications?
The K+/H+ pump in the membrane of specialized stomach cells pumps protons into the stomach in exchange for K+ at the expense of ATP hydrolysis, this generates acidic environment and releases heat
cAMP levels rise then PKA (protein kinase A) phosphorylates the proton pump and moved them to surface of cell
If the pump is overactive or the esophageal sphincter is weak, GERD is the result (add tums if over production of acid, histamine blocker blocks one half of pathway, and direct proton pump inhibitor)
Slides 8-9 Mar 8
What are zymogens?
All proteolytic enzymes are secreted as inactive zymogens
They are activated by proteolysis which allows for proper folding of the enzyme
Proteolytic enzymes are stored as zymogens so that they don’t breakdown proteins in the cells where they are made and stored
Slide 11 Mar 8 pepsinogen converted to active form (red catalytically inactive)
Slide 12 Mar 8
Why are there so many different proteolytic enzymes?
What are pepsin and trypsin examples?
They have different substrate specificities to allow proteins to be cut into much smaller fragments rapidly
Substrates have substrate specificity and side chains can be very different in amino acids
Pepsin- preferentially cleaves peptide bonds between hydrophobic amino acids and aromatic amino acids
Trypsin- cleaves peptide bonds following Arg or Lys residue
Slide 14 Mar 8
What is the 3 steps of the fate of the amino group of amino acids?
- Transanimation
α-amino acids and α-ketoglutarate are converted to α-keto acids and L-glutamate - Oxidative deamination
L-glutamate is converted to α-ketoglutarate and produces NH4+ (ammonia) - Urea cycle
NH4+ and CO2, Asp are converted to urea in the liver then moves to blood then kidney then urine
Transdeamination reaction= transamination + oxidative deamination reactions
Slide 5 Mar 11
What are the steps in transamination?
Enzyme- aminotransferase
Coenzyme- pyridoxal phosphate (PLP)
L amino acid transfers amino group to α-ketoglutarate (L-glutamate)
Slide 6-7 Mar 11
What are the two specific aminotransferases and their amino acid/Keto-acid pairings?
Alanine transaminase- glutamate + pyruvate = alanine + α-ketoglutarate
AST - glutamate + oxaloacetate = asparate + α-ketoglutarate
Slide 8 Mar 11
3rd one is aminotransferase with its four
What is the fate of glutamate in the liver?
Transported to mitochondria and undergoes oxidative deamination to release ammonia
Amino acids -> glutamate by aminotransferase
Glutamate+α-keto acid -> glutamate (in the mitochondrion)
Glutamate -> α-ketoglutarate + NH4+
Slide 9 Mar 11
What are the steps and enzyme uses in the oxidative deamination of glutamate?
Activators and inhibitors?
Enzyme- L-glutamate dehydrogenase
Coenzyme- NAD+ or NADP+
ADP activates and GTP inhibits
Removes amino group from glutamate as NH4+
High concentration of NH4+ is toxic
NH4+ is converted to urea in the liver
Slide 10 Mar 11
What are the 2 ways that ammonia produced in non liver tissues get to the liver so it can be converted to urea?
- In most tissues: NH4+ reacts with glutamate to form glutamine (by enzyme glutamine synthetase)
Glutamine is a non toxic storage and transport for NH4+ by the blood
NH4+ is released by glutamine by cleavage by the enzyme glutaminase - In muscle: glucose alanine cycle, glutamate is formed by transamination reactions, glutamate then transfers it’s amino group to pyruvate to form alanine which can leave muscles to the blood to liver where transamination occurs again to release the amino group as ammonium
Slides 11-12 Mar 11
What is the overview and goals of amino group catabolism in the liver?
Slide 2 Mar 13
Goal is to keep levels of free NH4+ low (high levels are harmful to CNS), and to get NH4+ to the liver so it can be used to produce urea which is non toxic and excretable
NH4+ is transported to liver as alanine and go
What is the urea cycle?
Cyclical pathway whereby excess NH4+ is converted to urea
(Memorize NH4+ structure slide 3 mar 13)
Occurs in liver through a series of reactions in the cytosol and mitochondria (cytosol is enzymes are present in a cluster)
Urea is secreted into the blood, filtered by kidneys, then excreted in urine
Costs 3 ATP
Examples slides 4-6 Mar 13
Overview slide 7 Mar 13
What is carbamoyl phosphate synthesis?
It’s enzyme?
Ammonia + bicarbonate -> carbamoyl phosphate
Enzyme: carbamoyl phosphate synthetase I
2 ATP in and 2 ADP + Pi out
THIS IS RATE LIMITING STEP IN UREA BIOSYNTHESIS
Requires N-acetylglutamate as allosteric activator
Slides 8-9 Mar 13
