Nitrogen metabolism

Question 1

Phenylalanine hydrolase

Answer 1

• PAH
• Phenylalanine + tehtrahydrobiopeterin (BH4) (cofactor)–>Tyrosine + dihydroiopeterin (BH2)

Defect in PKU I (classic PKU)

Question 2

PKU I

Answer 2

• defect in phenylalanine hydroxylase
• can’t convert phenylalanine to tyrosine (tyrosine becomes essential AA)
• decreased melanin synthesis (from tyrosine)–>decreased pigmentation of skin (phe–|tyrosinase)
• CNS symptoms: delay in milestones, low IQ (untreated, major IQ reduction in early development); Seizures @ high blood [phe]
• Phe metabolized to phenylpyruvate, phenylacetate, phenyllactate–>excrete in urine–>mousey odor
• blood [Phe] elevated

-IQ decreases after cessation of Phe free diet

Treatment:

• dietary restriction of Phe
• Sapropterin–>synthetic BH4 (mild or moderate forms of disease) (mutant enzyme with low cofactor affinity)

Question 3

Sapropterin

Answer 3

synthetic tetrahydrobiopterin (BH4)

Question 4

Maternal PKU syndrome

Answer 4

High Phe in mothers is tratogenic–>leads to birth defects

• microcephaly, mental retardation, congenital heart defects
• kid isn’t PKU + (ususally heterozygous)

Question 5

PKU II

Answer 5

• malignant PKU
• deficiency of diydrobiopterin reductase (BH2/BH4) or BH2 synthesis
• more severe/worse prognosis than PKU I
• CNS symptoms worse–>decreased neurotransmitter synthesis (serotonin, dopamine, catecholamines)
• treatment: Phe restriction, dietary biopterin and precursors of neurotransmitters (blood/brain barrier limits efficacy)
• elevated Phe and metabolites
• phenylpyruvic acid in urine leads to mousey odor

Question 6

dihydrobiopterin reductase

Answer 6

Dihydroiopterin (BH2)–>tetrahydrobiopterin (BH4)

deficient in PKU II

Question 7

Homogentisic acid oxidase

Answer 7

Full name homogentisate 1,2-dioxygenase

homogentisic acid—> maleylacetoacetate

used in pathway from tyrosine to fumarate and acetoacetate

Question 8

Alkaptonuria

Answer 8

• defect in homogentisate 1,2-dioxygenase
• homogentisic acid–>maleylacetoacetate
• ^ is a brown pigment
• relatively benign
• Ochronosis: homogentisic acid deposits in cartilage and connective tissue–>leads to severe arthritis
• homogentisic acid is excreted in urine–>brown color on standing (oxidation of homogentisic acid)
• dietary restriction of Phe and Tyr may reduce deposition
• bluish-black discoloration of sclera and auriculum)

Question 9

Tyrosinosis

Answer 9

• Tyrosinemia type I
• deficinecy of fumarylacetoacetate hydrolase
• build up of fumaryl acetoacetate leads to kidney and liver damage
• severe usually fatal
• cabbage-like odor of urine
• attempt dietary restriction of Phe and Tyr (difficult b/c both essential and needed for neurotransmitter synthesis)

Question 10

Fumarylacetoacetate Hydrolase

Answer 10

fumarylacetoacetate–>fumarate + acetoacetate

defective in Tyrosinemia Type I

Question 11

Maple Syrup Urine Disease (MSUD)

Answer 11

• deficiency of branched chain α-ketoacid dehydrogenase (branched chain keto acid–>___acyl-CoA)
• rare
• symptoms develp @ 4-7 days
• presents with poor feeding, vomiting, poor weight gain, increasing lethargy
• neurological signs (alternating muscular hypotonia and hypertonia, seizures, encepalopathy)
• ketosis–>maple syrup odor
• coma and death in early infancy if untreated
• Treatment: dietary restriction of branched chain amino acids (leu, ile, val)–>all essential, difficult (improves neurological manifestations; dietary supplementation with TPP (vit B1 useful in some pts with low coenzyme affinity)

Question 12

Branched chain α-ketoacid dehydrogenase

Answer 12

• Requires TPP
• deficiency causes MSUD
• branched chain keto acid–> corresponding acyl-CoA
• paralog of αKgDH, PDH

Question 13

Methylmalonic Aciduria

Answer 13

• deficiency in Methylmalonyl-CoA Mutase
• elevated levels of methylmalonic acid (methylmalonic acidemia)
• metabolic acidosis
• Methylmalonic Aciduria
• neurological symptoms: seizures, encephalopathy
• some pts improve with B12 (cobalmin) supplementation–>those with reduced coenzyme affinity

Question 14

Methylmalonyl-CoA Mutase

Answer 14

• methylmalonyl-CoA to succinyl-CoA
• reuqires vit B12 cofactor dervived cofactor-adenosylcobalamin
• deficiency causes methymalonic aciuria

Question 15

Homocystinuria/Hyperhomocysteinemia

Answer 15

• group of disorders involving homocysteine metabolism–>commonly Cystathionine β-synthase
• homocysteine accumulates in connective tissue and disrupts the structure (forms disulfide bridges with collagen cys residues)
• dislocation of lens (ectopia lentis) after age 3 (and other ocular abnormalities)
• skeletal abnormalities (childhood osteoporosis)
• mental retardation
• premature arterial disease (lipid deposits–>atheromas; lipid oxidation and platelet aggregation–>fibrosis & calcification of atherosclerotic plaques)
• some pts respond to oral vit B6
• special diet

-Hyperhomocysteinemia is typically managed with vitamin B6, folic acid, and vitamin B12 supplementation. [3] Taurine supplementation also has been found to reduce homocysteine levels.[4] (http://en.wikipedia.org/wiki/Hyperhomocysteinemia)

Question 16

Cystathionine β-synthase

Answer 16

• part of transulfuration pathway (methionine to cys)
• homocysteinine–>cystathionine
• requires PLP (vit B6)

Question 17

Fate of homocysteine

Answer 17

• recycled to methionine (required THF and vit B12)
• sulfur transfered to serine by Cystathionine β-synthase in transulfuration rxn forming cysteine and a carbon skeleton (require B6=PLP), carbons–>Succinyl-CoA (needs B12)

Question 18

Amino acid pool

Answer 18

• circulating free amino acids
• sources: dietary, tissue protein catabolism, synthesis of non-essential

Uses:

• Amnio acid catabolism: ammonia–>urea
• Carbon skeleton: glucose/lipid synthesis, oxidation in TCA (pyruvate)
• stynthesize nitrogen containing compounds: creatine, heme, neurotransmitters, purines, pyrimidines, etc
• build proteins

Question 19

Essential Amino Acids

Answer 19

• Phenylalanine (F), Valine (V), Tryptophan (W), Threonine (T), Isolucine (I), Methionionine (M), Arginine* (R), Leucine (L), Lysine (K)
• Arg is essential only during high demand in childhood

The Whole Food Ladder Really Must Have Various Key Ingredients

Question 20

Conditionally Essential AA

Answer 20

• Cysteine-when met is insufficient
• Arg-conditional during rapid growth when in high demand
• Tyrosine: Y and F can be interconverted, one is needed

Question 21

Protein degredation pathways

Answer 21

• Lysosomal-extracellular or membrane proteins

- ubiquitin/proteasome-proteins made by the cell

Question 22

Ubiquitin/Proteasome degredation

Answer 22

• used for oxidatively damaged, or denatured proteins

- PEST sequences-rich in pro, blu, ser, and the have short t1/2

Question 23

Lysosome functions

Answer 23

• normal degredation fo some cellular components
• material from phagocytosis
• receptor mediated endocytosis (i.e.: LDL receptor)
• autophagy
• extracellular digestion: acrosome, inflammatory processes can cause inappropriate release of lysosomes from WBC’s (i.e.: gout)

Question 24

Liver in N metabolism

Answer 24

• deamination (AA–>NH3 + carbon skeleton)
• NH3–>urea (urea cycle)
• carbon skeleton–>gluconeogenesis, TCA, ketogenesis, probably FA de novo synthesis

Question 25

Kidney in N metabolsim

Answer 25

• excretes urea from liver in urine
• excrete NH3 as NH4+ (regulation of acid/base balance; source is gluatmine, glutaminase)
• excretes uric acid (end product of purine degradation), creatinine (end product of creatine degradation), nitrogenous non-protein substances

Question 26

Cystinuria

Answer 26

• caused by decreased tubular reabsorption of cystein (and other dibasic aa’s ornitine, arg, lys)
• inherited deficiency of cystine transporter
• Cystine excreted in urine
• Cys precipitates in renal tubules (systine stones)–>cause of renal stones in children

Question 27

Hartnup’s Disease

Answer 27

• inherited defect in transport of neutral amino acids (ex: tryptophan)
• decreased absorption and increased excretion (due to decreased reabsorption)
• Some pts experience niacin def (low protein diet)–>NAD+ deficiency aka pellagra (niacin is usually synthesized from W)
• 4D’s of Pellagra: diarrhea, dermatitis, dementia, death

Question 28

Ketogenic Amino acids

Answer 28

exlusively: Leu, Lys
also glucogenic: Ile, Phe, Tyr, Trp

Ile, Leu—>acetyl-CoA
Leu, Lys, phe, trp, tyr–>acetoacetyl-CoA

Question 29

Glucogenic AA

Answer 29

everything except Leu and Lys
also Ketogenic: Ile, Phe, Tyr, Trp

*Asn, Asp-->OAA
Phe, Tyr--->fumarate
Ile, Val (branched chain)-->Succinyl-CoA
**Ala-->pyruvate
**Glu, Gln-->α-ketogluterate

Question 30

ALT

Answer 30

• Alanine aminotransferase/transaminase
• Requires PLP (B6)

Ala + αKG Pyruvate + Glu

reversable, driven by concentration

-in liver, entrance of asp into TCA, also another enzyme that can interconvert Glu and α-KG

Question 31

Importance of Alanine

Answer 31

• major transport Amino acid from muscle to liver (glucose/alanine cycle)
• major precursor of glucose genesis (ALT to pyruvate)

Question 32

Glucose/Alanine cycle

Answer 32

a/k/a Cori Cycle:

• pyruvate formed in muscle converted to Ala and transported to liver
• in liver turned back to pyruvate, used as substrate for glugoneogenesis, glucose put back into blood to muscle

Question 33

Glutamate dehydrogenase

Answer 33

Glutamate + NAD+ α-ketogluterate + NH3 + NADH

• Oxidative deamination/reductive amnination (backwards)
• Goes forwards in liver to deliver α-ketogluterate to TCA under starvation, also release NH3 for urea cycle

-Goes reverse in peripheral tissues to sequester NH3 for transport to liver for urea cycle when tissue [NH3] is high

1 of 3 enzymes that can incoporate free NH3

Question 34

AST

Answer 34

Aspartate aminotransferase a/k/a serum glutamic oxaloacetic transaminase (SGOT)

Requires PLP (B6)

Aspartate + α-ketogluterate Oxaloacetate + Glutamate

-in liver, entrance of asp into TCA, also another enzyme that can interconvert Glu and α-KG

Question 35

enzymes that do: α-ketogluterateglutamate

Answer 35

ALT, AST, and glutamine transaminase

Question 36

Glutamine Synthetase

Answer 36

Glutamate + NH3 + ATP—->Glutamine + ADP + Pi

• present in peripheral tissues, especially important in Brain (neurotransmitter synthesis I belive uses many deaminations, maybe) and endothelium of hepatic vein (prevent free NH3 from getting to the rest of the body)
• 1 of 3 enzymes that can incorporate free NH3
• Glutamine used to transport NH3 to liver

Question 37

Glutaminase

Answer 37

• Glutamine + H2O—>Glutamate + NH3
• present in renal tubules and liver
• renal: used to maintain acid/base balance, excrete as NH4+
• liver: NH3 goes into urea cycle, glutamate gives off another NH3 using GDH, and α-KG goes into TCA

Question 38

Asparagine Synthetase

Answer 38

Aspartate + Glutamine + ATP —->Asparagine + AMP + PPi

-uses glutamine as source of Nitrogen

Question 39

Asparaginase

Answer 39

Asparagine + H2O —> Aspartate + NH3

• ASP is used to make OAA by AST for TCA/gluconeogenesis
• NH3 to Urea cycle
• Used to treat leukemia pts (leukemia cells need Asn, reduce availability to limit growth)

Question 40

General transaminase rxn

Answer 40

α-Amino acid + α=ketogluterate α-keto acid + Glutamate

• All transaminases require PLP (vitamin B6)
• α-Kg is usually the amino acceptor but there are exceptions
• glutamate becomes important N carrying group

Question 41

Ammonia transport

Answer 41

• Alanine: from muscle; transamination of pyruvate buy ALT
• Glutamine: most tissues; from glutamine by glutamine synthase (glutamate from protein breakdown, glutamate dehydrogenase, ALT, AST)

Question 42

NH3 formation in liver

Answer 42

• Glutamate: Glutamate dehydrogenase, get NH3
• Glutamine: Glutaminase forms NH3 and glutamate
• Alanine and other AAs: transaminases (using PLP) form glutamate

Question 43

Sources of N in urea cycle

Answer 43

• 1st from NH3

- 2nd from Asp (remember asp forms OAA by AST using Glu as N source)

Question 44

Urea cycle enzymes in order

Answer 44

1. Carabmoylphosphate synthetase I, CPS-1 (mito) (rate limiting step)
2. Ornithine Transcarbamyolase, OTC (mito)
3. Arginosuccinate Synthetase, ASS (cyto)
4. Arginosuccinate Lyase, ASL (cyto)
5. Arginase, ARG1 (cyto)

Question 45

Urea cycle intermediates in order

Answer 45

Starting material: HCO3-, NH4+, 2 ATP

1. Carbamyl phosphate
2. Citrulline (+Aspartate)
3. Argininosuccinate
4. Arginine (+fumerate)
5. Ornithine (+Urea)

Question 46

CPS-I

Answer 46

Carbamoyl Phosphate Synthetase I
HCO3- + NH4+ 2 ATP —> Carbamyl Phosphate + 2 ADP + Pi

• 1st and rate limiting step
• Mitochondria
• N-acetylglutamate is required as an absolute activator
• 1 of 3 enzymes that incorporate free NH3

Question 47

OTC

Answer 47

Ornithine Transcarbamyolase
Carbamyl Phosphate + Ornithine –> Citrulline + Pi

• 2nd step
• mitochondria

Question 48

ASS

Answer 48

Argininosuccinate Synthetase
Citrulline + ATP + Aspartate –> Argininosuccinate + AMP + PPi

• 3rd step
• cytosol

Question 49

ASL

Answer 49

Argininosuccinate lyase
Argininosuccinate –> Arginine + Fumarate

• 4th step
• cytosol
• Fumerate my enter TCA or be oxidized back to oxaloacetate

Question 50

ARG-I

Answer 50

Arginase
Arginine–>Urea + Ornithine

• 5th step
• cytoplasm

Question 51

Enzymes that incorporate free NH3

Answer 51

Glutamate Dehydrogenase, Glutamine synthase, Carbamyl Phosphate Synthase I

Question 52

Energy used in urea cycle

Answer 52

4 high energy bonds: 2 ATP–>ADP, 1 ATP–>AMP

Question 53

Inherited Urea Cycle disorders

Answer 53

• accumulation of substrates of deficient enzyme (any complete absence would be miscarriage)
• Increased blood ammonia (hyperammonemia) and elevated blood glutamine
• urea formation decreased altough levels will be approximately normal
• Hyperammonemia symptoms appear in first few days: lethargy, irritability, feeding difficulties
• nerurological symptoms if untreated i.e.: seizures, mental retardation
• CPS1 and OTC (first two) are most severe

Question 54

Hyperammonemia Type I

Answer 54

• Carbamoyl-phosphate synthetase deficiency
• hyperammonemia
• neurological symptoms
• elevated glutamine
• sometimes respons to Arg intervention (arg stimulates NAG formation, might stimulate CPS-I)

Question 55

Hyperammonemia Type II

Answer 55

• Ornithinie Transcarbamyolase deficiency
• X-linked (more in male, more severe in male)
• most common
• hyperammonemia
• increased orotic acid in urine and serum (orotic aciduria/emia) (mostly worry about the urine)
• diagnose by elevated serum ammonia and urine orotic acid

Question 56

Citrullinemia

Answer 56

• Argininosuccinate synthetase deficiency
• diagnosis: hyperammonemia, very increased citrulline levels (blodd and urine)
• treatment may include arginine–>enhance urinary citrulline excretion. drive urea cycle with more substrate

Question 57

Argininosuccinic aciduria

Answer 57

• Argininosuccinate Lyase deficiency
• hyperammonemia
• diagnosis: argininosuccinate elevated in plasma and CSF, increased argininosuccinate levels in urine, moderately high citrulline
• can sometimes treat with arginine–>enhance urinary excretion, push urea cycle with substrates/intermediates

Question 58

(Hyper)argininemia

Answer 58

• Arginase deficiency
• increased arginine levels
• diagnosis: high serum arg and NH3 (NH3 not as high as other UCDs)
• restrict diet to essential amino acids excluding arginine
• frequently adult onset: neurological problems

Question 59

Treatment of hyperammonemia

Answer 59

• dialysis-emergency
• benzoic acid–>benzoyl-CoA + glycine–> Hippurate (remove 1 mol N per mol of drug)
• low protein/high carb diet (minimize N intake)
• avoid stresses leading to catabolic state
• long term: liver transplant
• phenylbutrate–>phenylacetate–>phenylacetyl-coA–>phylacetylglutamine (2 N per molecule removed in urine)

Question 60

Phenylbutrate

Answer 60

phenylbutrate–>phenylacetate–>phenylacetyl-coA–>phylacetylglutamine (condense with glutamine)

-2 N per molecule removed in urine

Question 61

benzoic acid

Answer 61

benzoic acid–>benzoyl-CoA + glycine–> Hippurate (remove 1 mol N per mol of drug)

Question 62

Fate of Urea

Answer 62

• transported to kidney, eliminated in urine
• 25% degraded by bacterial ureases in gut–>ammonia returns to circulation (85% portal, 25% systemic) and must go through urea cycle again
• kidney failure–>elevated blood urea nitrogen (BUN) wherease UCD leads to elevated NH3

Question 63

Aquired hyperammonemia

Answer 63

• liver disease (viral or drug induced hepatitis, alcoholic cirrhosis, I think some GSDs)
• cirrhosis–>portocaval anastamosis leads to higher [NH3] in systemic circulation b/c blood doesn’t go through liver–>neurotoxicity

Treatment:

• low protein/high carb diet (less N ingested)
• Lactulose-disaccharide, resistant to digestion–>used by intestinal flora–>produce lactic acid–>neutralized by NH4+–>N excreted in feces
• Neomycin (or other antibiotic)–>kill your flora, less urease
• other treatments

Question 64

Hypothesises for NH3 neurotoxicity:

Answer 64

Energy and osmotic effect:
α-ketogluterate–>glutamate requires reducing equivalents and consumes TCA cycle intermediates–>less TCA–>less ATP synthesis–>reduced K+/Na+ ATPase–>up osmotic pressure–>neuronal death

Neurotransmittler effect:
Glutamate to glutamine (using glutamine synthase–>high serum glutamine)–>reduced glutamate and GABA (made from glutamate in brain) (both reduced at high NH3) (GABA is an inhibitory NT, GLU is a major excitatory NT)

Question 65

Tyrosine hydroxylase

Answer 65

Tyrosine—>L-DOPA (dihydroxyphenylalanine)

requires tetrahydropiopterin (BH4) (–>BH2)

Question 66

DOPA Decarboxylase

Answer 66

L-DOPA—>Dopamine + CO2

Requires PLP (vit B6)

Question 67

Dopamine β-decarboxylase

Answer 67

L-DOPA + O2 —>Norepinepherine + H2O

Requires Vitamin C (absorbic acid—>dehydroxyascorbic acid)

Question 68

Phenylethalnolamine-N-methyltransferase

Answer 68

Norepinepherine + S-adenosyl-methionine (SAM)–>Epinepherine + homocysteine

Question 69

Parkinson’s Disase

Answer 69

• neurodegenerative disorder
• loss of dopamine producing cells
• movement disorders: spasticity, tremors, loss of memory, mood distrubances, postural instability
• improve with administration of L-DOPA–>converted to dopamine in brain (inc [substrate])
• Inhibit peripheral dopamine formation (so that L-DOPA is use preferentially in brain)–>DOPA decarboxylase inhibitor (presumably can’t cross blood brain barrier)

Question 70

Norepinephrine and Epinephrine degredation

Answer 70

2 enzymes: Monoamine Oxidase A (requires FAD), then Catechol-O-methyltransferase (COMT, requires S-adenosyl-methionine)
(Nor)epinephrine—->——>Vanillyl Mandelic Acid (VMA)

VMA excreted in urine, used to measure (nor)epinepherine levels

Question 71

Dopamine Degredation

Answer 71

2 Enzmes:
Monoamine oxidase (A or B don’t matter) (FAD)
Catechol-O-methyltransferase (COMT) (SAM)

Dopamine—>—>homovanillic acid (HVA)

-HVA in urine, presumably can beassayed for dompamine levels

Question 72

Pheochromocytoma

Answer 72

• tumor of adrenal gland medulla leading to overprocudtion of catecholamines
• predominant symptoms: headache, sweating, tachycardia
• also palpitations, anxiety, panic attacks, hypertension
• symptoms are episodic
• Diagnosis: high urinary VMA and catecholamines–>24 hr measurement during symptom episode

Question 73

Serotonin synthesis and degradation

Answer 73

Tryptophan—>5-hydroxytryptophan (5-HTP)—–>Serotonin (5-hydroxytryptamine)—–>5-hydroxyindole acetic acid (5-HIAA)

1. Tryptophan Hydroxylase (BH4)
2. (Aromatic L-) Amino acid Decarboxylase (PLP/B6)
3. MAO-A (FAD)

Produced in gut, platelets and CNS

Question 74

Tryptophan Hydroxylase

Answer 74

Tryptophan—->5-hydroxytryptophan

requires BH4–>BH2

Question 75

Aromatic acid decarboxylase

Answer 75

5-hydroxytryptophan—>Serotonin
-PLP

Wikipedia:
Full name: Aromatic L-amino acid decarboxylase
Same as Dopa decarboxylase
L-DOPA to dopamine - a neurotransmitter
5-HTP to serotonin (5-HT) - also a neurotransmitter
tryptophan to tryptamine - a precursor to many alkaloids found in plants and animals
Phenylalanine to phenethylamine - a trace neurotransmitter

Question 76

Carcinoid Syndrome

Answer 76

• tumor of serotonin producing cells in GIT (APUD cells)
• Cutaneous flushing
• gastrointestinal hypermotility–>diarrhea
• bronchospasm
• increase 5-HIAA in urine

Question 77

Melanin

Answer 77

-derived from Serotonin (which was derived from trypophan)

Question 78

Tetrahydrobiopterin

Answer 78

• BH4
• required cofactor in many amino acid hydroxylations
• Penylalanine/tyrosine/tryptophan hydroxylases
• Also Nitric oxide synthase (NOS) and Alkylglycerol monooxygenase

Question 79

Tetraydrobiopterin Deficiency

Answer 79

• caused by deficiency of dihydrobiopterin synthase of BH2 reductase
• hyperphenylalaninemia and decreased synthesis of neurotransmitters (catecholamines and serotonin)
• delayed mental development and seizures
• Managed with dietary BH4, dietary neurotransmitter precursors, restriction of Phe

Question 80

Glutamate Decarboxylase

Answer 80

Glutamic Acid—>Gamma amino butyric acid

requires PLP

Question 81

GABA

Answer 81

• inhibitory neurotransmitter in CNS

- formed from glutamate by glutamate decarboxylase

Question 82

Histidine Decarboxylase

Answer 82

Histidine——>histamine
PLP
(Sobering doesn’t care if we know something this simple)

Question 83

Histidine

Answer 83

• synthesized from Histidine by histidine decarboxylase (with PLP) in Mast Cells
• vasodialator
• antihistimine drugs reduce adverse affects of allergic reactions
• antihistimies are typically receptor antagonists or otherwise interrupt signalling pathway, do not normally interere in synthesis

Question 84

Creatine

Answer 84

• reservoir of high energy bonds in muscle
• synthesized from Arg, Gly, and SAM
• accepts Pi groups from ATP when resting (Creatine Kinase)
• dontates Pi to ADP when contracting (Creatine Kinase)
• spontaneously converted to Creatinine–>end product of creatine metabolsm

Question 85

Creatinine

Answer 85

• spontaneously formed from Creatine–>end product of creatine metabolsm, eliminated in urine
• dependent on muscle mass of individual
• serum creatinine used as marker of kidney fxn–>not efficiently filtered in renal failure, serum creatinine rises

Question 86

Creatine Kinase

Answer 86

• or Creatine Phosphokinase
• creatine + ATPcreatine-Pi + ADP
• total CK/CK-MB used as marker of MI

Question 87

Nitric Oxide

Answer 87

• Synthesized from Arginine–>NO⋅ + citrulline
• Nitric Oxide Synthase requires heme, NADPH, FAD, FMN, BH4
• made in enothelial cells
• local vasodialation
• nitroglycerin–>converted to NO⋅ causes vasodialiation of coronary blood vessels–>improvement of blood flow to dart
• short half life
• 2nd messenger of cGMP pathway (activates soluble guanylate cyclase)

Question 88

Albinism

Answer 88

• caused by deficiency of Tyrosinase (oxidase)
• defcient conversion of tyrosine to melanin
• group of disorders (partial to complete)-severe form affects eyes (oculocutaneous albinism)
• lower visual acuity adn photophobia
• light colored skina dn hair
• increased risk of sun damage from sun and skin cancer

Question 89

Melanin

Answer 89

• herogenous group of tyrosine derived pigments

- tyrosinase is rate limiting step in synthesis

Question 90

Thyroid hormone

Answer 90

• T3 or T4
• formed on tyroglobulin protein
• tyrosine acceps iodione (iodination)

Question 91

Glutathione

Answer 91

• tripeptide made from glutamate, cysteine, and glycine
• reducing agen
• detox of H2O2
• protects from membrane damage, mainatin free -SH ends of proteins
• conjugated to drugs to make them H2O soluble
• cofactor in some enzymatic rxns (glutathione peroxidase)
• aid in rearrangment of disulfide bonds
• protects RBC from oxidative stress
• glutathione reductase needs NADPH (from PPP)