Haem metabolism

Question 1

importance of haem

Answer 1

• oxygen transport and storage (haemoglobin, myoglobin)
• oxygen metabolism (oxidases, peroxidases, catalases, hydroxylases)
• electrons transfer and drug metabolism (cytochromes)
• signal transduction (nitric oxide synthase)

Question 2

why must iron bind to haem

Answer 2

free iron is toxic

iron binds to haem and haem is always bound to protein in circulation

Question 3

where is haem synthesised

Answer 3

most cells

Question 4

what metabolise the largest quantities of haem

Answer 4

liver and erythron

Question 5

how is haem transported

Answer 5

in plasma, bound to haemopexin or as haemoglobin bound to haptoglobin

Question 6

where is the main site of haem breakdown

Answer 6

macrophages, liver

Question 7

what is haem broken down to, and what happens next

Answer 7

bilirubin which is transported to the liver for conjugation and excretion

Question 8

principle site of haem synthesis in all tissues

Answer 8

erythroid cells ~85%

hepatocytes ~15%

Question 9

what is haem required for in hepatocytes

Answer 9

incorporation into cytocrhome p450

Question 10

where is majoriy of body’s iron content

Answer 10

80% of body’s iron is incorporated into haemoglobin in developing RBC

Question 11

overview of haem biosnythesis

Answer 11

• highly conserved process
• 8 enzymes
  
  • 4 in the mitochondira
  • 4 in the cytoplasm
• synthesis starts in the mitochondria
• metabolite moves out into the cytoplasm
• finishes in the mitochondria

Question 12

Rate limiting step of haem biosynthesis

Answer 12

Conversion of
succinyl CoA + Glycine –> aminolevulinic acid
- by action of ALAS enzyme (hence rate limiting)

succinyl CoA and glycine are in the mitochondria
aminolevulinic acid moves out to cytoplasm

Question 13

ALAS

Answer 13

aminolevuninc acid synthase

Question 14

what is the rate limiting enzyme of haem biosynthesis

Answer 14

ALAS

Question 15

Where does haem biosynthesis begin and with what

Answer 15

in the mitochondria with glycine and succinyl CoA

Question 16

basis of haem biosythesis

Answer 16

• glycine + succinyl CoA -> ALA
  enzyme: ALAS
  location mitochondria
• ALA -> Porphobilinogen
  enzyme: ALAD
  location: cytoplasm
• Porphobilinogen -> hydroxymethylbilane
  enzyme: PBDG
• hydroxymethylbilane -> Uroporphyrinoegn III
  enzyme: URO3S
• Uroporphyrinoegn III -> coproporphyrinoegn III
  enzyme: UROD
  -coproporphyrinoegn III -> protoporphyrinogen IX
  enzyme: CPO
  location: mitochondria
• protoporphyrinogen IX -> protoporhyrin IX
  enzyme: PPO
  -protoporhyrin IX -> HAEM
  enyzyme: FECH

Question 17

ALA

Answer 17

Aminolevulinic acid

Question 18

ALAS

Answer 18

Aminolevulinic acid synthetase = rate limit step

Question 19

ALAD

Answer 19

Aminolevulinic acid dehydrate (2x)

Question 20

PBDG

Answer 20

porphobilinogen deaminase
(4x)
deamination

Question 21

URO32

Answer 21

uropophyrinogen III sythetase

-cyclisation of HMB

Question 22

UROD

Answer 22

uropophyrinogen III decarboxylase

• change in side chains
• removal of 4 carboxylic groups of the acetic side chains AKA decarboxylation of methyl groups

Question 23

CPO

Answer 23

copropophyrinogen oxidase
- oxidative carboxylation of propionate groups of pyrrole rings A and B
AKA 2 propionate groups -> 2 vinyl groups

Question 24

PPO

Answer 24

• protoporphyrinogen oxidase
• in mitochondria
• oxidisation

Question 25

FECH

Answer 25

• Ferrocheletase
• insertion of iron in protoporphyrin ring
• in mitochondrion
  = haem

Question 26

types of ALA synthase in mammals

Answer 26

regulation of haem biosynthesis in mammals occurs via 2 distinct pathways

• nonerythroid cells
• erythroid precursor cells

Question 27

regulation of haem biosynthesis in non-erythroid cells

Answer 27

housekeeping = ALAS-1

• transcriptional regulation via haem
• also reguation of mitochondiral import of ALAS by haem - direct inhibition of the enzyme by haem

Question 28

regulation of haem biosynthesis in erythroid cells

Answer 28

eALAS = ALAS-2

• translational regulation
• iron responsive element (IRE) located in the 5’ end of mRNA
• iron regulatory protein (IRP) interact with IRE and inhibit translation

Question 29

regulation of haem synthesis

Answer 29

• feedback mechanism is important
• Inhibition of ALAS is well established
• transcriptional control by heam indicated, as well as control of mitochondrial import
• need to coordinate iron supply in erythroid cells
• 5’ IRE on eALAS mRNA
• other mechanisms are important but not well understood

Question 30

why is regulation of haem synthesis important

Answer 30

if excess haem produced, degradation occurs which willl release free iron causing iron toxicity

Question 31

how is haem degraded

Answer 31

• haem is oxidised which opens the ring by, by action of ER enzyme HO-1
• oxidation occurs on specific carbon producing the liner tetrepyrole biliverdin, ferric iron (Fe3+) and CO
• tetrepyrole biliverdin reduced to bilirubin

Question 32

what is HO-1

Answer 32

Heam-oxygenase-1

enyme from the endoplasmic reticulum which oxidises haem ring to open it, as part of degradation

Question 33

ferric iron

Answer 33

Fe 3+

Question 34

what happens to bilirubin produced by haem degradation

Answer 34

• bilirubin conjugated with gucuronic acid = bilirubin diglucuronide and excreted in the bile
• some is reabsorbed and excreted in urine = yellow
• rest is metabolised in colon by bacteria; intestinal bacteria metabolise bilirubin to urobilirubin

Question 35

biological activity of reaction products from haem degradation

Answer 35

• CO has anti-inflamatory, anti-thrombotic and anti-apoptopic effects
• biliverdin and bilirubin have anti-oxidant properties

Question 36

what are porphyrias

Answer 36

group of disorder caused by deficiencies in the activity of enzymes within haem biosynthesis pathway

• porphorias and/or their precursos (ALA, PBG) are abnormall produced in excess and accumulate in tissues and are excreted in urin and stool
• purple, red pigment

Question 37

classification of porphyrias

Answer 37

• hepatic
• erythropoetic
• acute hepatic
• cutaneous porphyrias

Question 38

acute hepatic porphyrias

Answer 38

clinical characteristics: neurological disturbances

biochemical characteristics: an overproduction of porhyprin precursos ALA and PBG

Question 39

porphoryn precursos

Answer 39

ALA and PBG

Question 40

cutaneous porphyrias

Answer 40

clinical characteristics: cutaneous photosensitivty

biochemically characteristics: excessive production of porphorias

Question 41

Acute Intermittent Porphyria (AIP)

Answer 41

• partial porphbilinogen deaminase (PBDG) deficiency
• Triggered by drugs that induce agents hepatic cyctochrome p450
• Causes a reduced haem level which disrupts regulation of ALAS by haem
• leads to accumulation of ALA and PBG
• neurological and psychiatric symptoms and severe abdominal pain
• reducing ALA and PBG, and excretion by intravenous heamatin injection is effective

Question 42

Porphyria Cutanea Tarda (PCT)

Answer 42

• most common of all forms of the porphyrias
• heterogenous group of cutaneous porphyric diseases due to UROD deficience
• inherited or more commonly acquired

Question 43

most common form of porphyrias

Answer 43

porphyria cutanea tarda

Question 44

what can lead to acquiring PCT

Answer 44

• increased amunt of hepatic iron (HFe)
• alcohol, chlorinated cyclic hydrocarbons
• hepatitis C and/or HIV virus infections
• oestrogens
• smoking
• low vit C and carotenoid status

Question 45

Variegate porphyria (VP)

Answer 45

• south african genetic porphyria
• heterozygouse deficiency in PPD activity
• inherited in autosomal manner
• biochemical marker is elevated concentration of fecal protoporphyrin IX
• plasma shows a fluorescnce emission when excited by long UV light

Question 46

what is elevated concentration of fecal protoporphyrin IX a biomarker for

Answer 46

Variegate porphyria (VP)

Question 47

photodynamic theory

Answer 47

• well established for certain skin cancers
• cells mae sensitive to light by treatment with ALA, either topically or by injection
• after time, protoporphyrin IX forms and light shone on cancer to kill cells
• can also be used for skin disorders
• being researched for treatment of other cancers

Question 48

Cellular iron metabolism is regulated through the IRE/IRP system, which acts at the level of

Answer 48

translation