BCH3001L Biochimie Métabolique 2
Cours : BCH3001L Biochimie Métabolique 2. Recherche parmi 300 000+ dissertationsPar THCadd • 18 Octobre 2022 • Cours • 2 184 Mots (9 Pages) • 213 Vues
BCH3001L Biochimie Métabolique 2
Prof Adriana E. MIELE Institut des Sciences Analytiques adriana.miele@univ-lyon1.fr
Planning of lectures
- The crossroads of intermediate Metabolism
- Photosynthesis
- Pentoses phosphate pathway (PPP)
- Nucleic acids metabolism
- Vitamins, cofactors & coenzymes
- Cholesterol & steroid hormones metabolism
- A case study: the nervous tissue
Cholesterol metabolism
- Cholesterol, bile salts and steroid hormones are a class of lipids present almost exclusively in eukaryotes
- The common part is the polycyclic non-aromatic ring: cyclopentane-perihydro-phenanthrene
- Cholesterol is the precursor of all this class of lipids in mammals
Cholesterol
- Cholesterol is a C27 cyclic hydrocarbon
- The 4 non aromatic rings make the molecule rigid
- When cholesterol is inserted into the membrane bilayer, the fluidity changes
- The alcoholic -OH group on C3 is the only
hydrophilic part of the molecule
Cholesterol synthesis
- The synthesis of cholesterol is carried out in liver only (cytosol and endoplasmic reticulum, ER)
- It can be divided into 4 steps, each subdivided by several reactions:
- Condensation of 3 acetyl-CoA (C2) into mevalonate (C6)
- Oxidative decarboxylation and phosphorylation of mevalonate into isopentenyl pyrophosphate (IPP, C5)
- Polymerization of 6 IPP into squalene (C30)
- Cyclisation of squalene into lanosterol; elimination of 3C to form cholesterol (C27)
Cholesterol synthesis:
2 Ac-CoA → acetoacetyl-CoA + CoA[pic 1]
Acetoacetyl-CoA + Ac-CoA → 3-hydroxy-3-methyl-glutarylCoA (HMG-CoA) + CoA
HMG-CoA + 2 NADPH,H+ → mevalonate + CoA +2 NADP+
- The first 2 reactions are in common with the ketonic corps production → same enzymes → thiolase + HMG-CoA synthase
- The 3rd is catalyse by HMG-CoA reductase → key checkpoint and pharmacologic target (statines)
Cholesterol synthesis:
In the cytosol
synthesis:
On the ER membrane
(endoplasmic reticulum)
Mevalonate
Voet & Voet, Biochemistry
Cholesterol synthesis: 2nd step
Mevalonate + 2 ATP → 5-PP-mevalonate + 2 ADP[pic 2]
5-PP-mevalonate + ATP → Isopentenyl-PP + ADP + Pi + CO2
- The second step consumes 3 ATP to synthesise an intermediate of high energy content and 5C → IPP
- IPP is both an intermediate of cholesterol and a donor of isoprenoid groups for post-translational modifications → geranylation et farnesylation of proteins to be inserted into membrane bilayers
synthesis: 2nd step
Stryer, Biochemistry
- 3-phosphoryl-5-PP-mevalonate is an intermediate of decarboxylation
- Marking the -OH in position 3 proved its elimination with the phosphate group
- CO2 is instantaneously transformed into bicarbonate by cytosolic carbonic anhydrase
synthesis: 3rd
2 IPP → geranyl-PP + 2 Pi
Geranyl-PP + IPP → farnesyl-PP + 2 Pi
2 F-PP + NADPH,H+ → squalene + 2 Pi + NADP+
- The consecutive polymerisation of IPP units is catalysed by prenyltransferase
- Each IPP contains a double bond which makes the
30C skeleton rigid and limits the number of possible conformations
synthesis: 3rd step
- Actually, prenyltransferase does not condesate 2
IPP, byt 1 IPP and 1 DAPP (dimethyl-allyl-PP)
- DAPP is formed by IPP-isomérase that uses the catalytic couple Glu-Cys as H+ acceptor/donor
synthesis: 3rd
Cholesterol synthesis: 4th step
Squalene + O2 + NADPH,H+ → lanosterol + H2O + NADP+
Lanosterol + 19 O2 + 19 NADPH,H+ → cholesterol + 19 H2O +
19 NADP+ + 2 CO2 + HCOOH (in 19 reactions)
- Squalene is converted into cyclic lanosterol by squalene epoxydase and oxosqualene cyclase
- Lanosterol is the common C30 molecules which gives rise to cholesterol, biliary salts and steroid hormones
synthesis: 4th
[pic 3]
19 NADP+ Stryer, Biochemistry
2 CO2
HCOOH
Cholesterol synthesis: a summary
[pic 4]
Energetic balance of cholesterol biosynthesis
● To synthesise 1 molecule of cholesterol liver cells need:
- 18 AcCoA (3 AcCoA for IPP and 6 IPP in total) → β-oxidation or glycolysis
- 32 NADPH,H+ (2 for each IPP + 20 for cyclisation) → PPP
- Min 18 ATP (3 for each IPP) → CRM
[pic 5]
Regulation of cholesterol synthesis
- The metabolic checkpoint is mevalonate synthesis by HMG-CoA réductase
- This is an integral membrane protein present on the rough ER membrane
- HMG-R is subjected to a regulation:
- Short term: inhibition by mevalonate & cholesterol; posttranslational modification
- long term: gene transcription and protein degradation
- Objective: keep the blood circulating [cholestérol] constant ≈ 800 mg/jour
HMG-R short term regulation
- Mevalonate is a competitive inhibitor; cholesterol is an allosteric inhibitor → direct inhibition by product and final metabolite
- HMG-R can be phosphorylated → inactive:
- Insulin and Thyroid hormone block phosphorylation → reductase active
- Glucagon and glucocorticoids activate phosphorylation → reductase inactive
- A low energetic charge (⭣[ATP]) inhibits HMG-R
HMG-CoA reductase regulation
[pic 6]
Long term regulation of HMG-R
- Protein quantity is regulated at transcriptional and post-translational level by steroid hormones:
- HMG-R has the catalytic part into the cytosol and the regulatory domain into the RER membrane → steroid hormones can bind in the membrane, change the conformation and induce proteolysis
- Steroid hormones can also bind to a sensor protein
(SREBP), anchored on the RER. Without hormones, SREBP is transferred into the nucleus → binds the DNA sequence SRE and activates HMG-R transcription
Long term HMG-R regulation
Voet & Voet, Biochemistry[pic 7]
- SREBP : sterol regulatory element binding protein
- SCAP: SREBP cleavage activating protein → steroid hormones sensor
- Insig: regulator of translocation between RER and Golgi
Long term regulation of HMG-R
- In the absence of sterols, Insig binds [pic 8]
COPII → SCAP-
SREBP complex is translocated to Golgi
- In Golgi, 2 proteases, S1P + S2P, digest
SREBP by freeing the
DNA binding domain
(bHLH)
- bHLH translocates into the nucleus, binds to
SRE and activates
Voet & Voet, Biochemistry genes transcription
...