BIOCHEMISTRY Nucleotide Metabolism PDF

Summary

This document provides an overview of nucleotide metabolism, focusing on purine degradation and associated diseases, such as gout and ADA deficiency. It details factors influencing purine levels and treatment options for these conditions.

Full Transcript

1A
BIOCHEMISTRY
NUCLEOTIDE METABOLISM (Part 2)

DR. BRENDO JANDOC M.D.
 X-linked PRPP synthetase mutation
OUTLINE  Increased PRPP  increases purine production  elevated
I. Degradation of Purine nucleotides (cont.) levels of plasma uric acid
 Diseases associated  Increased Vmax for the production of PRPP
 Gout  Lower Km for ribose 5-phosphate
 ADA deficiency  Decreased sensitivity to purine nucleotides
II. Pyrimidine synthesis and degradation  allosteric inhibitors
 Synthesis of carbamoyl phosphate  Lesch-Nyhan syndrome
 Synthesis of orotic acid  Hyperuricemia due to:
 Formation of a pyrimidine nucleotide  Decreased salvage of hypoxanthine and guanine
 Synthesis of UTP and CTP  Increased PRPP availability
 Synthesis of TMP from dUMP  Secondary Hyperuricemia
 Salvage of pyrimidines  Increased availability of purine
 Degradation of pyrimidine nucleotides  Myeloproliferative disorders
 Chemotherapy
 High rate of cell turnover
DEGRADATION OF PURINE NUCLEOTIDES  Seemingly unrelated metabolic diseases
A. Diseases associated with purine degradation  Von Gierke
1. GOUT  Fructose intolerance
 Characterized by high levels of uric acid (hyperuricemia)  Increased risk of gout
 End product of purine catabolism  Diet rich in meat and seafood
 Either the overproduction or underexcretion of uric acid.  Decreased risk
 Deposition of monosodium urate crystals in the:  Diet rich in low-fat dairy
 joints
 inflammatory response  acute gout  chronic C. Treatment of gout
gouty arthritis
 Anti-inflammatory agents
 soft tissues
 Colchicine
 resulting in chronic tophaceous gout
 Prevent microtubule formation  decrease
 Kidneys
movement of neutrophil to affected area
 Urolithiasis
 Steroidal drugs (prednisone)
 Typically asymptomatic and does not lead to gout, but gout
 Nonsteroidal drugs (indomethacin)
is preceded by hyperuricemia
 Uricosuric agent
 DIAGNOSIS:
 Lowering uric acid below its saturation point  prevent
 Aspiration and examination
deposition
of synovial fluid from an
 UNDEREXCRETORS
affected joint (or material
 Promote renal excretion
from a tophus)
 Probenecid
 Polarized light microscopy
 Sulfinpyrazone
show needle-shaped
 OVEREXCRETORS
monosodium urate crystals
 Inhibit uric acid synthesis
 Allopurinol
A. Underexcretion of uric acid  Converted to oxypurinol
 Inhibit xanthine oxidase
 Primary = due to as-yet-unidentified inherent excretory defects
 Secondary to known disease processes that affect how the  hypoxanthine and xanthine accumulation
kidney handles urate  more soluble
 Lactic acidosis  less likely to initiate inflammation
 lactate and urate compete for the same renal  normal HGPRT level
transporter)  hypoxanthine salvage  de novo synthesis
 Environmental factors  Febuxostat
 Use of drugs  Non-purine inhibitor of XO
 thiazide diuretics
 exposure to lead (saturnine gout) 2. ADENOSINE DEAMINASE (ADA) DEFICIENCY
 ADA
B. Overproduction of uric acid  Highest in lymphocytes
 Less common cause of gout is hyperuricemia  ADA deficiency
 Primary hyperuricemia  Accumulation of adenosine
 Idiopathic (having no known cause)  ADA  ribonucleotide or deoxyribonucleotide
 Via kinases

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NUCLEOTIDE METABOLISM (Part 2)

 Rise in dATP  inhibit ribonucleotide reductase C. Formation of a pyrimidine nucleotide
 Prevent production of deoxyribose-containing nucleotides  completed pyrimidine ring is converted to orotidine 5’-
 Cells cannot make DNA nor divide monophosphate (OMP)
 Developmental arrest and apoptosis of lymphocytes  orotate phosphoribosyltransferase
 Severe combined immunodeficiency disease  releases pyrophosphate
 Most severe form  PRPP as ribose-5-phosphate donor
 Autosomal recessive  OMP  uridine monophosphate
 Decrease in T, B and NK cells  Orotidylate decarboxylase
 Treatment  Removes acidic carboxyl group
 Bone marrow transplant  UMP synthetase domains
 Enzyme replacement therapy  Orotate phosphoribosyltransferase
 No treatment  Orotidylate decarboxylase
 Death at age 2  Orotic aciduria
 Purine nucleoside phosphorylase deficiency  Rare genetic defect
 Less severe  Deficiency of one or both activity of UMP synthase
 Primarily involves T cells  UMP  UDP  UTP

PYRIMIDINE SYNTHESIS AND DEGRADATION UDP
 PYRIMIDINE RING
 Synthesized before being attached to ribose-5-phosphate Ribonucleotide reductase
donated by PRPP
 SOURCES dUMP
 Glutamine
 Aspartic acid phosphorylation
 CO2
dUDP
A. Synthesis of carbamoyl phosphate
 Regulated step UTP diphosphatase
 Glutamine and CO2 
carbamoyl phosphate dUTP
 carbamoyl phosphate
synthetase (CPS) II
 Inhibited by UTP
 Activated by
PRPP
 Also synthesized by CPS I
 Precursor of urea
 Defect in ornithine
transcarbamylase
 Promote
pyrimidine
synthesis

B. Synthesis of orotic acid
 Second step  formation of carbamoylaspartate
 Aspartate transcarbamoylase
 Closed hydrolytically
 Dihydroorotase
 Oxidation of dihydroorotate  orotic acid
D. Synthesis of UTP and cytidine triphosphate (CTP)
 Dihydroorotate dehydrogenase
 CTP
 Inner mitochondrial membrane only
 Amination of UTP by CTP
 Multifunctional or multicatalytic peptide domain = CAD
synthetase
 CPS II
 Glutamine provides Nitrogen
 Aspartate transcarbamoylase
 Dephosphorylated to CDP
 dihydroorotase
 Substrate of ribonucleotide
reductase
 dCDP  dCTP
 for DNA synthesis

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E. Synthesis of thymidine monophosphate (TMP) from dUMP
 dUMP  dTMP
 thymidylate synthase
 inhibited by thymine analogs (5-fluorouracil)
 antitumor agents
 5-fluorouracil  5-FdUMP
 Permanently bound to inactivated
thymidylate synthase
 Suicide inhibitor
 N5,N10-methylene tetrahydrofolate as the source of the
methyl group
 THF contribute one-carbon unit, 2 hydrogen atoms
 Oxidized to DHF
 Can be reduced by dihydrofolate reductase
 Inhibited by Methotrexate
 Decrease THF supply
 Inhibit purine synthesis, prevent
methylation of dUMP to dTMP
 DNA synthesis is inhibited and slows cell
growth
 Trimethoprim
 Folate analogs
 Potent antibacterial activity
 Selective inhibition of bacterial dihydrofolate reductase

F. Salvage of pyrimidines
 Nucleotide kinases
 Utilizes ATP in the phosphorylation of nucleoside to
nucleotide
 Basis for using URIDINE in the treatment of hereditary orotic
aciduria

G. Degradation of pyrimidine nucleotides
 Opened and degraded to highly soluble products
 Β-alanine
 Β-aminoisobutyrate
 NH3 and CO2

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