nucleotide metabolism -biosynthesis- dr. sooad al-daihan 1
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Nucleotide MetabolismNucleotide Metabolism-Biosynthesis--Biosynthesis-
Dr. Sooad Al-DaihanDr. Sooad Al-Daihan
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Metabolic Pathways
• The biochemical reactions in the living cell are organized into metabolic pathways.
• The pathways have dedicated purposes:
Extraction of energy. Storage of fuels. Synthesis of important building blocks. Elimination of waste materials.
• The pathways can be represented as a map:
Follow the fate of metabolites and building blocks. Identify enzymes that act on these metabolites. Identify points and agents of regulation. Identify sources of metabolic diseases.
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Homeostasis• Organisms maintain homeostasis by keeping the concentrations of most
metabolites at steady state.
• In steady state, the rate of synthesis of a metabolite equals the rate of
breakdown of this metabolite.
• Pathways are at steady state unless perturbed.
• After perturbation a NEW steady state will be established.
• The flow of metabolites through the pathways is regulated to maintain
homeostasis.
• Sometimes, the levels of required metabolites must be altered very rapidly.
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Feedback Inhibition
• In many cases, ultimate products of metabolic pathways directly or
indirectly inhibit their own biosynthetic pathways.
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Rate of reaction depends on the concentration of substrates
• The rate is more sensitive at low substrate concentrations. Frequency of substrate meeting the enzyme matters.
• The rate becomes insensitive at high substrate concentrations. The enzyme is nearly saturated with substrate.
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Significances of nucleotides
They are precursors of DNA and RNA They are the energy currency in metabolic transactions. They are components of:
– Cofactors : such as NAD, FAD, S-adenosylmethionine, and coenzyme A
– Activated biosynthetic intermediates : such as UDP-glucose and CDP-diacylglycerol.
– Second messengers : such as cAMP and cGMP
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Overview of Nucleotide Metabolism
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Nucleotide Biosynthesis
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Begins with their metabolic precursors: amino acids, ribose 5-phosphate, CO2, and NH3.
Recycles the free bases and nucleosides released from nucleic acid breakdown
Question: Why do we need both pathways ?
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In these pathway, two features deserve to mention:
First, there is evidence, especially in the de novo purine pathway, that the enzymes are present as large, multienzyme complexes in the cell.
Second, the cellular pools of nucleotides (other than ATP) are quite small, 1% or less of the amounts required to synthesize the cell’s DNA.
Therefore, cells must continue to synthesize nucleotides, and in some cases nucleotide synthesis may limit the rates of DNA replication and transcription.
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Because of the importance of these processes in dividing cells, agents that inhibit nucleotide synthesis have become particularly important to modern medicine.
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Denovo Purine Nucleotide Biosynthesis
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The two parent purine nucleotides of nucleic acids are adenosine 5-monophosphate (AMP) and guanosine 5-monophosphate (GMP).
The origin of the carbon and nitrogen atoms of the purine ring system, as determined by John Buchanan using isotopic tracer experiments in birds
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Synthesis of Inosine Monophosphate (IMP)
• Basic pathway for biosynthesis of purine ribonucleotides.
• Starts from ribose-5-phosphate which is derived from the PPP.
• Requires 11 steps overall.
• Occurs primarily in the liver.
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Step 1: Activation of ribose-5-phosphate
• Enzyme: Ribose phosphate pyrophosphokinase• Product: 5-phosphoribosyl-a-pyrophosphate (PRPP).• PRPP is also a precursor in the biosynthesis of pyrimidine nucleotides and the amino acids histidine & tryptophan.
• This step is tightly regulated by feedback inhibition.
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Step 2: Acquisition of purine atom 9
• In this committed step, an amino group donated by glutamine is attached at C-1 of PRPP. • Enzyme: Amidophosphoribosyl transferase.• Product: Resulting in the formation of 5-phosphoribosylamine.
What is the properties of
committed step
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Step 3: Acquisition of purine atoms C4, C5, and N7
• Phosphoribosylamine reacts with ATP and glycine to produce glycinamide ribonucleotide (GAR).
• Enzyme: Glycinamide synthetase.
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Step 4: Acquisition of purine atom C8
• Formylation of free α-amino group of GAR.• Enzyme: GAR transformylase.• Co-factor of enzyme : N10-formyl THF
Step 5: Acquisition of purine atom N3• The amide amino group of a second glutamine is
transferred to form formylglycinamidine ribonucleotide (FGAM).
• Enzyme: FGAM synthetase.
Step 6: Closing the ring• Closing of the imidazole ring or formation of 5-
aminoimidazole ribonucleotide (AIR).• Enzyme: AIR synthetase.
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Step 7: Acquisition of C6
• C6 is introduced as HCO3-.
• The reaction is driven by hydrolysis of ATP.• Enzyme: AIR carboxylase (aminoimidazole ribonucleotide carboxylase).• Product: CAIR (carboxyaminoimidazole ribonucleotide).
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Step 8: Acquisition of N1• N1 is acquired from aspartate in an amide
condensation reaction that is driven by hydrolysis of ATP to produce 5-aminoimidazole-4-(N-succinylocarboxamide) ribonucleotide. Enzyme: SAICAR synthetase
Step 9: • Elimination of fumarate by the action of
adenylosuccinate lyase to produce 5-aminoimidazole-4-carboxamide ribonucleotide (AICAR)
Step 10: Acquisition of C2• Another formylation reaction catalyzed by AICAR
transformylase results in the formation of 5-formylaminoimidazole-4-carboxamide ribonucleotide (FAICAR)
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• The dependence of purine biosynthesis on folic acid compounds at Steps 4 and 10 means that antagonists of folic acid metabolism indirectly inhibit purine formation and, in turn, nucleic acid synthesis, cell growth, and cell division. • Clearly, rapidly dividing cells such as malignancies or infective bacteria are more susceptible to these antagonists than slower-growing normal cells.
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Step 11: Cyclization or ring closure
• Water is eliminated by the action of inosine monophosphate (IMP) synthase.• In contrast to step 6 (closure of the imidazole ring), this reaction does not require ATP hydrolysis.• Once IMP is formed, it is rapidly converted to AMP and GMP.
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Biosynthesis of AMP and GMP from IMP Lecture no.7
Purine nucleotide biosynthesis is regulated by feedback control
The significance of regulation:
(1 )Fulfill the need of the body, without wasting.
(2 )[GTP[=]ATP]
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Salvage Pathway of Purine
Two phosphoribosyl transferases are involved in this pathway:
• Adenosine phosphoribosyl transferase (APRT) Adenine + PRPP AMP + Ppi
• Hypoxanthine-guanine phosphoribosyl transferase (HGPRT) Hypoxanthine + PRPP IMP + Ppi
Guanine + PRPP GMP + Ppi
APRT is not very important because it generate little adenine
HGPRT, is exceptionally important and it is inhibited by both IMP and GMP
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• Mutations in genes that encode nucleotide biosynthetic enzymes can reduce levels of needed nucleotides and can lead to an accumulation of intermediates.
• Lesch-Nyhan syndrome is compulsive self-destructive behavior, caused by a deficiency of hypoxanthine-guanine phosphoribosyltransferase (HGPRT) of salvage pathway, The disease is inherited as a sex-linked recessive disorder.
• In the absence of HGPRT, PRPP levels rise and purines are overproduced by the de novo pathway, resulting in high levels of uric acid production and gout-like damage to tissue.
• The brain is especially dependent on the salvage pathways, and this may account for the central nervous system damage in children with Lesch-Nyhan syndrome.
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Pyrimidine Denovo Synthesis It is a shorter pathway than for purines. The base is made first, then attached to ribose-P (unlike purine
biosynthesis). Requires 6 steps (instead of 11 for purine). The product is UMP (uridine monophosphate). Only 2 precursors (aspartate and glutamine, plus HCO3
-) contribute to the 6-membered ring.
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Pyrimidine Denovo SynthesisPyrimidine Denovo SynthesisLecture no.7
Nucleotide Mono-, Di-, and Triphosphates Are Interconvertible
How is the other major pyrimidine ribonucleotide, cytidine, formed? It is synthesized from the uracil base of UMP, but UMP is converted into UTP before the synthesis can take place.
The di and triphosphates are the active forms of nucleotides in biosynthesis and energy conversions.
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Nucleoside monophosphates are converted into nucleoside triphosphates in stages.
First, nucleoside monophosphates are converted into diphosphates by specific nucleoside monophosphate kinases that utilize ATP as the phosphoryl-group donor. For example:
UMP + ATP UDP + ADP
Second, Nucleoside diphosphates and triphosphates are interconverted by nucleoside diphosphate kinase, an enzyme that has broad specificity, in contrast with the monophosphate kinases.
XDP + YTP XTP + YDP
UMP kinase
nucleoside diphosphate kinase
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CTP Is Formed by Amination of UTP
After uridine triphosphate has been formed, it can be transformed into cytidine triphosphate by the replacement of a carbonyl group by an amino group.
This reaction requires ATP and uses glutamine as the source of the amino group.
CTP can be used then in many biochemical processes, including RNA synthesis.
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Thymidylate Is Formed by the Methylation of Deoxyuridylate
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Uracil, produced by the pyrimidine synthesis pathway, is not a component of DNA. Rather, DNA contains thymine, a methylated analog of uracil.
Another step is required to generate thymidylate from uracil. Thymidylate synthase catalyzes this step -deoxyuridylate (dUMP) is methylated to thymidylate (TMP).
The methylation of this nucleotide facilitates the identification of DNA damage for repair and, hence, helps preserve the integrity of the genetic information stored in DNA.
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Conversion of dUMP to dTMP by thymidylate synthase and dihydrofolate reductase. In the synthesis of dTMP, all three hydrogens of the added methyl group are derived from the N5,N10-methylenetetrahydrofolate, as shown in red and gray.
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Pyrimidine Salvage pathway
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Nucleotide MetabolismNucleotide Metabolism-Degradation--Degradation-
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Purine Catabolism Purine nucleotides (AMP and GMP)are
degraded by a pathway in which they lose their phosphate through the action of 5’- nucleotidase ,to form adenosine and guanosine respectively.
Adenosine It is deaminated to inosine by adenosine
deaminase. Inosine is hydrolyzed to hypoxanthine
and D-ribose by the action of nucleosidase.
Hypoxanthine is oxidized successively to xanthine and then uric acid by xanthine oxidase
Guanosine It is cleaved to guanine and D-ribose by the
action of nucleosidase. Guanine undergoes hydrolytic removal of its
amino group to yield xanthine by the action of guanine deaminase.
Xanthine is converted to uric acid by xanthine oxidase .
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Purine Metabolism Disorders Genetic aberrations in human purine metabolism have been found, some
with serious consequences.
For example, adenosine deaminase (ADA) deficiency.
The absence of ADA leads to severe combined immunodeficiency disease (SCID) in which T lymphocytes and B lymphocytes do not develop properly.
Lack of ADA leads to a 100-fold increase in the cellular concentration of dATP, a strong inhibitor of ribonucleotide reductase involved in deoxynucleotide biosynthesis
Infants with this deficiency have a high fatality rate due to infections.
It is treated by administering ADA which can remain in the blood for 1 – 2 weeks , or by gene therapy where the gene that is missing or defective is replaced
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GOUT
Is a disease of the joints caused by an
elevated concentrations of uric acid in the
blood and tissues.
The joints become inflamed, painful, and
arthritic, owing to the abnormal
disposition of crystals of monosodium
urate monohydrate.
Usually affect joints in the lower
extremities (the big toe is the classic site).
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Allopurinol
It is a structural analog of
hypoxanthine that strongly inhibit
xanthine oxidase.
It is used to prevent of attacks of
gouty arthitis and nephropathy
It is also used during chemotherapy
of cancer and to prevent recurrent
calcium oxalate calculi.
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Allopurinol PathwayLecture no.7
Catabolism of a pyrimidineIn contrast to purines, pyrimidines undergo ring cleavage and the usual end products of catabolism are beta-amino acids plus ammonia and carbon dioxide.
Pyrimidines from nucleic acids or the energy pool are acted upon by nucleotidases and pyrimidine nucleoside phosphorylase to yield the free bases.
The 4-amino group of both cytosine and 5-methyl cytosine is released as ammonia.
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Ring CleavageIn order for the rings (Cytosine and Thymine) to be cleaved, they must first be
reduced by NADPH.
Atoms 2 and 3 of both rings are released as ammonia and carbon dioxide.
The rest of the ring is left as a beta-amino acid.
Beta-amino isobutyrate from thymine or 5-methyl cytosine is largely excreted.
Beta-alanine from cytosine or uracil may either be excreted or incorporated into
the brain and muscle dipeptides, carnosine (his-beta-ala) or anserine (methyl
his-beta-ala).
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