AIMST MBBS L30 Nucleic Acids - Chem Fn Metab PDF

Summary

Lecture notes on Nucleic Acids- Chemistry, Function and Metabolism. The lecture covers topics such as the structure of nitrogenous bases, the biological role of DNA and RNA and associated disorders, and discusses the structure, function, and types of nucleic acids (DNA and RNA).

Full Transcript

AIMST UNIVERSITY
FACULTY OF MEDICINE
Bachelor of Medicine and Bachelor of Surgery (MBBS)
MOLECULAR AND CELLULAR BASIS OF MEDICINE 1
INTRODUCTION TO BASIC SCIENCES
L30 NUCLEIC ACIDS – CHEMISTRY, FUNCTION & METABOLISM

Prof. Dr. Abd. Rahman Md. Said
Wed 23.10.24 10.00am MBBS L30 Nucleic acids LR1

20. 9. 2023 AIMST University Faculty of Medicine, MBBS.
 Learning Objectives

The objective of this lecture is to discuss:
the structure of nitrogenous bases,
the biological role of DNA and RNA and disorders associated.

AIMST University Faculty of Medicine, BSc (Hons) Biomedical
Sciences
 Topic Outcomes
30.1 Describe the structure, function and biological role of
nucleosides, nucleotides, and analogues.
30.2 Describe the structure, function, and types of nucleic acids (DNA
and RNA).
30.3 Explain purine and pyrimidine biosynthetic pathways and its
regulation.
30.4 Explain the role of ribonucleotide reductase.
30.5 Describe the disorders associated with purine and pyrimidine
metabolism.

AIMST University Faculty of Medicine, BSc (Hons) Biomedical
Sciences
 Nitrogenous Bases
Planar, aromatic, and heterocyclic
Derived from purine or pyrimidine
Numbering of bases is “unprimed”

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Sugars
Pentoses (5-C sugars)
Numbering of sugars is “primed”

D-Ribose and 2’-Deoxyribose

Lacks a 2’-OH group

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Nucleosides
Result from linking one of the sugars with a purine or pyrimidine base
through an N-glycosidic linkage
Purines bond to the C1’ carbon of the sugar at their N9 atoms
Pyrimidines bond to the C1’ carbon of the sugar at their N1 atoms

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Nucleotides
Result from linking one or more phosphates with a nucleoside onto the 5’
end of the molecule through esterification.
Phosphates can be bonded to either C3 or C5 atoms of the sugar.
Mono-, di- or triphosphates.

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Nucleotides
Monomers for nucleic acid polymers
Nucleoside Triphosphates are important energy carriers (ATP, GTP)
Important components of coenzymes
FAD, NAD+ and Coenzyme A
RNA (ribonucleic acid) is a polymer of ribonucleotides
DNA (deoxyribonucleic acid) is a polymer of deoxyribonucleotides
Both deoxy- and ribonucleotides contain Adenine, Guanine and Cytosine
Ribonucleotides contain Uracil
Deoxyribonucleotides contain Thymine

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Naming Conventions
Nucleosides:
Purine nucleosides end in “-sine”
Adenosine, Guanosine
Pyrimidine nucleosides end in “-dine”
Thymidine, Cytidine, Uridine
Nucleotides:
Start with the nucleoside name from above and add “mono-”, “di-”, or
“triphosphate”
Adenosine Monophosphate, Cytidine Triphosphate, Deoxythymidine
Diphosphate

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Nucleotide Metabolism
PURINE RIBONUCLEOTIDES: formed de novo
i.e., purines are not initially synthesized as free bases
First purine derivative formed is Inosine Mono-phosphate (IMP)
The purine base is hypoxanthine
AMP and GMP are formed from IMP

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Purine Nucleotides
Purine ring components came from:

N1: Aspartate Amine
C2, C8: Formate
N3, N9: Glutamine
C4, C5, N7: Glycine
C6: Bicarbonate Ion

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Purine Nucleotide Synthesis

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Purine Nucleotide Synthesis
ATP is involved in 6 steps
PRPP in the first step of Purine synthesis is also a precursor for Pyrimidine Synthesis, His and Trp synthesis
Role of ATP in first step is unique– group transfer rather than coupling
In second step, C1 notation changes from α to β (anomers specifying OH positioning on C1 with respect to C4
group)
In step 2, PPi is hydrolyzed to 2Pi (irreversible, “committing” stHydrolyzing a phosphate from ATP is
relatively easy
ΔG°’= -30.5 kJ/mol
If endergonic reaction released energy into cell as heat energy, wouldn’t be useful
Must be coupled to an exergonic reaction
When ATP is a reactant:

Part of the ATP can be transferred to an acceptor: Pi, PPi, adenyl, or adenosinyl group

ATP hydrolysis can drive an otherwise unfavorable reaction
(synthetase; “energase”)

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Purine Biosynthetic Pathway
Channeling of some reactions on pathway organizes and controls processing of substrates to
products in each step
Increases overall rate of pathway and protects intermediates from degradation
In animals, IMP synthesis pathway shows channeling at:
Reactions 3, 4, 6
Reactions 7, 8
Reactions 10, 11

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IMP Conversion to AMP

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IMP Conversion to GMP

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Regulatory Control of Purine Nucleotide Biosynthesis
GTP is involved in AMP synthesis and ATP is involved in GMP synthesis (reciprocal
control of production)
PRPP is a biosynthetically “central” molecule (why?)
ADP/GDP levels – negative feedback on Ribose Phosphate Pyrophosphokinase
Amidophosphoribosyl transferase is activated by PRPP levels
APRT activity has negative feedback at two sites
ATP, ADP, AMP bound at one site
GTP,GDP AND GMP bound at the other site
Rate of AMP production increases with increasing concentrations of GTP; rate of
GMP production increases with increasing concentrations of ATP

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Regulatory Control of Purine Biosynthesis

Above the level of IMP production:
Independent control
Synergistic control
Feedforward activation by PRPP
Below level of IMP production
Reciprocal control

Total amounts of purine nucleotides controlled
Relative amounts of ATP, GTP controlled

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Purine Catabolism and Salvage
All purine degradation leads to uric acid (but it might not stop there)
Ingested nucleic acids are degraded to nucleotides by pancreatic nucleases, and
intestinal phosphodiesterases in the intestine
Group-specific nucleotidases and non-specific phosphatases degrade nucleotides
into nucleosides
Direct absorption of nucleosides
Further degradation
Nucleoside + H2O 🡪 base + ribose (nucleosidase)
Nucleoside + Pi 🡪 base + r-1-phosphate (n. phosphorylase)

NOTE: MOST INGESTED NUCLEIC ACIDS ARE DEGRADED AND EXCRETED.

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Intracellular Purine Catabolism
Nucleotides broken into nucleosides by action of 5’-nucleotidase
(hydrolysis reactions)
Purine nucleoside phosphorylase (PNP)
Inosine 🡪 Hypoxanthine
Xanthosine 🡪 Xanthine
Guanosine 🡪 Guanine
Ribose-1-phosphate splits off
Can be isomerized to ribose-5-phosphate
Adenosine is deaminated to Inosine (ADA)

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Intracellular Purine Catabolism
Xanthine is the point of convergence for the metabolism of the purine
bases

Xanthine 🡪 Uric acid
Xanthine oxidase catalyzes two reactions

Purine ribonucleotide degradation pathway is same for purine
deoxyribonucleotides

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Adenosine Degradation

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Xanthosine Degradation

Ribose sugar gets recycled (Ribose-1-Phosphate 🡪 R-5-P )
– can be incorporated into PRPP (efficiency)
Hypoxanthine is converted to Xanthine by Xanthine Oxidase
Guanine is converted to Xanthine by Guanine Deaminase
Xanthine gets converted to Uric Acid by Xanthine Oxidase

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Xanthine Oxidase
A homodimeric protein
Contains electron transfer proteins
FAD
Mo-pterin complex in +4 or +6 state
Two 2Fe-2S clusters
Transfers electrons to O2 🡪 H2O2
H2O2 is toxic
Disproportionated to H2O and O2 by catalase

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 THE PURINE NUCLEOTIDE CYCLE
AMP + H2O 🡪 IMP + NH4+ (AMP Deaminase)

IMP + Aspartate + GTP 🡪 AMP + Fumarate + GDP + Pi (Adenylosuccinate Synthetase)

COMBINE THE TWO REACTIONS:

Aspartate + H2O + GTP 🡪 Fumarate + GDP + Pi + NH4+

The overall result of combining reactions is deamination of Aspartate to Fumarate at the expense of a
GTP
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Uric Acid Excretion
Humans – excreted into urine as insoluble crystals
Birds, terrestrial reptiles, some insects – excrete insoluble crystals in
paste form
Excess amino N converted to uric acid
(conserves water)
Others – further modification :

Uric Acid 🡪 Allantoin 🡪 Allantoic Acid 🡪 Urea 🡪 Ammonia

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Purine Salvage
Adenine phosphoribosyl transferase (APRT)
Adenine + PRPP 🡪 AMP + PPi

Hypoxanthine-Guanine phosphoribosyl transferase (HGPRT)
Hypoxanthine + PRPP 🡪 IMP + PPi
Guanine + PRPP 🡪 GMP + PPi

(NOTE: THESE ARE ALL REVERSIBLE REACTIONS)

AMP,IMP,GMP do not need to be resynthesized de novo !
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Gout
Impaired excretion or overproduction of uric acid
Uric acid crystals precipitate into joints (Gouty Arthritis), kidneys, ureters
(stones)
Lead impairs uric acid excretion – lead poisoning from pewter drinking goblets
Fall of Roman Empire?
Xanthine oxidase inhibitors inhibit production of uric acid, and treat gout
Allopurinol treatment – hypoxanthine analog that binds to Xanthine Oxidase
to decrease uric acid production

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ALLOPURINOL IS A XANTHINE OXIDASE INHIBITOR

A SUBSTRATE ANALOG IS CONVERTED TO AN INHIBITOR, IN THIS CASE A
“SUICIDE-INHIBITOR”

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Lesch-Nyhan Syndrome
A defect in production or activity of
HGPRT
Causes increased level of Hypoxanthine and Guanine (🡪↑ in degradation to uric
acid)
Also,PRPP accumulates
stimulates production of purine nucleotides (and thereby increases their
degradation)
Causes gout-like symptoms, but also neurological symptoms 🡪 spasticity,
aggressiveness, self-mutilation
First neuropsychiatric abnormality that was attributed to a single enzyme

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Purine Autism
25% of autistic patients may overproduce purines
To diagnose, must test urine over 24 hours
Biochemical findings from this test disappear in adolescence
Must obtain urine specimen in infancy, but it’s difficult to do!
Pink urine due to uric acid crystals may be seen in diapers

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Pyrimidine Ribonucleotide Synthesis
Uridine Monophosphate (UMP) is synthesized first
CTP is synthesized from UMP
Pyrimidine ring synthesis completed first; then attached to
ribose-5-phosphate
N1, C4, C5, C6 : Aspartate
C2 : HCO3-
N3 : Glutamine amide Nitrogen

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Pyrimidine Synthesis

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 UMP Synthesis Overview
2 ATPs needed: both used in first step
One transfers phosphate, the other is hydrolyzed to ADP and Pi
2 condensation rxns: form carbamoyl aspartate and dihydroorotate (intramolecular)
Dihydroorotate dehydrogenase is an intra-mitochondrial enzyme; oxidizing power
comes from quinone reduction
Attachment of base to ribose ring is catalyzed by OPRT; PRPP provides ribose-5-P
PPi splits off PRPP – irreversible
Channeling: enzymes 1, 2, and 3 on same chain; 5 and 6 on same chain

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OMP DECARBOXYLASE : THE MOST CATALYTICALLY PROFICIENT
ENZYME
FINAL REACTION OF PYRIMIDINE PATHWAY
ANOTHER MECHANISM FOR DECARBOXYLATION
A HIGH ENERGY CARBANION INTERMEDIATE NOT NEEDED
NO COFACTORS NEEDED !
SOME OF THE BINDING ENERGY BETWEEN OMP AND THE ACTIVE SITE IS USED TO
STABILIZE THE TRANSITION STATE
“PREFERENTIAL TRANSITION STATE BINDING”

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UMP 🡪 UTP and CTP
Nucleoside monophosphate kinase catalyzes transfer of Pi to UMP to
form UDP; nucleoside diphosphate kinase catalyzes transfer of Pi from
ATP to UDP to form UTP

CTP formed from UTP via CTP Synthetase driven by ATP hydrolysis
Glutamine provides amide nitrogen for C4 in animals

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 Regulatory Control of Pyrimidine Synthesis
Differs between bacteria and animals
Bacteria – regulation at ATCase rxn
Animals – regulation at carbamoyl phosphate synthetase II
UDP and UTP inhibit enzyme; ATP and PRPP activate it
UMP and CMP competitively inhibit OMP Decarboxylase
*Purine synthesis inhibited by ADP and GDP at ribose phosphate
pyrophosphokinase step, controlling level of PRPP 🡪 also regulates
pyrimidines

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Degradation of Pyrimidines
CMP and UMP degraded to bases similarly to purines
Dephosphorylation
Deamination
Glycosidic bond cleavage
Uracil reduced in liver, forming β-alanine
Converted to malonyl-CoA 🡪 fatty acid synthesis for energy metabolism

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Deoxyribonucleotide Formation
Purine/Pyrimidine degradation are the same for ribonucleotides and
deoxyribonucleotides

Biosynthetic pathways are only for ribonucleotide production

Deoxyribonucleotides are synthesized from corresponding
ribonucleotides

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ADENOSINE DEAMINASE DEFICIENCY

IN PURINE DEGRADATION, ADENOSINE 🡪 INOSINE
ENZYME IS ADA
ADA DEFICIENCY RESULTS IN SCID
“SEVERE COMBINED IMMUNODEFICIENCY”
SELECTIVELY KILLS LYMPHOCYTES
BOTH B- AND T-CELLS
MEDIATE MUCH OF IMMUNE RESPONSE
ALL KNOWN ADA MUTANTS STRUCTURALLY PERTURB ACTIVE SITE

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Adenosine Deaminase
CHIME Exercise: 2ADA
Enzyme catalyzing deamination of Adenosine to Inosine
α/β barrel domain structure
“TIM Barrel” – central barrel structure with 8 twisted parallel β-strands
connected by 8 α-helical loops
Active site is at bottom of funnel-shaped pocket formed by loops
Found in all glycolytic enzymes
Found in proteins that bind and transport metabolites

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 References
1. Harper’s Illustrated Biochemistry; 26th edition, ch13, pg 102 to 110
2. Google images
3. Google scholar
4. http://www.webmd.com/diet/fiber-health-benefits-11/insoluble-soluble-fiber?pag
e=1
5. TEXTBOOK OF BIOCHEMISTRY, for Medical Students Sixth Edition by DM Vasudevan
6. McGraw-Hills AccessMedicine.
7. http://www.nbs.csudh.edu/chemistry/faculty/nsturm/CHE452/19_Thyroid15.htm
8. Labtestsonline

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THANK YOU

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