Introduction
Nucleotides play a variety of important roles in all
cells. They are the activated precursors of DNA and RNA.
ATP, an adenine nucleotide, is a universal currency of
energy in biological systems. GTP is an essential
carrier of chemical energy. Adenine nucleotides are
components of the coenzymes NAD+, NADP+, FMN, FAD and
Coenzyme A. UDP-Glucose in Glycogen synthesis and
CDP-diacylglycerol in Phosphoglyceride synthesis are the
nucleotide derivatives that act as activated
intermediates. Cyclic AMP is a ubiquitous mediator for
the action of many hormones. All cells can synthesize
nucleotides from simple building blocks (de novo
synthesis) or by the recycling of pre-formed bases
(Salvage pathway). Nucleotides are phosphate esters of
pentoses in which a nitrogenous base is linked to C1� of
the sugar residue. A nucleotide without the phosphate
group is known as a nucleoside. The major purine
components of nucleic acids are adenine and guanine
residues. The major pyrimidine residues are those of
Cytosine, Uracil and Thymine. Pyrimidines are bound to
ribose through N 1 atoms.
Synthesis of purine ribonucleotides
IMP is synthesized from ribose 5-phosphate. There are 11 reactions
in the formation of IMP. IMP is converted to GMP and AMP with the
help of ATP and GTP respectively. Nucleoside monophosphates are
converted to nucleoside diphosphates by base specific monophosphate
kinases. Purine nucleotide synthesis is regulated by feedback
inhibitor � AMP, GMP and IMP. An important regulatory factor is the
availability of PRPP. Salvage pathway for purines is observed in RBC
and the brain. Free purines are salvaged by APRTase and HGPRTase
enzymes
Synthesis of pyrimidine ribonucleotides
Pyrimidine ring is synthesized as free pyrimidine and then it is
incorporated into the nucleotide. 6 reactions are involved in the
synthesis of UMP. UDP and UTP are synthesized from UMP with the help
of ATP. CTP is formed by adding an amino group from glutamine.
Pyrimidine can also be salvaged using PRPP. In orotic aciduria,
excretion of large amount of orotic acid is observed. It results
from the deficiency of either orotate phospho ribosyl transferase or
OMP decarboxylase.
Formation of deoxyribonucleotides
Ribonucleotide reductase catalyzes the synthesis of
deoxyribonucleotide. The reductant is NADPH. Thioredoxin transfers
electrons from NADPH for reduction of 2�-OH of ribose. dTMP is
formed by thymidylate synthase by methylation of deoxy uridine
monophosphate.
Degradation of nucleotides
Nucleotides of a cell undergo continuous turnover. Purines are
catabolized and the end product is uric acid. Gout is a disease
characterized by elevated levels of uric acid in body fluids. Sodium
urate crystals are precipitated in the joints and soft tissues to
cause painful arthritis. In Lesch-Nyhan syndrome, HGPRT deficiency
occurs, leading to excessive uric acid production through PRPP
accumulation. Gout is treated by allopurinol administration. Animal
cells degrade pyrimidine nucleotides to their component bases by
dephosphorylation, deamination and glycosidic bond cleavages to give
rise to carbon dioxide, ammonia, β-alanine and β-amino isobutyrate.
Nucleotide Coenzymes
Nucleotides are the components of many enzyme cofactors. Adenosine
is a part of their structure in a variety of enzyme cofactors
serving a wide range of chemical functions. Coenzyme A is
synthesized from pantothenic acid and ATP.
