Nucleotides an introduction
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About This Presentation
Nucleotides an introduction
Slide Content
Nucleotides & Nucleic Acids
by Mahwish Kazmi
Date 09 Dec 2014
by Mahwish Kazmi
Date 09 Dec 2014
What are Nucleotides?
•Nucleotides are the basic building blocks of nucleic acids
(both DNA & RNA)
•Structurally, nucleotides have 3 components
(1) a nitrogenous (nitrogen-containing) base,
(2) a pentose,
(3) a phosphate
•The molecule without the phosphate group is called a
nucleoside. nucleoside. nucleoside. nucleoside.
•Nucleotides are the basic building blocks of nucleic acids
(both DNA & RNA)
•Structurally, nucleotides have 3 components
(1) a nitrogenous (nitrogen-containing) base,
(2) a pentose,
(3) a phosphate
•The molecule without the phosphate group is called a
nucleoside. nucleoside. nucleoside. nucleoside.
Nucleotide Structure
Nitrogenous bases Nitrogenous bases Nitrogenous bases Nitrogenous bases
•They are derivatives of two parent compounds,
pyrimidine and purine.
•The bas es a re heterocyclic compounds.
•The carbon and nitrogen atoms in the parent structures
are conventionally numbered to facilitate the naming and
identification of the many derivative compounds.
Nitrogenous bases Nitrogenous bases Nitrogenous bases Nitrogenous bases
•They are derivatives of two parent compounds,
pyrimidine and purine.
•The bas es a re heterocyclic compounds.
•The carbon and nitrogen atoms in the parent structures
are conventionally numbered to facilitate the naming and
identification of the many derivative compounds.
Nitrogenous bases Nitrogenous bases Nitrogenous bases Nitrogenous bases
Both DNA and RNA contain
•two major purine bases, adenine adenine adenine adenine (A) and guanine guanine guanine guanine (G),
•and two major pyrimidines.
•In both DNA and RNA one of the pyrimidines is cytosine cytosine cytosine cytosine
(C), but the second major pyrimidine thymine thymine thymine thymine (T) in DNA
and uracil uracil uracil uracil (U) in RNA.
Both DNA and RNA contain
•two major purine bases, adenine adenine adenine adenine (A) and guanine guanine guanine guanine (G),
•and two major pyrimidines.
•In both DNA and RNA one of the pyrimidines is cytosine cytosine cytosine cytosine
(C), but the second major pyrimidine thymine thymine thymine thymine (T) in DNA
and uracil uracil uracil uracil (U) in RNA.
Pentose sugar Pentose sugar Pentose sugar Pentose sugar
•Nucleic acids have two kinds of pentoses.
•The recurring deoxyribonucleotide units of DNA contain 2 -
deoxy-D-ribose, and
•The ribonucleotide units of RNA contain D-ribose.
•In nucleotides, both types of pentoses are in their
β-furanose (closed five-membered ring) form.
•Nucleic acids have two kinds of pentoses.
•The recurring deoxyribonucleotide units of DNA contain 2 -
deoxy-D-ribose, and
•The ribonucleotide units of RNA contain D-ribose.
•In nucleotides, both types of pentoses are in their
β-furanose (closed five-membered ring) form.
Nucleotide Structure
•Ribofurano se rings in nucleotides ca n exist in four different
puckered conformation .
•Specific long sequences of A, T, G, and C nucleotides in DNA
are the repository of genetic information.
•The four major deoxyribonucleotides (deoxyribonucleoside 5-
monophosphates ) are the structural units of DNAs,
•The four major ribonucleotides (ribonucleoside 5 -
monophosphates) are the structural units of RNAs.
•Ribofurano se rings in nucleotides ca n exist in four different
puckered conformation .
•Specific long sequences of A, T, G, and C nucleotides in DNA
are the repository of genetic information.
•The four major deoxyribonucleotides (deoxyribonucleoside 5-
monophosphates ) are the structural units of DNAs,
•The four major ribonucleotides (ribonucleoside 5 -
monophosphates) are the structural units of RNAs.
Nucleotide and Nucleic Acid Nomenclature
Phosphodiester Bonds
•Phosphodiester Bonds Link
Successive Nucleotides in
Nucleic Acids
•The successive nucleotides
of both DNA and RNA are
covalently linked through
phosphate-group “bridges, ”
•in which the 5-phosphate
group of one nucleotide unit
is joined to the 3-hydroxyl
group of the next nucleotide,
creating a phosphodiester
linkage .
•Phosphodiester Bonds Link
Successive Nucleotides in
Nucleic Acids
•The successive nucleotides
of both DNA and RNA are
covalently linked through
phosphate-group “bridges, ”
•in which the 5-phosphate
group of one nucleotide unit
is joined to the 3-hydroxyl
group of the next nucleotide,
creating a phosphodiester
linkage .
Phosphodiester Bonds Phosphodiester Bonds Phosphodiester Bonds Phosphodiester Bonds
•All the phosphodiester linkages have the same orientation
along the chain, giving each linear nucleic acid strand a
specific polarity and distinct 5 ' and 3' ends.
•Thus the covalent backbones of nucleic acids backbones of nucleic acids backbones of nucleic acids backbones of nucleic acids consist of
alternating phosphate and pentose residues, and
•The nitrogenous bases may be regarded as side groups side groups side groups side groups
joined to the backbone at regular intervals.
•The backbones of both DNA and RNA are hydrophilic.
•The hydroxyl groups of the sugar residues form hydrogen
bonds with water.
•The phosphate groups, with a pKa near 0, are completely
ionized and negatively charged at pH 7, and the negative
charges are generally neutralized by ionic interactions with
positive charges on proteins, metal ions, and polyamines.
•All the phosphodiester linkages have the same orientation
along the chain, giving each linear nucleic acid strand a
specific polarity and distinct 5 ' and 3' ends.
•Thus the covalent backbones of nucleic acids backbones of nucleic acids backbones of nucleic acids backbones of nucleic acids consist of
alternating phosphate and pentose residues, and
•The nitrogenous bases may be regarded as side groups side groups side groups side groups
joined to the backbone at regular intervals.
•The backbones of both DNA and RNA are hydrophilic.
•The hydroxyl groups of the sugar residues form hydrogen
bonds with water.
•The phosphate groups, with a pKa near 0, are completely
ionized and negatively charged at pH 7, and the negative
charges are generally neutralized by ionic interactions with
positive charges on proteins, metal ions, and polyamines.
Effect of Nucleotides Effect of Nucleotides Effect of Nucleotides Effect of Nucleotides
•Chemical properties of nucleotides affect the structure as well
as function of nucleic acids.
1. Being highly conjugated molecules, they have important
consequences for the structure, electron distribution and light
absorption of nucleic acid.
2. Resonance among atoms in the ring gives most of the bonds
partial double-bond character which make them planar
structure.
3. Free pyrimidine and purine bases may exist in two or more
tautomeric forms depending on the pH.
4. As a result of resonance, all nucleotide bases absorb UV light,
and nucleic acids are characterized by a strong absorption at
wavelengths near 260 nm .
•Chemical properties of nucleotides affect the structure as well
as function of nucleic acids.
1. Being highly conjugated molecules, they have important
consequences for the structure, electron distribution and light
absorption of nucleic acid.
2. Resonance among atoms in the ring gives most of the bonds
partial double-bond character which make them planar
structure.
3. Free pyrimidine and purine bases may exist in two or more
tautomeric forms depending on the pH.
4. As a result of resonance, all nucleotide bases absorb UV light,
and nucleic acids are characterized by a strong absorption at
wavelengths near 260 nm .
Effect of Nucleotides Effect of Nucleotides Effect of Nucleotides Effect of Nucleotides
5. The purine and pyrimidine bases are hydrophobic hydrophobic hydrophobic hydrophobic and
relatively insoluble insoluble insoluble insoluble in water at the near-neutral pH of the cell.
6. At acidic or alkaline pH the bases become charged and their
solubility in water increases.
7.7.7.7. Hydrophobic Hydrophobic Hydrophobic Hydrophobic stacking interactions stacking interactions stacking interactions stacking interactions in which two or more
bases are positioned with the planes of their rings parallel
(like a stack of coins) are one of two important modes of
interaction between bases in nucleic acids.
8. Base stacking helps to minimize contact of the bases with
water, and base-stacking interactions are very important in
stabilizing the three-dimensional structure of nucleic acids .
5. The purine and pyrimidine bases are hydrophobic hydrophobic hydrophobic hydrophobic and
relatively insoluble insoluble insoluble insoluble in water at the near-neutral pH of the cell.
6. At acidic or alkaline pH the bases become charged and their
solubility in water increases.
7.7.7.7. Hydrophobic Hydrophobic Hydrophobic Hydrophobic stacking interactions stacking interactions stacking interactions stacking interactions in which two or more
bases are positioned with the planes of their rings parallel
(like a stack of coins) are one of two important modes of
interaction between bases in nucleic acids.
8. Base stacking helps to minimize contact of the bases with
water, and base-stacking interactions are very important in
stabilizing the three-dimensional structure of nucleic acids .
H-bond associated complementarity H-bond associated complementarity H-bond associated complementarity H-bond associated complementarity
•Hydrogen bonds involving the amino and carbonyl groups are
the second important mode of interaction between bases in
nucleic acid molecules.
•Hydrogen bonds between bases permit a complementary
association of two strands of nucleic acid.
•The most important hydrogen-bonding patterns are those
defined by James D. Watson and Francis Crick in 1953,
•In which A bonds specifically to T (or U) and G bonds to C .
•These two types of base pairs predominate in double-
stranded DNA and RNA, and the tautomers are responsible
for these patterns.
•It is this specific pairing of bases that permits the duplication
of genetic information .
•Hydrogen bonds involving the amino and carbonyl groups are
the second important mode of interaction between bases in
nucleic acid molecules.
•Hydrogen bonds between bases permit a complementary
association of two strands of nucleic acid.
•The most important hydrogen-bonding patterns are those
defined by James D. Watson and Francis Crick in 1953,
•In which A bonds specifically to T (or U) and G bonds to C .
•These two types of base pairs predominate in double-
stranded DNA and RNA, and the tautomers are responsible
for these patterns.
•It is this specific pairing of bases that permits the duplication
of genetic information .
H-bond associated complementarity H-bond associated complementarity H-bond associated complementarity H-bond associated complementarity
Thank You
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