Lesson 7: Nucleic Acids PDF

Summary

This document explains the structure and types of nucleic acids, including DNA and RNA. It details the components and functions of nucleotides, nucleosides, and their roles in energy transfer, as coenzymes, and as second messengers. The document also offers information about various aspects of DNA and RNA structure, replication, and functions.

Full Transcript

Biochemistry
Lesson 7
Nature of Biomolecules:
Nucleic Acids

CHAPTER OUTLINE

7.1. STRUCTURAL ELEMENTS:
•
•
•
•

GENERALITIES
NUCLEOTIDES STRUCTURE: PHOSPHATE ESTER BOND
NUCLEOSIDES STRUCTURE: N-GLYCOSIDIC BOD
NUCLEOTIDES OF BIOLOGICAL INTEREST:
 ENERGY
 SECOND MESSENGER
 COENZYMES

7.2. DNA:
•
•
•
•
•

PHOSPHODIESTER BOND
PRIMARY STRUCTURE
SECONDARY STRUCTURE
DNA REPLICATION
Tm and DENATURATION

7.3. RNA:
•

TYPES OF RNA:
•
•
•

MESSENGER RNA
RIBOSOMAL RNA
TRANSFERENCE RNA

7.4. GENE CONCEPT:
•
•

PROCARYOTIC AND EUCARYOTIC GENES
SPLICING

7.1. STRUCTURAL ELEMENTS
GENERALITIES
 Biopolymers formed by NUCLEOTIDE and NUCLEOSIDES subunits.
 A nucleotide consist of:
a nitrogenous base + a sugar (this conjugate is called nucleoside)
one or more phosphate groups.
 Composed by C, H, N and P atoms
 2 types:
DNA → deoxyribonucleic acid
RNA → Ribonucleic acid
 They contain genetic information:
Encoded information that allows organisms to develop their biological cycles.
 The bases of DNA molecules carry genetic information whereas their sugar and
phosphate groups perform a structural role.
 Other functions: energy intermediates, coenzymes and second messengers

7.1. STRUCTURAL ELEMENTS
STRUCTURE
 NUCLEOTIDES are complex molecules containing:

Phosphate group + Nitrogenous base + Pentose
• NUCLEOSIDES are composed of:
Nitrogenous base + Pentose
Pentose (Ribose or deoxyribose)

the deoxy prefix indicates that this sugar lacks an oxygen atom that
is present in ribose.

Deoxiribonucleotides

Ribonucleotides

DNA

RNA

β-D-Ribose

β-D-Deoxyribose

7.1. STRUCTURAL ELEMENTS
STRUCTURE

Nitrogenous bases:

Purine: Adenine (A) and Guanine (G)
Pyrimidine: Thymine (T), Cytosine (C) and Uracil (U)
Purines

Double ring
Purine

Adenine

Guanine

Pyrimidines

Single ring

Pyrimidine

Cytosine

Uracil

Thymine

7.1. STRUCTURAL ELEMENTS
STRUCTURE OF A NUCLEOSIDE
NB
(ex: adenine)

Nucleoside
(ex: adenosine)

N-Glycosidic Bond
+
N-glycosidic bond

Pentose
(ex: ribose)

Link between C-1’ pentose →

N-1 pyrimidine NB
N-9 purine NB

7.1. STRUCTURAL ELEMENTS
STRUCTURE OF A NUCLEOSIDE

Nitrogenous base + sugar = nucleoside

Cytosine

N-glycosidic bond
Deoxycytidine
(1-β-deoxyribofuranosil-cytosine)

Deoxyribose

Nucleoside are named by adding –osine (purine derivative) or –idine (pyrimidine)

7.1. STRUCTURAL ELEMENTS
NOMENCLATURE OF A NUCLEOSIDE

BASES

RIBONUCLEOSIDES

DEOXYRIBONICLOSIDES

A

Adenosine

deoxyadenosine

G

Guanosine

deoxyguanosine

C

Cytidine

deoxycytidine

U

Uridine

-----

T

------

deoxythymidine

DNA (A, C, G and T)
RNA (A, C, G and U)

7.1. STRUCTURAL ELEMENTS
STRUCTURE OF A NUCLEOTIDE
NUCLEOTIDE
It is formed by the binding of a phosphate group to the nucleoside.
The phosphoric acid (H3PO4) forms a phosphate ester bond with C-5 of the sugar
Such compound is called a nucleoside 5’-phosphate or a 5’-nucleotide

Pentose + NB+ phosphate = nucleotide

7.1. STRUCTURAL ELEMENTS
STRUCTURE OF A NUCLEOTIDE

nucleoside
(ex: adenosine)

NUCLEOTIDE
NUCLEOTIDE
(ex: adenosine 5’-monophosphate)

N-glycosidic bond

Phosphate ion
The most common site of esterification in
naturally occurring nucleotides is the hydroxyl
group attached to C-5 of the sugar

Ester
bond

7.1. STRUCTURAL ELEMENTS
STRUCTURE
Ribonucleotides
Adenosine
5’-monophosphate
(AMP)

Guanosine
5’-monophosphate
(GMP)

Uridine
5’-monophosphate
(UMP)

Cytidine
5’-monophosphate
(CMP)

Deoxyribonucleotides
deoxyadenosine
5’-monophosphate
(dAMP)

Deoxyguanosine
5’-monophosphate
(dGMP)

Deoxythymidine
5’-monophosphate
(dTMP)

deoxycytidine
5’-monophosphate
(dCMP)

7.1. STRUCTURAL ELEMENTS
NUCLEOTIDES OF BIOLOGIC INTEREST
The phosphate group in nucleoside 5’-monophosphate can be link to other
groups to form the following compounds:

- Energy molecules: ATP, ADP
- Second messengers: cAMP, cGMP
- Coenzyme: Coenzyme A, NAD

7.1. STRUCTURAL ELEMENTS
NUCLEOTIDES OF BIOLOGIC INTEREST

ATP: It forms highly energetic bonds between

other phosphate groups to form diphosphate
and triphosphate nucleotides.
The ATP constitutes the link between
catabolism and anabolism.

It is the energy exchange molecule in the cell.

The process of converting ATP to ADP and P is
coupled to many metabolic reactions.

ATP

7.1. STRUCTURAL ELEMENTS
NUCLEOTIDES OF BIOLOGIC INTEREST

ATP:

The energy needed in endergonic reactions is obtained by ATP hydrolysis.
It forms highly energetic bonds between other phosphate groups to form di- or
triphosphate nucleotides.

Dephosphorilation

Phosphorilation

7.1. STRUCTURAL ELEMENTS
NUCLEOTIDES OF BIOLOGIC INTEREST

Second messengers:
cAMP: ester bonds with –OH in position
3’, a intramolecular bridge is formed.
It is a signaling molecule.

INTRAMOLECULAR
BRIDGE

cAMP

7.1. STRUCTURAL ELEMENTS
NUCLEOTIDES OF BIOLOGIC INTEREST

Second messengers: cAMP
Ligand
(1st messenger)

Cyclic adenylate
(inactive)

Protein
receptor

Binding site

Cyclic adenylate
(active)

cAMP
(2nd messenger)

Inactive
enzyme

G protein

ATP

Synthesis
Active enzyme

Ligand + Protein receptor

activation

G protein

G protein

activation

cyclic adenylate

7.1. STRUCTURAL ELEMENTS
NUCLEOTIDES OF BIOLOGICAL INTEREST
Coenzymes:
They can be:
Coenzymes that participate in Redox reactions:
transfer H+ and electrons from one substrate to the other
a) Pyrimidine nucleotides: Nicotinamide derivatives: NAD, NADP
Nicotinamide nucleotide + adenine nucleotide

NAD + phosphate
Nicotin-adenindeoxynucleotide

NADP
(nicotin-adenin-deoxynucleotide
phosphate)

a) Flavin nucleotides: they have riboflavin (vitamin B2): FMN, FAD

7.1. STRUCTURAL ELEMENTS
NUCLEOTIDES OF BIOLOGICAL INTEREST
Coenzymes:
They can be:
Coenzymes that participate in the transfer of chemical groups: Coenzyme A
(CoA-SH) which transfer acetyl groups to other substrates. Contains vitamin B5
(pantothenic acid)

Vitamins
Organic compounds of diverse composition, essential in small quantities. They
are synthesized by plants and microrganisms but not by animals. The have to
intake in the diet. They act as coenzymes or form part of them.

7.2. DNA

DNA structure: Deoxyribonucleic acid
Structure
Primary
Linear
macromolecules
formed by
polymerization
of
deoxyribonucleo
tides 5’monophosphate
of:
A, G, C, T

Secondary

Double helix

DNA compactation
Chromatin
Histone
association

Chromosomes

Video

7.2. DNA

NH2
Nucleotides are linked by phosphodiester
bonds. The 3’ hydroxyl of the sugar moiety
of one deoxyribonucleotide is joined to the
5’-hydroxyl of the adjacent sugar by a
phosphodiester bridge.

H

H

N

O 5’
O P OCH2 O
O
HH
HH
3’

O

Phosphodiester bond

Video

N

=

Phosphate group:
acid, polar

N

N

H

OH

H
5’

NH2

N

O= P OCH2 O
O
HH
HH
HO

OH

N
O

7.2. DNA
Primary structure
The polynucleotide chain presents 2 free-ends:

5’ end
Adenine

• 5’ linked to phosphate group
• 3’ linked to hydroxyl

Cytosine

Each chain is different in:
• size
• composition
• base sequence

Guanine

The sequence is named with initial letter of
each base from 5’ to 3’ ends:

Thymine

ACGT

3’ end

7.2. DNA
Primary structure
There are two different parts:

5’ end
Adenine

• Backbone of polydeoxyribose-phosphate
• Nitrogenous bases

Cytosine
Guanine

Importance
The order determines a sequence of DNA.
Gene: specific DNA sequence → encodes
information for a functional molecule (protein
or RNA)

The Polynucleotide chain has
directionality, individuality and polarity.

Thymine

3’ end

7.2. DNA
Primary structure

Schematic view of DNA strand

Primary
Lineal polymers
of nucleotides

Secondary
Doble Hélice

James Watson
and Francis
Crick (1953)

3 types DNA: A, B o Z

7.2. DNA

Secondary structure

In 1953 Watson and Crick
published in Nature the model for
the molecular structure of DNA.
In 1962 they received the Nobel
price for their discovery

7.2. DNA
Secondary structure
Franklin and Wilkins studied the
DNA structure
using
x-ray
technology to study DNA fibers.
Franklin presented in 1951 data
on diffraction patterns of DNA

The pattern is in the form of a
“maltese cross” Tipical pattern
of helical structure.

X-ray diffraction pattern
produced by hydrated
DNA fibers

The α helix structure of
proteins had already been
proposed by Pauling.

nucleotide

7.2. DNA
DNA is a Double Helix that stores Genetic information
Chargaff discovered the DNA base ratios. He found that DNA followed certain
rules:
• The number of adenine residues is the same as thymine residues; and the
number of C residues equals the G residues. A attracts T and G attracts C.
• The number of hydrogen bonds depends on the base complementarity
A+G =T+ C

Adenine
Guanine

Cytosine

3 hydrogen bonds

Thymine

2 hydrogen bonds

7.2. DNA
Secondary structure

Hydrogen bonds between bases in a DNA helix.
The double helix is held together by H bonds between complementary pairs
and base-stacking interactions, which are nonspecific and make the major
contribution to the stability of the double helix.

7.2. DNA
Secondary structure
Double helix.

X-ray diffraction
pattern produced
by hydrated DNA
fibers

• The 2 polynucleotide chains are coiled around a
common axis. The chains run in opposite directions.
• It has 2 nm (20 Å) diameter
• NB are located in the interior linked by hydrogen bonds.
• The pair AT has the same size as the pair CG
• The backbone of phosphate is accommodated in the
exterior.
• Dextrorotatory
Phosphate
Backbone

• Each pair of nucleotides is 0.34 nm away from the
following.
• Each turn has 10 pairs of nucleotides at intervals of 34 Å
• Both strands are antiparallel and complementary

7.2. DNA

Secondary structure

Watson and Crick structure also refered as B

form

Minor DNA groove

Major DNA groove

http://highered.mcgrawhill.com/sites/9834092339/student_view0/c
hapter14/dna_structure.html

B form is the most stable form under physiological
conditions. It is the standard form in living organisms

7.2. DNA
Secondary structure

DNA can occur in
different structural forms.
DNA is flexible and rotation can occur
around a number of bonds in the
sugar-phosphate backbone, and
thermal fluctuation can produce
stretching, bending and melting
(unpairing) in the structure.

DNA A form is favored in many solutions that are devoid of
water. It is shorter and with greater diameter than B form.
Found in hybrid RNA-DNA structures.
DNA Z form: left-handed helical rotation. The DNA backbone
takes on a zig-zag appearance. In sequences were DNA
alterns C and G or 5-mC and G → role in gene regulation or
genetic recombination

7.2. DNA

Replication of DNA
The double helix model proposed by
Watson and Crick also suggests the
mechanism for the transmission of
genetic information.
The essential feature is the
complementarity of the two DNA strands.
Making a copy:
1. Separation of the 2 strands
2. Synthesis of a complementary strand
for each joining nucleotide in a
sequence specified by the base
pairing rules. The preexisting strands
acts as a template.

7.2. DNA

DENATURATION AND Tm
DNA strands get denatured by:
• High temperature (80-90ºC) → melting temperature, H bonds are broken as well as
hydrophobic interactions between bases. The double helical structure melts or unwinds to
form two single strands completely separated from each other.
• Changes in pH (extrem pH)
Denaturing is a reversible process, DNA can be renaturated. When the temperature and
pH are returned at physiological range, the unwound segments of the two strands
spontaneously rewind or anneal to yield the intact duplex.
Melting temperature (Tm)
depends on pH and ionic
strengh and the size and
base composition of DNA.
As a rule, the higher the
rate of CG the higher the
Tm

7.2. DNA

More complex DNA structures
How can 1 m of DNA be packed into a
nucleus of 10 µm of diameter?
Chromatin Condensation
The DNA associates to with special proteins:
HISTONES
Chromatin is compact DNA = DNA + histones

7.3. RNA
STRUCTURE
Polyribonucleotide formed by:
Pentose: Ribose
Nitrogenous bases: A, U, C and G
RNA is a single strand molecule (except
in some viruses), but rotation of the
strand results in regions where
nitrogenous bases face each other and
are stabilized by H bonds.

Double helix
region (hairpin)

This is responsible for the secondary
structure important for the function
of the RNA molecule.
Complementary bases
Loop

SEVERAL TYPES OF RNA CONTAIN DIFFERENT STRUCTURES
Secondary structures
Primary structure
Double helix
region (hairpin)

Loop
Secondary
structure

Complementary bases
Loop

The association of loops and helix can give a
TERTIARY STRUCTURE very complex (example
in tRNA)

Tertiary
structure
in a tRNA

Complementary
region

RNA

versus DNA

Primary structure

7.3. RNA

TYPES of RNA
• Messenger RNA (mRNA)
• Ribosomal RNA (rRNA)
• Transfer RNA (tRNA)
• Other RNA molecules:
- microRNA (miRNA)
- small Interference RNA (siRNA or iRNA)
- small nuclear RNA (snRNA)
- small nucleolar RNA (snoRNA)
- large intervening non coding RNA (LincRNA)
- iRNA

7.3. RNA

MESSENGER RNA
• It has only primary structure
• Contains the genetic information to be translated into proteins.
In Prokaryotes:
• It does not have introns
• 5’-end has a triphosphate
In Eukaryotes:
• 5’-end: methyl-guanosine + a triphosphate group: CAP (avoids degradation of the
RNA molecule by cellular RNAases and it helps to be recognized by the ribosome to
initiate the translation process).
• 3’-end: polynucleotide tail: Poly A tail (avoids degradation and drives the RNA molecule
migration from nucleus to cytoplasm)
• It has exons (sequences with genetic information) and introns (sequences without
genetic information).
• Undergo a process of splicing (maturation of RNA molecule that eliminates introns)

7.3. RNA

MESSENGER RNA

Differences in mRNA molecules
between prokaryotes and
eukaryotes

CAP

exons

eukaryotes

introns
polyA tail

prokaryotes

7.3. RNA
MESSENGER RNA in eukaryotic cells

Mature mRNA molecule

7.3. RNA

MESSENGER RNA

in eukaryotes

in prokaryotes

Sometimes the mRNA molecule has information for more than one gene and
a protein precursor is made and then in the cytoplasm is processed into the
different protein.

7.3. RNA

TRANSFER RNA
• It transports the amino acids to the ribosomes
• It has secondary structure and tertiary structure
• All tRNA share some characteristics:
- 5’-end: triplet with guanine and free-phosphoric acid
- 3’-end: 3 unpaired bases (CCA). In the end the amino acid is
attached
- In the Anticodon loop (arm A) there is a triplet of bases
called Anticodon, different for each tRNA depending on the
amino acid they carry.
Anticodon 3` UAC 5’
Codon
5 ‘ AUG 3` aminoacid methionin

TRANSFER RNA

7.3. RNA
STRUCTURE:
The tRNA molecule has a distinctive
folded structure with three hairpin
loops that form the shape of a threeleafed clover.
1) One of these hairpin loops contains
a sequence called the anticodon,
which can recognize and decode
an mRNA codon.
2) 3´end- OH. Each tRNA has its
corresponding amino acid attached
to its end.
FUNCTION: tRNA recognizes and

Mature tRNA molecule

binds to its corresponding codon in
the ribosome, the tRNA transfers
the appropriate amino acid to the
end of the growing amino acid
chain.

RIBOSOMAL RNA

7.3. RNA

• A group of different RNAs that constitute an 80% of the total cellular
RNA
• Molecules of different sizes, with secondary structure and tertiary
structure in some regions
• It forms part of ribosomes. It contributes to have specific sites to fit a
mRNA molecule and tRNAs at the same time.
• It is responsible for the synthesis of proteins, specifically catalyses the
formation of peptide bond (catalytic activity)

Ribosome
RNAs in a ribosome

7.3. RNA

RIBOSOMAL RNA

Processing of pre-rRNA
and assembling of
ribosomes.
rRNA precurssors are
synthetized in the nucleolus

7.3. RNA

OTHER RNA molecules
1. Nucleolar RNA:
It associates with different proteins to
form the nucleolus.

ribozyme

2. RNA in ribozymes (catalytic
function)
3. Ribonucleoproteins: ex. RNA in
SRP (signal recognition particle)
important in the transport of proteins
into the Endoplasmic reticulum (ER)
SRP

7.3. RNA

OTHER RNA molecules
• iRNA: dsRNA (double stranded
RNA) that interferes with gene
expression. They are essential in:
* Gene expression regulation
* Defense mechanisms
against exogen nucleic acids
(pathogens).
* Therapeutic potential.
• miRNAs: Family of endogenous
RNAs (more than 400 in humans).
Regulatory role.

7.4 GENE CONCEPT

What is a gene?

In molecular terms, a gene is the entire
nucleic acid sequence that is necessary
for the synthesis of one functional molecule
and that is inherited.

DNA
Transcription

RNA

PROTEINS
Translation

FLOW OF GENETIC INFORMATION

Transcription

Translation

7.5 GENE CONCEPT

A GENE includes:
-sequences that encode for the protein and/or a
functional RNA- CODING REGION
- sequences required for the synthesis of any
RNA-- NON CODING REGION located in the 5´end
and in the 3´-end (Enhancer, promoter, poly A sites),
splicing sites and could include introns (eukaryotic).
Diagram of
an
eukaryotic
gene

7.4 GENE CONCEPT

Genes in eukaryotes
contain introns

are usually monocistronics and

Monocistronic: the coding region encodes information for only one protein.
Gene 1
Gene 2

Gene X

Gene
DNA segment

Chromosome

Introns: sequences of DNA that are removed during RNA
processing in the nucleus before the mRNA is exported
to the cytosol. Usually introns are bigger in size than exons.

Genes in eukaryotes are usually monocistronics and contain introns.
In many cases introns in a gene are considerably longer that the exons.
The median intron length in human is 3.3 Kb. In comparison most human exons
contain only 50-200 base pairs.

The typical human gene
encoding a protein
(50,000 pb long), 95% of
that sequence consits of
introns and flanking 5´end
and 3´end.

Genes in prokaryotes are polycistronic and do not contain introns.
Polycistronic genes: include the coding region for several proteins that
function together in a common biological proces

The Chromosome in
prokaryotes is
circular without introns

PROKARYOTIC

The cluster of genes that forms
a bacterial operon comprises a
SINGLE TRANSCRIPTION UNIT
that is transcribed from a specific
promoter.
In this case a single transcription unit
contains several genes.

EUKARYOTIC

In eukaryotics, there are simple
and
complex eukaryotic transcription units.

A simple transcription unit
includes a
region that encodes one
protein,
and introns are removed.

90% of human transcription units are complex. The primary mRNA
transcript can be processed in more than a way-- ALTERNATIVE SPLICING
In eukaryotic cells:
Exon splicing is used to produce several mRNA transcripts for the
same gen in different tissues- the number of proteins is expanded in
higher organisms

Splicing only occurs in eukaryotic genes

Eukaryotic
Prokaryotic

7.5 LOCATION OF NUCLEIC ACIDS IN A EUKARYOTIC CELL

BASIC CONCEPTS
• MONOMERIC UNITS FOUND IN NUCLEIC ACIDS:
1) Differences between nucleosides and nucleotides
2) Type of nucleotides according to its composition
3) Chemical bonds implicated in its formation
4) Recognition of the different nitrogen bases
•

DNA: structure, types, composition, cellular location and function. Types of
bonds defining the DNA structure. Denaturalization of DNA

• RNA: structure, types, composition, cellular location and function
• Concept of gene: Differences in prokaryotes in Eukaryotes
• Differences in prokaryotes and eukaryotes in the DNA and mRNA