Bs Nursing Level 1 Biochemistry Lecture (MC 2 Lec) Nucleic Acid PDF

Summary

This document is a biochemistry lecture on nucleic acids aimed at nursing students, covering topics such as introduction to nucleic acids, nucleotide structure, and DNA/RNA structures, functions, and types. It's for an undergraduate course.

Full Transcript

BS NURSING LEVEL 1: BIOCHEMISTRY LECTURE (MC 2 LEC)
TOPIC 4: NUCLEIC ACID
MS. ANGELICA LOPEZ

5-carbon sugar is either ribose or
OUTLINE
deoxyribose making the nucleotide
either a ribonucleotide or a
1.1 INTRODUCTION TO NUCLEIC ACID
deoxyribonucleotide.
1.2 NUCLEOTIDE STRUCTURE In eukaryotic cells nucleic acids are
either: Deoxyribose nucleic acids (DNA)
1.3 NUCLEOTIDE AND NUCLEOSIDES OR Ribose nucleic acids (RNA)

1.4 DEOXYRIBOSE NUCLEIC ACID 1. Ribonucleic Acid (RNA)
The pentose sugar is Ribose (has a
hydroxyl group in the 2nd carbon---OH)
1.1 INTRODUCTION TO NUCLEIC ACID Involved in the transcription/translation
of genetic material (DNA)
NUCLEIC ACIDS Encodes or transfer information from
The 4th type of macromolecule one bateria to another
The chemical link between generations
and source of genetic information in 5 TYPES OF RNA
chromosomes Heterogenous nuclear RNA (hnRNA)
Messenger RNA (mRNA)
FUNCTION Small nuclear RNA (snRNA)
Dictate the amino acid sequence in Transfer RNA (tRNA)
proteins (sequence is important in order Ribosomal RNA (rRNA)
to avoid mutation caused by any
insertion and deletion) 2. Deoxyribonucleic Acid (DNA)
Give in formation to chromosomes, The pentose sugar is Deoxyribose (has
which is then passed from parent to a hydrogen-H, but the oxygen is absent)
offspring Deoxy = minus oxygen.
All life on earth uses the nucleic acid for Genetic material – sequence of
the storage of genetic information nucleotides encodes different amino
acids
DNA controls all living processes
including production of new cells – cell
division
Chromosomes are made of DNA

1.2 NUCLEOTIDE STRUCTURE

Building blocks for DNA and RNA (each
strand of DNA & RNA is a string of
nucleotide)
Intracellular source of energy – ATP
Second messengers – involved in
intracellular signaling (cAMP)
Important in Intracellular signaling
DNA is replicated/reproduced (DNA has switches (g proteins)
the ability to encode high information, Despite the complexity and diversity of
only four-letter code is used in the life, the structure of DNA is only
making of our DNA). Identical copies of dependent on 4 different nucleotides.
DNA are made (REPLICATION) Diversity is dependent on the nucleotide
- DNA will be used in the formation or sequence
transcription of RNA. Genetic messages Order of nucleotide bases determines
are read and carried out of the cell the primary structure of the nucleic acid.
nucleus to the ribosomes, where protein All nucleotides are 2 ring structures
synthesis occurs. (TRANSCRIPTION) composed of
- RNA (mRNA) is used in the formation 5 CARBON SUGAR: β-D-ribose (RNA)
of protein sequences. Genetic messages and β-D-deoxyribose (DNA)
are decoded to make proteins.
(TRANSLATION)

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NUMBER OF PHOSPHATE GROUPS
DETERMINES NOMENCLATURE

BASE: Purine and Pyrimidine

Pyrimidine contains two pyridine-like
nitrogen’s in a six-membered aromatic
ring. PYRCUT
AMP, ADP, and ATP
Additional phosphate groups can be
THYMINE – has a added to the nucleoside 5’
methyl and carboxyl monophosphates to form diphosphates
group. (FOR DNA and triphosphates.
ONLY) ATP is the major energy source for
cellular activity.

GUANINE – has an
amine group

URACIL – (FOR RNA
ONLY)

Purine has 4 N’s in a fused ring-like
structure. Three are basic like
pyridine-like and one is like that in
pyrrole. PURGA

ADENINE – has
-Adenosine 5’ monophosphate forms two phosphates
amine and 4 nitrogen and then with the removal of water adenosine 5’
diphosphate is formed. In every addition of water,
GUANINE – has the removal of water also occurs. ATP Structure –
amine, nitrogen, and five phosphate connected to a ribose sugar and
a carboxyl group. pyrimidine.

1.3 NUCLEOTIDES AND NUCLEOSIDES

PHOSPHATE GROUP: (bind directly on NUCLEOTIDES AND NUCLEOSIDES
a sugar) A nucleotide WITHOUT a NUCLEOTIDE – composed of a nitrogenous
phosphate group is a NUCLEOSIDE. base, pentose, and phosphate. (3-unit
molecule)
NUCLEOSIDE – composed of a nitrogenous
base and pentose (does not contain
phosphate)
NUCLEOBASE – composed of a nitrogenous
base (no sugar and phosphate)

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Nucleosides are more soluble in water than free
A nucleoside consists of a nitrogen base heterocyclic bases because of the hydrophilic
linked by a glycosidic bond to Cl’ of a ribose nature of the pentose’s - OH groups.
or deoxyribose.
Named by changing the nitrogen base ending Important characteristics of the nucleoside
to -osine for purines and -idine for formation process of combining two molecules
pyrimidines. into one are:

1. The base is always attached to C1′ of the sugar
(the anomeric carbon atom which is always in a
b-configuration. For purine bases, attachment is
through N9; for pyrimidine bases, N1 is involved. The
bond connecting the sugar and base is a
b-N-glycosidic linkage.
2. A molecule of water is formed as the two
molecules bond together; a condensation reaction
occurs

NUCLEOTIDE AND NUCLEIC ACID
NOMENCLATURE

Eight nucleosides are associated with nucleic
acid chemistry—four involve ribose (RNA
nucleosides) and four involve deoxyribose (DNA
nucleosides). The eight combinations are:

PURGA: PURINE – ADENINE &
GUANINE
PYRCUT: PYRIMIDINE – CYTOSINE –
URACIL - THYMINE NUCLEOTIDE FORMATION
- Nucleotides are nucleosides that have a
NUCLEOSIDE FORMATION phosphate group bonded to the pentose
sugar present. The following structural
A nucleoside is a two-subunit molecule equation is representative of the
in which a pentose sugar is bonded to a conversion of a nucleoside to a
nitrogen-containing heterocyclic base. nucleotide.
The following structural equation is
representative of nucleoside formation.

-After the formation of nucleoside, the fifth
carbon on the sugar will bind to the phosphate,
removing one molecule of water. Then a
3-subunit entity called nucleotide will be
- A pentose sugar is bonded to a formed.
nitrogen-containing heterocyclic base to form a -Many Nucleotide will form a Nucleic Acid
two-unit molecule called nucleoside.
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HYDROGEN BONDING INTERACTIONS
Two bases can hydrogen bond to form a
base pair
For monomers, a large number of base
pairs is possible
In polynucleotide, only few possibilities
exist
Watson-crick base pairs predominate in
double-stranded DNA
A pair with T
Important characteristics of the nucleotide formation
C pair with G
process of adding a phosphate group to a nucleoside Purine pairs with Pyrimidine
are the following:
1. The phosphate group is attached to the sugar at BASE PAIRING DNA: THE WATSON-CRICK
the C5′ position through a phosphoester linkage. MODEL
2. As with nucleoside formation, a molecule of water In 1953 Watson and Crick noted that
is produced in nucleotide formation. Thus, overall, DNA consists of two polynucleotide
two molecules of water are produced in combining a strands running in opposite directions
sugar.
and coiled around each other in a double
helix
1.4 DEOXYRIBOSE NUCLEIC ACID (DNA)
Strands are held together by hydrogen
bonds between specific pairs of bases
DNA stands for deoxyribose nucleic acid
Adenine and Thymine form strong
Chemical substance present in the
hydrogen bonds to each other but not to
nucleus of all cells in all living organisms
C or G
DNA controls all the chemical changes
Guanine and Cytosine form strong
which take place in cells
hydrogen bonds to each other but not to
Muscle, blood, nerve, and all cell are
A or T
controlled by DNA.
The strands of DNA is complementary
A very large molecule made up of long
because of H- bonding
chain of subunits called Nucleotides.
Whenever a G occurs in one strand, a C
Each nucleotide is made up of sugar,
occurs opposite in the other strand and
phosphate and base.
likewise with A and T
Nucleic acids are biopolymers made of
Phosphodiester Link when one nucleotide
nucleotides aldopentoses linked to a purine or
interacts with one nucleotide.
pyrimidine and a phosphate.

MANY NUCLEOTIDES = NUCLEIC ACID

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At third carbon, the phosphate bounds to another
nucleotide linked by the 3rd and 5th position though
the phosphate – serves as the bridge.

PRIMARY STRUCTURE OF NUCLEIC ACIDS
The primary structure of nucleic acid is
the nucleotide sequence
The nucleotides in nucleic acids are
joined by phosphodiester bonds.
The 3’-OH group of the sugar in one
nucleotide forms ann ester bond to the
phosphate group on the 5’-carbon of the
sugar of the next nucleotide.

Reading Primary Structure
A nucleic acid polymer has a free
5’-phosphate group at one end and a free
3’-OH group at the other end
The sequence is read from the free 5’-end
using the letters of the bases
This example reads 5’-A-C-G-T-3’

PROPERTIES OF A DNA DOUBLE HELIX –
SECONDARY STRUCTURE/3D
The strands of DNA are anti parallel
The strands are complimentary
There are hydrogen bond forces
There are base stacking interactions
There are 10 base pairs per turn

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OUTLINE

2.1 Describing a 2.6 Prediciting Base
sequence Sequence

2.2 Secondary 2.7 Nucleic Acid
Structure Structure: The double
helix

2.3 Properties of a DNA 2.8 Dna replication
double
helix-secondary-structu
re/3D

2.4 Model of DNA 2.9 Nucleic Acid
structure
Polymerization
➔ The sides of the ladder are:
2.5 Nucleic Acid P=phosphate
Structure “Base S=sugar molecule
Pairing” ➔ The steps of the ladder are C, G, T, A =
nitrogenous bases
(Nitrogenous means containing the element
2.1 DESCRIBING A SEQUENCE
nitrogen.)
Describing a sequence A=adenine (Apples are Tasty)
➔ Chain is described from 5’end, identifying T=thymine
the bases in order of occurrence, using the A always pairs with T in DNA
abbreviations A for Adenosine, G for C=cytosine (Cookies are Good)
Guanosine, C for Cytidine, and T for Thymine G=guanine
(or U for Uracil in RNA). C always pairs with G in DNA
➔ A typical sequence is written as TAGGCT Hydrogen bonding possibilities are more
2.2 SECONDARY STRUCTURE favorable when A-T and C-G base pairing
Secondary Structure: DNA Double Helix occurs
➔ In DNA there are two strands of nucleotides ➔ Base-paring combinations that do occur
that wind together in a double helix.
The strand run in opposite directions
The bases are arranged in step-like pairs
The base pairs are held together by
hydrogen bonding
➔ The pairing of the bases from the two
strands is very specific
➔ The complimentary base pairs are A-T and
G-C ➔ Base-pairing combinations that do not occur
two hydrogen bonds form between A and T
three hydrogen bonds form between G and
C
➔ Each pair consists of a purine and a
pyrimidine, so they are the same width,
keeping the two strands at equal distances
from each other.
2.3 PROPERTIES OF A DNA DOUBLE
HELIX-SECONDARY-STRUCTURE/3D 2.4 MODEL OF DNA
Properties of a DNA double Model of DNA:
helix-Secondary-Structure/3D ➔ The model was developed by Watson and
➔ The strands of DNA are antiparallel Crick in 1953.
➔ The strands are complimentary ➔ They received a nobel prize in 1962 for
➔ There are hydrogen bond forces their work.
➔ There are base stacking interactions ➔ The model looks like a twisted ladder –
➔ There are 10 bases pairs per turn double helix.

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2.5 NUCLEIC ACID STRUCTURE “BASE 2.8 DNA REPLICATION
PAIRING” DNA replication
Nucleic Acid Structure “Base Pairing” ➔ Before a cell divides, the DNA strands
➔ DNA base-pairing is antiparallel unwind and separate
i.e. 5’ - 3’ (l-r) on top: 5’ - 3’ (r-l) on ➔ Each strand makes a new partner by adding
the appropriate nucleotides
➔ The result is that there are now two
double-stranded DNA molecules in the
nucleus
➔ So that when the cell divides, each nucleus
contains identical DNA
When a eukaryotic cell divides, the process
is called mitosis
➔ the cell splits into two identical daughter
cells
➔ the DNA must be replicated so that each
daughter cell has a copy
DNA replication involves several processes:
➔ first, the DNA must be unwound, separating
the two strands
➔ the single strands then act as templates for
synthesis of the new strands, which are
complimentary in sequence
➔ bases are added one at a time until two new
DNA strands that exactly duplicate the
original DNA are produced

2.6 PREDICTING BASE SEQUENCE

Step 1
➔ Hydrogen bonds between base pairs are
broken by the enzyme DNA helicase and
DNA molecule unzips
➔ DNA molecule separates into
complementary halves

➔ Practice DNA base pairs
GATTACA
CTAATGT

2.7 NUCLEIC ACID STRUCTURE: THE
DOUBLE HELIX

Step 2
➔ Nucleotides match up with complementary bases

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Step 3
➔ Nucleotides are linked into 2 new strands of DNA by
theenzyme, polymerase—DNA polymerase also
proofreadsfor copying errors

Mutations occur when copying errors cause a
change in the sequence of DNA nucleotide bases

2.9 NUCLEIC ACID STRUCTURE

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5’-3’ester bonds of the leading strand
OUTLINE
The lagging strand, which grows in the 3’-5’
3.1 SEMI-CONSERVATIVE REPLICATION direction, is synthesized in short sections called
Okazaki fragments
3.2 STORAGE OF DNA The Okazaki fragments are joined by DNA
ligase to give a single 3’-5’ DNA strand
Spaces between “nicks”
3.3 DIRECTION OF REPLICATION
3.4 RNA MOLECULES
3.4 RNA MOLECULES
COMPOSITION
3.5 TYPES OF RNA MOLECULES
1. Ribose sugar (with O in 3rd carbon)
2. Phosphate group
3.1 SEMI-CONSERVATIVE REPLICATION 3. One of 4 types of bases (all containing nitrogen):
- Adenine
- Uracyl (only in RNA)
- Cytosine
- Guanine
RNA—Ribonucleic Acid
RNA is a messenger that allows the instruction of
DNA to bedelivered to the rest of the cell
RNA is different than DNA:
1. The sugar in RNA is ribose; the sugar in DNA is
deoxyribose
2. RNA is a single strand of nucleotides; DNA is a
double
strand of nucleotides
3. RNA has Uracil (U) instead of Thymine (T) which
is in
The process is called semi-conservative replication DNA
because 4. RNA is found inside and outside of the nucleus;
one strand of each daughter DNA comes from the parent DNA is
DNA and found only inside the nucleus
onestrand is new
The energy for the synthesis comes from There are three main types of RNA:
hydrolysis of 1. ribosomal (rRNA)
phosphate groups as the phosphodiester bonds form 2. messenger (mRNA)
between the bases. 3. transfer (tRNA)
- subtypes: heterogenous nuclear RNA (hnRNA) & small
3.2 STORAGE OF DNA nuclear
In eukaryotic cells (animals, plants, fungi) DNA RNA (snRNA)
is stored in the nucleus, which is separated from
the rest of the cell by asemipermeable 3.5 TYPES OF RNA MOLECULES
membrane
The DNA is only organized into chromosomes
during cell replication
Between replications, the DNA is stored in a
compact ballcalled chromatin, and is
wrapped around proteins called histones to
form nucleosomes

3.3 DIRECTION OF REPLICATION

Messenger RNA carries the genetic code to the
ribosomes
- they are strands of RNA that are complementary to the
DNA of
The enzyme helicase unwinds several sections the gene for the protein to be synthesized
of parent DNA Transfer RNA translates the genetic code from the
messenger
At each open DNA section, called a replication
RNA and brings specific amino acids to the ribosome for
fork, DNA polymerase catalyzes the formation of
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protein synthesis
Each amino acid is recognized by one or more
specific
tRNA
tRNA has a tertiary structure that is L-shaped

- one end attaches to the amino acid and the other binds
to the
mRNA by a 3-base complimentary sequence

PARTS OF TRANSFER RNA
There are 61 different tRNAs, one for each of the
61
codons that specifies an amino acid
tRNA has 70-100 ribonucleotides and is bonded
to a
specific amino acid by an ester linkage through the 3′
hydroxyl on ribose at the 3′ end of the tRNA
Each tRNA has a segment called an anticodon, a
codon sequence
Ribosomes are the sites of protein synthesis

-they consist of ribosomal DNA(65%) and proteins (35%)
- they have two subunits, a large one and a small one

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OUTLINE

4.1 HOW DNA WORKS

4.2 TRANSCRIPTION PROCESS

4.3 PROTEIN SYNTHESIS

4.4 RNA POLYMERASE

4.5 PROCESSING OF mRNA
Example of RNA Primary Structure
4.6 SPLICING In RNA, A, C, G, and U are linked by 3’-5’ ester
bonds between ribose and phosphate
4.1 HOW DNA WORKS
1. DNA stores genetic information in segments called
genes
2. The DNA code is in Triplet Codons (short sequences of
3
nucleotides each)
3. Certain codons are translated by the cell into certain
Amino acids.
4. Thus, the sequence of nucleotides in DNA indicate a
sequence of Amino acids in a protein.

4.2 TRANSCRIPTION PROCESS
Several turns of the DNA double helix unwind,
exposing the bases of the two strands
Ribonucleotides line up in the proper order by
hydrogen bonding to their complementary bases
on DNA
Bonds form in the 5 3 direction,
4.3 PROTEIN SYNTHESIS
The two main processes involved in protein
synthesis
are
the formation of mRNA from DNA
(transcription)
the conversion by tRNA to protein at the
ribosome (translation)

Transcription takes place in the nucleus, while
translation takes place in the cytoplasm
Transcription of RNA from DNA Genetic information is transcribed to form mRNA
Only one of the two DNA strands is transcribed much the same way it is replicated during cell
into mRNA
The strand that contains the gene is the coding
or sense strand
The strand that gets transcribed is the template
or antisense strand
The RNA molecule produced during transcription
is a copy of the coding strand (with U in place of
T)

division

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The exons that remain are joined to form the
mRNA that leaves the nucleus with the
information for the synthesis of protein

4.4 RNA POLYMERASE
During transcription, RNA polymerase moves
along theDNA template in the 3’-5’direction to
synthesize thecorresponding mRNA
The hnRNA is released at the termination point

4.6 SPLICING

Process of removing introns from an hnRNA
molecule and joining the remaining exons
together to form an mRNA molecule. The
process involves the snRNA which facilitates
splicing to occur.
snRNA is found complexed with protein together
called small nuclear ribonucleoprotein particles
snRNPs (pronounced as snurps)
A large complex of snurps is called a
spliceosome.
Spliceosome is a large assembly of snRNA
molecules and proteins involved in the
conversion of hnRNA molecules to mRNA
molecules

4.5 PROCESSING OF mRNA
Genes in the DNA of eukaryotes contain exons
thatcode for proteins along with introns that do
not
Because the initial mRNA, called a
pre-RNA/hnRNA includes the noncoding introns,
it must be processed before it can be read by the
Trna
While the mRNA is still in the nucleus, the introns
are removed from the pre-RNA
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\

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deoxyribose, becomes incorporated
into the new nucleic acid backbone.
OUTLINE 3. RNA polymerase is involved in the
linkage of ribonucleotides, one by
5.1 TRANSCRIPTION 5.6 GENETIC CODE
one, to the growing hnRNA molecule.
5.2 STEPS IN 5.7 mRNA CODONS 4. Transcription ends when the RNA
TRANSCRIPTION AND ASSOCIATED polymerase enzyme encounters a
PROCESS AMINO ACIDS sequence of bases that is “read” as a
stop signal. The newly formed
5.3 DNA-RNA BASE 5.8 READING THE hnRNA molecule and the RNA
PAIRING: THE GENETIC CODE polymerase enzyme are released, and
COMPLEMENTARY
the DNA then rewinds to re-form the
BASE PAIRS
original double helix.
5.4 REGULATION OF 5.9 THE STRUCTURE
TRANSCRIPTION OF tRNA

5.5 5.10 tRNA AND
RIBONUCLEOTIDES ANITCODON

5.1 TRANSCRIPTION
Is the process by which DNA directs the
synthesis of hnRNA/mRNA molecules
that carry the coded information needed
for protein synthesis. Figure 22-16 The transcription of DNA to form
hnRNA involves an unwinding of a portion of the
5.2 STEPS IN TRANSCRIPTION PROCESS DNA double helix. Only one strand of the DNA is
copied during transcription.
Several steps occur during transcription: (ppt) The strand of DNA used for
I. a section of DNA containing the gene hnRNA/mRNA synthesis is called the
unwinds (governed by RNA polymerase). template strand. It is copied proceeding
II. one strand of DNA is copied starting at in the 3′-to-5′ direction. The other DNA
the initiation point, which has the strand (the non-template strand) is
sequence TATAAA. called the informational strand. The
III. an hnRNA is synthesized using informational strand, although not
complementary base pairing with uracil involved in RNA synthesis, gives the
(U) replacing thymine (T). base sequence present in the hnRNA
IV. the newly formed mRNA moves out of strand being synthesized (with the
the nucleus to ribosomes in the exception of U replacing T).
cytoplasm and the DNA re-winds. Figure 22-16 shows the overall process
of transcription of DNA to form hnRNA.
(book)
1. A portion of the DNA double helix
unwinds, exposing a sequence of bases
(a gene). The unwinding process is
governed by the enzyme, “RNA
polymerase” rather than DNA helicase (a
replication enzyme).
2. Free ribonucleotides, one nucleotide at a
time, align along one of the exposed
strands of DNA bases, the template
strand, forming new based pairs. In this
process, U rather than T aligns with A in
Figure 31.14 A polyribosome consists of several
the base-pairing process. Only about 10
ribosomes simultaneously translating one mRNA.
base pairs of the DNA template strand
are exposed at a time. Because
ribonucleotides rather than
deoxyribonucleotides are involved in the
base pairing, ribose, rather than

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There are also codons that signal the
5.3 DNA-RNA BASE PAIRING: THE “start” and “end” of a polypeptide chain.
COMPLEMENTARY BASE PAIRS The amino acid sequence of a protein
can be determined by (1) reading the
DNA RNA triplets in the DNA sequence that are
complementary to the codons of the
A U mRNA, or (2) directly from the mRNA
sequence.
G C The entire DNA sequence of several
organisms, including humans, have been
C G
determined, however,
T A -only primary structure can be
determined this way.
-doesn’t give tertiary structure or
“RNA molecules contain the base U instead of protein function.
the base T.”
GENETIC CODE 1
5.4 REGULATION OF TRANSCRIPTION ❖ The sequence of bases in DNA forms the,
A specific mRNA is synthesized when the “Genetic Code.”
cell requires a particular protein ❖ A group of three bases (a triplet) controls the
The synthesis is regulated at the production of a particular amino acid in the
cytoplasm of the cell.
transcription level:
❖ The different amino acids and the order in
which they are joined up determines the sort
- feedback control, where the end of protein being produced.
products speed up or slow the synthesis CODING
of mRNA Example:
- enzyme induction, where a high level of
a reactant induces the transcription
process to provide the necessary
enzymes for that reactant

Regulation of transcription in eukaryotes
is complicated and we will not study it
here.
5.5 RIBONUCLEOTIDES

TRIPLE CODE
Each triplet codes for a specific amino acid:

The amino acids are joined together in the
correct sequence to make part of a protein:

5.6 GENETIC CODE
The genetic code is found in the
sequence of nucleotides in mRNA that is
translated from the DNA.
A codon is a triplet of bases along the
mRNA that codes for a particular amino
acid.
Each of the 20 amino acids needed to
build a protein has at least 2 codons.
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5.7 mRNA CODONS AND ASSOCIATED AMINO 5.9 THE STRUCTURE OF tRNA
ACIDS

5.10 tRNA AND ANTICODON
5.8 READING THE GENETIC CODE
Suppose we want to determine the
amino acids coded for in the following
section of a mRNA
5’—CCU —AGC—GGA—CUU—3’
According to the genetic code, the amino
acids for these codons are:
CCU = Proline AGC = Serine
GGA = Glycine CUU = Leucine
The mRNA section codes for the amino
acid sequence of Pro—Ser—Gly—Leu

Figure 22-19 A tRNA molecule. The amino acid
attachment site is at the open end of the
cloverleaf (the 3′ end), and the anticodon is
located in the hairpin loop opposite the open
end.

Figure 22-21 The interaction between anticodon
(tRNA) and codon (mRNA), which involves
complementary base pairing, governs the
proper placement of amino acids in a protein.

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TOPIC 4: NUCLEIC ACID
MS. ANGELICA LOPEZ

GROUP 6 (GAVANE, SALORIO, TAYABAS) || 17
 BS NURSING LEVEL 1: BIOCHEMISTRY LECTURE (MC 2 LEC)
TOPIC 4: NUCLEIC ACID
MS. ANGELICA LOPEZ

6.3 INITIATION
OUTLINE

6.1 TRANSLATION AND tRNA
ACTIVATION

6.2 INITIATION AND TRANSLOCATION

6.3 INITIATION

6.4 ELONGATION

6.5 TERMINATION

6.1 TRANSLATION AND tRNA ACTIVATION
Transcription
Once the DNA has been transcribed to
mRNA, the codons must be translated to
the amino acid sequence of the protein
The first step in translation is activation
of the tRNA
Each tRNA has a triplet called an
anticodon that complements a codon on
mRNA
An aminoacyl tRNA synthetase enzyme
uses ATP hydrolysis to attach an amino
acid to a specific tRNA

6.4 ELONGATION

6.2 INITIATION AND TRANSLOCATION
Initiation of protein synthesis occurs
when a mRNA attaches to a ribosome
On the mRNA, the start codon (AUG)
binds to a tRNA with methionine
The second codon attaches to a tRNA
with the next amino acid
A peptide bond forms between the
adjacent amino acids at the first and
second codons
The first tRNA detaches from the
ribosome and the ribosome shifts to the
adjacent codon on the mRNA (this
process is called translocation)
A third codon can now attach where the
second one was before translocation
GROUP 6 (GAVANE, SALORIO, TAYABAS) || 18
BS NURSING LEVEL 1: BIOCHEMISTRY LECTURE (MC 2 LEC)
TOPIC 4: NUCLEIC ACID
MS. ANGELICA LOPEZ

6.5 TERMINATION

GROUP 6 (GAVANE, SALORIO, TAYABAS) || 19