DNA and RNA PDF

Summary

This document provides an overview of DNA and RNA, including their discovery, structure, components, and functions. It discusses the process of transcription and translation, essential steps in gene expression. The text also includes practice questions for the reader to test their understanding of the material.

Full Transcript

GROUP 5
DNA AND RNA
 DISCUSS

General Info of DNA and RNA

Discovery of DNA and RNA

Differentiate
What is

DNA?
WHAT DOES IT STANDS FOR?
 Deoxyribo
nucleic Acid
What does dNA look like?
What does dNA look like?
What is

RNA?
WHAT DOES IT STANDS FOR?
ribOnucleic
Acid
What does rNA look like?
What does rNA look like?
Discovery of
DNA and RNA
 THE DISCOVERY

Friedrich Miescher
In 1869, Swiss chemist Friedrich
Miescher identified DNA in the nuclei of
human white blood cells. He named it
"nuclein"

Albrecht Kossel
In 1881, German biochemist Albrecht
Kossel discovered the nitrogenous
bases in DNA and changed the
name from "nuclein" to "DNA"
 THE DISCOVERY

Rosalind Franklin and Maurice Wilkins
They used X-ray crystallography
to study DNA's structure, which
helped Watson and Crick with
their discovery.

James Watson and Francis Crick
In 1953, they concluded that the
DNA molecule appears as a
three-dimensional double helix.
 THE DISCOVERY

Richard Altmann
In 1889, Altmann described
nuclear substances in the cell
nucleus, which were later
identified as RNA.

Phoebus Levene
In 1909, Levene determined that
RNA is made up of ribose,
phosphate, and nitrogenous
bases.
DNA AND RNA
COMPARISON
 Typically DOUBLE-
stranded, forming a
double helix structure.
“MORE STABLE”

Usually SINGLE-stranded,
though it can form
secondary structures
through internal base
pairing.
“LESS STABLE”
Thymine base(G–C–A–T)
long-term genetic storage

Uracil base
various functions in gene
expression.
 DNA
DNA stands for
deoxyribonucleic acid. It is a
long molecule made up of
monomers called nucleotides.

STRUCTURE PHOSPHATE
BASE
Deoxyribonucleic Acid
Sugar macro-molecule
[ stores the genetic material ]
DEOXYRIBOSE
SUGAR
 DISCUSS

DNA COMPONENTS

DOUBLE HELIX

PACKAGING
The twisted ladder
shape is called a
double helix.
How does DNA work?
The 4 letters of DNA make up codons.
These chemicals are repeated in various
orders over and over. These codons
make up genes. These genes tell cells
how to make a protein that controls
everything in the cell.
 NITROGEN BASES
Adenine Thymine

Cytosine Guanine
 Nucleotide

The backbone of DNA is
formed by alternating sugar
and phosphates held
together by a strong bond.
The rungs of the ladder are formed by the four
nitrogen bases and are held together by weak
hydrogen bonds.
 Let's Practice!
One strand of DNA has the base sequence

TACGATTGA
What is the complementary strand of DNA?
Answer!
TACGATTGA
ATGCTAACT
 RNA
STRUCTURE
ribonucleic Acid
SINGLE NUCLEOTIDE
STRAND
 DISCUSS

RNA COMPONENTS

THREE TYPES OF RNA

FUNCTIONS
THREE NUCLEOTIDE
PARTS:

1. Phosphate group -
sugar-phosphate
backbone
2. Ribose - RNA sugar
3. Nitrogen bases:

Adenine (A)
Guanine (G)
Cytosine (C)
Urasil (U)
THREE TYPES OF RNA

mRNA

tRNA

rRNA
MESSENGER RNA

mRNA
LOCATION: Starts in the nucleus
and then moves to a ribosome.
FUNCTION: Delivers a copy of DNA
code to a ribosome
Once the ribosome has the mRNA
instruction, it can then build a
protein in the process called
“Transitions”
TRANSFER RNA

tRNA
LOCATION: Cytoplasm
FUNCTION: Transfer Amino acids
from the cytoplasm to a
ribosome
Ribosomes will link the Amino
Acids together to form a protein
in a process called “Translation”
RIBOSOME RNA

rRNA
FUNCTION: Main components
of ribosomes.
rRNA bonds with special
proteins to form a ribosome
Ribosome: Orgarelle that
builds proteins.
TRANSCRIPTION
FROM

DNA RNA
TO
 DISCUSS
TRANSCRIPTION
PROCESS
STEPS
ENZYME AND FACTORS
 Transcription
What is transcription?
- is the process where a cell makes a copy of a specific part of its DNA into RNA. This
RNA carries the instructions from the DNA out of the nucleus and to the ribosomes in
the cytoplasm. The ribosomes then use this RNA to make proteins, which are essential
for the cell's functions. Essentially, transcription translates DNA's instructions into a
form that can be used to build proteins.
 Overview of the
Process
Initiation
- RNA polymerase binds to the the promoter region of DNA to begin transcription.

Elongation
- RNA polymerase moves along the DNA, adding RNA nucleotides to build the
mRNA strand.
Termination
- Transcription ends when RNA polymerase reaches the stop signal, and the
mRNA is released.
 STEP 1: INITIATION

- is the beginning of transcription. It occurs when the enzyme RNA polymerase binds
to a region of a gene called the promoter. This signals the DNA to unwind so the
enzyme can ‘‘read’’ the bases in one of the DNA strands. The enzyme is now ready to
make a strand of mRNA with a complementary sequence of bases.
 STEP 2: ELONGATION

is the addition of nucleotides to the mRNA strand. RNA polymerase reads the unwound
DNA strand and builds the mRNA molecule, using complementary base pairs. There is a
brief time during this process when the newly formed RNA is bound to the unwound DNA.
During this process, an adenine (A) in the DNA binds to an uracil (U) in the RNA.
 STEP 3: TERMINATION

is the ending of transcription, and occurs when RNA polymerase crosses a stop
(termination) sequence in the gene. The mRNA strand is complete, and it detaches from
DNA.
PROMOTER REGION
 ENZYMES AND
TRANSCRIPTION FACTORS
TRANSLATION the process which converts the
genetic information in mRNA into a
OF functional protein, a process vital

RNA
for cell function and life.

TO

PROTEIN
 DISCUSS
TRANSLATION
PROCESS
STEPS
RIBOSOMES AND tRNA
 Translation

What is Translation?
 Translation
Translation is the biological process
in which the genetic code in mRNA
(messenger RNA) is read and
translated into a sequence of amino
acids to form a protein.
 Translation
This is a critical step in gene
expression where the information in a
gene is used to synthesize a
functional product, usually a protein.
 Translation
CENTRAL DOGMA:
Translation follows transcription in
the central dogma of molecular
biology: DNA -> RNA -> Protein
 Translation
IMPORTANCE:
Proteins produced through translation
are essential for cellular functions,
including metabolism, structural support,
signaling, and immune response.
 Process
Location:
EUKARYOTIC CELLS
translation occurs in the cytoplasm,
specifically at the ribosomes, which may
be free-floating or attached to the
endoplasmic reticulum.
 Process
Location:
PROKARYOTIC CELLS
translation occurs simultaneously with
transcription in the cytoplasm due to
the absence of nucleat membrane.
 Process
Components Involved:
mRNA : encodes the sequence of amino acids
tRNA: brings the appropriate amino acids to
the ribosomes
Ribosomes: serve as the site where mRNA is
decoded
Amino acids: the building blocks that are
linked together to form a protein
 Steps

Three main stages: initiation,
elongation, and termination
 Initiation

1. mRNA Binding
2. Initiator tRNA Binding
3. Ribosome Assembly
 Elongation

1. Codon Recognition
2. Peptide Bond Formation
3. Translocation
ready for the next tRNA carrying new amino acids. This cycle
repeats, elongating the peptide chain one amino acid at a time
 Termination

1. Stop Codon Recognition
2. Release Factors
3. Disassembly
Ribosomes: The Machinery of Translation

Structure of Ribosomes
Ribosomes are composed of two sub units,
each made of ribosomal RNA (rRNA) and
proteins
Small sub unit
Large sub unit
Ribosomes: The Machinery of Translation

Three Functional Site
A (Aminoacyl) Site
P (Peptidyl) Site
E (Exit) Site
Ribosomes: The Machinery of Translation

Functions of Ribosomes:
Decoding Catalyzing Coordination
mRNA: Reactions: and Accuracy:
ribosomes move ribosomes facilitate the The ribosome’s structure
along the mRNA, formation of peptide ensures that translation
reading codons and bonds between amino proceeds with high
ensuring the correct acids, which is the core fidelity, maintaining the
tRNA matches with chemical reaction of integrity of the protein
each codon. translation. being synthesized.
 tRNA: The Adapter Molecule

Structure of tRNA
Anticodon Loop
Amino Acid attachment site
Shape
 tRNA: The Adapter Molecule

Functions of tRNA:
Amino acid Codon Bridge between
Delivery: Recognition: mRNA & Protein:
tRNA transports the The anticodon of tRNA tRNA acts as a physical
correct amino acids ensures that the correct link between the genetic
to the ribosome amino acids is added to code in mRNA and the
based on the mRNA the growing polypeptide amino acid sequence of
codon sequence. chain by matching with proteins, making it an
the complementary essential component in
mRNA codon. translation.
 Summary
Translation converts the genetic information in mRNA
into a functional protein, a process vital for cell
function and life
Steps Involved: Translation includes initiation
(starting protein synthesis), elongation (adding
amino acids), and termination (ending the synthesis).
Ribosomes act as the site and catalyst for
translation, ensuring proteins are built accurately
according to the genetic code
tRNA plays a crucial role by delivering the correct
amino acids to the ribosome and ensuring that the
genetic code is accurately interpreted during protein
synthesis.
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OVERVIEW