Central Dogma Of Molecular Biology PDF

Summary

This document provides an overview of the central dogma of molecular biology, including the processes of DNA replication, transcription, and translation. It also discusses genes, simple and complex organisms, and RNA Polymerase, and their functions.

Full Transcript

CENTRAL DOGMA GENES - nucleotide sequences that carry
of molecular biology specific instructions for the cell
- The smallest hereditary unit that
Central dogma of molecular biology can be passed from parent to
- Process of making copies of offspring
genetic information
- Process of conversion into protein Note: number and structure of gene
products DEPENDS per species
- DNA can be replicated and
converted to RNA and then into Gene expression - process of converting
proteins in this information into genes into a functional
protein product
DNA: stored in the nucleus
- Replicates after each cell division Simple organisms - more
segments/genes
DNA gets transcribed into RNA, - Prokaryotic
RNA gets translated into protein - Es: bacteria, archaea
- Tightly packed DNA with genes
DNA - goes through transcription
RNA- goes through Translation Note: prokaryotes or a simple organisms
because there only a little can fit inside
Proteins - is the final product them unlike humans
- These are enzymes, antibodies
Note: Eukaryotes like human have more
Reverse transcription non coding material known as “introns”
- Is an exception which are the gray area
- Only for viruses, they process RNA
to become DNA More complex organisms = more
- Only exhibited by retroviruses non-coding regions

Retroviruses example: Human Organism: Chromosomal segment
immunodeficiency virus (HIV) Bacteria: 20kb
Yeast: 20kb
Drosophila: 200kb
Note: All HUMAN cells , even a part of Human: 200kb
human cell (like hand cells, thigh cells, etc.)
are eukaryotes PROKARYOTES - the entire gene codes
for a protein or molecule

Musni, Pauleen Frances M. I BSN I biochem reviewer
EUKARYOTES - the gene consists of Mini- satellites & Microsatellites
coding and non-coding regions - Shorter repeats
INNON, EXCO - Repeated in the entire genome
INTRONS - non-coding region - Used to monitor mutations
- Nascent mRNA - undergo RNA implicated diseases like Cancer
splicing
- Remains inside the nucleus Additional:
- Note part of the mature RNA Genome - entirety of genetic material
- removed during transcription Gene - specific segment

EXONS- coding region DNA REPLICATION
- The one translate in for protein
synthesis REPLICATION - process by which DNA
- Mature RNA/ expressed/ exits the makes copies of itself
nucleus - Occurs in semi-conservative
- Joined together in transcription to manner
form FINAL mRNA product through - Takes place in NUCLEUS of
RNA Splicing Eukaryotic cells, and CYTOPLASM
of prokaryotic cells
SPLICING - process of intron removal and
exon joining Semi- conservative - one strand of the
parent DNA becomes the template for
Mature RNA only has exons the daughter strands
- When two strands separate they
Note: Only 3% of human DNA codes for become the template
proteins
Other models: Conservative model &
Additional:
Dispersive model
Maintenance of chromosomal
structure:
ORIGIN OF REPLICATION - Replication
starts here
Disease susceptibility
Where the double stranded DNA
Gene expression
(dsDNA) begins to open to form the
SATELLITES - highly repetitive “REPLICATION BUBBLE”
- A chromosome can have multiple
- Is a Non coding DNA sequence
origins
- Provide structural stability to - Eukar: multiple origin, Prokar: one
chromosomes origin
Has 2 kind: mini-satellites, microsatellites

Musni, Pauleen Frances M. I BSN I biochem reviewer
REPLICATION FORK - where replication Additional: oligonucleotide -
actively occurs polynucleotide molecules that contain small
number of nucleotides
REPLISOME - assembly of proteins that
facilitate DNA replication at the CLAMP PROTEIN
replication fork - Keeps DNA polymerase in place
- All proteins, enzymes, molecules
DNA POLYMERASE (DNA Pol)
COMPONENTS OF REPLISOME: - Synthesizes new DNA strand
GHP-CPL-SSB - Can only add to existing
- DNA Gyrase/ Topoisomerase nucleotide chain and cannot
- Helicase initiate replication
- Primase
- Clamp protein DNA LIGASE
- DNA Polymerase (DNA Pol) - Joins OKAZAKI FRAGMENTS in the
- DNA Ligase lagging strand
- Single- stranded Binding Proteins Okazaki fragments - short DNA regions
(SSB) that is replicated

DNA GYRASE/ TOPOISOMERASE SINGLE-STRANDED BINDING PROTEINS
- prevents DNA from supercoiling (SSB)
- Prevents by introducing breaks to - Stabilizes and protects the single
relieve stress stranded region of DNA during
HELICASE replication
- breaks the H-bonds between base pairs
to unzip the dsDNA LEADING VS LAGGING STRANDS
- Separate bonds
Where does replication occur?
PRIMASE - It occurs on both strands of the
- Synthesize primers for DNA DNA on both sides of DNA
polymerase replication bubble
- PRIMER - initiates replication
The newly synthesized DNA is called
Note: without the primer made by the either leading strand or lagging strand
primase DNA polymerase cannot start
replication Leading strand - 3
- Synthesized using the template
Note: DNA polymerase follow the primer 3’to 5 towards the replication fork
- Replication is continuous

Musni, Pauleen Frances M. I BSN I biochem reviewer
Lagging strand - 5
- Synthesized using template 5’to 3’ What should happen for transcription to
towards replication fork take place?
- Replication is discontinuous - DNA must be unwind and
- Forms Okazaki fragments that separated by proteins
are joined together at the end
Transcription bubble - opening in the
Why does leading and lagging strand double helix where transcription takes
happen? place
- Because of the DNA polymerase
- DNA polymerase can only Separated DNA strands:
synthesize 5’to 3 direction - Template strand
- Coding strand
Lagging strand - goes against fork
movement, discontinuos, 5’to 3’’ Template Strand - DNA strand that is
transcribed
Leading strand - goes with the fork - Also called the negative strand or
movement, continuous, 3’to 5’ antisense strand

Coding strand - DNA strand that is NOT
DNA REPLICATION IN BRIEF transcribe
1. Opening of the DNA - Called the positive strand or sense
superstructure strand
2. DNA relaxation via DNA gyrase
3. DNA unwinding via helicase RNA POLYMERASE
4. Primer synthesis bia primase - Enzyme responsible for RNA
5. DNA elongation via DNA synthesis
polymerase - Reads template from 3’ to 5
6. DNA ligation via DNA ligase - Synthesizes RNA from 5’ to 3’
- RNAPol II is used for mRNA
RNA TRANSCRIPTION - Cannot recognize genes on their
own
Transcription - process through which - Need help of transcription factors
genetic information from DNA is
converted into mRNA in the nucleus TRANSCRIPTION UNIT
- First step of gene expression - Protein-gene
- Can be divided into: Regulatory
Transcript - resulting mRNA molecule regions & structural gene

Musni, Pauleen Frances M. I BSN I biochem reviewer
Promoter region 2. Elongation - addition of the
- Located upstream, (before the appropriate complementary nucleotide to
transcription site) the growing transcript
- Identifies which DNA strand is the
template 3. Termination - release of the complete
- Initial binding site of transcription but non- functional transcript call the
factors pre-mRNA upon transcription of the
- call RNA polymerase for binding terminator region
-
Note: transcription factors - give signal to 4. Post-transcriptional modifications -
where RNA polymerase binds processing of pre-mRNA into functional
mature mRNA
PROMOTER REGION
- Consensus Sequence
- Initiation signal

Consensus sequence - identifies the
precise nucleotide at which transcription
begins
- Where initial transcription factors
binds
- EX: TATA box

Initial signal - gives RNA pol the signal
when to start transcription

TERMINATION REGION
- Nucleotides at the end of a gene
that signals RNA polymerase to
end transcription
- - ends transcription process

RNA TRANSCRIPTION IN BRIEF
1. Initiation - binding of transcription
and RNA polymerase to the promoter
region

Musni, Pauleen Frances M. I BSN I biochem reviewer