SACE44 Biology Semester 1 (SABG11) PDF

Summary

This document is a biology chapter covering various topics in cell biology, including DNA and proteins, Cell Theory, and the characteristics of prokaryotic and eukaryotic cells, as well as Bacteria. It provides an overview of the basics of cells and their functions.

Full Transcript

SACE44
BIOLOGY SEMESTER 1
(SABG11)
MS FARAH ANIZA SHAHRI
TOPIC 1: DNA AND PROTEINS

1.1 DNA Structure
and Function
 Cell Theory

1. All organisms are composed of
one or more cells.

2. The cell is the structural unit of
life for all organisms.

3. Cells can arise only by division
from a preexisting cell.
 Basics of Cells

most basic property of cells; (building
blocks of life)
they are the smallest units to exhibit this
property;
bounded or separated from outside world -
cell membrane
able to reproduce, respond to stimuli in
their environment & transform energy
able to stores DNA for biological
information
DNA stored in nucleus depending of
type of cell
 Characteristics of Prokaryotic and Eukaryotic cells

Comparison between prokaryotic and eukaryotic reveals many basic differences and
similarities

The shared properties reflect the fact that eukaryotes evolved from prokaryotic ancestor.
Share identical genetic language
Common set of metabolic pathways
Common structural features
 Characteristics of Prokaryotic and Eukaryotic cells

Two fundamentally different classes of cells
1. Size
2. The types of internal structures (Organelles)

All cells share certain characteristics
They are all enclosed by a membrane
They all use DNA as genetic information
 Prokaryotic Cells

Pro (before) - karyote (nucleus)
prokaryotes do not have a nucleus and (generally) no internal membranes (do not
contain membrane-bound organelles)
made up of the bacteria and cyanobacteria family most
prokaryotes are microscopic
prokaryotes are unicellular – aggregate singly or permanently in colonies
diameter: 1 – 5 μm; small size (very high ratio of surface are to volume)
 Bacteria
prokaryotic cells are enclosed by a plasma
membrane
surrounded by rigid & chemically complex cell wall
– maintain the shape of cells
has an outer sticky coat (capsule) – enable bacteria
to stick to certain surfaces
DNA consists of single loop; double stranded & has
plasmid (small, circular DNA)
have projections; help bacteria to move
1. Short projections - pili (singular: pilus)
2. Longer projections – flagella (singular: flagellum)
General Prokaryotic Cells
General Prokaryotic Cells
 Eukaryotic Cells
Larger in size, 10-100 μm
complex multicellular organisms
more highly organised and specialised
Eukaryotic Cells – Animal cells
Eukaryotic Cells – Plant Cells
 Eukaryotic Cells

The function of organelles and other structure in cells may be divided into four
major groups:
1. The manufacture of chemicals such as nucleic acids, polypeptides and lipids. Eg: nucleus,
ribosomes, endoplasmic reticulum and Golgi apparatus
2. The breakdown of materials, which may include foreign materials which are ingested. Eg
lysosomes & vacuoles
3. Energy processing, either using energy from the Sun in the process of photosynthesis or
obtaining the energy from foods that the organism has ingested. Eg mitochondria
(respiration) & chloroplasts (photosynthesis)
4. Support, movement & communication between & within cells, Eg cytoskeleton, cell walls
& membrane surfaces
Prokaryotic vs Eukaryotic
 Organelles with their own DNA
(Double-membrane organelles)

All organelle have membranes such as golgi, vesicles, ER, and others. But only
some organelle contain DNA.
Mitochondrial DNA (mtDNA) and chloroplast DNA is double-stranded but circular.
There is a theory said that mitochondria & chloroplast was once prokaryote. But
they undergo evolution and become organelle.
Organelles with their own DNA
(Double-membrane organelles)
 Structure and Function of DNA

DNA carries genetic code
Replicates to pass on genetic information
Instructions for synthesis of proteins
Proteins are required to build an organism and catalyze of its
biochemical reactions – controlling all of functions of cell and
organisms
 History of DNA

How was DNA discovered?
in 1869, the Swiss chemist Friedrich Miescher isolated DNA
he removed the nuclei of pus cells and found nuclein (self-named)
nuclein: rich in phoshorus, no sulfur like protein
further research by other chemists → nuclein found to have an acidic substance
they called nucleic acid
at that time, they were still unsure if DNA is the genetic material or proteins in
the chromosomes:
4 nucleotides VS 20 amino acids
 History of DNA

Rosalind
Franklin and her
experiment in
1952
 History of DNA

Watson and Crick
described the DNA molecule
from Franklin’s X-ray (1953)

Watson and Crick in 1953
 History of DNA

The Watson and Crick Model of DNA

In 1952, Rosalind Franklin, a student at King’s College London was able to
crystallize DNA and used X-rays to obtain an X-ray diffraction photograph of DNA
this photograph is then used by James Watson (American) and Francis Crick
(British) to formulated the model of the double helical structure of DNA
In 1962, Francis and Crick won the Nobel Prize for their discovery
 Structure and function of DNA

Main features of DNA:

1. DNA is double-stranded ; two polynucleotide stands alongside each
other and the strands are antiparallel, i.e. they run in opposite
directions (5'→ 3’ and 3’→5’)

2. The two strands are wound round each other to form a double
helix.

3. The two strands are joined together by hydrogen bonds between the
complementary base pairs.
 The Structure of DNA
short for deoxyribonucleic acid
composed of basic building block called nucleotides
a nucleotide consists of :
1. phosphate(phosphoric acid)
2. a pentose sugar
3. a nitrogen-containing base
Nucleotides – The building blocks of nucleic acids
(DNA and RNA)
 nucleotides are monomers of nucleic
acid (polymer)

the phosphate of one nucleotide is
attached to the sugar of the next
nucleotide in a line which results in a
backbone of alternating phosphates
and sugars

so DNA (a nucleic acid) is 2 strands of
long sugar phosphate chain/backbone
with organic bases attached to the
sugar
Building the Polynucleotides
 Nitrogenous bases

There are 4 different bases that can
attach to the pentose sugar of DNA:

1. Adenine (A)
2. Cytosine (C)
3. Guanine (G)
4. Thymine (T)
 Complementary base-pairing

each base on one strand of DNA can form weak
hydrogen bonds with a specific base on the
other strand
Adenine only bonds with Thymine (A—T)
Guanine only bonds with Cytosine (G—C)
A=T are linked by 2 hydrogen bonds
G≡C are linked by 3 hydrogen bonds
this is called complementary base pairing
 Complementary base-pairing

the number purine bases (A + G) always equals the number of
pyrimidine bases (T + C)
also, the amount of A = T and C = G in all species
 DNA Base pairing
PO4
PO4
adenine thymine

PO4
PO4
cytosine guanine

PO4
PO4

PO4
PO4
 DNA double-helix

DNA is twisted around each other
– double helix bases
DNA has 2 strands in a double helix
shape
the strands are complementary due
to the nitrogenous bases

sugar-phosphate
chain
 Variation of DNA between species

the sequence of bases varies for each molecule of DNA
across species, the length of DNA also varies
human DNA has ~3billion base pairs (bp), >40,000 genes and can be about 2m long
if stretched out
bacteria have much shorter length of DNA due to the simplicity of its form
but the bigger the animal may not correspond to longer DNA or more genes
 The Genome
Totality of genetic information of an organism
Encoded in the DNA (for some viruses, RNA)
Comparison of chromosomes in prokaryotes and eukaryotes
Comparison of chromosomes in prokaryotes and eukaryotes
Genetics Materials of Life

Double helix
structure
 What are chromosomes?
Genes → DNA → CHROMOSOMES→ Nucleus→ Cells→ Organism
found in the nucleus of cells
not visible unless the cell is dividing
when the cell is not dividing, the mass of chromosomes are called
chromatin
the whole DNA of an organism will be arranged into several
chromosomes
a whole set of chromosome in the cell of an organism is called a
karyotype
 Human Karyotypes

Male Karyotype Female Karyotype
46 chromosomes (usually numbered 46 chromosomes (usually numbered
from largest to smallest) from largest to smallest)
Has one X and Y sex chromosomes each Has two X sex chromosomes and no Y
chromosome
 Genes

genes are made up of DNA
they are regions of the DNA that form hereditary units that will be passed on
from parents to their offspring
the variation and sequence of the four bases A,T,C,G will determine the actual
type and nature of genes
most genes carry information to allow the cell to synthesize proteins
the specific proteins will manifest the organism’s inherited traits
 Genes and chromosomes

each gene (specific DNA sequence) has a
specific location(locus) on a specific
chromosome
chromosomes have a p-arm and a q-arm
which is important to map the location of
a gene’s locus
 on a chromosome, there can be hundreds or thousands of
genes
a specific location of a gene on a chromosome is called a
gene’s locus
 DNA Replication

What is it?
A mechanism for copying genetic material

Why is it important?
To produce an identical copy of genetic
material

Occurs before cell division (mitosis and
meiosis)

Replication doubles the DNA

Essential in passing on the genetic
information from one generation to the
next
 DNA Replication

Three postulated method
of DNA replication:

Semi conservative
Conservative
Dispersive
 Semiconservative replication
✓produce two copies that each contained one of the original strands and
one new strand

Conservative replication
✓leave the two original template DNA strands together in a double helix
and would produce a copy composed of two new strands containing all
of the new DNA base pairs

Dispersive replication
✓produce two copies of the DNA, both containing distinct regions of DNA
composed of either both original strands or both new strands
Alternative models of DNA replication:
Evidence for the semi-conservative method of DNA replication

Semi-conservative replication : each new DNA molecule contains one new strand
and one old strand

Meselson and Stahl (1958)
❖performed an experiment using the bacterium E. coli together with the
technique of density gradient centrifugation of 15N (heavy nitrogen) and 14N
(light nitrogen)
1958: Matthew Meselson & Frank Stahl’s Experiment

Semiconservative model of DNA replication (Fig. 3.2)
 DNA Replication

a single chromosome is duplicated to
form a double unit composed of two
chromatids, attached together at
the centromere
 Step 1: DNA double strands are separated

DNA replication occurs in the
nucleus of cells

DNA replication starts when an
enzyme called helicase
unwinds/separates the two
parent strands or old DNA strand
(separation of double helix)

Both of two strands will both
serve as a template for the
making of a new complementary
strand
 Step 2: The leading strand

On one parent strand, which runs from 3’ to 5’,

DNA replication will start when RNA primase lays down /synthesizes an RNA primer
complementary to the strand

After RNA primer has been synthesized, DNA polymerase will start adding free
nucleotides to the 3’ end of the primer to form a new DNA strand (5’ → 3’) called the
leading strand, complementary to the parent strand (3’→ 5’)

formation of hydrogen bonds between the bases of complementary strands

the replication on the leading strand is continuous towards the replication fork as
helicase unzips the double stranded DNA being replicated
 Step 3: The lagging strand
The DNA replication on the other parent
strand (5’ → 3’) is discontinuous, DNA
replication must start at the replication fork –
known as lagging strand
RNA Primase will lay down & synthesize an
RNA primer at the replication fork
DNA polymerase will synthesize the new
strand from the 3’ end of each primer and the
polymerase will actually move away from the
replication fork in the 5’ to 3’ direction
as helicase unzips another portion of the
double stranded DNA, RNA primase will lay
down another RNA primer at the replication
fork and DNA polymerase will synthesize the
new strand again
 Step 4: Okazaki Fragments and DNA Ligase

lagging strand will be synthesized in
fragments called Okazaki fragments
an Okazaki fragment will have an RNA
primer and also a short length of new
DNA
lastly, DNA ligase will join the Okazaki
fragments together to form a new DNA
strand (the lagging strand)
complementary to the parent strand
The end result of DNA replication is
two double stranded helical DNA
 DNA Replication: Key Enzymes

1. Helicase : unwinds DNA

2. RNA Primase : synthesizes RNA primers to start the replication process

3. DNA Polymerase : synthesizes new DNA strand/ add free nucleotide bind
complementary to template strand

4. DNA Ligase : joins the Okazaki fragments
Exercise
1. Enzyme ________ unzips and unwinds the DNA molecule.
A. DNA polymerase
B. Helicase
C. Primase
D. DNA ligase

2. Which of the following statements about DNA replication is TRUE?
A. the leading strand is replicated continuously, while the lagging strand is replicated discontinuously
B. the leading strand is replicated discontinuously, while the lagging strand is replicated continuously
C. both the leading and lagging strands are replicated continuously
D. both the leading and lagging strands are replicated discontinuously

3. DNA replication results in two identical daughter molecules each consisting of one old (original) strand and one
newly-synthesized strand
A. True
B. False

4. The point where separation of the DNA occurs is called the replication fork.
A. True
B. False
Central Dogma Theory
 Gene Hypothesis 1: Genes specify enzymes

1930, George Beadle and Edward Tatum did experiments using bread
mould which led to the one gene-one enzyme hypothesis
the one gene-one enzyme hypothesis stated that each gene specifies
the synthesis of one enzyme
later on it was soon discovered that other proteins besides enzymes
were also coded by their own respective genes
Which led to……
 Gene Hypothesis 2: Genes specify a polypeptide

many proteins are made up of
two or more different
polypeptide (amino acids) chains
and each chain of polypeptide
has its own specific gene
so, a gene can be said as a
segment of DNA that specifies
the sequence of amino acids in a
polypeptide of a protein
But even this second hypothesis
is not fully correct…
 Genes also specify RNAs
there are some genes that do not code for protein but actually code for structural
RNA (ribonucleic acid) molecules such as ribosomal RNA

There are three types of RNA:
1. Ribosomal RNA (rRNA)
- counts for 80% of cellular RNA
- associates with proteins to form ribosomes

2. Transfer RNA (tRNA)
- specific carriers of amino acids for protein synthesis

3. Messenger RNA (mRNA)
- mRNA is transcribed from DNA to carry the gene message out
to the ribosomes for translation into an amino acid sequence
 RNAs

The DNA Language is the
language of bases (A,C,T,G)….

The Protein Language is the
language of amino acids….
 Amino acids

monomers or building blocks of protein
molecules
a long chain of amino acids(monomer)
will form a chain of polypeptide(polymer)
cells make proteins from various
combinations of 20 different kinds of
amino acids
proteins can be made out of one, two or
more identical or different chains of
polypeptides
Consider this….
 Triplet codes, codons and amino acids
The genetic flow of information from DNA to protein uses the triplet code on DNA
and codons on mRNA, which then translates to amino acids

Most amino acids have more than one triplet code

The triplets of nucleotide sequences on mRNA are specifically called codons

So, as codons are triplets of bases, the number of nucleotides that make up the
genetic message must be three times the number of amino acids specified in the
protein

“In coding for a gene, n=amino acids, 3n=nucleotides”
Amino acids abbreviation

The 20 amino acids can be
abbreviated by a single
letter or three letters a
shown in the table
The flow of information from DNA to protein is unidirectional in most
organisms. i.e. from DNA → RNA → Protein
 5 Key Molecules in Protein Synthesis

1. DNA
2. Messenger RNA (mRNA)
3. Transfer RNA (tRNA)
4. Ribosomal RNA (rRNA)
5. Protein
 1. DNA

double helix with 2 complementary strands
4 bases: A, C, G, T
one strand acts as a coding strand
one strand of the DNA acts as template for the production of a molecule of mRNA
a gene represents a length of DNA that contains specific information for a
particular polypeptide chain
DNA
 2. Messenger RNA (mRNA)
Function:
❑takes a message from DNA in the nucleus to the ribosomes in the
cytoplasm for protein synthesis

it is made in the nucleus but will end up in the cytoplasm

it is a single stranded sequence that is transcribed from a DNA coding strand

similar to DNA except 2 differences:
1. The deoxyribose sugar is replaced by a ribose
sugar
2. Thymine (T) is replaced by Uracil (U). So the
bases are A, C, G, U
mRNA and Codons
When mRNA is transcribed from a molecule of DNA:

Adenine(DNA) bonds to Uracil (mRNA) : A-U

Thymine(DNA) bonds to Adenine (mRNA) : T-A

Guanine(DNA) bonds to Cytosine (mRNA) : G-C

Cytosine(DNA) bonds to Guanine (mRNA) : C-G
DNA VS RNA

RNA DNA

Ribose sugar Deoxyribose sugar
Bases: A, U, C, G Bases: A, T, C, G
Single stranded Double stranded
Not helical Helical
 3. Transfer RNA (tRNA)
also transcribed from DNA
is a single RNA strand (~80 nucleotides long) and has a clover leaf shape
Function
❑code amino acids that will be linked into the polypeptide molecule specified by a
particular sequence of bases on the mRNA
each type of tRNA will carry only one of the 20 amino acids
some amino acids can be carried by more than one tRNA molecule
a specific amino acid will be attached to one end of the tRNA molecule
 the other end of the tRNA molecule has three nucleotides (the
anticodon) which can attach to the matching set of three nucleotides
(codon) on the mRNA molecule
So, tRNA molecules have the same bases as the mRNA molecule (A, U, G
and C) /tRNA – anticodon
 4. Ribosomal RNA (rRNA)

Function:
❑along with proteins, makes up the ribosomes, where polypeptides are synthesized

produced from a DNA template in the nucleus

combined with proteins to make up ribosomes in the endoplasmic reticulum or
the cytoplasm

ribosomes are made up of 2 subunits: a large subunit and a small subunit
 5. Protein

macromolecules (large complex molecule) made from 20 different types
of amino acids
amino acids are monomers or building blocks of protein
two or more amino acids or peptides are called a polypeptide or protein
one or more polypeptide chains can be combined and folded into a
specific and unique shape
the shape of a protein molecule is vital for the function of the protein
molecule
protein synthesis or translation takes place in the cytoplasm and require
specific enzymes
Pathway of Protein Synthesis
DNA
Transcription

RNA
Translation

Amino acids

Polypeptides

PROTEIN
 Two steps of Protein Synthesis

Step 1: Transcription

Step 2: Translation - initiation
- elongation
- termination
 Key Points for Transcription

it occurs in the nucleus
the process where an mRNA molecule is formed that has a sequence of bases
complementary to a portion of one DNA strand
because DNA is double stranded, only one strand is used for the coding of protein
this strand is called the template strand
the other strand is called the complementary strand
 The Process of Transcription

1. a segment of the double stranded DNA helix unwinds and unzips to
separate the two strands. This is done by an enzyme called RNA
Polymerase
2. using the template strand of DNA, RNA polymerase will bring RNA
nucleotides and synthesize an mRNA strand complementary to the
template DNA
3. RNA polymerase joins the RNA nucleotides together in the 5’→3’ direction
4. that means, RNA polymerase can only add RNA nucleotides at the 3’end of
an RNA
5. the newly synthesized mRNA strand(RNA transcript) will undergo some
processing steps before it leaves the nucleus and goes into the cytoplasm
for the next step of protein synthesis
Transcription
 The Discovery of Introns

In eukaryotic cells, most mRNAs (some tRNAs and rRNAs) contain
introns
introns = are the sequences within the primary transcript that do not
appear in the mature, functional RNA
a piece of the DNA in a gene which does not give rise to an amino
acids sequence
before mRNA become functional mRNA, it is edited by cut out the
introns’s base sequences
 Exon and Intron

Introns and exons are parts of genes. Exons code for proteins, whereas introns do
not
exons are parts of DNA that are converted into mature messenger RNA (mRNA) -
the process by which DNA is used as a template to create mRNA is called
transcription
this mRNA then undergoes a further process called translation where the mRNA
is used to synthesize proteins, via another type of molecule called transfer RNA
(tRNA)
Introns are parts of genes that do not directly code for proteins
 RNA Processing - Splicing

The original transcript from the DNA is called
pre-mRNA.
Pre mRNA – the first (primary) transcript from a
protein coding gene and contains both introns
and exons
Introns (intervening sequences) – the non-
coding segments of nucleic acid that lie between
coding regions
Exons – the coding regions of a pre mRNA that
are translated to produce proteins (expressed)
The introns are removed by a process called
splicing to produce messenger RNA (mRNA) by
spliceosomes
 Key Points for Translation

occurs in ribosomes at the cytoplasm or the endoplasmic reticulum (where
ribosomes are found)
the process where the sequence of codons on the mRNA at a ribosome directs
the formation of a sequence of amino acids or a polypeptide
molecules that are involved: mRNA, ribosomes, tRNAs
can be divided into 3 steps:
1. Initiation
2. Elongation
3. Termination
 1. Initiation

starts when the mRNA strand associates with a ribosome
translation is initiated by a signal code and the “start” codon, AUG
the initiator tRNA with the anti codon UAC will bring the amino acid
methionine(met) which corresponds to the “start” codon (AUG)
1. Initiation
 2. Elongation

once the first amino acid, methionine, is brought to the ribosome, the ribosome
will start to “read” the mRNA strand
ribosomes “read” the mRNA strand one codon at a time (3 bases at a time)
while “reading” the mRNA strand, the ribosome will direct the correct tRNA to
the mRNA so that the correct amino acid will be synthesized
so elongation can be said as a process which a long amino acid chain is
produced from mRNA
2. Elongation
 3. Termination

Occurs when the ribosome reaches one of the stop codons
(UAG, UAA or UGA)

when this happens, the ribosome will stop reading the mRNA
and stop bringing in tRNAs with amino acids

the mRNA will then detach from the ribosome

the newly synthesized amino acid chain or polypeptide chain is
also released for further modifications or processing
3. Termination