Q2 Topics SY 2022-2023 - Biotechnology PDF

Summary

This document covers the topics of traditional and modern biotechnology, including techniques, microbes, and the roles of DNA, RNA, and proteins in heredity. It also discusses mutations and genetic diseases. The content is presented in a question-and-answer format, with activities, and includes a comparison chart of traditional and modern biotechnology.

Full Transcript

SECOND
QUARTER
TOPICS
 TRADITIONAL VS. MODERN BIOTECHNOLOGY
 TECHNIQUES OR PRACTICES USED IN TRADITI
ONAL BIOTECHNOLOGY
 MICROBES USED IN BIOTECHNOLOGY
 VITAL ROLE OF DNA, RNA, PROTEINS IN THE T
RANSMISSION OF THE HEREDITARY TRAITS
 MUTATIONS IN DNA/GENETIC DISEASES
TRADITIONAL MODERN
Traditional Biotechnology
is the use of natural organisms by humans to
create or modify foods or other useful
products. Examples of traditional biotechnology
include using yeasts for fermentation and practicing
selective seed collection to create hardier crops.
Early civilizations used traditional biotechnology
techniques in a trial and error manner without
understanding why they worked. Many traditional
biotechnology techniques continue to be used and
improved with a growing understanding of scientific
principles.
Modern Biotechnology
is the use of an organism, or a component of
an organism or other biological system, to
make a product or process for a specific use.
This is a very broad definition, and as
mentioned above, it can include both
cutting-edge laboratory techniques and
traditional agricultural and culinary techniques
that have been practiced for hundreds of years.
Difference?
We can distinguish between traditional and
modern biotechnology. Whereas traditional
biotechnology exploits the potential of
processes performed by living organisms,
such as fermentation, modern biotechnology
manipulates the genes of organisms and
inserts them into other organisms to acquire
the desired trait.
COMPARISON CHART
Traditional Biotechnology Modern Biotechnology
SLOGAN/POSTER/LOGO
RUBRICS:
TECHNIQUES OR PRACTICES USED
IN TRADITIONAL BIOTECHNOLOGY
HISTORY OF
BIOTECHNOLOGY
The utilization of biological processes,
organisms or systems to produce products that
are anticipated to improve human lives is
termed biotechnology. Broadly, this can be
defined as the engineering of organisms for the
purpose of human usage.
HISTORY OF
BIOTECHNOLOGY
Currently biotechnology places more emphasis
on the establishment of hybrid genes followed by
their transfer into organisms in which some, or
all, of the gene is not usually present. In
prehistoric times, a primitive form of
biotechnology was practised by agriculturalists
who established better-quality species of plants
and animals by methods of cross-pollination or
cross-breeding.
HISTORY OF
BIOTECHNOLOGY
Later, it was discovered that micro-organisms, e.g.
bacteria, yeast or molds, hydrolyze sugars when they
lack oxygen and are ultimately responsible for
fermentation. During the prehistoric era some
civilizations considered fermentation to be a gift from
their gods.
MOULDY CHEESE
EARLY EXAMPLES OF
BIOTECHNOLOGY
The earliest example of biotechnology is the
domestication of plants and animals.
Domestication began over 10,000 years ago when
our ancestors started keeping plants as a reliable
source of food. Wild animals were tamed to provide
milk or meat or help with ploughing or guarding
the farm. The dog, sheep and goat are thought to
be among the first animals that were
domesticated.
DOMESTICATED ANIMALS
Making new foods using biotechnology

Louis Pasteur (1822-1895) was a French chemist who made
several key discoveries. He proved that infectious diseases
were caused by microorganisms, developed the first
vaccines and invented pasteurisation. Louis Pasteur first
described the scientific basis for fermentation in the late
1800s. Pasteur’s hypothesis, called the germ theory,
showed the existence of microorganisms and their effect
on fermentation. Pasteur’s work gave birth to many
branches of science.
LOUIS PASTEUR
Making new foods using biotechnology

The products generated from fermentation
affect the nature of the food that
the microorganism is in - carbon
dioxide causes bread to rise, lactic acid makes
yoghurt sour, and alcohol is produced in the
formation of beer and wine.
TRADITIONAL MEDICINE
Peter Molan explains that honey has been used in
medicine since ancient Egyptian times. For example,
the ancient Egyptians used honey for
respiratory infections and as an ointment for wounds.
Honey is a natural antibiotic, killing the germs in
wounds. By about 600BC, the Chinese were using
mouldy soybean curds to treat boils. Similarly, Ukrainian
peasants were using mouldy cheese to treat infected
wounds.
PETER MOLAN
TRADITIONAL MEDICINE
The moulds released natural antibiotics that
killed bacteria and prevented the spread
of infection. Despite these natural treatments,
it wasn’t until 1928 that Alexander Fleming
first extracted penicillin – the first antibiotic –
from mould.
ALEXANDER FLEMING
SELECTIVE BREEDING
Teosinte is an ancient grain thought to have been
selectively bred into maize 6,000 to 10,000 years
ago. It has few kernels, and they are enclosed in
a hard casing. Early pioneers of selective
breeding mated organisms with
desirable traits to enhance these traits in their
offspring. Selective breeding pioneers were
manipulating the genetic makeup of organisms,
without even realising it.
TEOSINTE AND MAIZE
ACTIVITY: CROSSWORD!
ACROSS
1 it is the exploitation of biological processes
for industrial purposes. Especially genetic
manipulation of microorganisms for
production of antibiotics.
3 He was a French Chemist and
microbiologist
4 An individual animal, plant or single-celled
ACTIVITY: CROSSWORD!
DOWN
5 he was a New Zealand Biochemist,
noted for his education of medicinal
properties of manuka honey.
2 The chemical breakdown of a
substance by bacteria, yeasts, or other
microorganisms.
ACTIVITY: JEOPARDY!
The teacher will give an answer and the
learners will create a 1 question out of the
provided answer.
Answer Question

This is one of the processes from
Fermentation traditional biotechnology that is
being used until this modern
day?
ESSAY!
Enumerate 3 traditional biotechnology
techniques and describe each technique or
practices and answer question number 2
with a minimum of 5-10 sentences.
What do you think is the importance of
traditional biotechnology and its contribution
to our lives especially during this pandemic?
MICROBES USED IN
BIOTECHNOLOGY
LIFELINE:

CALL a FRIEND (x2)
AUDIENCE OPINION
5 points 5
points

1. Who is the father of traditional
biotechnology?
A. Karl Ereki
B. Karl Ereky
C. Karl Erecky
D. Karl Erekee
10 points 10
points

2. What Bacteria causes infections in the blood,
lungs (pneumonia) after surgery.
A. Pseudomonas
B. Escherichia Coli
C. Aspergillus
D. Bacillus
15 points 15
points

3. What bacteria is being shown?
A. Pseudomonas
B. Escherichia Coli
C. Aspergillus
D. Bacillus
20 points 20
points

4. It is by far the most common host cell for
recombinant DNA work.
A. Pseudomonas
B. Escherichia Coli
C. Aspergillus
D. Bacillus
25 points 25
points

5. It is a process in which packaged and non-
packaged foods are treated with mild heat,
usually to less than 100 °C, to eliminate
pathogens and extend shelf life.
A. Fermentation C. Segmentation
B. Pasteurization D. Propagation
TRUE or FALSE
1. Pseudomonas bacteria causes infection to
blood, lungs (pneumonia) commonly after
surgical operation.
2. E. Coli is a very versatile Gram-negative
bacterium is used in many
biotechnological processes.
TRUE or FALSE
3. Bacillus Subtilis is a yeast is used in
fermentations to produce chemicals.
4. Aspergillus is a type of filamentous fungus
that has been used for genetic engineering
in a few cases and which is also used to
produce citric acid by fermentation.
TRUE or FALSE
5. Clostridium Acetobutylicum is bacterium
is used as a source of enzymes.
Video Analysis
Enumerate at least 3 important
contributions of these microbes to
humanity?
What is the importance of these
commonly used microbes in the
evolution of biotechnology today?
 MICROBES!
Microbial biotechnology is a dynamic field; the
origins of microbiology can be traced back to
the pioneering research by scientists such as
Louis Pasteur and Robert Koch in the 19th
century. Within a few decades, increased
knowledge of microorganisms and genetics
made possible numerous important scientific
and technological developments.
 MICROBES!
Important technologies in the field of
microbial biotechnology include
genetically engineering microorganisms
for various purposes. The use of microbes
in biotechnology has provided a wide
range of products and services to a
diverse number of industries.
ASPERGILLUS
A type of filamentous
fungus that has been
used for genetic
engineering in a few
cases and which is
also used to produce
citric acid by
fermentation.
Bacillus Subtilis
This Gram-positive
bacterium is widely
used as a cloning host,
especially for the
expression of secreted
proteins.
Candida Utilis
A yeast used in
fermentations to
produce
chemicals
Clostridium Acetobutylicum

A bacterium used as
a source of enzymes.
Corynebacterium
Glutamicum

This is widely used
in fermentation
processes
producing amino
acids for food
supplements.
Escherichia Coli
It is by far the most common
host cell for recombinant DNA
work. It is also used in
fermentations to make many
amino acids and other
products since it grows on
many very cheap fermentation
substrates, grows fast, and can
be manipulated genetically to
accumulate many different
chemicals.
Penicillum
A group of
filamentous fungi
used primarily to
produce penicillin
antibiotics.
Pseudomonas
A group of soil bacteria
that contain some
extremely diverse
chemical abilities,
which biotechnology
has harnessed in
bioremediation.
Saccharomyces Cerevisiae

Brewers’ and bakers’
yeast, and as such is
probably the most
widely exploited
microorganism.
Streptomycetes
These Gram-positive
bacteria are used to
produce a range of
chemicals, especially
antibiotics. They have
also been used as the
host for genetic
engineering.
POSTER MAKING

Theme: Importance of
Microbes to Humans
RUBRICS
VITAL ROLE OF DNA, RNA, PROTEINS IN THE
TRANSMISSION OF THE HEREDITARY TRAITS
DNA = Deoxyribonucleic acid is a polymer
composed of two polynucleotide chains that coil
around each other to form a double helix.
RNA = Ribonucleic acid is a polymeric molecule
essential in various biological roles in coding,
decoding, regulation and expression of genes.
RNA and deoxyribonucleic acid are nucleic
acids.
Nucleic Acids = Nucleic acids are large
biomolecules that play essential roles in all cells
and viruses. A major function of nucleic acids
involves the storage and expression of genomic
information. Deoxyribonucleic acid, or DNA,
encodes the information cells need to make
proteins.
Proteins = Proteins are large, complex
molecules that play many critical roles in the
body. They do most of the work in cells and are
required for the structure, function, and
regulation of the body's tissues and organs.
Heredity = also called inheritance or biological
inheritance, is the passing on of traits from
parents to their offspring; either through
asexual reproduction or sexual reproduction,
the offspring cells or organisms acquire the
genetic information of their parents.
The classical principles of genetics were
deduced by Gregor Mendel in 1865, on the
basis of the results of breeding experiments
with peas. Mendel studied the inheritance of a
number of well-defined traits, such as seed
color, and was able to deduce general rules for
their transmission.
Inheritance talks about how these traits are passed
down from one generation to the next. Segments of
DNA, called genes, are responsible for distributing
this information. Each gene has the instructions to
make one protein. There can be multiple versions of a
gene, and these versions are called alleles. For
example, at the gene for eye color, you can have
either a brown allele or a blue allele (note: this is an
oversimplification). Each of your parents gave you one
allele for each gene you have.
Proteins are major components of cells that
perform a wide variety of tasks- they perform
chemical reactions, make pigments, and form your
muscles, hair, and nails. The presence or absence
of proteins creates your physical characteristics.
Eye, skin, and hair colour all depend on pigment
proteins being produced or not being produced.
These proteins are produced by a gene that tells
the cell how to make a protein.
MUTATIONS
IN DNA
Dominant Traits A dominant trait is an inherited
characteristic that appears in an offspring if it is
contributed from a parent through a dominant
allele. Traits, also known as phenotypes, may
include features such as eye color, hair color,
immunity or susceptibility to certain diseases
and facial features such as dimples and
freckles.
In sexually reproducing species, each individual
has two pairs of chromosomes; humans have 23
pairs of chromosomes, and so 46 chromosomes in
total. The chromosomes contain thousands
of genes which code for the proteins that express
and control all of the biochemical and physical
features of an organism; this set of genes is an
organism’s genotype.
Examples of Dominant Traits:
Dark hair is dominant over blonde or red hair.
Curly hair is dominant over straight hair.
Baldness is a dominant trait.
Having a widow’s peak (a V-shaped hairline) is
dominant over having a straight hairline.
Freckles, cleft chin and dimples are all examples of a
dominant trait.
Examples of Dominant Traits:
Having almond-shaped eyes is a dominant trait whereas
having round eyes is a feature controlled by recessive
alleles.
The trait of detached earlobes, as opposed to attached
earlobes, is dominant.
Right-handedness is dominant over left-handedness.
The ability to roll the tongue is dominant over the
inability to do so.
Examples of Dominant Traits:
Astigmatism is dominant over normal vision.
The presence of webbed fingers is a dominant trait.
The development of 6 fingers instead of 5 is controlled by
dominant alleles.
Brown eyes are dominant over blue eyes (however, eye color is
controlled by more than one gene and is thus a polygenetic
trait and cannot be explained by Mendelian genetics. People
with green and hazel eyes have a mix of alleles for brown and
blue eyes).
RECESSIVE TRAITS
A recessive trait is a trait that is expressed when
an organism has two recessive alleles, or forms of
a gene. Traits are characteristics of organisms
that can be observed; this includes physical
characteristics such as hair and eye color, and
also characteristics that may not be readily
apparent, e.g. shape of blood cells.
RECESSIVE TRAITS
Every organism that organizes its DNA into
chromosomes has two alleles for a trait, one from
their mother and one from their father.
Alleles can be dominant or recessive. Dominant
alleles mask the effects of recessive alleles, so a
recessive trait is only expressed when an
organism has two recessive alleles for a gene.
Examples of Recessive Traits:
Many traits we observe in the people around us are
examples of dominant and recessive traits. For
example, having a straight hairline is recessive, while
having a widow’s peak (a V-shaped hairline near the
forehead) is dominant. Cleft chin, dimples, and freckles
are similar examples; individuals with recessive alleles
for a cleft chin, dimples, or freckles do not have these
traits.
Examples of Recessive Traits:
Having round (as opposed to almond-shaped) eyes is
recessive, along with inability to roll one’s tongue.
Attached earlobes (as opposed to free) is also a
recessive trait. Having blue eyes is recessive to brown
eyes, but eye color is an example of a polygenic trait, a
trait that is affected by more than one gene, so it
cannot be explained via simple Mendelian inheritance.
(Eye color being polygenic is why green and hazel eyes
exist; a person with green or hazel eyes has some
genes for brown eyes and some for blue eyes.)
Examples of Recessive Traits:
Some disorders are autosomal recessive, such as cystic fibrosis,
Tay-Sachs disease, and sickle cell anemia. Autosomal means
that they are caused by a recessive gene found in one of the
chromosomes that is not a sex chromosome (i.e., not found on
the X or Y chromosomes). Certain other disorders are X-linked
recessive. They are found on the X chromosome and are more
common in males, since males have only one X chromosome.
Colorblindness, hemophilia, and Duchenne muscular dystrophy
are examples of recessive X-linked disorders.
Mutations in DNA:
A mutation is a change in a DNA sequence.
Mutations can result from DNA copying mistakes
made during cell division, exposure to ionizing
radiation, exposure to chemicals called mutagens,
or infection by viruses. Germ line mutations occur
in the eggs and sperm and can be passed on to
offspring, while somatic mutations occur in body
cells and are not passed on.
Mutations in DNA:
Mutation has been the source of many
Hollywood movies, but it's really a simple
process of a mistake made in a DNA sequence
as it's being copied. Some of that's just the
background noise that DNA copying is not
perfect, and we should be glad of that or
evolution couldn't operate.
Mutations in DNA:
But mutation can also be induced by things like
radiation or carcinogens in a way that can
increase the risk of cancers or birth defects. But
it's pretty simple; it's basically an induced
misspelling of the DNA sequence. That's a
mutation.
Causes od DNA mutations:
Mutations make the protein synthesis go wrong
during translation or mistakes in DNA are
present that result in abnormalities in bodies in
the form of some diseases like sickle cell
anaemia. So, the causes of mutation can be any
of the below mentioned points
Causes od DNA mutations:
 Mutations can be inherited from parents to a child.
 Mutations are spontaneous, e.g. - DNA replication
errors (internal factor), environmental factors and
completely random reasons.
 External factors such as certain types of chemicals
or excessive radiation also cause mutations to
occur.
Types of Mutation:
Gene Mutations
 DNA makes up genes and genes can code for proteins,
influencing various traits. However, not all genes code for
proteins and not all genes are turned on.
 Therefore, when a mutation in DNA occurs, it means a change in
one or more DNA bases takes place, and then different proteins
are produced which affect an organism’s traits.
Types of Mutation:
Gene Mutations
Germline mutation: A change in a gene that occurs in a parent’s
reproductive cells (egg or sperm) that affects the genetic makeup of their child
(hereditary).
Somatic mutation: A change in a gene that occurs after conception in the
developing embryo that may become a baby. These occur in all cells in the
developing body — except the sperm and egg. Somatic mutations can’t pass
from parents to their children (hereditary) because traits are passed only from
the sperm and egg.
Types of Mutation:
Chromosomal Mutations
 When mutations occur at the level of chromosome, it is called
chromosomal mutation. Chromosomes are made up of DNA and
protein, are highly organized and have lots of genes on them.
The human chromosome number is 46; 23 from an egg cell and
23 from a sperm cell. Similarly, fruit fly has 8 chromosomes, 4
come from an egg cell and 4 comes from the sperm cell.
Genetic Disorders:
Sickle Cell Disease
 Sickle cell disease is an inherited blood disorder. It is
marked by flawed hemoglobin. That’s the protein in red
blood cells that carries oxygen to the tissues of the body.
So, sickle cell disease interferes with the delivery of oxygen
to the tissues.
Genetic Disorders:
Cystic Fibrosis
 Cystic fibrosis (CF) is an inherited life-threatening disease
that affects many organs. It causes changes in the
electrolyte transport system causing cells to absorb too
much sodium and water. CF is characterized by problems
with the glands that make sweat and mucus. Symptoms
start in childhood. On average, people with CF live into
their mid to late 30.
Genetic Disorders:
Huntington’s Disease
 Huntington disease is a brain disorder in which brain cells,
or neurons, in certain areas of your brain start to break
down. As the neurons degenerate, the disease can lead
to emotional disturbances, loss of intellectual abilities, and
uncontrolled movements.
POEM

Make 4 line, 3
stanza poem about
DNA Mutations
GENETIC DISEASES
Sickle Cell Disease
 Sickle cell disease is an inherited blood disorder. It
is marked by flawed hemoglobin. That’s the protein
in red blood cells that carries oxygen to the tissues
of the body. So, sickle cell disease interferes with
the delivery of oxygen to the tissues.
GENETIC DISEASES
Cystic Fibrosis
 Cystic fibrosis (CF) is an inherited life-threatening disease
that affects many organs. It causes changes in the
electrolyte transport system causing cells to absorb too
much sodium and water. CF is characterized by problems
with the glands that make sweat and mucus. Symptoms
start in childhood. On average, people with CF live into their
mid to late 30.
GENETIC DISEASES
Huntington’s Disease
 Huntington disease is a brain disorder in which
brain cells, or neurons, in certain areas of your brain
start to break down. As the neurons degenerate, the
disease can lead to emotional disturbances, loss of
intellectual abilities, and uncontrolled movements.
GENETIC DISEASES
Down Syndrome
 Down syndrome is a genetic disorder. Most babies are born
with 23 pairs of chromosomes within each cell for a total of
46. A chromosome is a structure that contains genes, which
are made up of your DNA. Genes determine how a fetus
develops in the uterus and after birth. The majority of
babies with Down syndrome are born with an extra copy of
chromosome 21, with three copies of the chromosome
instead of the usual two.
GENETIC DISEASES
Fragile X Syndrome
Fragile X syndrome (FXS), also known as Martin-Bell syndrome, is an
inherited condition that causes developmental delays, intellectual
disabilities, learning and behavioral issues, physical abnormalities,
anxiety, attention-deficit/hyperactivity disorder and/or
autism spectrum disorder, among other problems. It’s the most
common form of inherited intellectual and developmental disability
(IDD).
FXS is named fragile X syndrome because, when looked at through a
microscope, part of the X chromosome looks “broken” or “fragile.”
GENETIC DISEASES
Muscular Dystrophy
Muscular dystrophy refers to a group of more than 30
inherited (genetic) diseases that cause muscle weakness.
These conditions are a type of myopathy, a disease of the
skeletal muscles. Over time, muscles shrink and become
weaker, affecting your ability to walk and perform daily
activities like brushing your teeth. The disease also can
affect your heart and lungs.
Some forms of muscular dystrophy are apparent at birth or
develop during childhood. Some forms develop later during
adulthood. Currently, there isn’t a cure.
GENETIC DISEASES
Ehlers-Danlos Syndrome

Ehlers-Danlos syndrome is a group of conditions that affect the
connective tissues in the body. These tissues include cartilage,
bone, fat and blood. They support organs and other tissues
throughout the body.
Doctors classify Ehlers-Danlos syndrome into 13 types based on
their most notable features and the parts of the body where
symptoms appear. People with the most common type have
symptoms including very loose joints and fragile skin that tears
easily.
INFORMATION BROCHURE

CREATE A SIMPLE INFO-BROCHURE
ABOUT GENETIC DISORDERS. YOUR
GROUP CAN CHOOSE 2 GENETIC
DISORDER (ASIDE FROM WHAT WE HAVE
DISCUSSED)
BROCHURE INCLUSIONS

INFORMATION ABOUT THE
DISEASE
HOW MANY CASES HERE IN THE
PHILIPPINES (PERCENTAGE)
TREATMENT/MANAGEMENT