WEEK 2 - Q2 Earth and Life Science PDF

Summary

This document is a set of notes on Earth and Life science, focusing on the concept of the origin and evolution of life. The document discusses the historical development of life, conditions on early Earth, and unifying themes of life.

Full Transcript

Week 2
2nd QUARTER

Earth and Life Science
At the end of the lesson the
student must be able to:

a. Discuss the historical development of the concept of
life including theories, experiments and evidences;
b. Describe the conditions on early Earth that made
the origin of life possible and the first life forms;
and
c. Discuss the unifying themes of life and how they
are interconnected
Many Scientists have dedicated themselves to finding
out how life first appeared on Earth. All in the name of
curiosity, science and discovery. Life is believed to
have existed on earth for billions of years now.
Scientists do not know exactly when did life begin on
Earth. However, they are able to trace how life
developed and evolved using some pieces of evidence.
This is a difficult question to answer, largely because
life itself is not a simple concept. If you try to write a
definition of “life,” you will find that it is not an easy
task, because of the loose manner in which the term is
used. However, a phenomena called LIFE transcends a
succinct one sentence/ phrase definition. It is because
we recognized life by what living things do, apparently
by the characteristics/ properties associated with life.
 SENSITIVITY
Living things are able to
respond to the environment
through a stimulus. Irritability
is an example. Another
example is a living thing‟s
response to light by facing the
sun and sweating as our body
response to heat which is also
connected to excretion.
 REPRODUCTION
Unicellular organisms
reproduce by DNA replication and
dividing equally as the new cell
prepares to form two new cells while
multicellular organisms often
reproduce using its gametes in order
to form new individuals. When there
is reproduction, genes with DNA will
passed from generation to generation
to make sure that the offspring
belong to the same species having
similar characteristics.
 GROWTH AND DEVELOPMENT
Organisms grow and develop
according to its genes that gives
instruction that will direct the
cellular growth and development
ensure that the offspring will grow
up and manifest many of the same
characteristics from the parents.
Mitosis and meiosis play an
important role in this matter.
 NUTRITION
Living things take in minerals
and food from the
environment in order to
survive and grow. It is the
process of which organism
obtain energy and raw
materials from nutrients such
as fats, carbohydrates and
proteins.
 RESPIRATION
It is the process in
which the energy from the food
eaten is being released in all
living cells. Organisms break
down the food within their
cells with a specific process to
carry out the following
processes.
 MOVEMENT
All living things move.
Animals move from one place to
another. Plants also move but not
as usually observable than
animals. Plants move in different
ways in order to grow and their
movement may be so slow that
people cannot even recognize. A
Makahiya leaf being touched is an
example of movement through
thigmotrophism.
 EXCRETION
All living things also
excrete but in different ways.
Excretion is the result of many
chemical reactions happening
in cells which they have to
remove the waste products
which might poison the cells.
Excretion is the removal of
toxic minerals in excess from
the organism.
There were many theories inferred by different scientists on the
origin of the universe. Few of these are the Theory of Special
Creation, Theory of Spontaneous Generation, Theory of
Biogenesis, Theory of Biochemical Evolution, Theory of
Panspermia, and Deep-sea hydrothermal vent theory. These
theories may have or may have not scientific basis.

Some believed that organisms were put to Earth by some divine
forces (Canoy, 2016) while others say that life did not originate
from Earth but from other celestial bodies. Among the scientists,
the most accepted theory is that life came from lifeless matter.
Alexander Ivanovich Oparin

Russian March 2, 1894 – April 21,
1980 a Soviet biochemist notable for
his theories about the origin of life,
and for his book The Origin of Life.
He also studied the biochemistry of
material processing by plants and
enzyme reactions in plant cells.
John Scott Haldane

Scottish May 2, 1860 –March
14/15 ,1936 a physiologist
famous for intrepid self-
experimentation which led to
many important discoveries
about the human body and the
nature of gases.
Oparin- Haldane
Hypothesis

This hypothesis suggested
that if the primitive
atmosphere was reducing (as
opposed to oxygen-rich), and
if there was an appropriate
supply of energy, such as
lightning or ultraviolet light,
then a wide range of organic
compounds might be
synthesized.
Primordial Soup
Haldane coined the term
'prebiotic soup' or 'prebiotic
atmosphere' that consisted of
an abundance of methane,
ammonia, and water. This
term became a powerful
symbol of the Oparin-
Haldane view of the origin of
life.
Harold Clayton Urey
American April 29, 1893 –
January 5, 1981 a physical
chemist played a significant role
in the development of the atom
bomb, but may be most
prominent for his contribution
to theories on the development
of organic life from non-living
matter.
Stanley Lloyd Miller
American March 7, 1930 – May
20, 2007 a chemist who made
landmark experiments in the
origin of life by demonstrating
that a wide range of vital organic
compounds can be synthesized
by fairly simple chemical
processes from inorganic
substances.
Stanley Miller and Harold
Urey After a day, they observed a
verified the primordial soup change of color in the solution.
theory by simulating the After a week, the solution was
formation of organic molecules tested, and they found out that
on the early Earth. They several amino acids were
confined methane, ammonia, produced.
water, and hydrogen in a
closed system and applied
continuous electrical sparks to
trigger the formation of the
building blocks of life.
All living things are made up of cells. Some are
unicellular and some are multicellular.
Unicellular organisms that are mostly known are
paramecium, amoeba, bacteria, and yeast. The
multicellular cells include animal cells, plant
cells, and the human body and germ cells. Given
what scientists know about relationships among
modern species.
Most assume that this common ancestor was
prokaryotic, meaning it did not have a nucleus.
There was a scarcity of oxygen during the early
Earth‟s atmosphere so the ancestral cell must
also have been anaerobic meaning capable of
living without oxygen.
What are the evidences to prove such
statement?

Cells are microscopic and cannot be seen through
our naked eye and is difficult to fossilize.
Furthermore, few ancient rocks that could hold
early fossils still exist. Tectonic plate movements
have destroyed nearly all rocks older than about 4
million years, most slightly younger rocks have been
heated that destroy traces of biological material.
What are the evidences to prove such
statement?

Structures formed by non-biological mechanisms
sometimes resemble fossils. To avoid mistakes on
accepting materials like genuine fossils, scientists
repeatedly analyze purported (not definitely true or
real) fossil finds and they often question one
another‟s conclusion.
What are the evidences to prove such
statement?

The Oldest Fossil Cells
The divergence that separated the two prokaryotic
domains, Bacteria and Archaea, occurred rarely in
the history of life, and no fossils from before this
divergence have been discovered.
It has been studied that the first form of life is believed
to have appeared 3.5 billion years ago.
What are the evidences to prove such
statement?

The Oldest Fossil Cells
Paleontologists are the scientists who study fossils
found microscopic living cells known as microfossils in
rocks that formed 3.5 billion years ago after Earth
cooled and solidified using radioisotope dating (which
uses radioactive materials such as the radioactive
components of potassium-argon).
What are the evidences to prove such
statement?

The Oldest Fossil Cells
Paleontologists are the scientists who study fossils
found microscopic living cells known as microfossils in
rocks that formed 3.5 billion years ago after Earth
cooled and solidified using radioisotope dating (which
uses radioactive materials such as the radioactive
components of potassium-argon).
What are the evidences to prove such
statement?

The Oldest Fossil Cells
The microfossils‟ filaments found in Western Australia
resemble chains of modern photosynthetic bacteria and
the rocks in which they occur are thought to be remains
of ancient stromatolites which are mounded, layered
structure that forms in shallow sunlit water when a mat
of photosynthetic bacteria traps minerals and sediment.
Example of microfossils
of sulphur-metabolizing
cells in 3.4-billion-year-
old rocks of Western
Australia
Many types of bacteria carry out
photosynthesis, but only one group,
cyanobacteria, do so by an oxygen-producing
pathway. The microfossils of cyanobacteria
were among the easiest to recognize. The forms
of these organisms were remained the same
and left chemical fossils in the form of broken
products from pigments.
The first microfossil that showed remains of
organisms with differences in structure and
characteristics was seen 1.5 billion years ago
on the rocks. They are bigger compared to
bacteria and have internal membranes and
thicker wall.
These findings marked the beginning of eukaryotic
organisms on Earth. The evolution of oxygen-
producing photosynthesis in cyanobacteria had
started on early life. About 2.5 billion years ago,
oxygen released by these bacteria had begun to
accumulate in Earth‟s air and creating a new, global
selection pressure. Other species considered oxygen
as toxic thus evolved gradually in its absence.
How did multicellular organisms evolve?

Multicellular organisms are believed to have
evolved from unicellular eukaryotes and until now it
is the concept that we believe. Single eukaryotic
cells, just like unicellular algae, formed multicellular
aggregates through association with another cell
producing colonies. From colonial aggregates, the
organisms evolved in order to form multicellular
organisms through cell specialization. Organisms
like protozoans, sponges, and fungi came to being.
How did multicellular organisms evolve?

The soft-bodied animals were the first fossilized
animals which were discovered 580 million years.
The continuous process of cell specialization
brought the emergence of diverse plants and
animals, including human beings and including the
complex ones. Charles Darwin said that organisms
change over time as a result of adaptation to their
environment in order to survive.
Rise of the Eukaryotes
Nucleus is not often preserved during fossilization but
other traits provide evidence that a fossilized cell was
eukaryotic. These eukaryotic cells are generally larger
than the prokaryotic cells. A cell wall with complex
patterns, spines, or spikes probably belonged to a
eukaryote. Researchers and scientists also look for
biomarkers (substance that occurs only or predominantly
in cells of a specific type) for each eukaryote just like the
steroids found present only to eukaryotes.
 Table 1. Difference between Prokaryotes and Eukaryotes
Prokaryotic Cell Eukaryotic Cell

„pro‟= pre, „karyon‟=nucleus „eu‟ = true , „karyon‟=
nucleus
Originated about 3.5 billion Originated about 1.2 billion
years ago years ago
Primitive forms Advanced

Unicellular Multicellular

Developing nucleus True nucleus present

Small in size Larger in Size

Non-bounded membrane Membrane-bounded
 Table 2. Origin of Some Organelles
Organelle Origin
 Nucleus - The DNA (deoxyribonucleic acid) of the prokaryotes lies
on unenclosed in the cell‟s cytoplasm while the DNA of
the eukaryotes are enclosed with an endomembrane
(group of members and organelles). The nucleus and
endomembrane system evolve when plasma membrane of
an ancestral prokaryote folded inward.
 Mitochondria and - Mitochondria and chloroplasts resemble bacteria in their
Chloroplast size and shape, and they replicate independently of the
cell that holds them. Bacteria have their own DNA in the
form of a singular chromosome and have at least two
outer membranes and innermost membrane similar to
bacterial plasma membrane.
- Chloroplast is the site of photosynthesis.
 Table 3: Functions of Other Cell Organelles
Cell
Function
Organelles
Ribosomes - Makes protein

Golgi - Does the packaging and processing of
Apparatus proteins
Lysosomes - Contain enzymes to help break the food
down
Endoplasmic - Transports items around the cell
Reticulum
Vacuole - For water or food storage

Chloroplasts - Present in plants only; uses sunlight to
make food through photosynthesis
Cell wall - Rigid; supports the cell
One of the most important theories in biology is
evolution. Ever since its formulation in the mid-1800s
by two English naturalists, Charles Darwin and Alfred
Russel Wallace, the theory of evolution has been
supported by fossil finds, geological studies, radioactive
dating of rocks, genetics, molecular biology,
biochemistry, and breeding experiments.
Evolution is the unifying theory that explains the origin
of diverse forms of life as a result of changes in their
genetic make-up. The theory of evolution states modern
organisms descended, with modification, from pre-
existing life-forms.
In the word of biologist Theodosius Dobzhansky, “Nothing in
biology makes sense, except in the light of evolution.” Why don‟t
snakes have legs? Why are there dinosaur fossils but no living
dinosaurs? Why are monkeys so like us, not only in
appearance, but also in the structure of their genes and
proteins? The answers to those questions, and thousands
more, lie in the process of evolution. Evolution is so vital to our
understanding and appreciations of biology that we must review
its important principle before going further.
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