History of Life on Earth
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Transcript History of Life on Earth
History of Life on Earth
Chapter 12
Section 12-1
HOW DID LIFE BEGIN?
The Early Earth
was Lifeless
When Earth formed about 4.3
billion years ago, it was a fiery ball
of molten rock. It could not have
supported the development of life.
Eventually, the planet’s surface
cooled and formed a rocky crust.
Water vapor in the atmosphere
condensed to form vast oceans.
Many scientists think life first
evolved in these oceans. Scientists
think the evolution of life took
hundreds of millions of years to
occur. Evidence that Earth has
existed long enough for this
evolution to have taken place can
be found by measuring the age of
Earth.
Measuring Earth’s Age
• Scientists are able to calculate the
age of Earth through radiometric
dating.
– Calculation of the age on an object by
measuring the proportions of the
radioactive isotopes of certain
elements
• Radioactive isotopes, or
radioisotopes, are unstable
elements that break up and give off
energy in the form of charged
particles (radiation).
• By measuring how many half-lives
have passed since a rock was
formed,
– The time it takes for one-half of a
given amount of a radioisotope to
change is called its half-life.
Most scientists think that life on
Earth developed through natural
chemical and physical processes.
Spontaneous origin is the process
through which life is thought to
have developed when molecules of
nonliving matter reacted
chemically during the first billion
years of Earth’s history. These
molecules formed many different
simple, organic molecules.
Energized by the sun and volcanic
heat, these molecules formed
more complex molecules that
eventually became the building
blocks of the first cells. This
hypothesis has been tested and
confirmed using scientific methods
in laboratory experiments.
How the Basic
Chemicals of Life
were Formed
The “Primordial Soup” Model
• In the 1920s, Russian scientist A. I. Oparin and British scientist
J.B.S. Haldane each suggested that the early Earth’s oceans
once contained large amounts of organic molecules.
• They both hypothesized that these molecules formed
spontaneously in chemical reactions activated by energy from
solar radiation, volcanic eruptions, and lightning.
• Oparin hypothesized the atmosphere lacked oxygen which
allowed hydrogen to react with other molecules.
• In 1953, the primordial soup model was tested by Stanley
Miller by placing the proposed gases into a device and
stimulating lightning by providing electrical sparks.
• After a few days, Miller had a complex “chemical zoo” which
included life’s basic building blocks: amino acids, fatty acids,
and other hydrocarbons.
Reevaluating the Primordial Soup
Model
• Recent discoveries of fossils
indicate life started much
earlier than first thought.
• Without the protective
ozone layer, ultraviolet
radiation would have
destroyed any ammonia and
methane present in the
atmosphere.
• Without these molecules,
the experiment is not
successful in making key
biological molecules.
The Bubble Model
In 1986, geophysicist Louis Lerman suggested that the
key processes that formed the chemicals needed for
life took place within bubbles on the ocean’s surface.
Organic Chemicals
Became Complex
Though many scientists disagree
about the details of the process
that led to the origin of life, most
scientists accept that by adding
energy, the basic molecules of life
could have formed spontaneously
through organic molecules and
living cells. How did amino acids
link to form proteins? How did
nucleotides form the long chains of
DNA that store the instructions for
making proteins? In the laboratory
scientists have not been able to
make either of these
macromolecules form
spontaneously in water. However,
short chains of RNA, the nucleic
acid that helps carry out DNA’s
instructions, have been made form
on their own in water.
A Possible Role for Catalysts
• 1980s, Cech and Altman found
that certain RNA molecules can
act like enzymes.
• Its 3-d shape provides a surface
on which chemical reactions can
be catalyzed.
• Perhaps RNA was the first selfreplicating information-storage
molecule.
• After such a molecule had
formed, it could also have
catalyzed the assembly of the
first proteins.
• Such a molecule would have
been capable of changing from
one generation to the next.
Microspheres May Have Led to Cells
• Observations show that
lipids, which make up cell
membranes, tend to
gather together in water.
• Lab experiments have
shown that short chains of
amino acids tend to gather
into tiny vesicles called
microspheres.
• Scientists think that
formation of microspheres
might have been the first
step toward cellular
organization.
Origin of Heredity
• Most scientists agree that
double-stranded DNA
probably evolved after RNA
and that RNA “enzymes”
catalyzed the assembly of the
earliest proteins.
• Because researchers do not
yet understand how DNA,
RNA, and hereditary
mechanisms first developed,
how life might have originated
naturally and spontaneously
remains a subject of intense
interest, research, and
discussion among scientists.
Section 12-2
COMPLEX ORGANISMS DEVELOPED
Prokaryotes Are
the Oldest Group
of Organisms
When did the first organisms
form? To find out, scientists
study the best evidence of
early life that we have,
fossils. A fossil is the
preserved or mineralized
remains or imprint of an
organism that lived long ago.
The oldest fossils, which are
microscopic fossils of
prokaryotes, come from 3.5billion-year-old rock deposits
found in western Australia.
Recall that prokaryotes are single-celled organisms
that lack internal membrane-bound organelles.
Prokaryotes are also known as bacteria. Among the
first of the bacteria to appear were cyanobacteria.
Cyanobacteria are photosynthetic bacteria. Before
cyanobacteria appeared, oxygen gas was rare on
Earth. But as ancient cyanobacteria carried out
photosynthesis, they released oxygen gas into Earth’s
oceans. After hundreds of millions of years, the
oxygen produced by cyanobacteria began to escape
into the air. Over the billions of years that followed,
more oxygen was added to the air. Today oxygen gas
makes up 21 percent of the Earth’s atmosphere.
Two Groups of Bacteria
•
•
•
•
Eubacteria
Prokaryotes that contain a
chemical called
peptidoglycan in their cell
walls
Have the same type of
lipids in their cell
membranes as eukaryotes
do
Include many bacteria that
cause disease and decay
E. coli
•
•
•
•
Archaebacteria
Prokaryotes that lack
peptidoglycan in their cell
walls
Have unique lipids in their
cell membranes
Thought to be closely
related to the first bacteria
to have existed on Earth
Sulfolobus
The First
Eukaryotes
Evolved
About 1.5 billion years ago, the
first eukaryotes appeared. Recall
that a eukaryotic cell has a
complex system of internal
membranes and has DNA that is
enclosed within a nucleus. A third
characteristic of almost all
eukaryotes is the presence within
the cells of complex bacteria-sized
mitochondria and chloroplasts.
These organelles contain their
own DNA. Except for one rare
primitive form, all eukaryotes have
mitochondria. Chloroplasts, which
carry out photosynthesis, are
found only in protists and plants.
The Evolution of Mitochondria and
Chloroplasts
• Endosymbiosis was first
presented in 1966 by
Lynn Margulis
• It proposes that
mitochondria are the
descendants of
symbiotic, aerobic
eubacteria
• A second successful
invasion of by
photosynthetic
bacteria gave rise to
chloroplasts
Multicellularity
Evolved Many
Times
The unicellular body plan has
been tremendously successful,
with unicellular organisms
today constitution about half
the biomass on Earth. But a
single cell has limits. Distinct
types of cells in one body allow
an organism to specialize in
different functions including
protection from diseases,
predators, and environment or
movement to find prey or
mates. With all these
advantages, it is not surprising
that multicellularity has arisen
independently many times.
Mass Extinctions Have a Major Impact
The fossil record indicates a sudden change occurred
at the end of Ordovician period about 440 million
years ago. A large percentage of the organisms on
Earth suddenly became extinct. This was the first of
five major mass extinctions that have occurred on
Earth. A mass extinction is the death of all members
of many different species, usually caused by a large
ecological disaster.
• 1st Extinction- 440 million years ago
• 2nd Extinction- 360 million years ago
• 3rd Extinction- 245 million years ago; worst of all
mass extinctions
• 4th Extinction- 210 million years ago
• 5th Extinction- 65 million years ago; bye bye
dinosaurs
• Is a 6th happening right now? Many scientists think
one is taking place right now with the destruction
of many of Earth’s ecosystems.
Section 12-3
LIFE INVADED THE LAND
Ozone Enables
Survival on Land
The sun provides both lifegiving light and dangerous
ultraviolet radiation. Early in
Earth’s history, life formed in
the seas, where early
organisms were protected
from UV radiation. These
organisms could not leave
the water because the UV
radiation made life on dry
ground unsafe. What enabled
life-forms to leave the
protection of the seas and
live on the land?
Formation of the Ozone Shield
• About 2.5 billion years ago,
photosynthesis by
cyanobacteria began adding
oxygen to the atmosphere.
• As oxygen reached the
upper atmosphere, the sun’s
rays caused O2 to bond and
from molecules of O3.
• In the upper atmosphere,
ozone blocks the UV rays of
the sun.
• After millions of years, the
Earth’s land became a safe
place to live.
• Plants and fungi began living on the
land together
• Arthropods crawled out of the sea
• Vertebrates followed onto land
–Fishes evolved
–Amphibians were the first vertebrates
on land
–Reptiles arose from amphibians
–Evolution of mammals and birds