Download Evolution Biol 4802 History Of Life On Earth

2/4/13
Evolution Biol 4802
Lecture 5, Chapter 5!
n 
Topics for today
n  Archean
n  Proterozoic
n  Paleozoic
–
Cambrian
explosion
History Of Life On Earth!
Chapter
intro
figure
1
2/4/13
History Of Life On Earth!
n 
Common themes:
n  Climates
and land mass distributions have
changed over time
n  Composition of life on Earth is also constantly
changing
n  Several “mass extinction” events have
occurred
n  Diversification rates are generally quite high
after mass extinctions
n  Extinct taxa are often replaced by unrelated
but ecologically similar taxa
Before Life Began!
n 
“Big Bang” – around 14 billion years ago
universe originated via explosion of
exceptionally hot, dense particle
Before Life Began!
n 
Solar system (including Earth) is about 4.6
billions years old
2
2/4/13
Before Life Began!
n 
Earth’s early atmosphere – lot of water
vapor, little oxygen
n 
Extensive volcanic activity released
additional gases – carbon dioxide,
hydrogen sulfide, etc.
n  Also
methane, ammonia, other gases
Miller-Urey Experiment!
n 
Test for what sorts of chemicals would
form under environmental conditions of
early Earth
n  Conditions
produced:
n  More
than 20 different
amino acids
n  Sugars
n  Precursors to purines
and pyrimidines
n  Precursors to other
biomolecules
Miller-Urey Experiment!
n 
Miller-Urey conditions weren’t completely
realistic – need to replicate output from
volcanoes
n  Hydrogen
sulfide, sulfur dioxide, carbon
dioxide
Now get even greater variety of
biomolecules and precursors
n  Other experiments have produced lipidbased cell membrane-like substances
n 
3
2/4/13
The Problem of Replication!
n 
Currently, we have:
n  DNA,
which can store and transmit genetic
information, but can’t perform biological tasks
n  Proteins, which can perform a wide variety of
biological tasks, but can’t replicate
n 
How do we solve this
chicken-or-egg
problem?
Ribozymes!
n 
Small RNA molecules that have selfcatalytic properties
Sydney Altman, Thomas Cech
Ribozymes!
n 
Small RNA molecules that have selfcatalytic properties – including splicing,
chemical modification, and…replication!!
n 
So RNA can act as both genetic material
(information containing) and biological
catalyst (enzyme)
4
2/4/13
“RNA World”!
First replicating “organisms” were selfreplicating RNAs
n  Selection favored RNAs that were most
efficient and accurate at self-replication
n 
Fig. 5.1
“RNA World”!
Adsorption of nucleotides to clay particles
may have facilitated polymerization
n  Clay particles can also catalyze formation
of lipid
envelope
n 
“RNA World”!
n 
Earliest self-replicating “organisms” were
aggregations of molecules (RNA, protein,
lipid)
n  Self-replicating
“organisms” probably arose
multiple times, but just a single origin to all
extant life
n 
Initially no phenotype to self-replicating
molecules except replication speed/
accuracy
5
2/4/13
Where Did Proteins Come In?!
n 
As cofactors to ribozymes?
n  May
also explain origin of genetic code
Fig. 5.2
Why is There Little Evidence of Early Life?!
Earth was still very volatile
n  Ongoing bombardment by meteors
n  Erosion, volcanoes, plate tectonics
n  Complex aggregations of molecules
generally don’t leave a fossil record
n 
Fig. 4.1
But There is Some Evidence!
n  13C
: 12C ratio in atmosphere is ~1 : 99
n  Living organisms prefer 12C
n  3.7 BYO graphite deposits in Greenland
have isotopic signature of life
6
2/4/13
But There is Some Evidence!
n 
Fossilized dividing cells from rocks in
South Africa
3.26 byo fossils
of dividing cells
Modern dividing cells
Knoll and Barghoorn 1977
Geological Time!
n 
If the history of the Earth were represented
as a single year:
n  First
evidence of life in late March
marine animals in late October
n  Extinction of dinosaurs and diversification of
mammals on December 26
n  Human/chimp divergence ~11:00 AM on 12/31
n  Common Era (AD) begins at 11:59:47 PM on
12/31
n  Everything from US Civil War to present is in
last second of the “year”
n  First
Precambrian Life!
Time before
Paleozoic Era
(~550 MYA and
earlier)
n  Includes:
n 
n  Archean
(origin of
life, photosynthesis)
n  Proterozoic (origin
of eukaryotes,
multicellularity)
7
2/4/13
First Life Forms!
Stromalites – layers of microorganisms
that build up layers of sediment
n  First life probably looked a lot like modern
stromalites on the coast of Australia
n 
Fig. 5.3
Photosynthesis!
n 
First organisms were anaerobic – energy
production occurs in absence of oxygen
n  Oxygen
actually harmful to some anaerobes
Aerobic energy production is much more
efficient
n  Photosynthesis evolved ~3 BYA in some
prokaryotes
n 
n  Gradually
oxygen levels in atmosphere built
up, allowing for evolution of efficient aerobic
respiration
Evolution of Domains of Life!
For ~2 billion years, all life was prokaryotic
n  Single-celled eukaryotes evolved ~1.5
BYA
n 
Fig. 2.1
Fig. 5.4
8
2/4/13
Deep Roots of Tree of Life are
Somewhat Uncertain!
n 
Different genes tell different
stories…
Freeman and Herron 2004
Fig. 2.1
Horizontal Gene Transfer!
Likely very common among early
prokaryotes
n  Still common in bacteria today
n 
Perna et al. 2001 link on web
Another View of the Tree of Life!
Endosymbiosis
(formation of
mitochondria and
chloroplasts)
Fig. 2.1
9
2/4/13
Evolution of Multicellularity!
For another 800-900 million years, all life
was single-celled
n  Oldest multicellular fossils date to 550-575
MYA (Ediacaran fauna)
n 
Related to sea anemones
“Problematica” – related to ??
Fig. 5.7
Cambrian Explosion!!
Cambrian Period
represents start of
Paleozoic Era
n  During ~20 MY
period, almost all phyla and classes of
marine animals suddenly appeared in the
fossil record
n 
Fig. 5.8
Burgess Shale!
Giant mudslide off coast of Canada 505
MYA; successive mudslides created
Burgess Shale
n  Discovered in 1909, understood in 1970s
n 
10
2/4/13
Burgess Shale!
n 
Included earliest known jawless vertebrates
(e.g. lampreys)
Fig. 5.9
Burgess Shale!
n 
Most current body plans arose during
Cambrian
Cambrian Explosion!
Fig. 5.11
11
2/4/13
What Caused the Cambrian Explosion?!
Possible large evolutionary changes to
developmental regulatory genes (e.g. Hox
genes)
n  Increase in oxygen levels may have
allowed larger body sizes
n  Larger, more complex body structures
may have led to new interactions among
species (predation, competition) and
associated adaptive evolution
n  We don’t really know…
n 
In-Class Discussion Question!
Was the Cambrian explosion really an
explosion?
n  It occurred over 20 MY in the fossil record
n  Molecular clock-based estimates of phyla
ages are 580-1,000 MYA
n 
n  But
Cambrian explosion in fossil record didn’t
begin until ~540 MYA
n 
How do we explain apparent contradiction
between molecular estimates and fossil
estimates?
12