PSC182 Life in the Universe Lecture Notes (Ch. 6) PDF

Summary

These lecture notes cover the development of life on Earth from a brief history to a lecture plan and early atmosphere. The author also details how life may have started.

Full Transcript

2024-10-22

PSC182
(Life in the Universe, Ch.6)

Lectures 15+
Development of Life on Earth

A brief history of life on Earth

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Lecture plan:

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How did Life start?
The essential organic materials (CO2, CH4, NH3, water, H2, N2,…)
already here.
Comets & meteorites may have brought more complex organic
molecules ready-made from outer space and additional water.

BUT... Big steps still needed to explain how life started:

1. Formation of (specific?) organic molecules: amino acids & nucleotides.

2. Joining of large molecules into (functional) proteins and nucleic acids.

3. Aggregation into droplets (cells?) with chemical properties different
from what is in the environment.

4. Replication & heredity: via RNA & DNA (or their percursor).

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Earth's Early Atmosphere
Did not contain oxygen; dominated by CO2, with hydrogen compounds.

Volcanic gases: carbon dioxide (CO2, ~35% ?, ~1,000× more than now),
nitrogen (N2), hydrogen sulfide (H2S), steam (H2O), methane (CH4).

Red or orange in colour, thick and opaque.

Heat deposited through frequent hits by comets and meteors. Some
hits vaporized the oceans, but some brought additional water (ice)
from the outer solar system.

Rapid changes in level of solar illumination:
- Early Sun was more variable and 30% fainter than today.

Rapid rotation of the globe (8–12 hour days?). Violent lightning storms.

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Earth, a water planet
◆ Ocean crust eventually
sinks (subducts) back
into mantle
◆ Continental crust
floats on top and
grows over time.

◆ The total amount of water on Earth is 0.1% of Earth's total mass.
compare this with bodies in the outer solar system: (e.g.- Europa may be
20% water)
◆ Height-variation of rocky surface: 8 km above to 5 km below sea level (today)
average ocean depth: 4km.
If Earth had twice as much water as it does today (i.e.- 0.2% of mass),
oceans would cover all the land.

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The Miller – Urey experiment

In the 1920s, realization (by Oparin,
Haldane) that Earth's early atmosphere
was without any oxygen.

In the 1950s (Stanley Miller & Harold C.
Urey), conduct experiments with
electric discharges in an atmosphere
of water vapour, methane, ammonia
and hydrogen gases......after 1 week, it produced many
amino acids (among the 18 produced,
6 occur in living organisms).

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Origins of Life: Early ideas
Some early ideas for where life originated no longer fit current
scientific knowledge…

◆“Pungent ponds of tidal water full of stuff”:
Vulnerable to UV radiation (no oxygen, hence no ozone-layer)
Vulnerable to impacts
◆“Soup of organic molecules” formed by sunlight or lightning
Miller-Urey experiment used (based on what we now know)
an unrealistic atmosphere composition
products created would be too diluted in the ocean
Lack of chemical disequilibrium
Chemical reactions always go both ways.
So need a dis-equilibrium to force reactions in a
preferential direction.
Doesn’t work in a uniform "primordial soup".

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Origin of Life: in Mid-Ocean Ridges?
◆One good possibility:
◆ deep-ocean hydrothermal fields
For example: Lost City

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Fig. 1. (A) The Atlantis massif is located ∼15 km to
the west of the MAR axial valley.

D S Kelley et al. Science 2005;307:1428-1434

Published by AAAS 9
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Fig. 2. Three-dimensional view, looking toward the northeast, of the LCHF. This
image is based on 17 ABE missions using the SM2000 sonar system in a down-
looking and side-looking mode.

D S Kelley et al. Science 2005;307:1428-1434

Published by AAAS 10
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Fig. 4. Hydrothermal
deposits at Lost City.

10’s of meters
Hydrogen, H2S, and other
chemicals and minerals
percolate out of the ocean
floor and form structures.

Steady stream of chemicals
creates dis-equilbrium

D S Kelley et al. Science 2005;307:1428-1434

Published by AAAS 11
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Fig. 5. Active vent deposits from Lost City.

D S Kelley et al. Science 2005;307:1428-1434

Formations have many small crevices to
concentrate chemicals, with walls that may hold
minerals that can act as catalysts.
Published by AAAS 12
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BUT a long way from molecules to cells

First single cell organisms, even if
simple by current standards, were
much more complex than just
ensembles of organic molecules.

A prokaryotic cell typically contains
one long DNA molecule in the central
parts and several other components.

First cells were probably much
simpler.

The inner content (cytoplasm) is
confined within a membrane.

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Complex organic molecules
Lipids (fats & oils) have ends that “sense”
the electric asymmetry of the water
molecules.

If put on water, they sit with hydrophilic
end in the water. They can create a
monolayer (one molecule thick) of oriented
molecules.

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Complex pre-biotic molecules

When the mixture is shaken, small spherical drops form, the
“micelles”. This is still long way to life, yet they look and
even behave like very simple cells…

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Complex pre-biotic molecules

Bilayer arrangement of lipid molecules, and the spherical
vesicles that this can form.
These structures may change form and behaviour according
to external conditions like salinity (salt concentration), etc.

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The initial structures?

Amino acid droplets Microscopic membranes
made by cooling a warm made from lipids mixed
water solution of amino acids with water

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Some necessary steps

1. Amino acids and other organic materials.
…
2. Strands of RNA form, perhaps capable of self-replication.
(Viruses utilize RNA as genetic material.)
3. Membranes enclosing pre-cells, trapping organic molecules.
4. Natural selection among the (replicating) RNA
molecules => increased complexity.
…
5. Natural selection and formation of DNA.

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The tree of life possibly grew this way

Last Universal Common Ancestor LUCA

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Oxygen and eukaryotes (2)

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Earth's atmosphere
Earth's early atmosphere contained essentially
no oxygen. Now 21%, the 2nd most abundant
gas.

Living organisms collectively produced oxygen
in large amounts.

Without constant replenishment, oxygen
would disappear in ~2 Myr through
oxidization of minerals; it would react with
the more abundant atmospheric nitrogen to
form nitric acid, HNO3 (present in "acid
rain").

Current rate of production determines oxygen
content of the atmosphere(averaged only over Earth's current atmo-
~2Myr). spheric composition

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Photo-synthesis: Building organic material

The first photo-synthesis (light-utilizing) bacteria utilized the
common greenhouse gases, hydrogen sulfide and carbon
dioxide (H2S, CO2), to produce carbohydrates :
nCO2 + 2nH2S + solar energy → (CH2O)n + nH2O + 2nS
Chemically, relatively easy.

Today, the most common photosynthesis reaction is of the
type:

nCO2 + nH2O + solar energy → (CH2O)n + nO2

More efficient and uses widely available water, but chemically
more difficult.

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Advantages of Oxygen
◆Aerobic metabolism more efficient than anaerobic metabolism
Aerobic (oxygen-based): about 40% of possible energy is utilized
Anaerobic (non-oxygen, sulfur-, hydrogen-, iron-
based): only organic matter + O2

◆But respiration (burning of organic matter to obtain energy) uses O2
organic matter + O2 => Energy + CO2 + H2O
◆Ifall organic matter is consumed by bacteria & animals,
then NO net increase in Oxygen

=> Burial of organic matter is required to raise Oxygen levels
99.99% of organic matter is consumed
0.01% is buried