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1.5 The Origin of Cells

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Title: Evolution Author: De Souza, Monica (Michael Power/St Joseph) Last modified by: TCDSB Created Date: 8/16/2006 12:00:00 AM Document presentation format – PowerPoint PPT presentation

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Title: 1.5 The Origin of Cells


1
1.5 The Origin of Cells
  • Cells come from pre-existing cells
  • The first cells arose from non-living materials
  • Endosymbiosis

2
Cell Division The Origin of Cells
  • All cells are formed by the division of
    pre-existing cells.
  • You are made of trillions of cells.
  • Any cell that is produced by your body is the
    product of cell division from another cell.
  • You originally started life as a single cell, a
    zygote, that underwent numerous cell divisions to
    produce the trillions of cells that comprise you
    today.

3
  • Even that single celled zygote came from
    other cells the combination your
    fathers sperm cell and your
    mothers egg cell.
  • We can trace the origins of all the cells in our
    parents back to the zygotes from which they
    developed, to our human ancestors before them, to
    humans pre-existing ancestral species, all the
    way back to the earliest cells on Earth.

4
  • We, and all other living things on this planet,
    are descendants from the first cell.
  • But if all cells come from pre-existing cells,
    where did the first cell come from?
  • How did life start on this planet?

5
Problems for starting life on Earth
  • How could the lifeless ball of rock that the
    planet Earth was 3.5 billion years ago, become
    home to such lush vegetation and a wide variety
    of bacteria, fungi, protists, and animals that we
    see today?
  • There are 4 problems which needed to be overcome
    for life on Earth to exist.

6
Requirements to start life
  1. Production of Simple Organic Compounds
  2. The assembly of organic compounds into polymers
  3. Development of a mechanism for inheritance.
  4. Formation of membranes

7
1. Production of Simple Organic Compounds
  • Life as we know it is based on organic compounds
    (compounds containing carbon and hydrogen), such
    as amino acids (the building blocks of proteins)
  • But early Earth only had inorganic matter rocks,
    minerals, gases, water.

8
  • Abiogenesis had to occur.
  • abiogenesis the creation of organic matter from
    inorganic matter)
  • It is believed that organic molecules were formed
    in the shallow waters of the oceans as the
    products of chemical reactions between compounds
    in the atmosphere and the water.

9
Miller and Urey
  • Scientists Stanley Miller
    and
    Harold Urey

    performed a ground-

    breaking experiment in 1953
  • They recreated the conditions of early Earth and
    proved that organic compounds could be
    synthesized from inorganic compounds.

10
N2 nitrogen gas H2O water H2 hydrogen
gas NH3 ammonia gas CO2 carbon dioxide
gas CH4 methane gas
11
The Experimental Design
  • The apparatus included an oceanic compartment
    and an atmospheric compartment
  • The H2O in the oceanic compartment was heated to
    evaporate and cooled to condense thereby
    recreating the H2O cycle.
  • Since early Earth did not have an ozone layer,
    they kept the system at a warm temperature and
    exposed it to UV radiation
  • Generated electric sparks to simulate lightning

12
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13
The Results
  • After 1 week
  • 15 of the carbon was now found in organic form!
  • 13 of the 20 amino acids had formed inside the
    primordial soup!
  • Sugars had formed!
  • The nitrogenous base adenine (a component of DNA
    and ATP) had formed!!!

14
The Conclusion
  • Early Earth had the proper conditions for
    abiogenesis.

15
2. Assembly of these molecules into polymers
  • Organisms are organized!
  • Simple organic molecules would have needed to
    undergo a process of polymerization to form the
    larger more complex organic chemicals required by
    cells.

16
Deep-Sea Vents
  • Organic molecules could have first formed around
    hydrothermal vents places where hot water
    emanated from beneath the ocean floor.
  • Form when cracks in the crust of the seabed
    expose sea water to rocks below which are heated
    by magma

17
  • As the hot water rises it picks up countless
    minerals along the way.
  • Hydrothermal vents are sometimes referred to as
    black smokers because the water coming out of
    them contains so many dark minerals it looks like
    smoke.
  • The chemicals and source of energy in this
    environment could be suitable for the formation
    of biological polymers.

18
3. The development of a mechanism for inheritance
  • Today, most organisms use DNA as its
    molecule for heredity.
  • To replicate DNA and pass it on to the next
    generation, enzymes are required
  • However, enzymes cannot be made without DNA.
  • Therefore, it is unlikely that DNA was the early
    molecule for heredity

19
Ribozymes
  • However, the small sequences of the molecule RNA
    can act as enzymes and replicate itself.
  • These are called ribozymes
  • Thus, RNA may be the early
    molecule for hereditary.

20
4. Formation of Membranes
  • Water is important to life but tends to
    depolymerize (break down)molecules
  • Many compounds dissolve in water, making it
    difficult to organize into polymers
  • The formation of closed membranes is likely an
    early and important event in the origin of
    cellular life
  • It allows for the development of an internal
    chemistry different from the external environment

21
Coacervates
  • Coacervate - a microscopic sphere that forms
    from lipids in water.
  • Forms spontaneously due to the hydrophobic forces
    between the water and lipid molecules.
  • Can maintain an internal chemical environment
    different from the surrounding environments.
  • Coacervates can be selectively permeable

22
Coacervates
  • Coacervates (lipids)

23
  • Although they are not living organisms,
    coacervates are a significant step toward the
    formation of cells.
  • They solve the problem of protecting polymers
    from their destructive environments.
  • Could be primitive versions of the first cell
    membranes

24
  • PROTOBIONTS the first precursors to cells, were
    likely coacervate droplets which included
    polynucleotides (DNA or RNA)
  • (remember our cell membranes are lipid based)
  • Overtime, true cell membranes evolved and other
    characteristics of cells developed.
  • Cellular respiration
  • Asexual reproduction

25
Spontaneous Generation
  • While spontaneous generation must of occurred
    billions of years ago to give rise to the first
    cells, spontaneous generation of cells and
    organisms does not now occur on Earth.
  • This is supported by experiments conducted by
    Louis Pasteur in 1864.

26
Spontaneous Generation
  • Before Pasteur, many people believed spontaneous
    generation possible and believed it explained why
    mould would grow seemingly out of nowhere, and
    why fruit flies would appear in a room that
    didnt have any previously.
  • Many people believed that spontaneous generation
    could occur as long as there was access to air.

27
Pasteurs Experiments
  • He created a nutrient broth by boiling water
    containing yeast and sugar, thereby killing the
    organisms
  • When the broth was kept in a sealed flask it
    remained unchanged no fungi or organisms
    appeared.

28
  • When exposed to air that travelled through a swan
    neck, it also remained unchanged because the
    apparatus prevented microorganisms from entering
    the broth
  • When the swan neck was removed, microorganisms
    could enter the broth and proliferate

29
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30
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31
Where did all the oxygen come from?
  • 1/5 of the air you are breathing right now is
    oxygen.
  • However, there was none at all present 4 billion
    years ago.
  • The earliest life forms on Earth were bacteria
    and they lived in an environment with an
    atmosphere of mostly CO2
  • Thus, early life forms were anaerobic cells (did
    not require oxygen)

32
  • These single-celled organisms would consume
    organic molecules (i.e. simple sugars) that were
    forming from chemical reactions on Earth
  • The more they reproduced, the more food that was
    consumed.

33
  • After million of years, their population would
    have reached such large numbers that food began
    to be scarce.
  • In this food shortage, bacteria that could make
    their own food would have an advantage.

34
  • 3.5 billion years ago, bacteria (that is
    believed to be related to todays
    cyanobacteria)developed the ability to
    photosynthesize.
  • Must have contained a form of chlorophyll

35
  • Development of photosynthesis was one of the most
    significant evens in the history of Earth
  • Gives bacteria a source of energy (sunlight) to
    survive
  • Created a mass pollution of the atmosphere
  • Pollution of oxygen!!!

36
  • Oxygen gas is toxic to the kinds of bacteria
    which preceded photosynthetic ones, so this
    pollution would have eventually killed off large
    populations of anaerobes.
  • Anaerobic bacteria that survived would live in
    mud of places protected from the new oxygen-rich
    atmosphere.

37
  • The ability of an organism to make its own food
    gives it a distinct advantage over those that
    cannot.
  • As a result, photosynthetic bacteria proliferated
    and produced more and more oxygen

38
Endosymbiosis
  • 3.8-2 bya, bacteria (prokaryotic cells) were the
    only organisms on Earth
  • The first fossils of cells with a nucleus
    (eukaryotes) is from around 2 bya.
  • How did prokaryotes develop into eukaryotes?
  • Endosymbiosis is the most popular theory

39
Endosymbiosis
  • ENDOSYMBIOSIS when one organism lives within the
    other and they both benefit
  • Ex bacteria that live inside our digestive tract

40
Endosymbiotic Theory
  • The chloroplasts and mitochondria that are found
    inside eukaryotic cells today were once
    independent prokaryotic cells.
  • They were engulfed by a bigger prokaryotic cell.
  • Rather than being digested, the prokaryotes were
    kept alive inside the host cell in exchange for
    their services

41
Endosymbiotic Theory
  • The host cell would provide protection for the
    smaller prokaryotic cell
  • The engulfed cell would be beneficial to the host
    if
  • it was photosynthetic like the chloroplast
    (providing food) for the host or
  • able to metabolize food efficiently and produce
    energy for the host like the mitochondrion

42
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43
Evidence for Endosymbiosis
  • Mitochondria and chloroplasts are very similar to
    prokaryotic cells. The many similarities suggest
    that they were once independent prokaryotic cells.

44
Evidence of Endosymbiosis
  1. Chloroplasts and mitochondria are surrounded by a
    double membrane (like the prokaryotic plasma
    membranes)
  2. Mitochondria and bacteria (a prokaryote) have a
    similar size

45
Evidence of Endosymbiosis
  • Mitochondrial and bacterial ribosomes are very
    similar in size and shape.
  • Mitochondria and chloroplasts have their own DNA
    which is circular like bacteria.
  • Mitochondria divide in a process similar to
    binary fission like bacteria

46
Problems with Endosymbiosis
  • The ability to engulf another cell and have it
    survive in the cytoplasm does not guarantee that
    the host cell can pass it on to its offspring the
    genetic code to synthesize the newly acquired
    organelle
  • When chloroplasts or mitochondria are removed
    from a cell, they cannot survive on their own.
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