1.
The Importance of Plants, their origins and ways of life
Text book pages:
548-553
604, 609,
626-639,
Objectives of the lecture:
1. Describe some ways that plants provide the foundation of life.
2. Provide the basic sequence of plant evolution and its relationship
to changes in earth landforms and environment.
3. Describe the endosymbiosis theory.
4. Identify important adaptations of plants that enable them to live on
land.

2.
Ginkgo biloba
Illustration in Pen Tsao
Kang Mu of Ginkgo with
seeds (1578)
The only surviving species of a diverse group originating in
the Permian, closely related fossils 200m ybp
Motile male sperm
Ginkgo biloba extract (Gbe) and two ingredients, bilobalide
and ginkgolide B, are part of a review of botanicals being used
as dietary supplements in the United States. Deregulation of
botanicals now permits Gbe to be sold as a dietary
supplement to a willing public eager to "improve brain
functioning" or "promote radical scavenging activity".

3.
Medicinal!!
Ginkgo biloba- the wonder drug!
What, ginkgo? I thought that was
just for old people who couldn't
keep a train of thought? Nope,
you're wrong. Ginkgo can be a
very beneficial herb to
bodybuilders as well.
http://www.teenbodybuilding.com/gingko.htm

4.
Plan for Biology 220 Spring 2010
Wk
5 Th April 29 Importance of plants, their origins and problems.
6 M May 3
Tu May 4
W May 5
Th May 6
Exam
The Dicot plant, morphology, meristems, cell types, and tissues
Cellulose, wood structure and water transport in the plant
Structure and function of the leaf.
7 M May 10
Tu May 11
W May 12
Th May 13
Stomata: structure, control, CO2 exchange and transpiration
Photosynthesis I: Chemistry, chloroplast, chlorophyll, action spectra
Photosynthesis II: continued
Photosynthesis III: C4 and CAM photosynthesis, photo-inhibition
8 M May 17
Tu May 18
W May 19
Th May 20
Photosynthesis IV: canopy photosynthesis and global change.
Translocation
Plant nutrition
Exam #3 on lectures May 3 through May 17.
9 M May 24
Tu May 25
W May 26
Th May 27
Plant reproduction and diversity.
Plant reproduction continued
Seed formation, dormancy and germination.
Plant hormones and development
10 M May 31
Tu June 1
W June 2
Th June 3
Memorial Day
Plant hormones and development continued.
Fungi, decomposition, mycorrhizae, and lichens.
Fungi continued.
W June 9 Final Exam: Cumulative Plant 2:30-4:20.

5.
Why are plants important for human life?
Page 627-630
1. Plants produce oxygen
2. Plants build soil
3. Plants hold soil
4. Plants moderate the local climate
4. Plants hold water
6. Plants provide food, fuel and fibre
7. Plants provide drugs
How do they do that?
Green plant photosynthesis
Rock weathering and carbon build-up and decomposition
Root strength and ramification through soil
The “reservoir” function of plants and soil
Evapo-transpiration and particle capture
Next slide

6.
Figure 30-4-Table 30-1
What functions might these substances have in plants?
Know 5 of these

7.
Opium poppy, Papaver somniferum
The opium poppy is the principal source of all natural opiates. Opiates are
extracted from opium and poppy straw. Opium is the latex harvested by
making incisions on the green capsules (seed pods).
Mature seed pod of the opium poppy (Papaver somniferum) with milky latex
sap dripping from a recent cut. The latex sap contains a mixture of naturally-
occurring narcotic alkaloids including morphine and codeine. Morphine is
acetylated to produce diacetylmorphine, better known as heroin.
Evolution?

8.
Figure 30-8
Cooksonia pertoni Seed fern leaves
Cones from Araucaria mirabilis,
an early gymnosperm
Archaefructus, an early angiosperm
Angiosperms abundant
Present
Diversification of flowering plants
Both wet and dry environments
blanketed with green plants for
the first time
Gymnosperms abundant
Extensive coal-
forming swamps
Carboniferous:
Lycophytes and
horsetails abundant
Most major
morphological
innovations:
stomata, vascular
tissue, roots, leaves
Silurian-Devonian
explosion
Origin
of land
plants
First evidence
of land plants:
cuticle, spores,
sporangia
475 mya 444 359 299 145

9.
History of evolution of major plant types on land

10.
Life’s Timeline: The Precambrian
How did multi-cellular green organisms develop?

11.
An endosymbiont is any organism that lives within the body or cells of
another organism, i.e. forming an endosymbiosis (Greek: ἔνδον endon
"within", σύν syn "together" and βίωσις biosis "living").
Endosymbiosis
How did multi-cellular green organisms develop?
Andreas Schimper observed in 1883 that the division of chloroplasts in green
plants closely resembled that of free-living cyanobacteria (blue-green algae)
and tentatively proposed that green plants had arisen from a symbiotic union
of two organisms.
Margulis and Sagan (2001) "Life did not take over the globe by combat, but by networking"
Examples:
nitrogen-fixing bacteria (called rhizobia) that live in root nodules
on legume roots,
single-celled algae inside reef-building corals,
and bacterial endosymbionts that provide essential nutrients to
about 10%–15% of insects.

12.
Anaerobic
eukaryote
Aerobic
bacterium
2. Bacterium lives
within eukaryotic
cell.
Pyruvate
and O2
THE ENDOSYMBIOSIS THEORY FOR MITOCHONDRIA
AND CHLOROPLAST EVOLUTION
1. Eukaryotic cell
surrounds and
engulfs bacterium.
3. Eukaryote supplies
bacterium with protection
and carbon compounds.
Bacterium supplies
eukaryote with ATP.
ATP
Page 604
Proposed evolutionary origin for mitochondria
Each would have performed mutually benefiting functions from their symbiotic
relationship.
The aerobic bacteria would have handled the toxic oxygen for the anaerobic
bacteria, and the anaerobic bacteria would utilize ingested food and protected the
aerobic "symbiote".

13.
Secondary Endosymbiosis
Serial ingestion of photosynthetic
bacteria by endosymbiontic
prokaryotes or eukaryotes led to the
ancestors of eukaryotic plants.
All other lineages of plastids have arisen through secondary (or tertiary)
endosymbiosis, in which a eukaryote already possessing plastids is engulfed
by a second eukaryote. Considerable gene transfer has occurred among
genomes and, at times, between organisms.
As the ingested photosynthetic
bacteria adapted to the ingesting
prokaryotic host cell, plastids, such
as the chloroplast evolved.
Primary plastids are found in some
algae because their plastids are
derived directly from a
Cyanobacterium.
p609

14.
The most convincing evidence of the descent of these organelles from
bacteria is the position of mitochondria and plastid DNA sequences in
phylogenetic trees of bacteria.
Mitochondria and chloroplasts contain DNA
There are also organisms alive today, called
living intermediates, that are in a similar
endosymbiotic condition to the prokaryotic cells
and the aerobic bacteria. For example, the giant
amoeba Pelomyxa lacks mitochondria but has
aerobic bacteria that carry out a similar role. A
variety of corals, clams, snails, permanently
host algae in their cells.
Chloroplasts have DNA sequences that indicate origin from the
cyanobacteria (blue-green algae).
Mitochondria have sequences that clearly indicate origin from a group
of bacteria called the alpha-Proteobacteria.
Multiple nuclei

15.
Multiple ingestions lead to a
variety of endosymbiotic
structures

16.
Figure 30-39
Lycopodium species
Plant of the Day

17.
Life’s Timeline: The Paleozoic Era

18.
Atmospheric O2 and CO2 concentrations through geological time
Carboniferous coal
formation
Origin of
insect flight
Denser atmosphere,
Greater O2 partial pressure
Widespread arthropod
gigantism
70cm wing dragonfly
1m long millipede
and giant spiders
CO2 removed from the
atmosphere by plant
synthesis and limestone type
rock formation

19.
Devonian
plant
community
Devonian plant community found at Rhynie, in Scotland. A reed-like
marsh, 370-380 million years ago.
Simple dichotomous branching
MAIN FEATURES
15 to 30 cm tall
No roots
Stomata with guard cells
Most had a central vascular strand
Cuticle
Asteroxylon had leaves –without a
vascular connection
Sporangia
Asteroxylon

20.
Life’s Timeline: The Mesozoic Era

21.
Life’s Timeline: The Cenozoic Era

22.
The land that plants colonized was hostile to life.
Land plants required several adaptations to be successful that require
multi-cellular tissues
Adaptation to living on land
mechanical strength for support,
exposed light catching surfaces,
anchoring system,
conducting system for water,
system for obtaining mineral nutrients,
a way to restrict water loss in desiccating air,
a means of reproducing and dispersing on land
Soil development was minimal.

23.
Things you need to know ...
1. Why plants are important for human life.
2. Some drugs derived from land plants.
3. The geological time periods when plants of different types were
abundant and how this relates to the environment of those periods.
4. The adaptations shown by plants to living on land.