Introductory Biology II Module 2: Diversity of Life | BIOL 1104 PDF

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The document is a module on introductory biology about diversity of life, single-celled life, plants, and fungi.

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Module 2:
Diversity of life,
Single-celled life,
Plants, Fungi
BIOL 1104 Introductory Biology II

2.1 Diversity of Life

BIOL 1104 | Fall 2024 | Sep 24 | 10:00-11:15am
Module 2: Diversity of life,
Single-celled life, Plants, Fungi
Topics for the module
1. Diversity of life
2. Single-celled life
3. Plants
4. Fungi
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Topic 1: Diversity of life
1. Classification and Systematics
2. Phylogenetics
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Tree of Life
All life on Earth evolved
from a common
ancestor

From a single point on
the tree of life, the
three domains of life
diverge and then
branch repeatedly
Figure 12.2 In the evolution of life on Earth, the three
domains of life—Archaea, Bacteria, and Eukarya—branch
from a single point. (credit: modification of work by Eric Gaba)
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Phylogeny and Systematics
The evolutionary history of a species or group of species is
called phylogeny.

Systematics is the study of organisms with the purpose of
deriving their relationships.
Fossil record, structure of body parts or molecules used by
an organism, and by DNA analysis.
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Levels of Classification
Taxonomy is the science of naming and group species to construct an
international shared classification system

Taxonomic classification system (Linnaean system) developed by Carl
Linneaus.
A hierarchical system that has levels:
Domain, Kingdom, Phylum, Class, Order, Family, Genus, and
Species
The groups at the lowest level belong to a series of nested
groups
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Levels of Classification
inclusive

Phylogenetic taxa can be arranged DOMAIN Eukarya

into ranks on the basis of KINGDOM Animalia
Inclusiveness vs. Exclusiveness. PHYLUM (DIVISION) Chordata

CLASS Mammalia
The group at each level is called a ORDER Carnivora
taxon
FAMILY Felidae
For example, for lions, they are
in the order named Carnivora. GENUS Panthera

SPECIES Panthera leo
exclusive
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Figure 12.3 At each sublevel in the taxonomic
classification system, organisms become more

Taxonomic levels move toward similar. Dogs and wolves are the same species
because they can breed and produce viable
specificity offspring, but they are different enough to be
classified as different subspecies.

Organisms become more
similar as they are closely
related

The classification system should
reflect evolutionary
relationships
All members of a taxon
should have a common
ancestor and more closely
related than members of
other taxa
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Scientific Names
Taxonomists assign each species a two-part
scientific name, or binomial nomenclature.
The first part is the genus: a proper noun
The second part, the specific epithet, is
used to distinguish each species within a
genus: an adjective.
Example: "White Oak" = Quercus alba
Only genus name is capitalized
The entire name is italicized or underlined
Sometimes includes an author or year:
Pholcus phalangioides Linnaeus
Pholcus phalangioides Linnaeus, 1758
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Other examples of scientific names...
Scaptia beyonceae
Could also be written as:
S. beyonceae
Scaptia beyonceae Lessard
Scaptia beyonceae Lessard, 2011

Classification:
Domain Eukarya
Kingdom Animalia
Phylum Arthropoda
Class Insecta
Order Diptera
Family Tabanidae
Genus Scaptia
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The problem with common names...
M2 Diversity, single-celled, plants, fungi | 1/4 Diversity of life | 1. Classification and systematics
M2 Diversity, single-celled, plants, fungi | 1/4 Diversity of life | 1. Classification and systematics
M2 Diversity, single-celled, plants, fungi | 1/4 Diversity of life | 1. Classification and systematics
M2 Diversity, single-celled, plants, fungi | 1/4 Diversity of life | 1. Classification and systematics

Classification and Phylogeny
Phylogenetic tree: shows
evolutionary pathways and
connections among
organisms
A lineage from a
common ancestor
A hypothesis that
proposes the
relationships among
organisms
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1735: Linnaeus—kingdoms Plantae and Animalia
Limitations: bacteria placed with eukaryotes, some
protists possess characteristics seen in both plants
and animals.
1866: Ernst Haeckel—Kingdom Protista for unicellular
organisms. Kingdom Monera added later for cells that
lack nuclei.

Ernst Haeckel’s rendering of the tree of life,
from his 1866 book General Morphology of
Organisms, contained three kingdoms:
Plantae, Protista, and Animalia. He later
added a fourth kingdom, Monera, for
unicellular organisms lacking a nucleus.
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1969: Robert
Whittaker—added
Kingdom Fungi to make
a five-kingdom tree.
Empire Eukaryota:
organisms with
membrane-bound
nuclei in cells
(Kingdom Fungi,
Protista, Plantae, and
Animalia).
Empire Prokaryota:
no nuclei in cells.
Kingdom Monera. This timeline shows how the shape of the tree of life has changed over the
centuries. Even today, the taxonomy of living organisms is continually being
reevaluated and refined with advances in technology.​
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Topic 1: Diversity of life
1. Classification and Systematics
2. Phylogenetics
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Phylogenetic Tree Components
Branch Points – Represents a common ancestor; divergence of lineage
Basal Taxa – Older Taxa found at the bottom of the Phylogenetic Tree
Sister Taxa – Two lineages stemming from the same branch point
Polytomy – Multiple Taxa diverging from a common ancestor
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Example of Phylogenetic Tree

Figure 12.4 A phylogenetic tree is rooted and shows how
different organisms, in this case the species and subspecies of
living apes, evolved from a common ancestor.
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Phylogenetic Tree and Characteristics
Branches and branch points
also imply significant
character/evolutionary
changes
The branch point that gives
rise to organisms with legs
is indicated at the common
ancestor of mammals,
reptiles, amphibians, and
jawed fishes. Figure 12.5 This phylogenetic tree is rooted by an organism
that lacked a vertebral column. At each branch point,
organisms with different characters are placed in different
groups.
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Limitations of Phylogenetic Trees
Closely related organisms don’t
always look alike!
Different selective pressures!
Distantly related may look similar
= convergent evolution

Branches do not account for length
of time, only evolutionary order
Long branch ≠ More Time

Phylogenetic trees do not grow in
one direction after a new branch
develops.
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Two Degrees of Similarity
Evaluation of
Morphological characters
Genetic evidence

Homologous structures: similarity in
physical features and genetic
sequences.
Common origin
Implies an evolutionary relationship
Figure 12.6 Bat and bird wings,
For example, forelimbs of the foreleg of a horse, the flipper
vertebrates. of a whale, and the arm of a
human are homologous
structures, indicating that bats,
birds, horses, whales, and
humans share a common
evolutionary past.
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Misleading Appearances
Closely related organisms may
have major morphological
differences due to minor genetic
changes.
Chimpanzees and Humans
share 99% of their genes.
Difference in length of arms
and legs, and protrusion of
jaw.
Figure 12.7 (a) The chimpanzee jaw protrudes to a much
greater degree than (b) the human jaw.
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Two Degrees of Similarity, cont.
Analogous characters
Superficial similarities of form and
function
Adaptations formed due to
convergent evolution
Does not imply an evolutionary
relationship
For example, wings in insects, birds,
and bats.
Difference in development
signals no sharing of a common
ancestor that had a wing. Figure 12.8 The wing of a honey bee is similar in shape
to a bird wing and a bat wing and serves the same
function (flight).
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Molecular Comparisons
Molecular systematics uses DNA
(or RNA, or protein) sequences to
infer relatedness
More similar sequences inferred to
mean more recent branching of two
species from a common ancestor
Less similar sequences inferred to
mean lineages are more distantly
related
Sequences of myoglobin from five different animals are compared to create
a phylogenetic tree. Each molecule is colored to show differences from the
human protein. Amino acids that are identical are pink, amino acids that are
different but similar are lighter pink, and amino acids that are completely
different are in white. The heme is shown in bright red.
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Evolutionary history is documented in genomes
Different genes evolve at different rates
Example 1: DNA coding for ribosomal RNA (rRNA)
changes relatively slowly and
is useful for investigating relationships between
taxa that diverged hundreds of millions of years
ago.
Example 2: DNA in mitochondria (mtDNA)
evolves rapidly
useful to about