The Tree of Life Introduction to Biological Diversity.
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Transcript of The Tree of Life Introduction to Biological Diversity.
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The Tree of Life
Introduction to Biological Diversity
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Tools for Studying Historyof Life: Phylogenies and the Fossil Record
The evolutionary history of a group of organisms is called a phylogeny
A phylogenetic tree shows ancestor-descendant relationships among evolutionary groups (usually species or populations).
Fossils are physical evidence left by organisms from the past. The fossil record includes all fossils that have been found and recorded.
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The Parts of a Phylogenetic Tree
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A Field Guide to Reading Phylogenetic Trees
Populations are represented by branches Nodes show where ancestral groups split into descendant groups.
a polytomy is a node where more than two descendant groups branch off.
Adjacent branches are sister taxa a taxon is any named group of organisms
Tips are branch endpoints represent living groups or a group’s end in extinction.
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Field Guide Continued Rooted
The most ancient node of the tree is shown at the bottom Location of this node is determined using an out groupa taxonomic group that diverged before the rest of the taxa being studied.
An ancestor and all its descendants form a monophyletic group
a clade or lineage
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Phylogeneticic Tree Illustrating Some of the Great Apes
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Alternative Phylogenetic Treesrepresenting the same evolutionary relationships
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Ways to Estimate Phylogenies
Morphological and genetic characteristics are used to estimate phylogenetic relationships among species.
Two approaches Phenetic approach Cladistic approach
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The Phenetic Approach
Computes a statistic that summarizes the overall similarity among populations based on the data. A computer program then compares the similarities among populations and builds a tree
clusters the most similar populations places more divergent populations on more distant branches.
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The Cladistic Approach
Focus on synapomorphiesthe shared derived characters of the species under study
A computer program is used to identify which traits are unique to each monophyletic group
many such traits measuredthen place the groups on a tree in the correct relationship to one another
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Difficulties with the Cladistic Approach
Cases of convergent evolution. Biologists then use parsimony to try to identify the phylogenetic tree that minimizes the overall number of convergent evolution events.
Principle of logic stating that the most likely explanation or pattern is the one that implies the least amount of change or the least complexity. Assumes that convergent evolution should be much rarer than similarity due to shared descent.
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Whale Evolution: A Case History
Traditionally, phylogenetic trees based on morphological data place whales outside of the artiodactyls
mammals such as cows, deer, and hippos have hooves an even number of toes unusual pulley-shaped ankle bone (astralagus)
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Whale Evolution
DNA sequence datasuggest a close relationship between whales and hippos
A phylogenetic tree showing closely related whales and hippos is less parsimonious than the tree based on morphological data because it requires the evolution and then loss of the astralagus in whales.
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Recent Data Recent data on short interspersed nuclear elements (SINEs) show that whales and hippos share several that are absent in other artiodactyl groups.
These SINEs are shared derived traits (synapomorphies) and support the hypothesis that whales and hippos are indeed closely related.
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SINE Genes
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Environment Changes Life/Life Changes Environment
Geological events that alter environments Change the course of biological evolution
Conversely, life changes the planet that it inhabits
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EARLY EARTH
Earth formed about 4.5 billion years ago Along with the rest of the solar system
Earth’s early atmosphere Contained water vapor and many
chemicals released by volcanic eruptions
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A. Oparin and J. Haldane In the 1920s, independently postulated that
conditions on the early Earth favored the synthesis of organic compounds from inorganic ones. The environment in the early atmosphere
would have promoted the joining of simple molecules to form more complex ones.
The energy required to make organic molecules could be provided by lightning and UV radiation in the primitive atmosphere.
The lack of an ozone layer in the early atmosphere would have allowed this radiation to reach the Earth.
They reasoned that this cannot happen today because high levels of oxygen in the atmosphere attack chemical bonds.
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Stanley Miller and Harold Urey, 1953
tested the Oparin-Haldane hypothesis creating, in the laboratory, the conditions that had
been postulated for early Earth
They discharged sparks in an “atmosphere” of gases and water vapor. H2O, H2, CH4, and NH3 a more strongly reducing environment than is
currently believed to have existed on early Earth
Produced a variety of amino acids and other organic molecules
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Miller and Urey experiment
CH4
NH3
H2
Water vapor Electrode
Condenser
Cold Water
Cooled water containing organic molecules
Sample for chemical analysis
H2O
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Deep-Sea Vents
Instead of forming in the atmosphere The first organic compounds on Earth may
have been synthesized near submerged volcanoes and deep-sea vents
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Extraterrestrial Sources of Organic Compounds
Some of the organic compounds from which the first life on Earth arose May have come from space
Carbon compounds Have been found in some of the
meteorites that have landed on Earth
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Protobionts Laboratory experiments demonstrate
that protobionts aggregates of abiotically produced
molecules surrounded by a membrane or membrane-like structure
Could have formed spontaneously from abiotically produced organic compounds
Example: small membrane-bounded droplets called liposomes Can form when lipids or other organic
molecules are added to water
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Liposomes20 m
(a)Simple reproduction. This lipo-some is “giving birth” to smallerliposomes (LM).
(b) Simple metabolism. If enzymes—in this case, phosphorylase and amylase—are included in the solution from which the droplets self-assemble, some liposomes can carry out simple metabolic reactions and export the products.
Glucose-phosphate
Glucose-phosphate
Phosphorylase
Starch
Amylase
Maltose
Maltose
Phosphate
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The “RNA World” and the Dawn of Natural Selection
The first genetic material Was probably RNA, not DNA RNA
molecules called ribozymes have been found to catalyze many different reactions, including
Self-splicing Making complementary copies of short
stretches of their own sequence or other short pieces of RNA
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Ribozyme(RNA molecule)
Template
Nucleotides
Complementary RNA copy
3
5 5
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How life actually began is speculative
There are clues in the molecules and anatomical developments of each species. These clues together with the fossil record have produced several theories about how life evolved on Earth.
Earth formed about 4.5 billion years ago,
The oldest fossils embedded in rocks from western Australia about 3.5 billion years old. resemble bacteria, so scientists think that life originated
much earlier. may have been as early as 3.9 billion years ago
when Earth began to cool to a temperature at which liquid water could exist.
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Using the Fossil Record
The fossil record is the only source of direct evidence about what prehistoric organisms looked like, where they lived, and when they existed.
Careful study of fossils opens a window into the lives of organisms that existed long ago and provides information about the evolution of life over billions of years.
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Most Fossils Form When an Organism is Buried in Sediment Before Decomposition Begins
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Four Types of Fossils
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Index fossils
Are similar fossils found in the same strata in different locations
Allow strata at one location to be correlated with strata at another location
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Absolute Ages of Fossils
Can be determined by radiometric dating
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Limitations of the Fossil Record
There are several features and limitations of the fossil record that must be recognized
habitat biastaxonomic biastemporal biasand abundance bias
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Limitations are Recognized
Paleontologists recognize that they are limited to asking questions about tiny and scattered segments on the tree of life Yet analyzing fossils is the only way scientists have of examining the physical appearance of extinct forms and inferring how they lived.
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The Geologic Record
By studying rocks and fossils at many different sites Geologists have established a geologic
record of Earth’s history Three Eonss the Archaean the Proterozoic the Phanerozoic
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Life’s Timeline Major events in the history of life are marked on the timeline which has been broken into four segments
the Precambrianthe Paleozoicthe Mesozoicthe Cenozoic).
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Precambrian
Almost all life was unicellular. Little or no oxygen in atomosphere.
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Paleozoic
Paleozoic era
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Mesozoic
Ended with extinction of the dinosaurs
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Cenozoic
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The Cambrian Explosion
Animals first originated around 565 million years ago
Animals diversified into almost all the major groups extant today
Known as the Cambrian explosion.
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Cambrian Fossils
•Three major fossil beds record this explosion of animal life
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The Doushantuo Microfossils
Researchers identified Sponges Cyanobacteria Multicellular algae
Samples dated 570–580 Ma
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Also Animal Embryos
In early stages of development Samples contained
one-celled, two-celled, four-celled, and eight-celled fossilsindividuals containing larger cell numbers whose overall size was the same exactly the pattern that occurs during cleavage in today’s animals.
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The Ediacaran Faunas
found in these Australian deposits Sponges Jellyfish Comb jellies
Traces of other animals dated 544–565 Ma
Indicate that shallow-water marine habitats contained a diversity of animal species
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•Virtually every major animal group is represented in the Burgess Shale fossils
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Compelling Picture of Life in the Oceans 525–515 Ma
Few, if any, species in the Ediacaran faunas are also found in the Burgess Shale–type assemblages 20–40 million years later
New species of sponges, jellyfish, and comb jellies are abundant Entirely new groups as well
arthropods mollusks.
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Oldest Fossils
As prokaryotes evolved, they exploited and changed young Earth
The oldest known fossils are stromatolites Rocklike structures composed of many
layers of bacteria and sediment Which date back 3.5 billion years ago
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Stromatolites
Lynn Margulis (top right), of the University of Massachussetts, and Kenneth Nealson, of the University of Southern California, are shown collecting bacterial mats in a Baja California lagoon. Themats are produced by colonies of bacteria that live in environments inhospitable to most other life. A section through a mat (inset) shows layers of sediment that adhere to the sticky bacteria asthe bacteria migrate upward.
Some bacterial mats form rocklike structures called stromatolites,such as these in Shark Bay, Western Australia. The Shark Baystromatolites began forming about 3,000 years ago. The insetshows a section through a fossilized stromatolite that is about3.5 billion years old.
(a)
(b)
Figure 26.11a, b
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Oxygenic photosynthesis
Probably evolved about 3.5 billion years ago in cyanobacteria
Figure 26.12
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The First Eukaryotes
The oldest fossils of eukaryotic cells Date back 2.1 billion years
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Endosymbiotic Origin of Mitochondria and Plastids
The theory of endosymbiosis Proposes that mitochondria and plastids
were formerly small prokaryotes living within larger host cells
Probably gained entry to the host cell as undigested prey or internal parasites
The host and endosymbionts would have become a single organism
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Eukaryotic Cells as Genetic Chimeras
Additional endosymbiotic events and horizontal gene transfers May have contributed to the large
genomes and complex cellular structures of eukaryotic cells
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The Earliest Multicellular Eukaryotes
Molecular clocks Date the common ancestor of
multicellular eukaryotes to 1.5 billion years
The oldest known fossils of eukaryotes Are of relatively small algae that lived
about 1.2 billion years ago
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The Colonial Connection The first multicellular organisms were
colonies Collections of autonomously replicating cells
Figure 26.1610 m
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Specialized Cells
Some cells in the colonies Became specialized for different
functions The first cellular specializations
Had already appeared in the prokaryotic world
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Mass Extinctions
The rapid extinction of many groups
loss of at least 60% of all species within 1 million yearscaused by catastrophic episodes. traditionally recognize five mass extinctions
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Background and Mass Extinctions
Background extinctions typically occur when normal environmental change or competition reduces a population to the point where it dies out. Mass extinctions occur when unusual large-scale environmental change causes the extinction of many normally well-adapted species. Natural selection causes most background extinctions, whereas random chance plays a large
role in mass extinctions.
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Permian
The Permian extinction Claimed about 96% of marine animal
species and 8 out of 27 orders of insects Is thought to have been caused by
enormous volcanic eruptions
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Cretaceous The Cretaceous extinction (K-T)
Doomed many marine and terrestrial organisms, most notably the dinosaurs
Is thought to have been caused by the impact of a large meteor
Figure 26.9
NORTHAMERICA
ChicxulubcraterYucatán
Peninsula
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Evidence Conclusive evidence—including iridium, shocked quartz, and microtektites found in rock layers dated to 65 million years ago, as well as a huge crater off the Yucatán Peninsula—has led researchers to accept the impact hypothesis. The large-scale environmental change triggered by the asteroid impact caused the extinction of 60% to 80% of all species.
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Selectivity Some evolutionary lineages were better able than others to withstand the environmental change brought on by the asteroid impact. Why certain groups survived while others perished is still a mystery.
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Recovery Ferns appear to have replaced diverse woody and flowering plants in many habitats following the K-T extinction. Mammals diversified to fill the niches left empty following the dinosaur extinctions.
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Reconstructing the Tree of Life: A Work in Progress
A three domain system Has replaced the five kingdom system Includes the domains Archaea, Bacteria,
and Eukarya Each domain
Has been split by taxonomists into many kingdoms
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Adaptive Radiations One broad pattern that can be observed in the tree of life
Dense groups of branches scattered throughout the tree Star phylogenies
represent major diversification over a relatively short period of time
a process known as adaptive radiation.
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Colonization Events as a Trigger
Adaptive radiations occurred following the colonization of unoccupied island habitats Example: Anolis lizards of the Caribbean islands
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The Role ofMorphological Innovation
Morphological innovation Opportunities for adaptive radiation
Examples: Important new traits such as limbs, wings, flowers, and jaws Allowed descendants to live in new areas, move in new ways, and exploit new sources of food
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