Topic 13 - The Evolution of Animals II PDF

Summary

This document provides learning outcomes and an overview of the evolution of animals, including invertebrates and vertebrates. Diagrams and classification are included.

Full Transcript

Topic 13
The evolution of animals II

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Learning Outcomes

Define key characteristics of invertebrates
Classify invertebrate organisms into clades based on embryological or anatomical characteristics
Place the evolution of body symmetry and the embryological formation of the mouth on a phylogeny
Justify the importance of the notochord in the evolution of vertebrates
Organize the key innovations of vertebrates on a phylogeny
Associate key innovations of vertebrates with the names of the clades they define
Describe how gill arches and rods have evolved in vertebrates
Explain how specific structures found in the early tetrapods allowed vertebrates to colonize land
Organize the key innovations of tetrapods on a phylogeny
Associate key innovations of tetrapods with the names of the clades they define
Classify adaptations based on the physical or chemical challenges faced by tetrapods on land
Define and identify exaptations

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https://www.wooclap.com/BIO1130
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 Topic 13
The evolution of animals II
13.1 – Invertebrates

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Animal phylogeny
P r o t o s t o m ia

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Invertebrates ates form
a
Invertebr ic group!
et
paraphyl
Invertebrates = absence of backbone (spine)

95% of all known animal species (1M insect species)!

Many ancestral traits were lost

Chordates (and vertebrates) evolved from deuterostome invertebrates
Protostomia

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 Porifera (sponges)

Diploblastic
Radial symmetry
Sessile
No true tissues

Protostomia
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Ctenophora

Diploblastic
Radial symmetry

Multiple layers of cells (tissues):
a sensory epidermis
networked nervous system.
Protostomia

Ctenophora

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Ctenophora

Diploblastic
Radial symmetry

Multiple layers of cells (tissues):
a sensory epidermis
networked nervous system.
Protostomia

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 Cnidaria

Diploblastic
Radial symmetry
Sessile polyp and swimming medusa
Hydrostatic skeleton (gastrovascular cavity contraction).

Protostomia
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Bilateria

Bilateral symmetry evolved at the same time as triploblasty (mesoderm): 670Mya

Acoela and platyhelminthes:
Lost their body cavity (coelome)
Protostomia

Do not have a digestive tract

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Ecdysozoa

Protostome animals that produce an exoskeleton (cuticle) periodically molted (ecdysis)
à Compensating the increase of body size

Arthropods show a very rigid exoskeleton made of protein
and chitin and that is segmented into functional units
Presence of ganglions (clustered of nerve cell bodies)
Protostomia

Caenorhabditis elegans Lamprima aurata Latrodectus hesperus

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 Lophotrochozoa
Helix pomatia

Lumbricus terrestris Dugesia subtentaculata

Protostome animals possess either:

Lophophore: crown of ciliated tentacles around the mouth (feeding)

Trochophore: specific larval stage

Protostomia
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Echinodermata

Bilateral symmetry
Deuterostome (evidence from larval embryological data)

Water circulatory system (ambulatory system)
à nutrition, respiration, locomotion and excretion
Protostomia

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Topic 13
The evolution of animals II
13.2 – The notochord

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 Chordata (530Mya)

Chordates possess:
A notochord: longitudinal flexible rod (mesoderm, anterior-posterior axis)

Muscles attach to the notochord (locomotion)
Dorsal nerve chord (ectoderm)

Pharyngeal slits behind the mouth (filtration during feeding, gas

exchange and bones of the skull)
A post-anal tail with a skeleton and muscles

Protostomia
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Chordata
Cyclostomes

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Cephalochordates

Feeding through filtration in the pharynx.
Lateral movement for locomotion
Cyclostomes

Lancelet

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 Cephalochordates

Feeding through filtration in the pharynx.
Lateral movement for locomotion

Cyclostomes
Lancelet

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Urochordates

Vertebrates may have evolved through paedomorphosis:
à retention in an adult of juvenile features of its ancestors

à larvae evolved the ability to reproduce before
metamorphosis
Cyclostomes

à loss of 4 hox genes

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Vertebrates

Skeletal system formed by a vertebral column (spinal cord = backbone)
à Muscle attachment, protection of dorsal nerve tube

à Solidification (cartilage or bone) of vertebrae

à Duplication of hox genes
Cyclostomes

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 Cyclostomes (vertebrates without jaws)

No jaws à circular mouth

Lampreys can be parasites of fishes.

Cartilaginous skeleton without collagen

Cyclostomes
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Gnathostomes (vertebrates with jaws)

Modification of 2 skeletal rods (gill arches)
Mandibular arch à jaws
Hyoid arch à support structures
Cyclostomes

Anterior gill slits (suspension feeding à gas exchange)

Mineralization of the skeleton

Duplication of Hox genes à more complex body plans

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Chondrichthyes (cartilaginous fish)

Skeleton made of cartilage: flexible and elastic connective tissue made of collagenous fibers

Cartilaginous fish have placoid scales.
Cyclostomes

à homologous to vertebrate teeth (dentine + enamel)
Homology = similarity due to shared ancestry

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 Chondrichthyes (cartilaginous fish)

Internal fertilization with 3 modes or reproduction:

Oviparous: egg laying and external hatching

Ovoviviparous: embryo feeds from the egg’s yolk,
then hatches in the uterus

Cyclostomes
Viviparous: embryo feeds from the mother through
the placenta and until birth

Claspers for sperm transfer

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Osteichthyes (bony fish)

Bones made of calcium phosphate

Dorsal swim bladder filled with gas (flotation)

Early osteichthyes had lungs
Cyclostomes

Most bony fish are oviparous

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Osteichthyes

Ray-finned bony fish (Actinopterygii):
à fins do not have an internal skeleton
à rays project from basal bones
Cyclostomes

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 Osteichthyes

Lobed-finned bony fish (Sarcopterygii):
à internal skeleton to which muscles attach
à Early lobed-finned bony fish lived in
coastal wetlands and may have been
able to “walk” on the substrate.

Cyclostomes
Cubitus

Radius

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Osteichthyes

Lobed-finned bony fish (Sarcopterygii):
à internal skeleton to which muscles attach
à Early lobed-finned bony fish lived in
coastal wetlands and may have been
able to “walk” on the substrate.
Cyclostomes

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Dipnoi (lungfish)

Functional lungs homologous to tetrapod lungs
Also possess gills
Can crawl in the mud (long pectoral fins)

Resistance to dryness (burrowing in mud – torpor)
Cyclostomes

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 Dipnoi (lungfish)

Functional lungs homologous to tetrapod lungs
Also possess gills
Can crawl in the mud (long pectoral fins)

Resistance to dryness (burrowing in mud – torpor)

Cyclostomes
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Topic 13
The evolution of animals II
13.3 – Colonization on land by vertebrates

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Tetrapods

Acanthostega
Tetrapods = “Four limbs” with digits

New land niches (all of the biotic and abiotic
resources used by a species):

à plants, insects, new ranges in temperature, humidity,
Cyclostomes

protection against predators, less competition, etc.

Adaptations leading to colonization of land:
Support of the body against gravity
Breathing in the air
Hearing in the air
Resistance against dry environments
Vascular system with lungs and organs

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 Tetrapods

Tiktaalik (“Large freshwater fish” in Inuktitut): fossil of a lobe-finned fish with both fish and tetrapod traits.

Tiktaalik roseae (375M ya)

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Amphibians
Urodela Anura Apoda
Amphibian (“double life”):
1. Aquatic larval stage (gills, lateral line) herbivorous
Cyclostomes

2. Metamorphosis (loss of tail, formation of legs)

3. Terrestrial predator adult stage

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Amniotes

Air insulation (during the embryo development) and ventilation (thoracic cage in adults)

4 embryonic membranes:
Chorion: outer-membrane (gas- exchange)

Amnion: surrounds the cavity (mechanic protection)
Cyclostomes

Allantois: surrounds the disposal sac (metabolic wastes)

Yolk sac: stock of nutrients

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 Reptiles

Dry skin with scales containing keratin à protection from desiccation

Ectothermic (except birds) à behavioral adaptations to control body temperature

Improved locomotion capacity (walking, running, flying)

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Birds

Paleontological, embryological and genetic data show that birds are reptiles and are also bipedal dinosaurs.

Feathers were first used for temperature regulation, courtship, protection, camouflage...

…but later became an exaptation (opportunistic adaptation
used for a new function, not initially selected for).

Adaptations to flight:
no bladder are
aurs
only one ovary Dinos extinct!
not
small gonads
high metabolic rate
absence of teeth
light skull and skeleton
wings and feathers Archaeopteryx
(animal the closest to birds)

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Mammals
Moose Kangaroo rat

Mammary glands and production of milk (source of proteins, carbohydrates, lipids, minerals, vitamins, etc.)
Endothermy
Larger forebrain with ability to learn
Differentiated teeth with specific functions
Cyclostomes

Hair and fat layer under the skin (insulation)

Kidneys (excretion of metabolic waste, water retention)

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 Primates

Opposable thumb (adaptation for grasping)
Large brain and short jaw
Parental care and social behaviors
Tree-dwelling animals (hand-eye coordination)
Overlapping visual fields (orbits located at the front of the skull)

à binocular vision (depth perception)

Hominids:

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Primates Chimp Gorilla
Human Orangutan

Opposable thumb (adaptation for grasping)
Large brain and short jaw
Parental care and social behaviors
Tree-dwelling animals (hand-eye coordination)
Overlapping visual fields (orbits located at the front of the skull)

à binocular vision (depth perception)

Hominids:

Karyotype: human (2n = 46) and chimpanzee (2n = 48)

à 2 ancestral chromosomes fused to form the
chromosome 2 in human

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Humans

First hominins (sub-family of hominidae): ~6.5Mya
Bipedal (walk on two legs)
Reduced jaw bones
Short digestive tract

Language, complex and symbolic thought, artistic
expression, manufacture of complex tools

99% of the human genome is identical to the chimpanzee
à differences in the expression of 19 regulatory genes with
large effects

First representant of the Homo genus: ~2.5Mya (Homo habilis)
Stone age tools (-3.4Ma)

Ardipithecus ramidus (4.4Mya)
found in Ethiopia

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 Humans

First hominins (sub-family of hominidae): ~6.5Mya
Bipedal (walk on two legs)
Reduced jaw bones
Short digestive tract Chauvet Cave (37,000ya)

Language, complex and symbolic thought, artistic
expression, manufacture of complex tools H. neanderthalensis and H. sapiens
(Sawyer and Maley - 2005)

99% of the human genome is identical to the chimpanzee
à differences in the expression of 19 regulatory genes with
large effects

First representant of the Homo genus: ~2.5Mya (Homo habilis)

Homo neanderthalensis (350,000ya) the closest
relative species to Homo sapiens (share a common ancestor).
à Some limited gene flow occurred between them.

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