Download Chapter 34A

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
Document related concepts

Organisms at high altitude wikipedia , lookup

Evolutionary history of life wikipedia , lookup

Umbilical cord wikipedia , lookup

Evolutionary developmental biology wikipedia , lookup

Earthworm wikipedia , lookup

Regional differentiation wikipedia , lookup

Transcript 
Chapter 34A:
The Origin & Evolution of Vertebrates I
1. Overview of the Chordates
2. Invertebrate Chordates
1. Overview of Chordates
Echinodermata
Chordates
Cephalochordata
ANCESTRAL
DEUTEROSTOME
Urochordata
NOTOCHORD
Common ancestor
of chordates
Vertebrates
Myxini
Petromyzontida
Gnathostomes
Osteichthyans
Lobe-fins
Chondrichthyes
Vertebrae
Actinopterygii
Jaws, mineralized skeleton
Actinistia
Lungs or lung derivatives
Dipnoi
Lobed fins
Reptilia
Limbs with digits
Amniotic egg
Mammalia
Milk
Tetrapods
Amniotes
Amphibia
Phylogeny of
Chordates
Derived Characters of Chordates
All chordates have the following derived characteristics at
some point in their life cycle*:
• NOTOCHORD
• DORSAL HOLLOW NERVE CHORD
• PHARYNGEAL SLITS
OR CLEFTS
• MUSCULAR POST-ANAL
TAIL
*In many species these
characters are only apparent
during embryonic development.
Notochord
Dorsal, hollow nerve cord
Muscle
segments
Mouth
Anus
Post-anal tail
Pharyngeal slits or clefts
Notochord
The notochord is a longitudinal, flexible rod between the
ventral digestive tube and the dorsal nerve cord.
• provides structural support
throughout the length of
the chordate body
• develops into some of the
“backbone” structures in
most adult vertebrates,
thought remnants of the
notochord may be retained
Notochord
Dorsal Hollow Nerve Cord
The nerve cord of chordate embryos develops from a plate of
ectoderm that folds inward forming a neural tube dorsal to
the notochord.
• the neural tube will
develop into the
central nervous
system – the brain
and spinal cord
Pharyngeal Slits or Clefts
In most chordates the pharyngeal slits open to the outside of
the body and can have the following functions:
• filtering food from water
in suspension feeders
• gas exchange in nontetrapod vertebrates
Pharyngeal slits or clefts
• in tetrapod vertebrates
develop into structure of
the jaw, head & neck
Muscular Post-Anal Tail
All chordates have some sort of tail posterior to the anus:
• may be greatly reduced during embryonic development in some
species (e.g., Homo sapiens)
• contains skeletal and
muscle elements that may
play a role in propulsion
(aquatic species) or
balance & support
(terrestrial species)
Post-anal tail
2. Invertebrate Chordates
2 Groups of Invertebrate Chordates
In invertebrate chordates, the notochord is retained into
adulthood to provide longitudinal support, thus there is no
vertebral column or “backbone”.
There are two groups of invertebrate chordates:
CEPHALOCHORDATA – the lancelets
UROCHORDATA – the tunicates
Cephalochordata (Lancelets)
Cephalochordata
Urochordata
Myxini
Petromyzontida
Chondrichthyes
Actinopterygii
Actinistia
Dipnoi
Amphibia
Reptilia
Mammalia
1 cm
• the lancelets are basal chordates
• they are suspension feeders named for
their blade-like shape
Cirri
Notochord
Mouth
Dorsal, hollow
nerve cord
Pharyngeal slits
Atrium
Digestive tract
Atriopore
Segmental
muscles
Anus
Tail
Urochordata (Tunicates)
Tunicates are more closely related to vertebrate chordates
than the lancelets.
• tunicates draw water into an
incurrent siphon and expel water
through an excurrent siphon, filtering
out food particles in the process
• when threatened they shoot water
out the excurrent siphon, hence their
common name – “sea squirts”
Cephalochordata
Urochordata
Myxini
Petromyzontida
Chondrichthyes
Actinopterygii
Actinistia
Dipnoi
Amphibia
Reptilia
Mammalia
Tunicate Structure
Water flow
Notochord
Incurrent
siphon
to mouth
Excurrent
siphon
Dorsal, hollow
nerve cord
Tail
Excurrent
siphon
Incurrent
siphon
Muscle
segments
Intestine
Stomach
Atrium
Pharynx with slits
(a) A tunicate larva
Excurrent
siphon
Anus
Intestine
Esophagus
Stomach
(b) An adult tunicate
Atrium
Pharynx
with
numerous
slits
Tunic
(c) An adult tunicate
Hox Genes & Early Chordate Evolution
The Hox genes responsible for the formation of the lancelet nerve
cord (e.g., BF1, Otx & Hox3) also play a key role in the organization of
the vertebrate central nervous system and are expressed in the same
general pattern.
BF1
Otx
• vertebrates have more
Hox genes that lancelets
and tunicates due to
gene duplication and
subsequent mutation
• (i.e., paralogous genes)
Hox3
Nerve cord of
lancelet embryo
BF1
Hox3
Otx
Brain of vertebrate
embryo (shown
straightened)
Forebrain
Midbrain
Hindbrain
Related documents
29.2 Invertebrate Chordates
29.2 Invertebrate Chordates
3/12/2015 The Origin & Evolution of Vertebrates I 1. Overview of Chordates
3/12/2015 The Origin & Evolution of Vertebrates I 1. Overview of Chordates
Invertebrate Chordates
Invertebrate Chordates
Lecture 29 - Matthew Bolek
Lecture 29 - Matthew Bolek
• Phylum Chordata • I. General characteristics – A. Notochord (Gr
• Phylum Chordata • I. General characteristics – A. Notochord (Gr
Chordates
Chordates
Chapter 34 Presentation
Chapter 34 Presentation
UNIT 8
UNIT 8
Cho - Chordate Practice
Cho - Chordate Practice
Nonvertebrate Chordates, Fishes, and Amphibians
Nonvertebrate Chordates, Fishes, and Amphibians
Introduction to Phylum Chordata
Introduction to Phylum Chordata