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Animal Bauplan Symmetry and complexity

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Title: Animal Bauplan Symmetry and complexity

1
Animal BauplanSymmetry and complexity

Chapter 3 Animal Architecture

2
What is a Bauplan?
3
What is a Bauplan?

Bauplan is a German word meaning building plan or
blueprint.

4
What is a Bauplan?

Bauplan is a German word meaning building plan or
blueprint.
It is used by biologists to refer to the overall
and consistent structure of a group of organisms.

5
What is a Bauplan?

Bauplan is a German word meaning building plan or
blueprint.
It is used by biologists to refer to the overall
and consistent structure of a group of organisms.
The animal bauplan
The Annelid bauplan, etc.

6
Architectural Pattern in Animals
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Crustacea
Arachnida
Vertebrata
Tunicata
Insecta
Chordata
Arthropoda
Hemi- chordata
Mollusca
Annelida
Echinodermata
Protostomes
Deuterostomes
Pseudocoelomates
Coelomates
Triploblasts Diploblasts
Acoelomates
Bilateria
Radiata
Cnidaria
Ctenophora
Eumetazoa
Mesozoa
Parazoa
Metazoa
Protozoa
Monera (Bacteria)
9
Body Plans

As most kingdoms, animals are divided into groups
based on body architecture.
I. Grades of Complexity
II. Major Body Types
III. Symmetry
IV. Cleavage

10
ENTODINIUM CAUDATUM
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I. Grades of Complexity

Protoplasmic all functions take place in single
cells, or each cell (if colonial)
--Protists have this grade of complexity

13
CATTLE RUMEN CILIATES ENTODINIUM CAUDATUM
14
I. Grades of Complexity

Protoplasmic all functions take place in single
cells, or each cell (if colonial)
--Protists have this grade of complexity
Cellular there is division of labor among cells,
but no segregation of cells that perform the
functions

15
I. Grades of Complexity

Protoplasmic all functions take place in single
cells, or each cell (if colonial)
--Protists have this grade of complexity
Cellular there is division of labor among cells,
but no segregation of cells that perform the
functions
Tissue specialized cells segregate organ, or
organ-system there is segregation of tissues

16
Crustacea
Arachnida
Vertebrata
Tunicata
Insecta
Chordata
Arthropoda
Hemi- chordata
TISSUE
Mollusca
Annelida
Echinodermata
Protostomes
Deuterostomes
Pseudocoelomates
Coelomates
Triploblasts Diploblasts
Acoelomates
Bilateria
Radiata
Cnidaria
Ctenophora
Eumetazoa
CELLULAR
Parazoa
Mesozoa
Metazoa
PROTOPLASMIC
Protozoa
Monera (Bacteria)
17
II. Major Body Types

Cell aggregate
Blind sac
Tube-in-tube

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Ephydatia fluviatilis
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Cell Aggregate

There is no gut, energy absorption throughout
No germ layers, no true tissues or organs.

Example sponges (Phylum Porifera)
20
Sac-like Body Plan
21
Sac-like Body Plan

Has only one opening for both food intake and
waste removal.

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Sac-like Body Plan

Has only one opening for both food intake and
waste removal.
Sac-like body plan animals do not have tissue
specialization or development of organs.

23
Example sea anemones (Phylum Cnidaria)
24
Tube-within-a-tube
25
Tube-within-a-tube

Two openings one for food to enter the body
(mouth), one for wastes to leave the body (anus).

26
Tube-within-a-tube

Two openings one for food to enter the body
(mouth), one for wastes to leave the body (anus).
The tube-within-a-tube plan allows specialization
of parts along the tube

27
Tube-within-a-tube

Two openings one for food to enter the body
(mouth), one for wastes to leave the body (anus).
The tube-within-a-tube plan allows specialization
of parts along the tube
Animals with the tube-within-a-tube plan are
10 more efficient at digesting and absorbing
their food than animals with the sac-like body
plan.

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Example round worm (Phylum Nematoda)
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Crustacea
Arachnida
Vertebrata
Tunicata
Insecta
Chordata
Arthropoda
Hemi- chordata
TUBE IN TUBE
Mollusca
Annelida
Echinodermata
Protostomes
Deuterostomes
Pseudocoelomates
Coelomates
Triploblasts Diploblasts
Acoelomates
BLIND SAC
Bilateria
Radiata
Cnidaria
Ctenophora
Eumetazoa
CELL AGGREGATE
Parazoa
Mesozoa
Metazoa
Protozoa
Monera (Bacteria)
31
III. Symmetry
32
III. Symmetry

Asymmetrical animals no general body plan or
axis of symmetry

33
III. Symmetry

Spherical symmetry round or any plane passing
through the center divides the body into
equivalent or, mirrored, halves.

34
III. Symmetry

Radial symmetry body parts organized about a
center axis and tend to be cylindrical in shape.

35
III. Symmetry

Bilateral symmetry a single plain of symmetry
that produces mirror halves.

36
III. Symmetry
37
III. Symmetry
Planes of symmetry
None Many Many
One
38
Crustacea
Arachnida
Vertebrata
Tunicata
Insecta
Chordata
Arthropoda
Hemi- chordata
BILATERAL
Mollusca
Annelida
Echinodermata
Protostomes
Deuterostomes
Pseudocoelomates
Coelomates
Triploblasts Diploblasts
Acoelomates
Bilateria
Radiata
RADIAL
Cnidaria
Ctenophora
Eumetazoa
Parazoa
Mesozoa
ASYMMETRICAL
Metazoa
Protozoa
Monera (Bacteria)
39
Question 1.

What type of symmetry does this organism have?
Asymmetrical
Spherical
Radial
Bilateral

40
IV. Cleavage
41
IV. Cleavage

Cleavage is the initial process of development
after fertilization of the egg.

42
Radial Cleavage planes are symmetrical to the
polar axisProduces regulative development
43
Spiral Cleavage cleavage planes are oblique to
the polar axisProduces mosaic development
44
Regulative and mosaic cleavage
45
Crustacea
Arachnida
Vertebrata
Tunicata
Insecta
Chordata
Arthropoda
Hemi- chordata
Radial
Spiral
Mollusca
Annelida
Echinodermata
Protostomes
Deuterostomes
Pseudocoelomates
Coelomates
Triploblasts Diploblasts
Acoelomates
Bilateria
Radiata
Cnidaria
Ctenophora
Eumetazoa
Parazoa
Mesozoa
Metazoa
Protozoa
Monera (Bacteria)
46
Development in Eucoelomates
47
The Big Picture