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Architectural Pattern of an Animal

Architectural Pattern of an Animal. Chapter 9. The Appearance of Major Body Plans. The Cambrian explosion marks the earliest fossil appearance of all major groups of living animals plus some groups that are only known from fossils. All major body plans appeared at this time.

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Architectural Pattern of an Animal

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  1. Architectural Pattern of an Animal Chapter 9

  2. The Appearance of Major Body Plans • The Cambrian explosion marks the earliest fossil appearance of all major groups of living animals plus some groups that are only known from fossils. • All major body plans appeared at this time. • Result of extensive selection. • Are limiting determinant of future adaptational variants.

  3. Body Plans • One way in which zoologists categorize the diversity of animals is according to general features of morphology and development. • A group of animal species that share the same level of organizational complexity is known as a grade.

  4. Hierarchical Organization – 5 Levels • Protoplasmic grade of organization – protists are the simplest eukaryotes, but they still carry out life functions and show division of labor among the various cell structures. • Metazoans are multicellular animals that have cells specialized for particular functions. This is the Cellular grade of organization. • Shown by the simplest metazoans – Volvox, sponges.

  5. Hierarchical Organization – 5 Levels • Cell-tissue Grade – Usually, specialized cells are grouped together and perform their common function as a coordinated unit, a tissue. • Jellyfish • Tissue-organ Grade – Tissues are then assembled into organs like the heart (primarily muscle tissue, but connective, nervous, and epithelial also present). • Flatworms

  6. Hierarchical Organization – 5 Levels • Organ-system grade – In the highest level of organization, organs work together as organ systems like the circulatory system.

  7. Animal Body Plans • Body plans are constrained by ancestry, major features may become modified, but are rarely lost. • Animal body plans differ in their grade of organization, body symmetry, number of germ layers, and type of body cavity.

  8. Symmetry • Spherical symmetry occurs when anyplane passing through the center divides the body into mirror image halves. • Mostly found among the protists.

  9. Symmetry • Radial symmetry applies when more than two planes passing through the longitudinal axis can divide the organism into mirror image halves. • Jellyfish • Biradial symmetry – two planes will divide the organism. • Comb jellies

  10. Radiata • The Cnidarians (jellyfish, corals & sea anemones) and Ctenophores (comb jellies), the radial or biradial animals, comprise the Radiata. • No front/back • Weak swimmers • Can interact with environment in all directions.

  11. Symmetry • Bilateral symmetry is found in organisms where one plane can pass through the organism dividing it into right and left halves. • Better for directional movement. • Monophyletic group called Bilateria.

  12. Cephalization • Bilateral symmetry is associated with cephalization, differentiation of a head. • Nervous tissue, sense organs, and often the mouth are located in the head. • Advantages for organisms moving head first – directional movement. • Elongation along anteroposterior axis.

  13. Regions of a Bilaterally Symmetrical Animal • Anterior-posterior (transverse plane) • Dorsal-ventral (frontal plane) • Left-right (sagittal plane) • Proximal-distal • Medial-lateral

  14. Body Cavities • Examples of body cavities include the gut, blastocoel, and a pseudocoel or coelom. • The gut forms from the archenteron during gastrulation. • The blastocoel persists in some, but usually fills with mesoderm. • Pseudocoel and coelom are fluid filled body cavities that cushion organs and provide support.

  15. Body Cavities • In protostomes, mesoderm forms as endodermal cells from near the blastopore migrate into the blastocoel. • Three body plans possible: • Acoelomate (no body cavity) • Pseudocoelomate (body cavity between endoderm & mesoderm) • Coelomate (body cavity surrounded by mesoderm)

  16. Body Cavities • Coeloms surrounded by mesoderm can arise in two ways: • Schizocoely – mesodermal cells fill the blastocoel, forming a solid band of tissue around the gut, then a space opens inside the mesodermal band. • Enterocoely – portions of the gut lining form pockets that pinch off and form a ring of mesoderm.

  17. Developmental Patterns • Sponges develop only to blastula stage, then reorganize to form adult. • Gastrulation allows animals to proceed to tissue level organization. • Diploblastic – 2 germ layers • Cnidarians, Ctenophores • Triploblastic – 3 germ layers

  18. Other Key Features of Body Plans • In some organisms, the gut does not form a complete tube. • Waste must come back out the mouth. • Food must be digested & waste expelled before eating again. • A complete gut forms a tube within a tube body plan.

  19. Other Key Features of Body Plans • Segmentation is a serial repetition of similar body segments along the body. • Each segment is a metamere or somite. • May include external & internal components. • Obscured in many animals, like humans. • Permits greater body mobility and complexity of structure & function.

  20. Components of Metazoan Bodies • Extracellular Components - noncellular components of metazoan animals: • Body fluids • Extracellular structural elements

  21. Tissue Structure and Function • A tissue is a group of similar cells specialized for performing a common function. • Different types of tissues have different structures that are suited to their functions. • Tissues are classified into four main categories: • Epithelial • Connective • Muscle • Nervous • Cellular Components - Tissues

  22. Epithelial Tissue • Epithelial tissue covers the outside of the body and lines organs and cavities within the body. • Squamous, cuboidal, columnar. • Simple vs. stratified.

  23. Connective Tissue • Connective tissue functions mainly to bind and support other tissues. • Contains sparsely packed cells scattered throughout an extracellular matrix.

  24. Muscle Tissue • Muscle tissue is composed of long cells called muscle fibers capable of contracting in response to nerve signals. • Smooth • Skeletal • Cardiac

  25. Nervous Tissue • Nervous tissue senses stimuli and transmits signals throughout the animal. • A neuron (nerve cell) receive signals at the dendrites and send them out via the axons.

  26. Complexity and Body Size • Increased complexity allows for an increase in body size. • Larger size decreases the surface area to volume ratio. • Necessitates complex systems for respiration, nutrition, and excretion – diffusion not adequate. • Buffers environmental fluctuation. • Escape predators.

  27. Complexity and Body Size • Cost of maintaining body temperature is less per gram of body weight than in small animals. • Energy costs of moving a gram of body weight over a given distance less for larger animals.

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