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Systematic Adaptations of Phylum Platyhelminthes

Systematic Adaptations of Phylum Platyhelminthes. The Flatworms. Derived Characteristics. Organ level of organization Well developed, specialized anatomical structures Incomplete gastrulation Gastrovascular cavity with one opening Triploblastic

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Systematic Adaptations of Phylum Platyhelminthes

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  1. Systematic Adaptations of Phylum Platyhelminthes The Flatworms

  2. Derived Characteristics • Organ level of organization • Well developed, specialized anatomical structures • Incomplete gastrulation • Gastrovascular cavity with one opening • Triploblastic • True mesodermal tissue filling space between endoderm and ectoderm (note “parenchyma”) • Bilateral Symmetry • 2 symmetrical sides about longitudinal axis • Cephalization • Concentration of sensory apparatus at anterior end

  3. Body Form & Development • Acoelomate • Parenchyma derived from mesodermal tissue • Elongated body • No appendages

  4. Integumentary • Simple integument • Ciliated in free living flatworms, but lacking cilia in parasitic forms • Glandular tissue associated with skin • Mucous glands • “Dual gland” for adhesion and release

  5. Skeletal & Muscular • Hydrostatic Skeleton • Parenchymal tissue holds a constant (“static”) volume of water (“hydro”) • Compression/contraction in one direction must necessarily result in expansion/elongation in a different direction • Well developed muscles are present in the body wall • Longitudinal • Circular • Oblique

  6. Muscular arrangement • Predict the result from the contraction of: • Longitudinal muscle (2) • Circular muscle (1) • Oblique muscle (3)

  7. Watch these flatworms move • https://www.youtube.com/watch?v=zCH37KI_R_E • https://www.youtube.com/watch?v=HekwSO6dBG0 • https://www.youtube.com/watch?v=OCOYrHAkjVE

  8. Nervous & Sensory • Centralized nervous system • Paired solid, ventral nerve cords • “Ladder” type nervouse organization – Transverse nerves connecting longitudinal nerve cords • Concentration of nerve tissue forming cephalic ganglia (simple brain)

  9. Nervous & Sensory • Cephalization • Concentration of sense organs in anterior body region • Sense organs • Photoreceptors (note “ocelli”) • Chemoreceptors (note “auricles”)

  10. Digestion • The development of the digestive cavity is incomplete, forming a gastrovascular cavity with a single opening • Digestion is largely extracellular, although some flatworms complete the process in food vacuoles (intracellular) • The class turbellaria are free living and carnivorous, and have well developed gastrovascular cavities • The other classes of flatworms are parasitic, dependent upon the host for digestion

  11. Digestion • Mouth located ventrally • Free living turbellaria have an extensible pharynx • The highly branched gastrovascular cavity brings digested food in close proximity to all body tissues • As the gastrovascular cavity has only 1 opening, wastes are excreted through the pharynx or retained

  12. Watch these flatworms feeding • https://www.youtube.com/watch?v=9QJF93WlNew • https://www.youtube.com/watch?v=eUmOJ6fWN9w&feature=endscreen&NR=1 • https://www.youtube.com/watch?v=Ich4Y_K6GuM

  13. Digestion • The gastrovascular cavity in parasitic forms is diminished (as in this photo) or absent (as in the tapeworms) • When present, the gastrovascular cavity is generally Y shaped

  14. Osmoregulation vs. Excretion? • Osmoregulation is the removal of excess water • Excretion is the removal of metabolic waste (mostly nitrogen compounds like ammonia or urea that accumulate from metabolism of protein) and excess dissolved materials (salts) • The flame cells are concerned with osmoregulation • Metabolic wastes are generally removed by simple diffusion

  15. Excretion & Osmoregulation • “Protonephridia” – primitive excretory tubules driven by Flame Cells. • The “flame” consists of several flagellae that drive fluids through tubules that lead to collecting tubules

  16. Excretion & Osmoregulation • There is considerable variation in the structure of osmoregulation systems in the flatworm classes, from simple excretory pores to a bladder

  17. Reproduction • Due to the simplicity of the flatworm body form, many are capable of reproducing asexually. In low density populations, asexual reproduction (by budding or fission) may be predominant • Flatworms are monoecious (one reproductive form – AKA hermaphroditic) but generally are unable to self-fertilize • Parasitic forms have complex life cycles, often involving one or more intermediate hosts.

  18. Flatworm reproductive organs • This flatworm is free living. Its muscular and digestive systems, while not shown above, are well developed • Note the presence of both male and female gonads (Monoecious)

  19. Fluke reproductive organs • This liver fluke is parasitic. It depend on its host for locomotion and digestion, allowing it to devote more of its energy and anatomy to reproduction • Note that is also is monoecious. The testes are more pink, and located posteriorly • The ovary is darker and more centrally located

  20. Tapeworm reproductive organs • Tapeworms are parasitic. Their digestive system is absent. Almost their entire anatomy is devoted to reproduction • They have a segmented body, with both testes and ovaries located in each segment

  21. Life cycle of the Liver fluke

  22. Trematode Life Cycle • https://www.youtube.com/watch?v=r7okJ6wHYLA • https://www.youtube.com/watch?v=EEBbtwGqPEs • https://www.youtube.com/watch?v=9fmx24FbZoM

  23. Classes of Platyhelminthes • The Phylum platyhelminthes is divided into 4 classes • Class Turbellaria – The free living flatworms • Class Trematoda – The digenetic flukes • Digenetic = 2 or more hosts • Class Monogenea – The monogenetic flukes • Monogenetic = 1 host • Class Cestoda – The tapeworms

  24. Class Turbellaria • The only class of free living flatworms • Ciliated epidermis with mucous secreting rhabdites • Acoelomate • Extensible pharynx • Includes the planaria

  25. Class Trematoda • Parasitic flukes • Syncytial tegument (multinucleate skin) without cilia • Y shaped gastrovascular cavity • Oral sucker for obtaining food and ventral sucker for attachment • No hooks for attachment to host • Digenetic – 2 or more hosts • Intermediate host – usually an invertebrate, frequently a mollusc • Definitive host – a vertebrate • Includes fasciola, schistosoma and clonorchis

  26. Class Monogenea • Parasitic flukes • Syncytial tegument (multinucleate skin) without cilia • Free living, ciliated larvae • Y shaped gastrovascular cavity • A single oral sucker • A series of posterior hooks (opisthaptor) for attachment to the host • Monogenetic – parasitic on a single host, usually a fish, amphibian or reptile

  27. Class Cestoda • Tapeworms, parasitic to the digestive tracts of vertebrates • Syncytial tegument without cilia • The tegument is covered with fingerlike extensions to increase the surface area for food absorption • Gastrovascular cavity is absent • Anterior structure (scolex) with hooks/suckers for attachment to the host • Body is formed into segments called proglottids. Each proglottid has testes and ovaries. Self-fertilization is possible • Gravid proglottids from feces of infected animals may be consumed by a new host, or may be spread by consuming larvae in the flesh of an infected animal

  28. Tapeworms • https://www.youtube.com/watch?v=Q5BuXmDIJxs • https://www.youtube.com/watch?v=9qyEfeg-334

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