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Biology 320 Invertebrate Zoology Fall 2005 Chapter 10 – Phylum Platyhelminthes Phylum Platyhelminthes 20,000 species of soft, dorsoventrally compressed worms Mainly marine or freshwater Three major groups Class Turbellaria – free-living flatworms Class Trematoda – parasitic flukes Class Cestoda – parasitic tapeworms Most are acoelomate and also lack a hemal system Small size is an adaptation to living in tight spaces, such as under rocks, in body cavities, etc. Class Turbellaria Two types, grouped according to size Microturbellaria Microturbellaria Macroturbellaria The majority of turbellarians at 4500 spp. 0.5mm – a few mm Macroturbellaria Normally several cm Largest lives in a lake in Russia and can reach 60cm in length Body Wall Typically have one layer of ciliated epidermis Cilia may only be present on ventral surface Name means “whirlpool,” due to ciliary action Microvilli also present on epidermis Soft; lack a cuticle Often have a fibrous endoskeleton containing actin filaments Epidermis is glandular; secretes: Mucus Adhesives Rhabdoids Rhabdoids Membrane-bound Rod-shaped Released onto epidermal surface Expand to form mucus Rhabdite is the most common type Adhesion facilitated by Glands Cilia Muscular suckers Many have structures known as duo-gland organs Consists of two different kinds of gland cells in one complex Viscid gland secretes adhesive Releasing gland secretes de-adhesive Musculature and Locomotion Fairly complex musculature Typical circular and longitudinal Diagonal Dorsoventral Capable of many types of movement Ciliary gliding Creeping Swimming using dorsoventral undulations of lateral body margins Twisting Somersaulting Nervous System Variable Primitive flatworms Ring-like brain One or more nerve cords extending posteriorly Nerve net Dugesia, and similar worms Bilateral brain Two ventrolateral longitudinal nerve cords Transverse commissures that give the nervous system an ladder-like appearance Sensory structures Usually two pigment cup ocelli Some possess statocysts Photoreceptors Many flatworms are negatively phototactic Balance and orientation Mechanoreceptors Senses pressure, touch, etc. Most posses a blind gut used for ingestion and egestion Extremely long flatworms have a through-gut A single layer of gastrodermis lines gut Phagocytes Glandular Ciliated in more primitive turbellarians Gut design varies depending on body size Microturbellaria have simple, unbranched guts Macroturbellaria often have digestive ceca to increase SA for digestion, absorption, etc. Nutrition Location of mouth varies Usually located midventrally, but anywhere along the ventral midline Presence / absence / type of pharynx varies Zero pharynx – no pharynx Simple pharynx – ciliated tube Plicate pharynx – long, muscular, protrusible tube. Housed in a sheath when retracted Bulbous pharynx – muscular sucking bulb; can be everted in some Type of prey is related to pharynx structure and body size Small - bacteria, unicellular algae, and protozoans Large - small inverts such as rotifers, insect larvae, crustaceans, and annelids Most are carnivorous, but some are scavengers Many methods of prey capture Wrap around prey Entangle in mucus (sometimes toxic) Capture with everted raptorial proboscis (has adhesive cups or hooks) Pin prey to substrate with adhesive organs Some even stab with penis stylet May ingest whole prey items or pieces of prey Eversible pharynx penetrates prey or carrion, and pumps contents into gut Digestion Extracellular initially. Pharynx is muscular and often has enzyme releasing pharyngeal glands Intracellular later Can withstand long periods of starvation by reabsorbing and metabolizing gut tissue, reproductive tissue, and various connective tissues Symbiosis Some harbor endosymbiotic photosynthesizers Some are commensals of molluscs and arthropods Bdelloura lives on gills of horseshoe crabs Shares food collected by host Several are endoparasites of molluscs, crustaceans, and echinoderms Internal Transport Most lack a coelom and hemal system Vermiform design and flatness provides large SA:vol Gas exchange occurs across body wall and general body surfaces Nutrient circulation and diffusion Simple gut is not diffusion limited Digestive ceca provide enough surface area to meet diffusion requirements in larger worms Gastrodermis has cilia for circulation Excretion Nitrogen from protein metabolism is in the form of ammonia Released along with water and other metabolites Protonephridia are the excretory “organs” Posses lots of protonephridia, as there is no circulatory system to pump blood to a centralized kidney Essentially a cup with ciliated terminal cells Cilia draw fluid into cup Cup filters fluid through a meshlike structure Waste travels through ducts which open to the surface via pores Asexual Reproduction Regeneration Amazing regenerators (1/300th of body can grow into an entire worm) Active area of research Interesting patterns of regeneration, depending on where the animal is cut Clonal Transverse fission – posterior end attaches, anterior end pulls and separates Paratomy – resembles strobilation in cnidarians Fragmentation – cyst forms around fragment. Regeneration occurs and cyst hatches Parthenogenesis – “virgin birth” Sexual Reproduction Hermaphroditic Male organs Two testes that each lead to a sperm duct… Then to a seminal vesicle (storage) Penis – copulatory organ that may be armed with a sharp, hardened stylet Female organs Gonopore for copulation Copulatory bursa for short term storage of partners sperm Seminal receptacle for long term sperm storage Copulation Reciprocal Rarely self fertilize Internal fertilization Hypodermic impregnation Eggs Oviposited from gonopore (singly, clutches, strings) Relatively few eggs Carefully spawned and have protective capsules Some FW spp. produce both summer eggs and resting (winter) eggs Usually direct development Some produce planktotrophic larvae Diversity of Class Turbellaria Order Catenulida Small, long, and slender Few epidermal cilia Head has one statocyst and two ciliated pits Mouth opens into simple pharynx Gonads unpaired Aflagellate sperm May reproduce via paratomy Catenula Order Acoela Less than 2mm long Many cilia on epidermis No pharynx Lack cellular gut Individual germ cells rather than gonads Biflagellate sperm No oviduct, eggs rupture wall No protonephridia Amphiscolops Order Macrostomida Lots of epidermal cilia Rhabdites Duo-glands Small paired ocelli Simple pharynx One pair of ventrolateral nerve cords w/ commissures Aflagellate sperm Macrostomum Order Polycladida Many epidermal cilia Rhabdites and duogland organs Biflagellate sperm Plicate pharynx Large, up to 30cm Oval, flattened Large gut w/ many ceca Some produce larvae May be brightly colored (aposematic in some) Stylochus Order Tricladida Many epidermal cilia Rhabdites and duo-gland organs Biflagellate sperm Plicate pharynx Yolky eggs Large gut with three branches and many ceca Bdelloua, Dugesia Order Rhabdocoela Several suborders Many epidermal cilia Rhabdites and duo-gland organs Biflagellate sperm Protrusible bulbous pharynx Some have proboscis which can be everted Some have ventral adhesive disc Mesostoma Neodermata Flukes, tapeworms and relatives belong to the taxon Neodermata Cellular epidermis is later replaced with syncytium called neodermis Non-ciliated No intracellular spaces due to syncytium One multinucleate cell Nothing unwanted passes Class Trematoda Flukes Belong to Subclass Digenea, which means “two generations” Endoparasites of vertebrates 11,000 spp. Body Form and Function Flat 0.2 mm – 6.0 cm long Various adhesion devices Oral sucker surrounding mouth Ventral sucker Facultative anaerobes that mainly rely on glycolysis Neodermis helps protect against host’s digestive enzymes Circular, longitudinal, and diagonal musculature Nervous system Similar to that of the turbellarians Pair of anterior cerebral ganglia (brain) Longitudinal nerve cords (variable) Ocelli in infective larval stages (miracidia and cercaria) Excretory system Protonephridia Two longitudinal collecting ducts Posterior bladder One nephridiopore Reproduction Highly organized reproductive system Constant supply of nutrients from host allow for large egg production 10,000 to 100,000 that of turbellarians Male system Two testes Two ducts External seminal vesicle Cirrus sac (internal seminal vesicle, prostate, copulatory cirrus) Genital atrium shared between male and female reproductive systems; contains one gonopore Female system One ovary (germarium) Oviduct - where seminal vesicles and vitellaria (yolk producing structures) are added Ootype (sac which encapsulates egg and yolk cells in protein) Uterus To genital atrium; out gonopore Some dioecious, but most are monoecious Most cross-fertilize, but some can selffertilize No asexual reproduction in adults No need, as adults usually have a constant supply of nutrients Asexual reproduction in some larval stages Trematode Life Cycles Two or more hosts / infective larval stages 1st intermediate host is usually a gastropod mollusc (snail) 2nd intermediate host is usually an arthropod or fish Definitive host is a vertebrate Aquatic cycle (may also occur on land) Eggs are passed in feces If land in water, hatch as miracidia (infect snails) Miracidium sloughs off epidermis and metamorphoses into sporocyst, which contains many embryos Sporocyst embryos form redia (feeding larvae with digestive system; also produce embryos) Redia embryos develop into cercaria (possess digestive tract, suckers and tail) Cercaria leave snail, swim, and infect 2nd intermediate host (usually arthropod or fish), and encyst as metacercaria Definitive host eats infected muscle tissue, and metacercaria develops into adult Free metacercaria can also be found attached to rocks or aquatic plants Chinese Liver Fluke Opisthorchis (or Chlonorchis) sinensis Infects bile ducts of 20 million people in Asia Adults are 2.5 cm long Live up to 8 years Produce 4000 eggs / day Causes jaundice, gallstones, and possibly liver cancer Blood Fluke Schistosoma mansoni Found in neotropics, and Africa Causes schistosomiasis Dioecious 300 million people worldwide One of three worst parasitic diseases Male and female permanently paired Smaller female fits in groove on male Live in intestinal veins Eggs laid in venules Work way into lumen using spikes / enzymes Life cycle is typical of trematodes Cercaria penetrate human skin w/ enzymes and muscular boring Enter circulation and transform into adults on way to intestine First pass through lungs and liver Damage to organs and vessels from various life stages (eggs are the worst) Causes inflammation, necrosis, and fibrosis Class Monogenea 1100 spp. Typically 1 – 5 mm long, but up to 20 mm Mainly ectoparasites of aquatic vertebrates; therefore rely on aerobic metabolism Name means “one generation,” because they lack clonal reproduction Also lack intermediate hosts Have a large attachment organ Known as a haptor Located posteriorly Has suckers and hooks Egg develops into a hooked miracidium Called oncomiracidium Has two ocelli Adult Head (sometimes has muscular oral sucker, or adhesive glands) Trunk Haptor Pharynx secretes protease which degrades host’s epidermis Feed on: Cellular debris Blood mucus Remaining body systems are similar to turbellarians and trematodes Life Cycles Dactylogyrus Ectoparasite of fish gills Serious problem in hatcheries Leads to death by blood loss or secondary infection Polystoma Inhabits bladders of old world frogs Synchronization of life cycles (host and parasite eggs released at same time) Oncomiracidia attach to tadpole’s gills When tadpole becomes frog, parasite migrates from gill chamber to bladder Class Cestoda The tapeworms 3400 spp. All endoparasites of vertebrate guts Lack gut entirely Long; can reach 25 m Body Form Ribbon-like Three regions Scolex – head with hooks and suckers for attachment Neck – narrow growth zone containing stem cells Strobila – segmented trunk consisting of proglottids (segments) Neodermis allows worm to avoid host’s immune system Rely almost entirely on anaerobic respiration Muscular, nervous, and protonephridial system is similar to that of turbellarians and trematodes Reproduction Strobilation occurs at neck region Each proglottid has a miniature reproductive system When one worm is present Cross fertilize Worms have proglottids that are in different stages of sexual maturity Self fertilize using one proglottid Serf fertilize between two proglottids When two or more worms are present During copulation, cirrus is everted and inserted into gonopore Eggs constantly being produced Mature (gravid) proglottids break off from strobila and are passed in feces Life Cycles Usually two or more hosts Definitive host always a vertebrate Aquatic and terrestrial life cycles Diphyllobothrium is a fish tapeworm that can infect humans Eggs in feces are deposited in water Hatch into a ciliated, swimming oncosphere larva (has hooks) Oncosphere is ingested by a copepod Oncosphere moves to hemocoel of copepod, sheds ciliated epidermis, replaces with neodermis, and develops into a procercoid larva Fish eats copepod Procercoid migrates from gut of fish to muscle, and transforms into a juvenile called a plerocercoid (metacestode) Development is completed in the gut lumen of a fish-eating vertebrate after ingestion of infected muscle tissue Taenia is a terrestrial Can reach 20 m but is typically 3 to 5 m Lifecycle tapeworm that infects domestic animals and humans Eggs are removed in feces Animal ingests eggs and oncosphere bores through intestinal wall and migrates to skeletal muscle Oncosphere develops into a cysticercus (another metacestode w/ inverted scolex) Development is completed in the gut lumen of a vertebrate after ingestion of infected muscle tissue Tapeworm infections cause diarrhea, weight loss, and lethargy Occasionally humans accidentally serve as an intermediate host, by becoming infected with a cysticercus Echinococcus is often responsible for this Cysticercus ends up in lung, liver, heart, brain, etc. Swells up Known as a hydatid or hydatid cyst Must be removed surgically Some mortality