Platyhelminthes BIO 205 PDF

Summary

This document provides notes on the Phylum Platyhelminthes, also known as flatworms. It details their characteristics, including acoelomate body cavities, triploblastic structure and osmoregulatory systems. It also discusses the various classes, life cycles, and adaptations to parasitism seen in some species.

Full Transcript

Phylum
Platyhelminthes
(Flatworms & co)

Chapter 8
 METAZOA
Bilateria

Protostomia Deuterostomia
Lophotrochozoa Ecdysozoa

choanofla
gellates sponges cnidarians molluscs annelids flatworms nematodes arthropods echinoderms chordates

Gastrulation
Diploblasty
Multicellularity
Blastulation
 Bilateria
Animals actively looking for food,
shelter, and sexual partners
– Need for strategies and structures
– Radial symmetry NOT appropriate
– 2 major innovations:
Cephalization & central nervous system
– Concentration of sensory organs in the head region
Bilateral symmetry
 METAZOA
Bilateria

Protostomia Deuterostomia
Lophotrochozoa Ecdysozoa

choanofla
gellates sponges cnidarians molluscs annelids flatworms nematodes arthropods echinoderms chordates

(Org. & Syst. level)
Gastrulation Bilateral symmetry
Diploblasty Cephalization
Triploblasty
Multicellularity
Blastulation
Phylum Platyhelminthes

Acoelomate: body cavity filled with parenchyma
Muscle cells and parenchyma derived from mesoderm

Triploblastic
 METAZOA
Bilateria

Protostomia Deuterostomia
Lophotrochozoa Ecdysozoa

choanofla
gellates sponges cnidarians molluscs annelids flatworms nematodes arthropods echinoderms chordates

Mouth formed from
blastopore, etc. (Org. & Syst. level)
Gastrulation Bilateral symmetry
Diploblasty Cephalization
Triploblasty
Multicellularity
Blastulation
Lophotrochozoa

Phyla: Phyla:
ex. Ectoprocta - Molluscs
(NOT covered in BIO205) - Annelids
- Platyhelminthes

Lophophores Trochophore larvae
 METAZOA
Bilateria

Protostomia Deuterostomia
Lophotrochozoa Ecdysozoa

choanofla
gellates sponges cnidarians molluscs annelids flatworms nematodes arthropods echinoderms chordates

Trochophore larva
Mouth formed from
blastopore, etc. (Org. & Syst. level)
Gastrulation Bilateral symmetry
Diploblasty Cephalization
Triploblasty
Multicellularity
Blastulation
Phylum Platyhelminthes

“Flat worms”
20-30K species
Marine & freshwater but some terrestrial
Many endoparasites
Phylum Platyhelminthes

“flat worms”
Great surface / volume ratio
Appropriate for gas exchange,
nutrition and wastes management
Phylum Platyhelminthes

Synapomorphy: lamellate rhabdites (rod-shaped structures that swell when
discharged in water to form a mucus coating)
Role: locomotion & gas exchange
 Platyhelminthes
Lamellate
rhabdites
Phylum Platyhelminthes
What’s new?
Excretory/ osmoregulatory system
Copulation and copulatory organs
Cephalization & Central nervous system
Phylum Platyhelminthes
What’s new?
Excretory system / osmoregulation
Cephalization & central nervous system
Copulation
Phylum Platyhelminthes

EXCRETION: elimination of metabolic waste products (such as ammonia,
urea and uric acid)

OSMOREGULATION: maintenance of stable internal solutes
concentrations, regulation of osmolarity (total amount of solutes in a
solution)
Excretion and osmoregulation are often linked, since nitrogenous
wastes are important (and usually toxic) solutes
In sponges and cnidarians, these are dealt with mainly at a cellular level but
most bilaterally symmetrical animals need a system to collect metabolic waste
and/or regulate amount of water in tissues
 Phylum Platyhelminthes

Vertebrates Invertebrates
300 mOsm/L 1 000 mOsm/L
Fresh water Salty water
< 50 mOsm/L (marine or sea water)
1 000 mOsm/L

1 000 mOsm/L

Planaria
 Phylum Platyhelminthes
Platyhelminthes living in fresh water need a
system to regulate the amount of water (and
solutes) in their tissues

Fresh water
< 50 mOsm/L

1 000 mOsm/L

Planaria
 Osmoregulatory system

Protonephridia: network of tubules
capped by flame cells inside and
opening outside by a nephridiopore
Primary role: Protonephridial
à Remove excess water (especially system
in freshwater)
Secondary role:
à Excretion of ammonia
In Platyhelminthes, NH3 is
primarily excreted by diffusion
through body wall
Phylum Platyhelminthes
What’s new?
Excretory system / osmoregulation
Cephalization & central nervous system
Copulation
Central nervous system
Cephalization: Sensory
Ocellus reception (ocelli and
chemoreceptors) on the head
Phylum Platyhelminthes
What’s new?
Excretory system / osmoregulation
Cephalization & central nervous system
Copulation

Direct contact between 2 individuals to
transfer sperm from the body of the
‘male’ to the body of the ‘female’
Internal fertilization
 Reproductive
system

With copulatory organs

Platyhelminthes are
Monoecious
Physiology
Respiratory ‘system’?
Diffusion through body surface
Mucus = humid (terrestrial organisms)
Skeletal ‘system’?
Muscles et parenchyma
Circulatory ‘system’?
None… but surface area optimized for many ‘systems’
Phylum Platyhelminthes

Acoelomate
Triploblastic
Osmoregulatory system
Copulatory organs
Cephalization and CNS
Gut present (blind) or absent
Phylum Platyhelminthes

Four groups (3 covered in BIO 205):
Turbellaria grade (flatworms)
Class Trematoda (flukes)
Class Cestoda (tapeworms)
Figure 8_02

Paraphyletic group
(grade)
Phylum
Platyhelminthes
Grade Turbellaria

29
Grade Turbellaria (flatworms)

Mostly free-living scavengers and predators, 50-500 mm
NOT parasites
Typically creep along substrate using mucus and ventral cilia
Grade Turbellaria (flatworms)

Mostly free-living scavengers and predators, 50-500 mm
Typically creep along substrate using mucus and ventral cilia
Epidermis: formed by rhabdite cell & cilia
Digestive and
nervous systems
No anus
Cephalization
Primitive CNS
 Grade Turbellaria
Ocellus

Sensory reception: ocelli and chemoreceptors on the head
Phylum
Platyhelminthes
Grade Turbellaria

34
 Reproduction

Copulatory organs
Grade Turbellaria (flatworms)

Reproduction and life cycle
Sexual reproduction
Monoecious
Usually practice cross-fertilization
Asexual reproduction
fission, fragmentation and regeneration
Simple life cycle with direct development
(immature instead of larva)
Videos

Planarian, eating
http://www.youtube.com/watch?v=w0QzSYQGsnA&feature=related
Terrestrial planarian, moving
http://www.youtube.com/watch?v=Fq_aSR5FK0Y&feature=fvw
http://www.youtube.com/watch?v=NgkFnY3aaX4
Fission
http://www.youtube.com/watch?v=E1d9MyJBLlg&feature=related
Members of Neodermata
are all endoparasitic
 Platyhelminthes :
Clade Neodermata
Endoparasites
àComplex life-cycles
Need to pass through specific sequences of 2 or more
hosts to complete life cycle
In intermediate host(s):
Worms are immature
ØNo sexual reproduction
ØAsexual reproduction (in some species)
In definitive host:
Worms are mature (adults)
ØSexual reproduction
Platyhelminthes :
Clade Neodermata
Endoparasites
àImportant adaptations:
Penetration glands
Hooks
↑ reproductive capacity
Epidermis :
NOT ciliated
Loss of rhabdites
Syncytial tegument
Epidermis/tegument Promotes nutrient, wastes and gas exchanges
Protects against digestive enzymes

Epidermal cell Microvilli (cytoplasm)

Muscles

Parenchyma

Rhabdite cell
Tegumentary cell Non ciliated covering
Cellular ciliated epidermis Syncytial tegument
Turbellaria All other classes
Class Trematoda

Leaf-like form, relatively similar
to turbellarians BUT…
All endoparasitic… Anterior adhesive organ :
suckers and hooks
socio-economically devastating
parasites
Body design reflects
adaptations to parasitism
Life cycle involves both sexual
and asexual reporduction
Ex. 1 Clonorchis sinensis,
Chinese liver fluke Definitive host

(monoecious)
Second
intermediate host

First
intermediate host
 egg
1

Up to
250 000

àMany different immature stages
àMuch asexual replication
1 egg à 1 miracidium à 1 sporocyst à many rediae à many cercariaeà
1 metacercaria per cercariaà 1 adult per metacercaria
Endoparasites
Ex. 2 Schistosoma mansoni,
Blood fluke Definitive host

intermediate host
48
Class Cestoda

Tapeworms
All endoparasitic- adults infect gut of vertebrates
Syncytial tegument (like trematodes)
Intermediate hosts: vertebrates or invertebrates
Monoecious
Some very large (>8m.)
Class Cestoda

Basic body plan:
Scolex, attachment device (suckers and hooks), NOT head!
Strobila
Continuous growth behind scolex
Made of many proglottids
Each proglottid is fully
reproductive

Self-fertilization
common

microvilli

tegument
 Each proglottid is fully
reproductive

Self-fertilization
common

microvilli

No mouth, no digestive system
How do they feed?

tegument
 Definitive host
Beef tapeworm Scolex

Taenia saginata

Scolex

“bladder worm”

Shelled larva hatches in cow stomach,
burrows in blood vessel and migrates to Intermediate
skeletal muscles where it forms a cyst host
Beef tartare anyone?
 Eaten by human
Definitive
Intermediate
host
Pork tapeworm in raw/ rare pork
host

Taenia solium
Cysts in human
muscles and organs
Cysticercosis
Caused when humans eat
eggs of T. solium and
become an intermediate
host instead of a definitive
host
Self-infection is common
Cysticerci develop in any
organs such as muscles,
brain, eyes, livers, spinal
cord, etc. à can cause Cysts in muscle Intermediate
extensive damage
(“measly pork”)
host
Eggs on ground
ingested by pork
Cysticercosis Cysticerci infection (cysticercosis)
from pig tapeworm, Taenia solium
Cysticercosis

Human brain infected with
cysticerci of pig tapeworm,
Taenia solium
Cysticerci infection causes
much more damage than
tapeworm infection
Class Cestoda

Asexual reproduction is rare but does occur
in a few taxa.
Massive size range
Whale tapeworm can reach 30 m
3-6 mm Echinococcus granulosus from dog
8.8 m Diphyllobothrium nihonkaiense
isolated from a human
Grade Turbellaria Class Trematoda (flukes)

Free-living Endoparasite
Cellular epidermis Syncytial tegument (no rhabdites)
Rhabdites Complex life cycle with 2+ hosts
Simple life cycle 1 egg = many adults
Many harmful to humans
Class Cestoda (tapeworms)

Endoparasite
Syncytial tegument (no rhabdites)
Complex life cycle usually with 2+ hosts
Massive egg production
1 egg = 1 adult (usually)
Some harmful to humans