Transcript Document

The Protists
• Even a low-power
microscope can reveal a
great variety of organisms
in a drop of pond water
• These amazing organisms
belong to the diverse
kingdoms of mostly singlecelled eukaryotes
informally known as
protists
• Advances in eukaryotic
systematics have caused
the classification of
protists to change
significantly
Kingdom Protista??
• now part of the Domain Eukaryota
– eukaryotes = true nucleus
– evolution of a nucleus for the genetic information
– evolution of membrane-bound organelles
• diverse group of single and colonial forms informally
known as The Protists
• but Kingdom Protista really doesn’t exist anymore – too
polyphyletic
• probably arose from more than one prokaryotic group
• 7 to 45 phyla recognized depending on zoologist
Protists
– include groups that are photoautotrophs,
heterotrophs and mixotrophs
• mixotrophs = combine photosynthesis and
heterotrophic nutrition
– divide the protists into three categories:
– 1. Photosynthetic – plant-like or algae
– 2. Ingestive – animal-like or protozoans
• amoeba
– 3. Absorptive – fungus-like
The 5 “Supergroups” of Eukaryotes
• old classification scheme – 5 kingdoms
• new classification scheme – 3 domains
• Phylogenetic classification of eukaryotes now produces five
Clades:
• 1. Excavata (Kingdom)
– trypanosomes, euglena
• 2. Chromalveolata (Kingdom)
– dinoflagellates, diatoms, ciliates, brown algae
• 3. Rhizaria (Kingdom)
• 4. Archaeplastida (unranked kingdom)
– red algae, green algae and land plants
• 5. Unikonta (unranked kingdom)
– slime molds, amoebas, fungi and animals
Ancestral eukaryote
Plants
Charophyceans
(Opisthokonta)
Chlorophytes
Plantae
Charophyta
Chlorophyta
Rhodophyta
Animalia
Fungi
Unikonta
Red algae
Metazoans
Choanoflagellates
Amoebozoa
Fungi
Cellular slime molds
Radiolaria
Cercozoa
Rhizaria
Plasmodial slime molds
Entamoebas
Gymnamoebas
Radiolarians
Foraminiferans
Chromalveolata
Chlorarachniophytes
Brown algae
Golden algae
Diatoms
Ciliates
Clade: Excavata
Apicomplexans
Stramenopila
Oomycetes
Euglenozoa
Parabasala
Alveolata
Dinoflagellates
Euglenids
Kinetoplastids
Parabasalids
Diplomonads Diplomonadida
Eukaryotic Phylogenetic Tree
Archaeplastida
(Viridiplantae)
• Clade Excavata – the Euglenozoans
– considered photosynthetic protists similar to algae
– like algae – the photosynthetic protists have chlorophylls
found in chloroplasts
– BUT some can be parasitic to humans
Euglenozoan: Trypanosomes
– parasites of animals, plants and other protists
• Trypanosoma gambienese – sleeping sickness (neurological disease) &
Chagas’ disease (congestive heart failure) in humans
Trypanosomes
Life cycle
-cycles between the tse tse fly and
the human
-different forms of the
trypanosome depending on what
host (fly vs. human) and where it is
in the host
1.
2.
3.
4.
fly injects the trypanosome
multiplication in the human
host – e.g. in the blood
bit by fly and transfer back to
fly
multiplication in the fly’s gut
and then in the salivary gland
Euglenozoans – The Euglena
– unicellular protist
– most are autotrophic & photosynthetic
– main characteristic - two flagella that emerge
from a “pocket” structure – long (locomotion)
and short
– contain a large, contractile vacuole that gets
rid of excess water that constantly flows into
the protist
– eyespot (stigma) - near the flagella
• filters light
– light detector (photoreceptor) – detects the
filtered light and results in movement toward
the light direction
– Chloroplasts for photosynthesis – containing
chlorophylls
https://www.youtube.com/watch?v=f
I7nEWUjk3A
Clade: Chromalveolata
• originated more than a billion years
ago when their ancestor ingested a
photosynthetic red algae
• one member: Dinoflagellates
LE 28-10
Flag
3 µm
– “dinos” = whirling
– surrounded by a cell wall encrusted with silica - act
as “armor”
– most are photosynthetic
– two flagellae – located in perpendicular grooves
• one flagella propels the dinoflagellate forward
and causes it to spin
• the other flagella acts as the rudder
– capable of proliferating explosively – “blooms”
• “red tide” (carotenoid pigments found in the plastids)
• dinoflagellates produce a toxin that kills off invertebrates
– some can be bioluminescent – ATP driven reaction that
creates a glow at night
• scares off predators
Clade Chromalveolata - Ciliates - Paramecium
• use of cilia to move and feed
– cilia may completely cover the protist or may cluster in a few rows or tufts
• distinguished by the presence of two types of nuclei: macronucleus (large)
and micronucleus (small)
– may have one or more of each type
– macronucleus – controls the everyday function of the cell
– micronucleus – exchanged during reproduction
FEEDING, WASTE REMOVAL, AND WATER BALANCE
Paramecium, like other freshwater
protists, constantly takes in water
by osmosis from the hypotonic
environment. Bladderlike contractile
vacuoles accumulate excess water
from radial canals and periodically
expel it through the plasma
membrane.
Contractile
vacuole
Paramecium feeds mainly on bacteria.
Rows of cilia along a funnel-shaped oral
groove move food into the cell mouth, where
the food is engulfed into food vacuoles by
phagocytosis.
Oral groove
Cell mouth
Thousands of cilia cover the
surface of Paramecium.
50 µm
Food vacuoles combine with lysosomes. As the
food is digested, the vacuoles follow a looping
path through the cell.
Micronucleus
Macronucleus
The undigested contents of food
vacuoles are released when the
vacuoles fuse with a specialized
region of the plasma membrane that
functions as an anal pore.
Clade Chromalveolata - Ciliates - Paramecium
• freshwater protist – constantly
taking on water
• they contain contractile
vacuoles to get rid o the excess
water
https://www.youtube.com/watch?v=9Ynm5ZO
W59Q
Chromalveolata - Diatoms
• 100,000 species of unicellular algae
• surrounded by unique glass-like wall made of silica
embedded in an organic matrix
• most are photosynthetic
• major component of plankton in fresh and marine
environments – source of food
– upon death –sink to the bottom = diatomaceous earth
– active ingredient in detergents, fine abrasive polishes, paint
removers, decoloring oils, filtering agents, components of
insulation and soundproofing products, reflective paint
additive
Chromalveolata - Brown algae
• brown algae – most complex of
the algae
– all are multicellular and all are
marine
– have the most complex
multicellular anatomy of all algae
– some have specialized tissues like
animals and plants
– include the seaweeds
– giant seaweeds in intertidal zones –
kelps
• brown algae
– composed of a thallus = algal body
that is plant-like
– thallus has a rootlike hold-fast
which anchors the seaweed and a
stem-like stipe that supports leaflike blades
– BUT there are no true roots, stems
and leaves!
– blades – surface for photosynthesis
– blades can come equipped with
floats to keep them near the
surface
LE 28-18
Brown algae Thallus
Clade Archaeplastida
• more than a billion years ago – heterotrophic protist
ingested a photosynthetic bacteria
• these bacteria evolved into plastids for photosynthesis
• protist became the red and green algae
• 475 million years ago – green algae ancestors evolved into
land plants
• red algae, green algae and land plants are now placed into
the same clade based on molecular data – Archaeplastida
Plastid
Red algae
Bacterium
Heterotrophic
eukaryote
Plastid
Green algae
Archaeplastida - B. Green algae: Phylum Chlorophyta
• green algae
– named for the green chloroplasts
– chloroplasts contain chlorophyll pigments that are very
similar to plants in structure and function
– 7000 species of green algae
• mostly freshwater
• chlorophylls pigments for photosynthesis
• sugar storage form = starch
• cell walls made of cellulose just like plants
• most are unicellular
• some are also multicellular - colonial, filamentous
(pond scum) and sheet-like forms
Unicellular Green Algae
• e.g. Chlamydomonas – example of a unicellular
algae
–
–
–
–
two flagellae of equal length at the anterior end
a pyrenoid for carbohydrate synthesis
eyespot or stigma for movement towards light
two small contractile vacuoles for getting rid of
excess water
Colonial Green Algae
• not really multicellular
• colony of unicellular algae
– e.g. Volvox
• colony or 500 to 60,000 cells that resemble Chlamydomonas
• individual cells have eyespots – will orient toward the light
• cells at the equator are reproductive - called gonads  gametes for
fertilization  zygote
• zygote undergoes mitosis to form a small daughter colony
• the daughter colony remains in the parental colony until it bursts free
https://www.youtube.com/watch?v=9pjW1cMfTz8
https://www.youtube.com/watch?v=d8xs8F9gln0
https://www.youtube.com/watch?v=cmSs157KvTg
Volvox, a colonial freshwater chlorophyte. The colony is a hollow
ball whose wall is composed of hundreds or thousands of
biflagellated cells embedded in a gelatinous matrix. The cells are
usually connected by strands of cytoplasm; if isolated, these cells
cannot reproduce. The large colonies seen here will eventually
release the small “daughter” colonies within them.
Clade Unikonta
• recently proposed clade
• supergroup of eukaryotes that includes animals, fungi and
some protists
• means “one flagella”
• two major clades:
• A. Amoebozoans: the amoebas & slime molds
• B. Opisthokonts: fungi and animals
Unikonta: Amoebozoans
• 2. Entamoebas
–
–
–
–
parasitic amoebae
infect all classes of vertebrates and some invertebrates
humans are host to at least 6 species
Entamoeba histolytica – amoebic dysentery
• third leading cause of death in the world due to parasites – 100,000 deaths each year
Amoeba movement:
https://www.youtube.com/watch?v=o-PjvIRrbbw
https://www.youtube.com/watch?v=FcCvhYmjaXE
Amoeba proteus