“Protists” Lectures on Protists - Cabrillo Collegencrane/bio1c/botPDFs/Protists1F12.pdf ·...
Transcript of “Protists” Lectures on Protists - Cabrillo Collegencrane/bio1c/botPDFs/Protists1F12.pdf ·...
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“Protists”
1) Basic traits of the protists
2) Evolutionary origin and diversification of the eukaryotes via endosymbiosis
3) Modern diversity of protists, Part 1: Plant-like protists
Lectures on Protists • Generalizations about protist ecology • For each group, pay attention to:
– Mode of nutrition – Life cycle – Distinguishing characteristics
• Serial endosymbiosis, primary vs. seconday endosymbiosis
• Eukaryotic Cell Advantages • Know how the different groups we study
are related
Figure 27.2 The three domains of life Figure 26.1 Some major episodes in the history of life
Figure 28.2 “Protista” is NOT a monophyletic group.
• All are eukaryotes • Varied Nutrition:
photoautotrophs (“algae” and “phytoplankton”), ingestive heterotrophs (“protozoa”), absorptive heterotrophs (fungus-like), and “mixotrophs” (e.g., Euglena)
• Most have at least one stage that is motile (via flagella)
• Much variation in life cycles (pay attention to diploidy vs. haploidy)
• Most are found in water (damp soil, oceans, lakes, streams, animal bodies)
Diversity in traits of protists: “Protists”
1) Basic traits of the protists
2) Evolutionary origin and diversification of the eukaryotes via endosymbiosis
3) Modern diversity of protists, Part 1: Plant-like protists
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Figure 28.4 A model of the origin of eukaryotes from prokaryotes: plasma membrane infolding and specialization, followed by “serial endosymbiosis.”
Step 1
Step 2
(Step 3) Evidence supporting the serial
endosymbiosis theory • Existence of endosymbioses today
(wolbachia) • Similarity between bacteria and
mitochondria/chlorplasts – Similar size – inner membrane enzymes & transport systems – replication by binary fission – circular DNA molecule, with similar sequences – similar ribosomes
Figure 28.5 A model for the evolution of algal diversity, especially diversity in plasmids: secondary endosymbiosis. Notice: each endosymbiotic event adds a membrane layer to the engulfed plastid.
Figure 26.1 Some major episodes in the history of life. Note: the evolution of the eukaryotic cell resulted in a burst of evolutionary diversification on earth. Why did this happen?
“Protists”
1) Basic traits of the protists
2) Evolutionary origin and diversification of the eukaryotes via endosymbiosis
3) Modern diversity of protists, Part 1: Plant-like protists
Figure 28.8 A tentative phylogeny of eukaryotes.
Clade Euglenozoa: Phylum Euglenophyta
Clade Stramenopila: Phylum Chrysophyta Phylum Bacillariophyta
Clade Alveolata: Phylum Dinophyta
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Figure 28.3 Euglena: an example of a single–celled protist. The first eukaryotes were similar single-celled ancestors of the protists. How did the first eukaryote evolve from a prokaryote ancestor? Key features of Phylum
Euglenophyta • Eye spot, light detector, phototaxis • Unicellular • Motile • Mixotrophy • Asexual reproduction only (? Sexual
reproductionis unknown) • No cell walls (protein bands for
strength) • Chlorophyll a and b and carotenoids
Figure 28.25 A hypothetical history of plastids in the photosynthetic eukaryotes Figure 28.8 Euglena. Important traits of Euglenoids: unicellular, motile, many
are mixotrophic or heterotrophic
Figure 28.8 Euglena. Important traits of Euglenoids: unicellular, motile, many are mixotrophic or heterotrophic
phototaxis
Figure 28.8 Euglena. Important traits of Euglenoids: unicellular, motile, many are mixotrophic or heterotrophic
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Figure 28.8 Euglena. Important traits of Euglenoids: unicellular, motile, many are mixotrophic or heterotrophic Table 27.1 Classifying organisms by how they obtain carbon (to build cells and
organic molecules) and energy (to power metabolism and molecular construction).
Table 27.1 Classifying organisms by how they obtain carbon (to build cells and organic molecules) and energy (to power metabolism and molecular construction). Mixotrophy
• Euglena have chloroplasts and carry out photosynthesis, acquiring energy from sunlight (autotrophic)
• When light availability is inadequate, Euglena can absorb organic nutrients from the environment or engulf prey (heterotrophic)
• This ability to switch between autotrophy and heterotrophy is called mixotrophy
Protist Diversity cont.
• The golden browns: Chrysophyta • The Dinoflagellates: Dinophyta • The Diatoms: Bacillariophyta
• Evolutionary notes • General Characteristics • Reproduction • Ecology/human impact
Figure 28.4 A tentative phylogeny of eukaryotes.
Chrysophyta: Golden brown algae
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Figure 28.4 A tentative phylogeny of eukaryotes.
How many membranes do you think the golden algae’s chlorplasts have?
Golden Algae: PhylumChrysophyta
• Photosynthetic • Chlorophyll a & c and
carotenoids (Fucoxanthin) • Biflagellated • Autotrophs or mixotrophs • Can form cysts • Unicellular or colonial • Mostly fresh water • Cellulose or silica cell walls
Diatoms: Phylum Bacillariophyta **see the dinoflagellate?? Figure 28.8 A tentative phylogeny of eukaryotes.
Alga = photosynthetic protist
“Heterokont” algae are the algae in Stramenopila (browns, goldens, and diatoms)
The plastids of the heterokont algae evolved by secondary endosymbiosis, and thus have triple membranes.
Stramenopila = hairy flagellum
The colors of algae are due to accessory pigments in their plastids
Figure 28.17 Diatoms (Phylum Bacillariophyta): one of the heterokont algae. Diatoms have unique glass-like cell walls made of silica. They are VERY abundant as “plankton” in the surface waters of lakes, rivers, and oceans. They reproduce sexually only rarely. Diatoms: Phylum Bacillariophyta
• Photoautotrophs • Solitary or colonial • Make up phytoplankton in oceans, lakes,
streams - extremely important contributors to global Oxygen!
• Silica cell walls • Primarily asexual reproduction, diploid - some
sexual reproduction • Form auxospores - resting stage • Chlorophyll a and c and fucoxanthin (a
carotenoid)
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Figure 28.17x Diatom shell. Note: diatoms have a two-part cell wall, one of which fits inside the other like the parts of a shoe box. Pseudo-nitzchia australis
A diatom that carries The toxin domoic acid
pennate vs. centric shapes Diatom Life Cycle asexual Reproduction
A diatom frustule
They get smaller with successive generations!
When diatoms do reproduce sexually, their life cycle is like an animal’s, except never multicellular
(and some algae, like diatoms)
Figure 28.4 A tentative phylogeny of eukaryotes.
Dinoflagellates: Dinophyta
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Figure 28.25 A hypothetical history of plastids in the photosynthetic eukaryotes Figure 28.9 Alveolates are characterized by membrane-bound sacs (alveoli)
beneath the plasma membrane.
Figure 28.10 Dinoflagellates spin due to the beating of a pair of spiral flagella lying in a groove encircling the cell.
Dinoflagellates (Dinophyta) • Mostly phosynthetic autotrophs, some are
heterotrophic • Unicellular • 2 flagella (many) • Chlorophyll a & c, carotenoids (peridinin) • Cellulose cell wall (or none) • Many are bioluminescent • Some are mutualistic symbionts in marine
invertebrates • Some species are responsible for red tides
(toxins)
Sexual (2N)
Asexual (binary fission) 1N
Red tides
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Zooxanthellae - keys to coral reef productivity
Figure 32.1 A coral reef. Corals are colonial animals, with photsynthetic dinoflagellate symbionts.
Protists are a diverse group!
Next we’ll be looking at multicellular protists: the Algae