1. Chapter 28
Protists

2. Overview: Living Small
Even a low-power microscope can reveal a great variety of organisms in a drop of pond water
Protist is the informal name of the group of mostly unicellular eukaryotes
Advances in eukaryotic systematics have caused the classification of protists to change significantly
Protists constitute a polyphyletic group, and Protista is no longer valid as a kingdom
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3. Figure 28.1
Figure 28.1 Which of these organisms are prokaryotes and which are eukaryotes?
1 m

4. Concept 28.1: Most eukaryotes are single-celled organisms
Protists are eukaryotes
Eukaryotic cells have organelles and are more complex than prokaryotic cells
Most protists are unicellular, but there are some colonial and multicellular species
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5. Structural and Functional Diversity in Protists
Protists exhibit more structural and functional diversity than any other group of eukaryotes
Single-celled protists can be very complex, as all biological functions are carried out by organelles in each individual cell
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6. Protists, the most nutritionally diverse of all eukaryotes, include
Photoautotrophs, which contain chloroplasts
Heterotrophs, which absorb organic molecules or ingest larger food particles
Mixotrophs, which combine photosynthesis and heterotrophic nutrition
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7. Some protists reproduce asexually, while others reproduce sexually, or by the sexual processes of meiosis and fertilization
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8. Endosymbiosis in Eukaryotic Evolution
There is now considerable evidence that much protist diversity has its origins in endosymbiosis
Endosymbiosis is the process in which a unicellular organism engulfs another cell, which becomes an endosymbiont and then organelle in the host cell
Mitochondria evolved by endosymbiosis of an aerobic prokaryote
Plastids evolved by endosymbiosis of a photosynthetic cyanobacterium
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9. Figure 28.2 Diversity of plastids produced by endosymbiosis.
Dinoflagellates
Secondary endosymbiosis
Membranes are represented as dark lines in the cell.
Apicomplexans
Red alga
Cyanobacterium 1 2 3
Primary endosymbiosis
Stramenopiles
Heterotrophic eukaryote
Secondary endosymbiosis
Plastid
Figure 28.2 Diversity of plastids produced by endosymbiosis.
One of these membranes was lost in red and green algal descendants.
Euglenids
Secondary endosymbiosis
Green alga
Chlorarachniophytes

10. Primary endosymbiosis
Figure 28.2a
Membranes are represented as dark lines in the cell.
Red alga
Cyanobacterium 1 2 3
Primary endosymbiosis
Heterotrophic eukaryote
One of these membranes was lost in red and green algal descendants.
Figure 28.2 Diversity of plastids produced by endosymbiosis.
Green alga

11. Secondary endosymbiosis
Figure 28.2b
Plastid
Dinoflagellates
Secondary endosymbiosis
Apicomplexans
Red alga
Figure 28.2 Diversity of plastids produced by endosymbiosis.
Stramenopiles

12. Secondary endosymbiosis Secondary endosymbiosis
Figure 28.2c
Plastid
Secondary endosymbiosis
Euglenids
Secondary endosymbiosis
Figure 28.2 Diversity of plastids produced by endosymbiosis.
Green alga
Chlorarachniophytes

13. The plastid-bearing lineage of protists evolved into red and green algae
The DNA of plastid genes in red algae and green algae closely resemble the DNA of cyanobacteria
On several occasions during eukaryotic evolution, red and green algae underwent secondary endosymbiosis, in which they were ingested by a heterotrophic eukaryote
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14. Five Supergroups of Eukaryotes
It is no longer thought that amitochondriates (lacking mitochondria) are the oldest lineage of eukaryotes
Many have been shown to have mitochondria and have been reclassified
Our understanding of the relationships among protist groups continues to change rapidly
One hypothesis divides all eukaryotes (including protists) into five supergroups
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15. Figure 28.3 Exploring: Protistan Diversity.
Figure 28.3a
Diplomonads
Parabasalids
Euglenozoans
Excavata
Dinoflagellates
Apicomplexans
Ciliates
Diatoms
Golden algae
Brown algae
Oomycetes
Alveolates
Chromalveolata
Stramenopiles
Cercozoans
Forams
Radiolarians
Rhizaria
Red algae
Chlorophytes
Charophytes
Land plants
Green algae
Archaeplastida
Figure 28.3 Exploring: Protistan Diversity.
Slime molds
Gymnamoebas
Entamoebas
Nucleariids
Fungi
Choanoflagellates
Animals
Amoebozoans
Unikonta
Opisthokonts

16. Excavata Chromalveolata
Figure 28.3aa
Diplomonads
Parabasalids
Euglenozoans
Excavata
Dinoflagellates
Apicomplexans
Ciliates
Diatoms
Golden algae
Brown algae
Oomycetes
Alveolates
Chromalveolata
Figure 28.3 Exploring: Protistan Diversity.
Stramenopiles

17. Rhizaria Green algae Archaeplastida
Figure 28.3ab
Cercozoans
Forams
Radiolarians
Rhizaria
Red algae
Chlorophytes
Charophytes
Land plants
Green algae
Archaeplastida
Figure 28.3 Exploring: Protistan Diversity.

18. Slime molds Gymnamoebas Entamoebas Nucleariids Fungi Choanoflagellates
Figure 28.3ac
Slime molds
Gymnamoebas
Entamoebas
Nucleariids
Fungi
Choanoflagellates
Animals
Amoebozoans
Unikonta
Opisthokonts
Figure 28.3 Exploring: Protistan Diversity.

19. Giardia intestinalis, a diplomonad parasite
Figure 28.3b
5 m
Figure 28.3 Exploring: Protistan Diversity.
Giardia intestinalis, a diplomonad parasite

20. 50 m Diatom diversity Figure 28.3c
Figure 28.3 Exploring: Protistan Diversity.
Diatom diversity

21. Globigerina, a foram in the supergroup Rhizaria
Figure 28.3d
100 m
Figure 28.3 Exploring: Protistan Diversity.
Globigerina, a foram in the supergroup Rhizaria

22. Figure 28.3da
Figure 28.3 Exploring: Protistan Diversity.

23. Globigerina, a foram in the supergroup Rhizaria
Figure 28.3db
100 m
Figure 28.3 Exploring: Protistan Diversity.
Globigerina, a foram in the supergroup Rhizaria

24. Volvox, a colonial freshwater green alga
Figure 28.3e
20 m
50 m
Figure 28.3 Exploring: Protistan Diversity.
Volvox, a colonial freshwater green alga

25. Figure 28.3ea
20 m
Figure 28.3 Exploring: Protistan Diversity.

26. Volvox, a colonial freshwater green alga
Figure 28.3eb
50 m
Figure 28.3 Exploring: Protistan Diversity.
Volvox, a colonial freshwater green alga

27. A unikont amoeba 100 m Figure 28.3f
Figure 28.3 Exploring: Protistan Diversity.
100 m
A unikont amoeba

28. Concept 28.2: Excavates include protists with modified mitochondria and protists with unique flagella
The clade Excavata is characterized by its cytoskeleton
Some members have a feeding groove
This controversial group includes the diplomonads, parabasalids, and euglenozoans
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29. Diplomonads Excavata Parabasalids Kinetoplastids Euglenozoans
Figure 28.UN01
Diplomonads
Parabasalids
Excavata
Kinetoplastids
Euglenozoans
Euglenids
Chromalveolata
Rhizaria
Archaeplastida
Unikonta
Figure 28.UN01 In-text figure, p. 580

30. Diplomonads and Parabasalids
These two groups lack plastids, have modified mitochondria, and most live in anaerobic environments
Diplomonads
Have modified mitochondria called mitosomes
Derive energy from anaerobic biochemical pathways
Have two equal-sized nuclei and multiple flagella
Are often parasites, for example, Giardia intestinalis (also known as Giardia lamblia)
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31. Parabasalids
Have reduced mitochondria called hydrogenosomes that generate some energy anaerobically
Include Trichomonas vaginalis, the pathogen that causes yeast infections in human females
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32. Flagella 5 m Undulating membrane Figure 28.4
Figure 28.4 The parabasalid Trichomonas vaginalis (colorized SEM).
Undulating membrane

33. Euglenozoans
Euglenozoa is a diverse clade that includes predatory heterotrophs, photosynthetic autotrophs, and parasites
The main feature distinguishing them as a clade is a spiral or crystalline rod of unknown function inside their flagella
This clade includes the kinetoplastids and euglenids
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34. Flagella 0.2 m 8 m Crystalline rod (cross section)
Figure 28.5
Flagella
0.2 m
8 m
Crystalline rod
(cross section)
Figure 28.5 Euglenozoan flagellum.
Ring of microtubules
(cross section)

35. 0.2 m Crystalline rod (cross section) Ring of microtubules
Figure 28.5a
0.2 m
Crystalline rod
(cross section)
Figure 28.5 Euglenozoan flagellum.
Ring of microtubules
(cross section)

36. Kinetoplastids
Kinetoplastids have a single mitochondrion with an organized mass of DNA called a kinetoplast
They include free-living consumers of prokaryotes in freshwater, marine, and moist terrestrial ecosystems
This group includes Trypanosoma, which causes sleeping sickness in humans
Another pathogenic trypanosome causes Chagas’ disease
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37. Figure 28.6
Figure 28.6 Trypanosoma, the kinetoplastid that causes sleeping sickness.
9 m

38. Trypanosomes evade immune responses by switching surface proteins
A cell produces millions of copies of a single protein
The new generation produces millions of copies of a different protein
These frequent changes prevent the host from developing immunity
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39. Euglenids
Euglenids have one or two flagella that emerge from a pocket at one end of the cell
Some species can be both autotrophic and heterotrophic
Video: Euglena
Video: Euglena Motion
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40. Long flagellum Eyespot Short flagellum Light detector
Figure 28.7
Long flagellum
Eyespot
Short flagellum
Light detector
Contractile vacuole
Nucleus
Figure 28.7 Euglena, a euglenid commonly found in pond water.
Chloroplast
Plasma membrane
Pellicle
Euglena (LM)
5 m

41. Long flagellum Eyespot Contractile vacuole Nucleus Chloroplast
Figure 28.7a
Long flagellum
Eyespot
Contractile vacuole
Nucleus
Figure 28.7 Euglena, a euglenid commonly found in pond water.
Chloroplast
Plasma membrane
Euglena (LM)
5 m

42. Concept 28.3: Chromalveolates may have originated by secondary endosymbiosis
Some data suggest that the clade Chromalveolata is monophyletic and originated by a secondary endosymbiosis event
The proposed endosymbiont is a red alga
This clade is controversial and includes the alveolates and the stramenopiles
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43. Excavata Dinoflagellates Apicomplexans Alveolates Ciliates
Figure 28.UN02
Excavata
Dinoflagellates
Apicomplexans
Ciliates
Alveolates
Chromalveolata
Diatoms
Golden algae
Brown algae
Oomycetes
Stramenopiles
Figure 28.UN02 In-text figure, p. 582
Rhizaria
Archaeplastida
Unikonta

44. Alveolates
Members of the clade Alveolata have membrane-bounded sacs (alveoli) just under the plasma membrane
The function of the alveoli is unknown
The alveolates include
Dinoflagellates
Apicomplexans
Ciliates
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45. Figure 28.8
Flagellum
Alveoli
Alveolate
Figure 28.8 Alveoli.
0.2 m

46. Figure 28.8a
Flagellum
Alveoli
Figure 28.8 Alveoli.
0.2 m

47. Dinoflagellates
Dinoflagellates have two flagella and each cell is reinforced by cellulose plates
They are abundant components of both marine and freshwater phytoplankton
They are a diverse group of aquatic phototrophs, mixotrophs, and heterotrophs
Toxic “red tides” are caused by dinoflagellate blooms
Video: Dinoflagellate
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48. Figure 28.9
Flagella
Figure 28.9 Pfiesteria shumwayae, a dinoflagellate.
3 m

49. Apicomplexans
Apicomplexans are parasites of animals, and some cause serious human diseases
They spread through their host as infectious cells called sporozoites
One end, the apex, contains a complex of organelles specialized for penetrating host cells and tissues
Most have sexual and asexual stages that require two or more different host species for completion
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50. The apicomplexan Plasmodium is the parasite that causes malaria
Plasmodium requires both mosquitoes and humans to complete its life cycle
Approximately 900,000 people die each year from malaria
Efforts are ongoing to develop vaccines that target this pathogen
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51. Inside human Merozoite Liver Liver cell Apex Red blood cell Merozoite
Figure
Inside human
Merozoite
Liver
Liver cell
Apex
Red blood cell
Merozoite
(n)
0.5 m
Red blood cells
Figure The two-host life cycle of Plasmodium, the apicomplexan that causes malaria.
Key
Gametocytes
(n)
Haploid (n)
Diploid (2n)

52. Inside mosquito Inside human Merozoite Liver Liver cell Apex
Figure
Inside mosquito
Inside human
Merozoite
Liver
Liver cell
Apex
Red blood cell
Merozoite
(n)
0.5 m
Zygote
(2n)
Red blood cells
Figure The two-host life cycle of Plasmodium, the apicomplexan that causes malaria.
FERTILIZATION
Gametes
Key
Gametocytes
(n)
Haploid (n)
Diploid (2n)

53. Inside mosquito Inside human Merozoite Sporozoites (n) Liver
Figure
Inside mosquito
Inside human
Merozoite
Sporozoites
(n)
Liver
Liver cell
Oocyst
Apex
MEIOSIS
Red blood cell
Merozoite
(n)
0.5 m
Zygote
(2n)
Red blood cells
Figure The two-host life cycle of Plasmodium, the apicomplexan that causes malaria.
FERTILIZATION
Gametes
Key
Gametocytes
(n)
Haploid (n)
Diploid (2n)

54. Merozoite Apex Red blood cell 0.5 m Figure 28.10a
Figure The two-host life cycle of Plasmodium, the apicomplexan that causes malaria.
Red blood cell
0.5 m

55. Ciliates
Ciliates, a large varied group of protists, are named for their use of cilia to move and feed
They have large macronuclei and small micronuclei
Genetic variation results from conjugation, in which two individuals exchange haploid micronuclei
Conjugation is a sexual process, and is separate from reproduction, which generally occurs by binary fission
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56. (a) Feeding, waste removal, and water balance Key
Figure 28.11
Contractile vacuole
Oral groove
Cell mouth
Cilia
50 m
Micronucleus
Food vacuoles
Macronucleus
(a) Feeding, waste removal, and water balance
Key
Conjugation
Asexual reproduction
MEIOSIS
Haploid micronucleus
Diploid micronucleus
Compatible mates
Figure Structure and function in the ciliate Paramecium caudatum.
The original macronucleus disintegrates.
Diploid micronucleus
MICRONUCLEAR
FUSION
(b) Conjugation and reproduction

57. (a) Feeding, waste removal, and water balance
Figure 28.11a
Oral groove
Contractile vacuole
Cell mouth
Cilia
50 m
Micronucleus
Macronucleus
Figure Structure and function in the ciliate Paramecium caudatum.
Food vacuoles
(a) Feeding, waste removal, and water balance

58. (b) Conjugation and reproduction
Figure 28.11b-1
Compatible mates
MEIOSIS
Haploid micronucleus
Diploid micronucleus
Figure Structure and function in the ciliate Paramecium caudatum.
Key
Conjugation
Asexual reproduction
(b) Conjugation and reproduction

59. The original macronucleus disintegrates.
Figure 28.11b-2
Compatible mates
MEIOSIS
Haploid micronucleus
Diploid micronucleus
The original macronucleus disintegrates.
Diploid micronucleus
MICRONUCLEAR
FUSION
Figure Structure and function in the ciliate Paramecium caudatum.
Key
Conjugation
Asexual reproduction
(b) Conjugation and reproduction

60. Figure 28.11c
50 m
Figure Structure and function in the ciliate Paramecium caudatum.

61. Video: Paramecium Cilia
Video: Paramecium Vacuole
Video: Vorticella Cilia
Video: Vorticella Detail
Video: Vorticella Habitat
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62. Stramenopiles
The clade Stramenopila includes important phototrophs as well as several clades of heterotrophs
Most have a “hairy” flagellum paired with a “smooth” flagellum
Stramenopiles include diatoms, golden algae, brown algae, and oomycetes
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63. Hairy flagellum Smooth flagellum 5 m Figure 28.12
Figure Stramenopile flagella.
5 m

64. Diatoms
Diatoms are unicellular algae with a unique two-part, glass-like wall of hydrated silica
Diatoms usually reproduce asexually, and occasionally sexually
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65. Figure 28.13
Figure The diatom Triceratium morlandii (colorized SEM).
40 m

66. Diatoms are a major component of phytoplankton and are highly diverse
Fossilized diatom walls compose much of the sediments known as diatomaceous earth
After a diatom population has bloomed, many dead individuals fall to the ocean floor undecomposed
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67. This removes carbon dioxide from the atmosphere and “pumps” it to the ocean floor
Video: Diatoms Moving
Video: Various Diatoms
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68. Golden Algae
Golden algae are named for their color, which results from their yellow and brown carotenoids
The cells of golden algae are typically biflagellated, with both flagella near one end
All golden algae are photosynthetic, and some are mixotrophs
Most are unicellular, but some are colonial
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69. Flagellum Outer container Living cell 25 m Figure 28.14
Figure Dinobryon, a colonial golden alga found in fresh water (LM).
25 m

70. Brown Algae Brown algae are the largest and most complex algae
All are multicellular, and most are marine
Brown algae include many species commonly called “seaweeds”
Brown algae have the most complex multicellular anatomy of all algae
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71. Giant seaweeds called kelps live in deep parts of the ocean
The algal body is plantlike but lacks true roots, stems, and leaves and is called a thallus
The rootlike holdfast anchors the stemlike stipe, which in turn supports the leaflike blades
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72. Blade Stipe Holdfast Figure 28.15
Figure Seaweeds: adapted to life at the ocean’s margins.
Holdfast

73. Alternation of Generations
A variety of life cycles have evolved among the multicellular algae
The most complex life cycles include an alternation of generations, the alternation of multicellular haploid and diploid forms
Heteromorphic generations are structurally different, while isomorphic generations look similar
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74. The diploid sporophyte produces haploid flagellated spores called zoospores
The zoospores develop into haploid male and female gametophytes, which produce gametes
Fertilization of gamates results in a diploid zygote, which grows into a new sporophyte
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75. Key Haploid (n) Diploid (2n) Sporangia MEIOSIS 10 cm Sporophyte (2n)
Figure
Key
Haploid (n)
Diploid (2n)
Sporangia
MEIOSIS
10 cm
Sporophyte (2n)
Zoospore
Female
Figure The life cycle of the brown alga Laminaria: an example of alternation of generations.
Gametophytes
(n)
Male
Egg
Sperm

76. Developing sporophyte
Figure
Key
Haploid (n)
Diploid (2n)
Sporangia
MEIOSIS
10 cm
Sporophyte (2n)
Zoospore
Female
Developing sporophyte
Figure The life cycle of the brown alga Laminaria: an example of alternation of generations.
Gametophytes
(n)
Zygote (2n)
Male
Egg
Mature female gametophyte (n)
FERTILIZATION
Sperm

77. Figure 28.16a
Figure The life cycle of the brown alga Laminaria: an example of alternation of generations.
10 cm

78. Oomycetes (Water Molds and Their Relatives)
Oomycetes include water molds, white rusts, and downy mildews
They were once considered fungi based on morphological studies
Most oomycetes are decomposers or parasites
They have filaments (hyphae) that facilitate nutrient uptake
Their ecological impact can be great, as in potato blight caused by Phytophthora infestans
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79. Germ tube Cyst Hyphae ASEXUAL REPRODUCTION Zoospore (2n)
Figure
Germ tube
Cyst
Hyphae
ASEXUAL
REPRODUCTION
Zoospore (2n)
Zoosporangium (2n)
Key
Figure The life cycle of a water mold.
Haploid (n)
Diploid (2n)

80. Antheridial hypha with sperm nuclei
Figure
Germ tube
Oogonium
Egg nucleus
(n)
Cyst
Antheridial hypha with sperm nuclei
(n)
MEIOSIS
Hyphae
ASEXUAL
REPRODUCTION
Zoospore (2n)
Zoosporangium (2n)
Key
Figure The life cycle of a water mold.
Haploid (n)
Diploid (2n)

81. Antheridial hypha with sperm nuclei
Figure
Germ tube
Oogonium
Egg nucleus
(n)
Cyst
Antheridial hypha with sperm nuclei
(n)
MEIOSIS
Hyphae
ASEXUAL
REPRODUCTION
Zoospore (2n)
FERTILIZATION
Zygote germination
Zygotes
(oospores)
(2n)
SEXUAL
REPRODUCTION
Zoosporangium (2n)
Key
Figure The life cycle of a water mold.
Haploid (n)
Diploid (2n)

82. Figure 28.17a
Figure The life cycle of a water mold.

83. Video: Water Mold Oogonium
Video: Water Mold Zoospores
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84. Concept 28.4: Rhizarians are a diverse group of protists defined by DNA similarities
DNA evidence supports Rhizaria as a monophyletic clade
Amoebas move and feed by pseudopodia; some but not all belong to the clade Rhizaria
Rhizarians include radiolarians, forams, and cercozoans
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85. Excavata Chromalveolata Radiolarians Foraminiferans Rhizaria
Figure 28.UN03
Excavata
Chromalveolata
Radiolarians
Foraminiferans
Cercozoans
Rhizaria
Archaeplastida
Unikonta
Figure 28.UN03 In-text figure, p. 589

86. Radiolarians
Marine protists called radiolarians have tests fused into one delicate piece, usually made of silica
Radiolarians use their pseudopodia to engulf microorganisms through phagocytosis
The pseudopodia of radiolarians radiate from the central body
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87. Figure 28.18
Figure A radiolarian.
Pseudopodia
200 m

88. Forams
Foraminiferans, or forams, are named for porous, generally multichambered shells, called tests
Pseudopodia extend through the pores in the test
Foram tests in marine sediments form an extensive fossil record
Many forams have endosymbiotic algae
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89. Cercozoans
Cercozoans include most amoeboid and flagellated protists with threadlike pseudopodia
They are common in marine, freshwater, and soil ecosystems
Most are heterotrophs, including parasites and predators
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90. Paulinella chromatophora is an autotroph with a unique photosynthetic structure
This structure evolved from a different cyanobacterium than the plastids of other photosynthetic eukaryotes
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91. Chromatophore 5 m Figure 28.19
Figure A second case of primary endosymbiosis?
5 m

92. Concept 28.5: Red algae and green algae are the closest relatives of land plants
Over a billion years ago, a heterotrophic protist acquired a cyanobacterial endosymbiont
The photosynthetic descendants of this ancient protist evolved into red algae and green algae
Land plants are descended from the green algae
Archaeplastida is the supergroup that includes red algae, green algae, and land plants
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93. Excavata Chromalveolata Rhizaria Red algae Archaeplastida Chlorophytes
Figure 28.UN04
Excavata
Chromalveolata
Rhizaria
Red algae
Chlorophytes
Charophytes
Green algae
Archaeplastida
Figure 28.UN04 In-text figure, p. 590
Land plants
Unikonta

94. Red Algae
Red algae are reddish in color due to an accessory pigment called phycoerythrin, which masks the green of chlorophyll
The color varies from greenish-red in shallow water to dark red or almost black in deep water
Red algae are usually multicellular; the largest are seaweeds
Red algae are the most abundant large algae in coastal waters of the tropics
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95. Figure 28.20 Figure 28.20 Red algae. Bonnemaisonia hamifera 20 cm 8 mm
Dulse (Palmaria palmata)
Nori
Figure Red algae.

96. Bonnemaisonia hamifera 8 mm
Figure 28.20a
Figure Red algae.
Bonnemaisonia hamifera
8 mm

97. Dulse (Palmaria palmata) 20 cm
Figure 28.20b
Figure Red algae.
Dulse (Palmaria palmata)
20 cm

98. Figure 28.20c
Figure Red algae.
Nori

99. Figure 28.20d
Figure Red algae.
Nori

100. Figure 28.20e
Figure Red algae.
Nori

101. Green Algae Green algae are named for their grass-green chloroplasts
Plants are descended from the green algae
Green algae are a paraphyletic group
The two main groups are chlorophytes and charophyceans
Charophytes are most closely related to land plants
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102. Most chlorophytes live in fresh water, although many are marine
Other chlorophytes live in damp soil, as symbionts in lichens, or in snow
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103. Larger size and greater complexity evolved in chlorophytes by
The formation of colonies from individual cells
The formation of true multicellular bodies by cell division and differentiation (e.g., Ulva)
The repeated division of nuclei with no cytoplasmic division (e.g., Caulerpa)
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104. (b) Caulerpa, an intertidal chlorophyte
Figure 28.21
2 cm
(a) Ulva, or sea lettuce
Figure Multicellular chlorophytes.
(b) Caulerpa, an intertidal chlorophyte

105. 2 cm (a) Ulva, or sea lettuce Figure 28.21a
Figure Multicellular chlorophytes.
(a) Ulva, or sea lettuce

106. (b) Caulerpa, an intertidal chlorophyte
Figure 28.21b
Figure Multicellular chlorophytes.
(b) Caulerpa, an intertidal chlorophyte

107. Video: Volvox Daughter
Video: Volvox Colony
Video: Volvox Daughter
Video: Volvox Female Spheroid
Video: Volvox Flagella
Video: Volvox Inversion 1
Video: Volvox Inversion 2
Video: Volvox Sperm and Female
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108. Most chlorophytes have complex life cycles with both sexual and asexual reproductive stages
Video: Chlamydomonas
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109. Figure 28.22 
1 m
Flagella
Cell wall 
Gamete
(n)  
Nucleus
Zoospore
Mature cell
(n)
FERTILIZATION
Cross section of cup-shaped chloroplast
ASEXUAL
REPRODUCTION
SEXUAL
REPRODUCTION
Zygote
(2n)
(TEM)  
Figure The life cycle of Chlamydomonas, a unicellular chlorophyte.  
MEIOSIS
Key
Haploid (n)
Diploid (2n)

110. Zoospore Mature cell (n) ASEXUAL REPRODUCTION Key Haploid (n)
Figure 28.22a-1
Zoospore
Mature cell
(n)
ASEXUAL
REPRODUCTION
Figure The life cycle of Chlamydomonas, a unicellular chlorophyte.
Key
Haploid (n)
Diploid (2n)

111.   Gamete (n)   Zoospore FERTILIZATION Mature cell (n) ASEXUAL
Figure 28.22a-2  
Gamete
(n)  
Zoospore
FERTILIZATION
Mature cell
(n)
ASEXUAL
REPRODUCTION
SEXUAL
REPRODUCTION
Zygote
(2n)
Figure The life cycle of Chlamydomonas, a unicellular chlorophyte.    
MEIOSIS
Key
Haploid (n)
Diploid (2n)

112. Cross section of cup-shaped chloroplast
Figure 28.22b
1 m
Flagella
Cell wall
Nucleus
Cross section of cup-shaped chloroplast
Figure The life cycle of Chlamydomonas, a unicellular chlorophyte.
(TEM)

113. Concept 28.6: Unikonts include protists that are closely related to fungi and animals
The supergroup Unikonta includes animals, fungi, and some protists
This group includes two clades: the amoebozoans and the opisthokonts (animals, fungi, and related protists)
The root of the eukaryotic tree remains controversial
It is unclear whether unikonts separated from other eukaryotes relatively early or late
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114. Excavata Chromalveolata Rhizaria Archaeplastida Amoebozoans
Figure 28.UN05
Excavata
Chromalveolata
Rhizaria
Archaeplastida
Amoebozoans
Nucleariids
Fungi
Unikonta
Figure 28.UN05 In-text figure, p. 593
Choanoflagellates
Animals

115. Common ancestor of all eukaryotes
Figure 28.23
RESULTS
Choanoflagellates
Animals
Fungl
Amoebozoans
Unikonta
Common ancestor of all eukaryotes
Diplomonads
Excavata
Euglenozoans
Alveolates
Stramenopiles
Rhizarians
Chromalveolata
Figure Inquiry: What is the root of the eukaryotic tree?
DHFR-TS gene fusion
Rhizaria
Red algae
Green algae
Archaeplastida
Plants

116. Amoebozoans
Amoebozoans are amoeba that have lobe- or tube-shaped, rather than threadlike, pseudopodia
They include slime molds, gymnamoebas, and entamoebas
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117. Slime Molds Slime molds, or mycetozoans, were once thought to be fungi
Molecular systematics places slime molds in the clade Amoebozoa
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118. Plasmodial Slime Molds
Many species of plasmodial slime molds are brightly pigmented, usually yellow or orange
Video: Plasmodial Slime Mold
Video: Plasmodial Slime Mold Streaming
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119. Figure 28.24 The life cycle of a plasmodial slime mold.
4 cm
FERTILIZATION
Zygote
(2n)
Feeding plasmodium
Mature plasmodium (preparing to fruit)
Young sporangium
Amoeboid cells
(n)
Flagellated cells
(n)
Mature sporangium
Germinating spore
Figure The life cycle of a plasmodial slime mold.
Spores
(n)
MEIOSIS
1 mm
Stalk
Key
Haploid (n)
Diploid (2n)

120. Mature plasmodium (preparing to fruit)
Figure 28.24a-1
Feeding plasmodium
Mature plasmodium (preparing to fruit)
Young sporangium
Mature sporangium
Figure The life cycle of a plasmodial slime mold.
Key
Stalk
Haploid (n)
Diploid (2n)

121. Mature plasmodium (preparing to fruit)
Figure 28.24a-2
Feeding plasmodium
Mature plasmodium (preparing to fruit)
Young sporangium
Amoeboid cells
(n)
Flagellated cells
(n)
Mature sporangium
Germinating spore
Spores
(n)
Figure The life cycle of a plasmodial slime mold.
MEIOSIS
Key
Stalk
Haploid (n)
Diploid (2n)

122. Mature plasmodium (preparing to fruit)
Figure 28.24a-3
FERTILIZATION
Feeding plasmodium
Zygote
(2n)
Mature plasmodium (preparing to fruit)
Young sporangium
Amoeboid cells
(n)
Flagellated cells
(n)
Mature sporangium
Germinating spore
Spores
(n)
Figure The life cycle of a plasmodial slime mold.
MEIOSIS
Key
Stalk
Haploid (n)
Diploid (2n)

123. Figure 28.24b
Figure The life cycle of a plasmodial slime mold.
4 cm

124. Figure 28.24c
Figure The life cycle of a plasmodial slime mold.
1 mm

125. The plasmodium is not multicellular
At one point in the life cycle, plasmodial slime molds form a mass called a plasmodium (not to be confused with malarial Plasmodium)
The plasmodium is not multicellular
It is undivided by plasma membranes and contains many diploid nuclei
It extends pseudopodia through decomposing material, engulfing food by phagocytosis
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126. Cellular Slime Molds
Cellular slime molds form multicellular aggregates in which cells are separated by their membranes
Cells feed individually, but can aggregate to form a fruiting body
Dictyostelium discoideum is an experimental model for studying the evolution of multicellularity
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127. Spores (n) Emerging amoeba (n) Solitary amoebas (n) 600 m ASEXUAL
Figure
Spores (n)
Emerging amoeba (n)
Solitary amoebas (n)
600 m
Fruiting bodies (n)
ASEXUAL
REPRODUCTION
Aggregated amoebas
Migrating aggregate
Figure The life cycle of Dictyostelium, a cellular slime mold.
200 m
Key
Haploid (n)
Diploid (2n)

128. Spores (n) Emerging amoeba (n) Zygote (2n) SEXUAL REPRODUCTION
Figure
Spores (n)
FERTILIZATION
Emerging amoeba (n)
Zygote (2n)
SEXUAL
REPRODUCTION
Solitary amoebas (n)
600 m
MEIOSIS
Amoebas (n)
Fruiting bodies (n)
ASEXUAL
REPRODUCTION
Aggregated amoebas
Migrating aggregate
Figure The life cycle of Dictyostelium, a cellular slime mold.
200 m
Key
Haploid (n)
Diploid (2n)

129. Figure 28.25a
Figure The life cycle of Dictyostelium, a cellular slime mold.
600 m

130. Figure 28.25b
Figure The life cycle of Dictyostelium, a cellular slime mold.
200 m

131. Gymnamoebas
Gymnamoebas are common unicellular amoebozoans in soil as well as freshwater and marine environments
Most gymnamoebas are heterotrophic and actively seek and consume bacteria and other protists
Video: Amoeba
Video: Amoeba Pseudopodia
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132. Entamoebas
Entamoebas are parasites of vertebrates and some invertebrates
Entamoeba histolytica causes amebic dysentery, the third-leading cause of human death due to eukaryotic parasites
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133. Opisthokonts
Opisthokonts include animals, fungi, and several groups of protists
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134. Concept 28.7: Protists play key roles in ecological communities
Protists are found in diverse aquatic environments
Protists often play the role of symbiont or producer
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135. Symbiotic Protists Some protist symbionts benefit their hosts
Dinoflagellates nourish coral polyps that build reefs
Wood-digesting protists digest cellulose in the gut of termites
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136. Figure 28.26
Figure A symbiotic protist.
10 m

137. Some protists are parasitic
Plasmodium causes malaria
Pfiesteria shumwayae is a dinoflagellate that causes fish kills
Phytophthora ramorum causes sudden oak death
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138. Photosynthetic Protists
Many protists are important producers that obtain energy from the sun
In aquatic environments, photosynthetic protists and prokaryotes are the main producers
In aquatic environments, photosynthetic protists are limited by nutrients
These populations can explode when limiting nutrients are added
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139. Prokaryotic producers
Figure 28.27
Other consumers
Herbivorous plankton
Carnivorous plankton
Figure Protists: key producers in aquatic communities.
Protistan producers
Prokaryotic producers

140. Biomass of photosynthetic protists has declined as sea surface temperature has increased
If sea surface temperature continues to warm due to global warming, this could have large effects on
Marine ecosystems
Fishery yields
The global carbon cycle
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141. Figure 28.28
In regions between the black lines, a layer of warm water rests on top of colder waters.
Growth
Growth
Higher
Lower
SST
Figure Impact: Marine Protists in a Warmer World.
In the yellow regions, high SSTs increase the temperature differences between warm and cold waters, which reduces upwelling.

142. Figure 28.UN06
Figure 28.UN06 Summary table, Concepts 28.2–28.6

143. Figure 28.UN06a
Figure 28.UN06a Summary table, Concepts 28.2–28.3

144. Figure 28.UN06b
Figure 28.UN06b Summary table, Concepts 28.4–28.6

145. Figure 28.UN07
Figure 28.UN07 Appendix A: answer to Concept Check 28.1, question 3

146. Figure 28.UN08
Figure 28.UN08 Appendix A: answer to Test Your Understanding, question 7