Deck 28: Protists

A) increase the dosage of the least-expensive antimalarial drug administered to humans.
B) increase the dosage of the most common pesticide used to kill Anopheles mosquitoes.
C) introduce a predator of the malarial parasite into infected humans.
D) use a "cocktail" of at least three different pesticides against Anopheles mosquitoes.
E) insert genes from a Plasmodium-resistant strain of mosquito into Anopheles mosquitoes.

A) from infoldings of the plasma membrane, coupled with mutations of genes for proteins in energy-transfer reactions
B) from engulfed, originally free-living proteobacteria
C) by secondary endosymbiosis
D) from the nuclear envelope folding outward and forming mitochondrial membranes
E) when a protoeukaryote engaged in a symbiotic relationship with a protocell

A) the presence of filamentous feeding structures
B) zoospores that are spread by breezes
C) the same nutritional mode as possessed by cyanobacteria
D) a morphological similarity to fungi that is the result of common ancestry
E) a feeding Plasmodium

A) Many species within this kingdom were once classified as monerans.
B) Animals, plants, and fungi arose from different protist ancestors.
C) The eukaryotic condition has evolved more than once among the protists.
D) Chloroplasts among various protists are similar to those found in prokaryotes.
E) Some protists, all animals, and all fungi share a protist common ancestor, but these protists, animals, and fungi are currently assigned to three different kingdoms.

A) cyanobacteria → green algae → land plants
B) cyanobacteria → green algae → fungi → land plants
C) red algae → brown algae → green algae → land plants
D) cyanobacteria → red algae → green algae → land plants

A) thalli
B) bladders
C) holdfasts
D) gel-forming polysaccharides

A) They use pseudopods as locomotory structures or as feeding structures.
B) They are relatively specialized cells.
C) They can exchange genetic material with other ciliates by the process of mitosis.
D) Most live as solitary autotrophs in fresh water.
E) They are often multinucleate.

A) conjugation
B) horizontal gene transfer
C) binary fission
D) phagocytosis
E) meiosis

A) How does carbon dioxide get into these protists with their glasslike valves?
B) How do diatoms get transported from one location on the water's surface layers to another location on the surface?
C) How do diatoms with their glasslike valves keep from sinking into poorly lit waters?
D) How do diatoms with their glasslike valves avoid being shattered by the action of waves?
E) How do diatom sperm cells locate diatom egg cells?

A) unicellular.
B) eukaryotic.
C) symbionts.
D) monophyletic.
E) mixotrophic.

A) apicomplexans-internal parasites
B) golden algae-planktonic producers
C) euglenozoans-unicellular flagellates
D) ciliates-red tide organisms
E) entamoebas-ingestive heterotrophs

A) They possess two flagella.
B) All known varieties are autotrophic.
C) Their walls are usually composed of silica plates.
D) Many types lack mitochondria.
E) Their dead cells accumulate on the seafloor, and are mined to serve as a filtering material.

A) Water molds evolved from filamentous fungi.
B) Body shape reflects ancestor-descendant relationships among organisms.
C) In both cases, filamentous shape is an adaptation for the absorptive nutritional mode of a decomposer.
D) Filamentous body shape is evolutionarily ancestral for all eukaryotes.
E) Both the first and second responses above are correct.

A) It relies on photosystems that float freely in its cytosol.
B) It must have gained extra mitochondria when it lost its plastids.
C) It engulfs organic material by phagocytosis or by absorption.
D) It has an endospore.
E) It is protected by a case made of silica.

A) 1 and 2
B) 1 and 4
C) 2 and 3
D) 2 and 4
E) 4 and 5

A) foraminiferans
B) radiolarians
C) ciliates
D) kinetoplastids
E) slime molds

A) budding
B) meiotic division
C) mitotic division
D) conjugation
E) binary fission

A) radiolarians and forams
B) gymnamoebas
C) entamoebas
D) amoeboid stage of cellular slime molds
E) oomycetes

A) diatoms
B) foraminiferans
C) radiolarians
D) gymnamoebas

A) red
B) green
C) brown
D) yellow

A) oomycete
B) kinetoplastid
C) apicomplexan
D) diatom
E) radiolarian

A) The coral animals, which capture planktonic organisms, may be outcompeted by the diatoms.
B) The coral animals' endosymbiotic dinoflagellates may get "shaded out" by the diatoms.
C) The coral animals may die from overeating the plentiful diatoms, with their cases of silica.
D) The diatoms' photosynthetic output may over-oxygenate the water.

A) Paramecium.
B) Navicula (diatom).
C) Pfiesteria (dinoflagellate).
D) Entamoeba.
E) Plasmodium.

A) mid-winter
B) early spring
C) late summer
D) late fall

A) cellulose-digesting gut protists-wood-eating termites
B) dinoflagellates-reef-building coral animals
C) Trichomonas-humans
D) algae-certain foraminiferans
E) all except that involving humans

A) diatom.
B) dinoflagellate.
C) apicomplexan.
D) red alga.
E) radiolarian.

A) It would be polyphyletic.
B) It would be paraphyletic.
C) It would be monophyletic.
D) It would include all eukaryotes.

A) All protists have mitochondria, though in some species they are much reduced and known by different names.
B) The primary organism that transmits malaria to humans by its bite is the tsetse fly.
C) All apicomplexans are autotrophic.
D) All slime molds have an amoeboid stage that may be followed by a stage during which spores are produced.
E) Euglenozoans that are mixotrophic lack functional chloroplasts.

A) 1 and 2
B) 2 and 3
C) 2 and 4
D) 3 and 4
E) 4 and 5

A) Paramecium.
B) Navicula (diatom).
C) Pfiesteria (dinoflagellate).
D) Entamoeba.
E) Plasmodium.

A) DNA sequences.
B) nutritional modes.
C) choice of habitats.
D) physical appearance.
E) reproductive methods.

A) pseudopods
B) apical complex
C) excavated feeding grooves
D) nucleomorphs
E) mitosomes

A) Paramecium.
B) Navicula (diatom).
C) Pfiesteria (dinoflagellate).
D) Entamoeba.
E) Plasmodium.

A) are heterotrophs.
B) are unicellular.
C) have plastids.
D) have alternation of generations.
E) have cell walls containing cellulose.

A) prokaryotic or eukaryotic
B) unicellular or multicellular
C) diploid or haploid
D) autotroph or heterotroph

A) It will be monophyletic.
B) It will more accurately depict evolutionary relationships than does the current taxonomy.
C) It will be paraphyletic.
D) It will be a true clade.
E) It will be polyphyletic.

A) red algae
B) brown algae
C) green algae
D) dinoflagellates
E) golden algae

A) golden algae.
B) diatoms.
C) dinoflagellates.
D) green algae.
E) brown algae.

A) Paramecium.
B) Navicula (diatom).
C) Pfiesteria (dinoflagellate).
D) Entamoeba.
E) Plasmodium.

A) This finding indicates that there is a second evolutionary lineage of photosynthetic eukaryotes.
B) This finding represents the first time that primary endosymbiosis has been directly observed.
C) This finding is the strongest evidence yet for the theory of endosymbiosis.
D) This finding is an example of the phenomenon known as "serial endosymbiosis."
E) This finding is the first evidence that eukaryotic cells do not necessarily digest prokaryotic cells that manage to gain access to their cytoplasm.

A) 5; 5
B) 5; 10
C) 10; 10
D) 10; 20
E) 20; 20

A) 1 only
B) 1 and 2
C) 2 and 3
D) 2 and 4
E) 2, 3, and 4

A) morphological
B) ecological
C) biochemical
D) genetic
E) fossil

A) mitochondria of ancestral diplomonads.
B) nuclei of archaeans.
C) endospores of bacteria.
D) capsids of viruses.

A) 1, 3, and 5
B) 1, 4, and 5
C) 2, 3, and 6
D) 2, 4, and 5
E) 2, 4, and 6

A) peptidoglycan.
B) mitochondria or mitosomes.
C) anaerobic metabolic pathways.
D) nuclear envelopes.
E) microtubules.

A) If P. chromatophora is less fit without its cyanelle than with it.
B) If the cyanelle is less fit without the host cercozoan than with it.
C) If there is ongoing metabolic cooperation between the cyanelle and the host cercozoan.
D) If the magnesium-containing porphyrin ring in the cyanelle's chlorophyll molecules is built by the cyanelle, whereas the organic portion of the chlorophyll molecules is built by the host cercozoan.
E) If there has been movement of genes from the cyanelle genome to the nuclear genome, such that these genes are no longer present in the cyanelle genome.

A) are thickest, and laminarin is being produced rather than oil.
B) are thickest, and oil is being produced rather than laminarin.
C) are thinnest, and laminarin is being produced rather than oil.
D) are thinnest, and oil is being produced rather than laminarin.

A) It has electron transport systems that use oxygen as the final electron acceptor.
B) It has a double membrane.
C) It has thylakoids.
D) It contains microtubules, arranged in the "9 + 2 pattern."
E) It contains 80S (eukaryotic) ribosomes.

A) a threadlike pseudopod
B) a pigmented central vacuole, surrounded by a tonoplast
C) a vacuole with food inside
D) a secretory vesicle
E) a contractile vacuole

A) radiolarians
B) foraminiferans
C) all other amoeboid cells
D) all other rhizaria
E) diatoms

A) 1 and 2
B) 1 and 3
C) 2 and 3
D) 1, 2, and 4
E) 2, 3, and 4

A) its mitosomes.
B) endosymbiotic cyanobacteria.
C) the ventral disk by which it adheres to the intestinal lining.
D) osmosis involving aquaporins.
E) plasma membrane proteins that are transporters or pumps.

A) cold fresh water
B) warm fresh water
C) cold seawater
D) warm seawater
E) warm brackish water

A) plasmids; conjugation
B) plasmids; transformation
C) nucleus; horizontal gene transfer
D) nucleus; S phase

A) Robert Koch.
B) Robert Hooke.
C) Isaac Newton.
D) van Leeuwenhoek.
E) Louis Pasteur.

A) nucleus; archaean
B) nucleus; bacterium
C) mitochondrion; proteobacterium
D) mitochondrion; spirochete
E) chloroplast; cyanobacterium

A) 1 only
B) 3 only
C) 1 and 2
D) 1 and 3
E) 2 and 3

A) Lytic phage infections have targeted the chloroplast genome more often than the P. chromatophora genome.
B) P. chromatophora's cyanelle is the result of an evolutionarily recent endosymbiosis.
C) The genome of the chloroplast ancestor contained many more introns that could be lost without harm, compared to the cyanelle's genome.
D) All three of the conclusions above are valid.
E) Two of the conclusions above are valid.

A) positive chemotaxis
B) negative chemotaxis
C) positive phototaxis
D) negative phototaxis

A) rhizarians-morphologically diverse group defined by DNA similarities
B) diatoms-important producers in aquatic communities
C) red algae-acquired plastids by secondary endosymbiosis
D) apicomplexans-parasites with intricate life cycles
E) diplomonads-protists with modified mitochondria

A) parasitic
B) commensalistic
C) toxic
D) predator-prey
E) mutualistic

A) evolution from mitochondria.
B) fusion of plastids.
C) origin of the plastids from archaea.
D) secondary endosymbiosis.
E) budding of the plastids from the nuclear envelope.

A) mutualistic
B) commensal
C) parasitic
D) predatory
E) pathogenic

A) unicellular haploid forms.
B) unicellular diploid forms.
C) multicellular haploid forms.
D) multicellular diploid forms.
E) multicellular polyploid forms.

A) the products of photosynthesis could not be metabolized without mitochondrial enzymes.
B) all eukaryotes have mitochondria (or their remnants), whereas many eukaryotes do not have plastids.
C) mitochondrial DNA is less similar to prokaryotic DNA than is plastid DNA.
D) without mitochondrial CO₂ production, photosynthesis could not occur.
E) mitochondrial proteins are synthesized on cytosolic ribosomes, whereas plastids utilize their own ribosomes.

A) two; innermost
B) two; outermost
C) three; innermost
D) three; middle
E) three; outermost

A) green algae
B) dinoflagellates
C) red algae
D) brown algae
E) both green algae and red algae

A) If the cyanelle performs aerobic photosynthesis.
B) If the vesicle membrane that surrounds each cyanelle possesses glucose-transport proteins.
C) If the cyanelle performs aerobic respiration.
D) If radiolabeled ¹⁴CO₂ enters the cyanelle and if, subsequently, radiolabeled glucose is present in cercozoan cytosol.
E) If radiolabeled "heavy" water, ²H₂O, enters the cyanelle and if, subsequently, radiolabeled oxygen appears in cercozoan cytosol.

A) pseudopods.
B) a single flagellum composed of the protein, flagellin.
C) a single flagellum featuring the 9 + 2 pattern.
D) many cilia.
E) contractile vacuoles.

A) 1 only
B) 1 and 2
C) 1, 2, and 3
D) 1, 2, and 4
E) 2, 3, and 4

A) reciprocal mutations in the cyanelle and nuclear genomes.
B) horizontal gene transfer from bacterium to eukaryotes.
C) genetic recombination involving a protist and an archaean.
D) the origin of photosynthesis in protists.
E) transduction by a phage that infects both prokaryotes and eukaryotes.

A) photoautotroph
B) photoheterotroph
C) chemoheterotroph
D) chemoautotroph
E) mixotroph

A) abundant light, no bacterial prey
B) abundant light, abundant bacterial prey
C) no light, no bacterial prey
D) no light, abundant bacterial prey

A) The zoochlorellae also reproduced asexually, at an increasing rate over time.
B) The zoochlorellae also reproduced asexually, at a decreasing rate over time.
C) The zoochlorellae also reproduced asexually, at a fairly constant rate over time.
D) The zoochlorellae reproduced sexually, undergoing heteromorphic alternation of generations.
E) The zoochlorellae reproduced sexually, undergoing isomorphic alternation of generations.