Deck 28: Plants in the Environment

A) specific immunity.
B) constitutive defenses.
C) hypersensitive response.
D) systemic acquired resistance.
E) gene-for-gene resistance.

A) R proteins trigger specific immune responses.
B) PR proteins signal cells that have not yet been attacked.
C) Effector binds to cytoplasmic receptor (R protein)inside the cell.
D) Signaling molecules in the cell trigger production of defensive molecules.
E) Substances are produced to strengthen the cell wall and block plasmodesmata.

A) have both general and specific immunity.
B) have protective structures and substances on their outer surfaces.
C) have receptors that recognize molecules produced by pathogens.
D) produce molecules that deter both pathogens and predators.
E) produce specific recognition molecules for many different pathogens.

A) lenticels.
B) root system.
C) outer surface.
D) apical meristem.
E) vascular system.

A) Nitric oxide
B) siRNAs
C) Jasmonic acid
D) Phytoalexins
E) Hydrogen peroxide

A) general immunity.
B) gene-for-gene resistance.
C) a hypersensitive response.
D) systemic acquired resistance.
E) a pathogen associated molecular pattern.

A) Virus
B) Fungus
C) Bacterium
D) Protozoan
E) Herbivore

A) cannot fight off a pathogen.
B) has been killed by a pathogen.
C) has prevented a pathogen from spreading.
D) has successfully fought off a pathogen.
E) has stopped a pathogen,but only temporarily.

A) a resistance (R)gene in the susceptible soybean.
B) a resistance (R)gene in an unsusceptible organism.
C) an avirulence (Avr)gene in the soybean.
D) an avirulence (Avr)gene in an unsusceptible organism.
E) an avirulence (Avr)gene in the bacterial pathogen.

A) PAMP.
B) receptor protein.
C) cytoskeletal protein.
D) effector protein.
E) transporter protein.

A) PR protein
B) Salicylic acid
C) Phytoalexin
D) Nitric oxide
E) Hydrogen peroxide

A) cutin.
B) wax.
C) suberin.
D) elicitors.
E) cell walls.

A) Virus
B) Fungus
C) Protist
D) Bacterium
E) Herbivore

A) It is triggered by a PAMP.
B) It can never be genetically determined.
C) It is activated when constitutive defenses fail.
D) It is the first line of defense against pathogens.
E) It is always present and can be initiated at any time.

A) Only specific immunity requires activation by a trigger.
B) Only specific immunity involves changes in gene expression.
C) General immunity is much stronger than specific immunity.
D) General immunity is triggered by proteins;specific immunity is triggered by lipids or phospholipids.
E) General immunity responds to entire groups of pathogens;specific immunity responds to individual pathogens.

A) PAMP;general
B) PAMP;specific
C) effector;general
D) effector;specific
E) receptor;specific

A) A PAMP gene
B) An avirulence (Avr)gene
C) A resistance (R)gene
D) A pathogenesis-related (PR)gene
E) A gene coding for a phytoalexin synthetase

A) Lignin
B) Chitin
C) Avr gene
D) Flagellin
E) siRNA

A) elicitor.
B) immune system.
C) evoked defense.
D) induced defense.
E) constitutive defense.

A) Trichomes
B) Canavanine
C) Production of jasmonic acid
D) Change in cell membrane potential
E) Secondary metabolite that inhibits development

A) speeding up the plant's immune responses.
B) turning off the production of PR proteins.
C) stimulating immune responses in neighboring plants.
D) stimulating immune responses in other parts of the plant.
E) providing a unique form of immunity that is neither constitutive nor induced.

A) is a small molecule.
B) mimics insect hormone actions.
C) damages the nervous systems of herbivores.
D) is released when herbivores damage the plant.
E) is used for basic plant functions such as respiration and synthesis.

A) resistant only to that pathogen.
B) resistant to all pathogens.
C) susceptible only to that pathogen.
D) susceptible to all pathogens.
E) able to trigger the hypersensitive response.

A) a neurotoxic response or inhibited respiration.
B) a neurotoxic response or a change in membrane potential.
C) release of a chemical elicitor or a change in membrane potential.
D) release of a secondary metabolite or release of a chemical elicitor.
E) a response to trichomes or other surface structures or release of a chemical elicitor.

A) Birds
B) Insects
C) Reptiles
D) Mammals
E) Amphibians

A) necrotic lesions.
B) a constitutive defense.
C) a hypersensitive response.
D) systemic acquired resistance.
E) a response to herbivores.

A) cause most of their damage by physically feeding on plants.
B) are all generalists,feeding on many different types of plants.
C) cause most of their damage by producing secondary metabolites.
D) are all specialists,feeding on only one type of plant.
E) cannot be controlled by constitutive or induced defenses.

A) inhibit respiration.
B) act as a neurotoxin.
C) alter protein structure.
D) deter insects from feeding.
E) damage the digestive tract.

A) only acts against viruses.
B) affects only a small region of the plant.
C) begins with the production of salicylic acid.
D) uses apoptosis as a major mechanism of action.
E) only acts on the pathogen that originally triggered it.

A) Transport of phytoalexins to all parts of the plant
B) Death of cells near the infection
C) Synthesis of polysaccharides to seal off the infection
D) Death of infected cells
E) Production of phytoalexins by cells around the infection

A) The response relies on chemicals that are already present in the plant.
B) The response relies on chemical signals,which are always rapid.
C) The response relies on an elicitor,which can be made quickly.
D) The membrane is the cell structure closest to the environment.
E) Both b and c

A) recombinant DNA;viruses
B) RNA degradation;bacteria
C) RNA interference;viruses
D) RNA interference;bacteria
E) RNA degradation;both viruses and bacteria

A) plant;form mechanical barriers
B) plant;become immune to the virus
C) virus;die from a viral infection
D) virus;form mechanical barriers
E) virus;become immune to the virus

A) salicylic acid.
B) PR inducer.
C) phytoalexin.
D) cellulose.
E) chitin.

A) It is a plant hormone.
B) Its production is stimulated by elicitors.
C) It is part of the signal transduction pathway.
D) It is part of the plant's "chemical warfare" defenses.
E) It triggers production of volatile compounds that attract predatory insects.

A) R gene.
B) tRNA.
C) T gene.
D) detector.
E) Avr gene.

A) primary metabolites and constitutive defenses.
B) secondary metabolites and constitutive defenses.
C) primary metabolites and induced defenses.
D) secondary metabolites and induced defenses.
E) secondary metabolites and mechanical defenses.

A) Hormonal treatment to delay metamorphosis
B) Hormonal treatment to accelerate metamorphosis
C) RNA interference to stop production of improper proteins
D) Genetic engineering to add an enzyme enabling its tRNA to distinguish between arginine and canavanine
E) Genetic engineering to add an enzyme enabling its tRNA to distinguish between lecuine and canavanine

A) greater resistance to herbivores.
B) less resistance to herbivores.
C) more jasmonic acid.
D) better nervous system function.
E) greater tolerance to insecticides.

A) Many carry out basic plant functions.
B) They have a variety of effects on animals.
C) There are more than 10,000 known types.
D) They vary in size,but most are small molecules.
E) Some are produced by a single species,while others are produced by many different plants.

A) become toxic to most herbivores.
B) carry out alcoholic fermentation.
C) avoid the toxic effects of sodium.
D) extract water from the soil by osmosis.
E) initiate a signaling pathway to close stomata.

A) Heat
B) Cold
C) Drought
D) Saturation
E) High heavy metal concentrations

A) Production of protease inhibitors would decrease.
B) Elicitors would bind to receptors less readily.
C) Elicitors would bind to receptors more readily.
D) Production of protease inhibitors would increase.
E) Jasmonate production would decrease.

A) dissolving the cyanide in waxes.
B) storing the cyanide in separate vacuoles.
C) storing the cyanide in the intercellular spaces.
D) modifying the cyanide so it is only toxic outside the plant cell.
E) storing the cyanide precursor separately from its activating enzyme.

A) A deep taproot
B) Airborne roots
C) Fleshy leaves
D) Proline accumulation
E) A shallow but extensive root system

A) trichomes.
B) fleshy leaves.
C) pneumatophores.
D) shallow but extensive roots.
E) high concentrations of proline.

A) Receptor-elicitor binding,binding of jasmonate to JAZ,traveling of jasmonate through plasmodesmata,increased expression of protease inhibitor
B) Receptor-elicitor binding,binding of jasmonate to JAZ,increased expression of protease inhibitor,traveling of jasmonate through plasmodesmata
C) Receptor-elicitor binding,traveling of jasmonate through plasmodesmata,binding of jasmonate to JAZ,increased expression of protease inhibitor
D) Traveling of jasmonate through plasmodesmata,receptor-elicitor binding,binding of jasmonate to JAZ,increased expression of protease inhibitor
E) Traveling of jasmonate through plasmodesmata,receptor-elicitor binding,increased expression of protease inhibitor,binding of jasmonate to JAZ

A) Latex-producing plants have high survival rates.
B) Many insects do not feed on latex-producing plants.
C) Latex-producing plants release latex when their leaves are damaged.
D) Beetles that cut veins in the leaves can then feed on the released latex.
E) Beetles that drain latex out of part of a leaf can then feed on the drained part.

A) Spines
B) Fleshy leaves
C) Dense epidermal hairs
D) Pneumatophores
E) Stomata in sunken cavities

A) compartmentalizing the ricins.
B) storing the ricins on the plant surface.
C) storing the ricins in the plasma membrane.
D) both compartmentalizing the ricins and storing them as precursors.
E) both storing the ricins in the plasma membrane and storing them as precursors.

A) storing the latex in tubelike laticifers that empty into xylem tubes.
B) storing the latex in tubelike laticifers that empty into phloem tubes.
C) storing the latex in tubelike laticifers that run along the veins.
D) only synthesizing chemicals to store in latex when they are needed.
E) allowing the latex to leak out when it begins to poison the plant.

A) Marsh
B) Desert
C) Temperate evergreen forest
D) Area with very cold temperatures
E) Area with high mercury concentration

A) laticifers are always effective as plant defenses.
B) laticifers are always ineffective as plant defenses.
C) these beetles have learned to bypass an effective plant defense.
D) these beetles are able to overcome the toxicity of chemicals in latex.
E) milkweeds are unable to protect themselves from their own poisons.

A) succulence.
B) drought avoidance.
C) drought hardening.
D) hyperaccumulation.
E) solute accumulation.

A) Herbivory lasts longer than accidental injury.
B) Herbivory is more damaging than accidental injury.
C) Herbivores release chemicals that mimic plant reactions.
D) Herbivores cause mechanical damage;accidental injury does not.
E) Herbivores release elicitors in their saliva,triggering plant reactions.

A) vacuoles.
B) chloroplasts.
C) Golgi bodies.
D) cell membranes.
E) epidermal waxes.

A) Desert
B) Salt marsh
C) Grazed field
D) Freshwater marsh
E) Recently mined area

A) Heat
B) Cold
C) High salinity
D) Slow growth rates
E) Low oxygen concentration

A) A pigment that provides color for flowers
B) A volatile compound that acts as an insect neurotoxin
C) A substance produced as a byproduct of respiration
D) A volatile compound that attracts pollinators
E) An essential oil with a pleasant odor that attracts insects

A) excess water.
B) limited water.
C) limited nutrients.
D) high salt concentrations.
E) high heavy metal concentrations.

A) It stores oxygen.
B) It stores water.
C) It aids in buoyancy.
D) It has a low metabolic rate.
E) It diffuses oxygen to the rest of plant.

A) dehydration.
B) punctured organelles.
C) punctured cell membranes.
D) formation of ice crystals.
E) denaturation of proteins.

A) has spines.
B) has trichomes.
C) is a succulent.
D) has periods of dormancy.
E) has stomatal crypts.

A) determine if fish genes can survive in plants.
B) produce a rice plant that grows at colder temperatures.
C) produce a rice plant that speeds up the growth of ice crystals in freezing weather.
D) produce a rice plant that undergoes cold-hardening more quickly.
E) produce a rice plant that is more suitable for high temperature ranges.

A) jasmonic acid;abscisic acid
B) abscisic acid;jasmonic acid
C) LEA proteins;abscisic acid
D) abscisic acid;LEA proteins
E) LEA proteins;jasmonic acid

A) Tannins
B) Nicotine
C) Jasmonate
D) Canavanine
E) LEA proteins

A) flowers.
B) leaves.
C) roots.
D) spines.
E) stems.

A) Proline
B) Kinases
C) Nucleases
D) Antifreeze proteins
E) Chaperonins

A) decreased drought stress.
B) decreased heat stress.
C) increased drought stress.
D) increased heat stress.
E) decreased heavy metal concentrations.

A) High temperatures
B) Heavy metals
C) Low temperatures
D) Herbivores
E) High salt concentrations

A) Saline
B) Arctic
C) Desert
D) Swampy
E) Temperate

A) growing deep taproots.
B) inhibiting ATP production.
C) producing oxygen from water.
D) diffusing oxygen through lenticels.
E) releasing the hormone abscisic acid.

A) The ability to dissipate heat
B) The ability to form antifreeze proteins
C) The ability to form heat-shock proteins
D) The membrane's fluidity
E) The membrane's ability to contain substances

A) aerenchyma.
B) pneumatophores.
C) LEA proteins.
D) a thick cuticle.
E) additional stomata.

A) Protein structure and membrane integrity
B) Protein structure and cellular respiration
C) Membrane integrity and cellular respiration
D) Abscisic acid production and stomatal closing
E) Abscisic acid production and chaperonin production

A) ethylene.
B) abscisic acid.
C) canavanine.
D) jasmonate.
E) heat shock protein.

A) accumulate salt in their roots.
B) serve as barriers to salt intake.
C) secrete salt onto the leaf surface.
D) increase water loss from the plant.
E) maintain high salt concentrations in the plant.

A) The production of hairs
B) The growth of spines
C) The production of jasmonate
D) The production of chaperonins
E) The production of abscisic acid

A) are always present.
B) evolve more readily.
C) provide better protection.
D) are more energy-efficient.
E) do not require the use of energy.