Deck 39: Plant Responses to Internal and External Signals

A)only shoots depend upon auxin distribution.
B)only shoots depend upon the aggregation of statoliths.
C)only roots exhibit rapid elongation of specific cells.
D)only roots sense gravity at the tips.
E)the threshold and response time is much less in shoots than in roots.

A)abscisic acid
B)ethylene
C)cytokinin
D)gibberellin
E)auxin

A)only I
B)only II
C)only III
D)only I and II

A)Specific protein kinase 1 would be activated, and greening would occur.
B)Ca²⁺ channels would not open, and no greening would occur.
C)Ca²⁺ channels could open, and specific protein kinase 2 could still be produced.
D)No transcription of genes that function in de-etiolation would occur.
E)Transcription of de-etiolation genes in the nucleus would not be affected.

A)light causes auxin to accumulate on the shaded side of a plant stem.
B)auxin indirectly inhibits elongation of plant stem cells.
C)auxin is produced by the apical meristem of the coleoptile and moves downward.
D)all hormones move downward via the xylem.
E)cytokinins are more directly involved than auxins.

A)in plant cells naturally exist in very large amounts.
B)change their shape in response to stimulus.
C)are unable to move from one cell to another.
D)affect only cells with the appropriate receptor.

A)reception of light by phytochrome
B)activation of protein kinase 1 by cAMP
C)activation of protein kinase 2 by Ca²⁺
D)post-translational modification of existing proteins
E)100-fold decrease in cytosolic Ca²⁺ levels

A)calcium release from the endoplasmic reticulum of shaded cells.
B)whether the plant is in the northern or southern hemisphere.
C)gibberellin production by stems.
D)auxin production in cells receiving red light.
E)auxin movement toward the lower side of the stem.

A)plasma membrane.
B)cytoplasmic matrix.
C)endoplasmic reticulum.
D)nuclear membrane.
E)nucleoplasm.

A)calcium ions.
B)nonrandom mutations.
C)receptor proteins.
D)phytochrome.
E)secondary messengers.

A)carotenoids.
B)xanthophylls.
C)phytochrome.
D)chlorophyll.
E)auxin.

A)When shoots are exposed to light, a chemical substance migrates toward the light.
B)Agar contains a chemical substance that mimics a plant hormone.
C)A chemical substance involved in shoot bending is produced in shoot tips.
D)Once shoot tips have been cut, normal growth cannot be induced.
E)Light stimulates the synthesis of a plant hormone that responds to light.

A)they need sunlight energy for photosynthesis.
B)the sun stimulates stem growth.
C)cell expansion is greater on the dark side of the stem.
D)auxin is inactive on the dark side of the stem.
E)phytochrome stimulates florigen production.

A)auxin migrates to the lower part of the stem due to gravity.
B)there is more auxin on the light side of the stem.
C)auxin is destroyed more quickly on the dark side of the stem.
D)auxin is found in greatest abundance on the dark side of the stem.
E)gibberellins produced at the stem tip cause phototropism.

A)cell respiration via regulation of the citric acid cycle
B)cell division via the cell cycle
C)cell elongation through production of cellulase
D)cell differentiation through altered spliceosome activity
E)cell synthesis of proteins via altered gene expression

A)tip of the coleoptile.
B)part of the coleoptile that bends during the response.
C)base of the coleoptile.
D)cotyledon.
E)phytochrome in the leaves.

A)auxins.
B)cytokinins.
C)indole acetic acid.
D)ethylene.
E)carbon dioxide concentration (in air).

A)was first demonstrated in the coleoptiles of monocots.
B)has been found in all monocots and most eudicots.
C)has been shown to involve only IAA stimulation of cell elongation on the dark side of the stem.
D)can be demonstrated with unilateral red light, but not blue light.
E)is now thought by most plant scientists not to involve the shoot tip.

A)It is caused by an electrical signal.
B)One chemical involved is ethylene.
C)Auxin causes a growth increase on one side of the stem.
D)Auxin causes a decrease in growth on the side of the stem exposed to light.
E)Removing the apical meristem enhances phototropism.

A)ethylene
B)indoleacetic acid
C)gibberellin
D)cytokinin
E)abscisic acid

A)Auxin stimulates proton pumps in the plasma membrane and tonoplast.
B)Auxin-activated proton pumps lower the pH of the cell wall, which breaks bonds and makes the walls more flexible.
C)Auxins and gibberellins together act as a lubricant to help stretch cellulose microfibrils.
D)Auxins activate aquaporins that increase turgor pressure in the cells.
E)Auxins and gibberellins are transported to the vacuoles to build up turgor pressure.

A)oligosaccharins
B)abscisic acid
C)cytokinins
D)gibberellins
E)auxins

A)Animal receptors are very different than plant receptors.
B)Plant cells have a cell wall that blocks passage of many hormones.
C)Plants must have more precise timing of their reproductive activities.
D)Plants are much more variable in their morphology and development than animals.
E)Animal receptors are more hydrophobic than plant receptors.

A)auxin.
B)ethylene.
C)florigen.
D)abscisic acid.
E)gibberellin.

A)Auxin binds to different receptors in different cells.
B)Different concentrations of auxin have different effects.
C)Auxin causes second messengers to activate both proton pumps on the plasma membrane and certain genes within the same cells.
D)The dual effects are due to two different types of auxins that are produced by different genes.
E)Other antagonistic hormones modify auxin's effects.

A)some plants are long-day plants and others are short-day plants.
B)signal transduction pathways in plants are different from those in animals.
C)plant genes recognize pathogen genes.
D)auxin can stimulate cell elongation in apical meristems, yet will inhibit the growth of axillary buds.
E)gibberellin concentration can both induce and break dormancy.

A)dissolving sieve plates, permitting more rapid transport of nutrients.
B)dissolving the cell membranes temporarily, permitting cells that were on the verge of dividing to divide more rapidly.
C)changing the pH within the cell, which would permit the electron transport chain to operate more efficiently.
D)increasing wall plasticity and allowing the affected cell walls to elongate.
E)greatly increasing the rate of deposition of cell wall material.

A)auxins, abscisic acid, brassinosteroids
B)auxins, gibberellins, cytokinins
C)gibberellins, cytokinins, ethylene
D)phytochrome, cytokinins, abscisic acid
E)brassinosteroids, ethylene, phytochrome

A)auxin
B)cytokinins
C)abscisic acid
D)ethylene
E)gibberellins

A)auxins, gibberellins, cytokinins
B)gibberellins, brassinosteroids, cytokinins
C)auxins, abscisic acid, ethylene
D)auxins, phytochrome, brassinosteroids
E)gibberellins, cytokinins, abscisic acid

A)They only act by altering gene expression.
B)They often have a multiplicity of effects.
C)They function independently of other hormones.
D)They directly control plant protein synthesis and assembly.
E)They affect the division and elongation, but not the differentiation, of cells.

A)geotropism of shoots.
B)maintenance of dormancy.
C)phototropism of shoots.
D)inhibition of lateral buds.
E)fruit development.

A)they are a readily accessible monocot, and auxins affect only monocots.
B)they have a stiff coleoptile.
C)they green rapidly in the light.
D)their coleoptile exhibits a strong positive phototropism.
E)monocots inactivate synthetic auxins.

A)auxin and ethylene
B)phytochrome and gibberellins
C)gibberellins and abscisic acid
D)abscisic acid and ethylene
E)brassinosteroids and cytokinins

A)auxin.
B)gibberellins.
C)cytokinins.
D)abscisic acid.
E)ethylene.

A)auxins and cytokinins
B)auxins and abscisic acid
C)gibberellins and cytokinins
D)cytokinins and ethylene
E)abscisic acid and ethylene

A)Auxin is destroyed by light.
B)Gibberellins are destroyed by light.
C)Auxin synthesis is stimulated in the dark.
D)Auxin moves away from the light to the shady side.
E)Gibberellins move away from the light to the shady side.

A)altering the expression of genes.
B)modifying the permeability of the plasma membrane.
C)modifying the structure of the nuclear envelope membrane.
D)altering the expression of genes and modifying the permeability of the plasma membrane.
E)modifying the permeability of the plasma membrane and modifying the structure of the nuclear envelope membrane.

A)by preventing pollination
B)by inhibiting formation of the ovule
C)by promoting gene expression in cambial tissue
D)by promoting rapid growth of the ovary
E)by inducing the formation of brassinosteroids

A)stretching or shrinking movements up or down in response to light
B)folding and unfolding of leaves using muscle-like tissues
C)growth movements toward or away from light
D)cessation of plant growth in response to wind or touch
E)rapid responses using action potentials from nervous tissue cells similar to those found in the nervous tissue of animals

A)auxin spray early in the season
B)gibberellin spray early in the season
C)abscisic acid spray late in the season
D)auxin spray late in the season
E)auxin and gibberellin spray late in the season

A)indoleacetic acid
B)cytokinin
C)gibberellin
D)abscisic acid
E)ethylene

A)stem elongation.
B)photoperiodism.
C)positive phototropism.
D)tracking seasons.
E)all of the above.

A)grocers, to spray on fruit to enhance ripening in the store
B)consumers, to spray on fruit before eating to enhance taste
C)florists, to dip stems in to keep leaves green longer
D)farmers, to spray on fruit after picking to stall ripening

A)auxin
B)gibberellin
C)cytokinin
D)abscisic acid

A)The cells of lateral buds are more sensitive to auxin than stem cells.
B)Lateral buds are high in abscisic acid that prevents elongation.
C)Lateral buds are low in gibberellins.
D)Stem cells lack receptors for auxin.
E)Stem cells can overcome auxin inhibition with high levels of gibberellins.

A)proteins; amino acids
B)carbohydrates; sugars
C)auxins; cytokinins
D)amylase; protease
E)RNAase; DNAase

A)gibberellin.
B)abscisic acid (ABA).
C)auxin.
D)ethylene.

A)light destroys auxin.
B)auxin moves down the plant apoplastically.
C)auxin is synthesized in the area where the stem bends.
D)auxin can move to the shady side of the stem.
E)auxin is only of secondary importance in the process.

A)seedlings do not produce a hypocotyl.
B)seedlings do not have an etiolation response.
C)seeds require light to germinate.
D)seeds require a higher temperature to germinate.
E)seeds are very sensitive to waterlogging.

A)leaf abscission
B)fruit development
C)cell division
D)the detection of photoperiod
E)cell elongation

A)gibberellins; auxin
B)ethylene; cytokinins
C)auxin; ethylene
D)ABA; cytokinins
E)strigolactones; gibberellins

A)it is produced in very small amounts.
B)it is a gas.
C)it has multiple effects.
D)it is only produced in seedlings.
E)it is transported in the xylem and phloem.

A)only I and II
B)only I, III and V
C)only I, III, IV and V
D)only II, III, IV and V

A)comparing photoperiodic responses
B)comparing tropisms with turgor movements
C)subjecting plants to various abiotic stresses
D)studying plant/animal interactions
E)analyzing mutant plants

A)only I and II
B)only I, II and III
C)only II and III
D)only II, III and V

A)CO₂
B)cytokinins
C)ethylene
D)auxin
E)gibberellic acids

A)Ethylene
B)Zeaxanthin
C)Gibberellin
D)Abscisic acid

A)photosynthesis.
B)seed germination.
C)phototropism.
D)flowering.
E)entrainment of circadian rhythms.

A)day-neutral plants.
B)short-night plants.
C)devoid of phytochrome.
D)short-day plants.
E)long-day plants.

A)never flower.
B)might flower depending upon the duration of the light flash.
C)will not be affected and will flower.
D)might flower depending upon the wavelengths of the light flashes.
E)will still flower if ethylene is administered.

A)days are shorter than nights.
B)days are shorter than a certain critical value.
C)nights are shorter than a certain critical value.
D)nights are longer than a certain critical value.
E)days and nights are of equal length.

A)8 hours light/16 hours dark
B)4 hours light/20 hours dark
C)6 hours light/2 hours dark/light flash/16 hours dark
D)8 hours light/8 hours dark/light flash/8 hours dark
E)2 hours light/20 hours dark/2 hours light

A)gibberellin
B)ethylene
C)abscisic acid
D)cytokinins

A)grafting leaves of a hibiscus that was exposed to long night
B)grafting leaves of a hibiscus that was exposed to short night
C)exposing flower buds of the hibiscus bush to long nights
D)exposing flower buds of the hibiscus bush to short nights

A)are more predictable than air temperature changes.
B)alter the amount of energy available to the plant.
C)are modified by soil temperature changes.
D)can reset the biological clock.
E)are correlated with moisture availability.

A)maximizes light absorption by the chloroplasts for photosynthesis.
B)increases production of phototropic hormones.
C)maximizes heat absorption by the chloroplasts for cellular respiration.
D)increases adenosine triphosphate (ATP)production during the light-independent reactions.

A)circadian rhythm
B)photoperiodic response
C)phototropic response
D)biological clock
E)thigmomorphogenesis

A)depend on environmental cues.
B)affect gene transcription.
C)stabilize on a 24-hour cycle.
D)speed up or slow down with increasing or decreasing temperature.
E)do all of the above.

A)a burst of red light in the middle of the night
B)a burst of far-red light in the middle of the night
C)a day that is longer than a certain length
D)a night that is longer than a certain length
E)a higher ratio of Pr to Pfr

A)the duration of continuous light exceeds a critical length.
B)the duration of continuous light is less than a critical length.
C)the duration of continuous darkness exceeds a critical length.
D)the duration of continuous darkness is less than a critical length.
E)it is kept in continuous far-red light.

A)a phytochrome molecule that is activated by red light.
B)a protein that is synthesized in leaves, travels to the shoot apical meristems, and initiates flowering.
C)a membrane signal that travels through the symplast from leaves to buds.
D)a second messenger that induces Ca⁺⁺ ions to change membrane potential.
E)a transcription factor that controls the activation of florigen-specific genes.

A)exposure to far-red light
B)exposure to red light
C)long dark period
D)inhibition of protein synthesis
E)synthesis of phosphorylating enzymes

A)It may have the same signal transduction pathway in all organisms.
B)Once set, it cannot be changed.
C)It works independently of photoperiodic responses.
D)Once set, it is independent of external signals.
E)It can be changed to a longer or shorter period by altering the light quality.

A)cause increased flower production.
B)have no effect upon flowering.
C)inhibit flowering.
D)stimulate flowering.
E)convert florigen to the active form.

A)Leave the lights on at night as well as during the day.
B)Add additional fluorescent tubes to increase the light output.
C)Add some incandescent bulbs to increase the amount of red light.
D)Set a timer to turn on the lights for 5 minutes during the night.
E)Turn off the lights for 5 minutes during the day.

A)As a rule, short-day plants flower in the summer.
B)As a rule, long-day plants flower in the spring or fall.
C)Long-day plants flower in response to long days, not short nights.
D)Flowering in day-neutral plants is only influenced by day length if there is an exceptionally warm spring.
E)Flowering in short-day and long-day plants is controlled by phytochrome.

A)positive thigmotropisms.
B)rhythmic opening and closing of K⁺ channels in motor cell membranes.
C)senescence (the aging process in plants).
D)flowering and fruit development.
E)ABA-stimulated closing of guard cells caused by loss of K⁺.

A)red
B)far-red
C)blue
D)red followed by far-red
E)far-red followed by blue