Deck 50: Sensory and Motor Mechanisms

A) mechanoreceptors which function in orientation to gravity.
B) chemoreceptors used in selecting migration routes.
C) photoreceptors used in setting biological rhythms.
D) thermoreceptors used in prey detection.
E) chemoreceptors used in acid-base balance.

A) move.
B) sense light.
C) hear.
D) orient with respect to gravity.
E) respond to touch.

A) integration.
B) transmission.
C) transduction.
D) transcription.
E) amplification.

A) neural projections from taste receptors reach different parts of the brain than the neural projections from olfactory receptors.
B) the single area of the cerebral cortex that receives smell and taste signals can distinguish tastes and smells by the pattern of action potentials received.
C) tastant molecules are airborne, whereas odorant molecules are dissolved in fluids.
D) distinguishing tastant molecules requires learning, whereas smell discrimination is an innate process.
E) odorants bind to receptor proteins, but none of the tastant stimuli bind to receptors.

A) sensory adaptation → stimulus reception → sensory transduction → sensory perception.
B) stimulus reception → sensory transduction → sensory perception → sensory adaptation.
C) sensory perception → stimulus reception → sensory transduction → sensory adaptation.
D) sensory perception → sensory transduction → stimulus reception → sensory adaptation.
E) stimulus reception → sensory perception → sensory adaptation → sensory transduction.

A) tectorial membrane.
B) tympanic membrane.
C) round-window membrane.
D) hair cell membrane.
E) basilar membrane.

A) the receptor.
B) a G protein.
C) an enzyme-catalyzed reaction.
D) sensory adaptation.
E) triggering several receptors at once.

A) cold temperature.
B) hot temperature.
C) tactile stimulus.
D) odor of pepper.
E) deep pressure.

A) fluid and cells that can undergo mechanosensory transduction.
B) air and cells that produce wax.
C) air and small bones that vibrate in response to sound waves.
D) fluid with stacks of chemosensory cells.
E) air and statocysts activated by movement.

A) an actin-myosin complex.
B) a troponin-tropomyosin complex.
C) axons wound around muscle fibers.
D) a group of dendrite-encircled muscle fibers.
E) a muscle cell that makes up a muscle group.

A) vision.
B) gustation.
C) olfaction.
D) audition.

A) the hair cells in the cochlea move more than their normal limits.
B) moving fluid in the semicircular canals encounters a stationary cupula.
C) rods and cones provide information that does not correspond with information received by cochlear hair cells.
D) the basilar membrane makes physical contact with the tectorial membrane.
E) the utricle is horizontal but the saccule is vertical.

A) 1 → 2 → 3 → 4
B) 1 → 4 → 2 → 3
C) 2 → 4 → 1 → 3
D) 3 → 1 → 2 → 4
E) 3 → 1 → 4 → 2

A) tectorial membrane.
B) tympanic membrane.
C) round-window membrane.
D) hair cell membrane.
E) basilar membrane.

A) cold temperature.
B) hot temperature.
C) tactile stimulus.
D) odor of pepper.
E) deep pressure.

A) which part of the tympanic membrane is being vibrated by sound waves.
B) which part of the oval window produces waves in the cochlear fluid.
C) which region of the basilar membrane was set in motion.
D) whether or not the sound moves the incus, malleus, and stapes.
E) the listener having had training in music.

A) cochlea.
B) statoliths.
C) stapes.
D) pinnae.
E) antennae.

A) chemosensory structures.
B) tactile structures.
C) olfactory structures.
D) highly sensitive photoreceptors.
E) gustatory structures.

A) hair cells of the organ of Corti, which rests on the basilar membrane, coming in contact with the tectorial membrane.
B) hair cells of the organ of Corti, which rests on the tympanic membrane, coming in contact with the tectorial membrane.
C) hair cells of the organ of Corti, which rests on the tectorial membrane, coming in contact with the basilar membrane.
D) hair cells of the organ of Corti coming in contact with the tectorial membrane as a result of fluid waves in the cochlea causing vibrations in the round window.
E) hair cells on the tympanic membrane that stimulate the tectorial membrane neurons, leading to the auditory section of the brain.

A) ganglion cells.
B) horizontal cells.
C) amacrine cells.
D) bipolar cells.
E) lateral cells.

A) smell receptors in animals with hydrostatic skeletons.
B) mechanoreceptors that help birds remain oriented during flight.
C) a specific type of hair cell in the human ear.
D) insect taste receptors found on feet and mouthparts.
E) olfactory hairs located on insect antennae.

A) ganglion cells.
B) bipolar cells.
C) primary visual cortex.
D) optic chiasma.
E) lateral geniculate nuclei.

A) gustatory stimuli.
B) olfactory stimuli.
C) visual stimuli.
D) auditory stimuli.
E) stimuli related to the position of the head.

A) human sense of taste.
B) pain receptors in birds.
C) human sense of smell.
D) lateral line systems in fish.
E) eyes in arthropods.

A) depolarize due to the opening of sodium channels.
B) hyperpolarize due to the closing of sodium channels.
C) depolarize due to the opening of potassium channels.
D) hyperpolarize due to the closing of potassium channels.
E) fire one action potential for each photon received.

A) fire action potentials that will increase its release of glutamate.
B) undergo a graded depolarization that will increase its release of glutamate.
C) undergo a graded hyperpolarization that will increase its release of glutamate.
D) undergo a graded depolarization that will decrease its release of glutamate.
E) undergo a graded hyperpolarization that will decrease its release of glutamate.

A) cone cells can detect color, but rod cells cannot.
B) cone cells are more sensitive than rod cells to light.
C) cone cells, but not rod cells, have a visual pigment.
D) rod cells are most highly concentrated in the center of the retina.
E) rod cells require higher illumination for stimulation than do cone cells.

A) both types of stimuli are present in thousands of different chemicals.
B) both types of stimuli must be dissolved in a body fluid before they can be detected.
C) both types of stimuli are proteins (that is, molecules of very large size and high molecular weight).
D) both types of stimuli evoke action potentials in the cells to which they bind.
E) any given stimulus for one system evokes a response from the other system.

A) excellent hearing for detecting predators.
B) compound eyes with multiple ommatidia.
C) eyes with multiple fovea.
D) a camera-like eye with multiple fovea.
E) binocular vision.

A) human vision.
B) human olfaction.
C) human gustation.
D) human vestibular sense.
E) human thermoreception.

A) primary visual cortex.
B) thalamus.
C) optic chiasma.
D) sense of taste.
E) sense of touch.

A) gustatory complex.
B) anterior hypothalamus.
C) olfactory bulb.
D) occipital lobe.
E) posterior pituitary gland.

A) has been flattened, as a result of contraction of the ciliary muscles.
B) has been made more spherical, as a result of contraction of the ciliary muscles.
C) has been flattened, as a result of relaxation of the ciliary muscles.
D) has been made more spherical, as a result of relaxation of the ciliary muscles.
E) does not change its shape.

A) perception.
B) sensory transduction.
C) sensory adaptation.
D) habituation.
E) lateral inhibition.

A) all ipsilateral, meaning that left eye projections stay on the left side of the brain, and vice versa.
B) all contralateral, meaning that left eye projections project to the right side of the brain, and vice versa.
C) ipsilateral for the temporal side of each retina, and contralateral for the nasal side of each retina.
D) ipsilateral for the nasal side of each retina, and contralateral for the temporal side of each retina.
E) randomly crossed in terms of which side of the retina projects to either the left or right side of the brain.

A) ganglion cells.
B) amacrine cells.
C) bipolar cells.
D) horizontal cells.
E) rods and cones.

A) ~10:1
B) ~100:1
C) ~1,000:1
D) 1:1
E) 1:~100

A) sugar water.
B) a rich chocolate flavor.
C) a savory and complex cheese.
D) acidic orange juice.
E) salt water.

A) underlies habituation of vision.
B) enhances visual contrast.
C) prevents bleaching in bright light.
D) is required for color vision to occur.
E) recycles neurotransmitter molecules.

A) actin filaments coiling up to become shorter.
B) myosin filaments coiling up to become shorter.
C) actin and myosin filaments both coiling up to become shorter.
D) actin cross-bridges binding to myosin and then flexing.
E) myosin cross-bridges binding to actin and then flexing.

A) troponin.
B) tropomyosin.
C) actin.
D) myosin.
E) calmodulin.

A) tonus.
B) fused tetanus.
C) an all-or-none response.
D) fatigue.
E) a spasm.

A) A bands and I bands.
B) transverse tubules.
C) gap junctions.
D) motor units.
E) thick and thin filaments.

A) troponin.
B) tropomyosin.
C) actin.
D) myosin.
E) transverse tubules.

A) glucose.
B) sodium ions.
C) potassium ions.
D) hydrogen ions.
E) monosodium glutamate.

A) motor neurons lose their myelination and the ability to rapidly fire action potentials.
B) acetylcholine receptors are destroyed by an overactive immune system.
C) ATP production becomes uncoupled from mitochondrial electron transport.
D) the spinal cord is infected with a virus that attacks muscle stretch receptors.
E) troponin molecules become unable to bind calcium ions.

A) one actin binding site and its myosin partner.
B) one sarcomere and all of its actin and myosin filaments.
C) one myofibril and all of its sarcomeres.
D) one motor neuron and all of the muscle fibers on which it has synapses.
E) an entire muscle.

A) T tubules.
B) motor neuron axons.
C) sensory neuron axons.
D) motor neuron dendrites.
E) sensory neuron dendrites.

A) immediately relax.
B) release all actin-myosin bonds.
C) enter a state where actin and myosin are unable to separate.
D) fire many more action potentials than usual and enter a state of "rigor."
E) sequester all free calcium ions into the sarcoplasmic reticulum.

A) energized cross-bridges.
B) myosin.
C) actin.
D) tropomyosin.
E) troponin.

A) in the nasal cavity.
B) in the anterior pituitary gland.
C) in the posterior pituitary gland.
D) in the brain.
E) in the brainstem.

A) creatine phosphate.
B) glycolysis.
C) substrate phosphorylation.
D) oxidative phosphorylation.
E) de novo synthesis.

A) a higher concentration of myoglobin.
B) a higher density of mitochondria.
C) a darker visual appearance.
D) a smaller diameter.
E) less resistance to fatigue.

A) myosin.
B) troponin.
C) tropomyosin.
D) Z lines

A) ATP hydrolysis.
B) the initiation of an action potential.
C) maintaining its resting membrane potential.
D) initiating contraction.
E) its ability to sustain glycolysis.

A) breaking the actin-myosin cross-bridges.
B) binding to the troponin complex, which then relocates tropomyosin.
C) transmitting action potentials across the neuromuscular junction.
D) spreading action potentials through the T tubules.
E) reestablishing the resting membrane potential following an action potential.

A) phosphorylated myosin.
B) ATP needed to break actin-myosin bonds.
C) calcium ions needed to bind to troponin.
D) oxygen supplies needed for myoglobin.
E) sodium ions needed to fire action potentials.

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

A) extracellular fluid.
B) cytosol.
C) actin.
D) myosin.
E) sarcomeres.

A) 7.
B) 1.
C) 8.
D) 9.
E) 10.

A) hair cell-mechanoreceptor
B) muscle spindle-mechanoreceptor
C) taste receptor-chemoreceptor
D) rod-electromagnetic receptor
E) olfactory receptor-electromagnetic receptor

A) the skeleton of mammals.
B) the hydrostatic skeletons of earthworms.
C) the exoskeleton of insects.
D) the body hairs of mammals.
E) the skeleton in birds.

A) neuromast.
B) statocyst.
C) taste bud.
D) ommatidium.
E) olfactory bulb.

A) air pressure waves to fluid pressure waves.
B) fluid pressure waves to air pressure waves.
C) air pressure waves to nerve impulses.
D) fluid pressure waves to nerve impulses.
E) pressure waves to hair cell movements.

A) running by a 50-gram rodent.
B) running by a 40-kg ungulate.
C) flying by a 100-g bird.
D) swimming by a 10-g minnow (bony fish).
E) swimming by a 100-kg tuna (bony fish).

A) A
B) B
C) C
D) D
E) E

A) A
B) B
C) C
D) D
E) E

A) 2, 3, and 4.
B) 2, 5, and 7.
C) 4.
D) 5.
E) 7 and 8.

A) skeletal muscles and smooth muscles.
B) cardiac muscles and skeletal muscles.
C) smooth muscles and cardiac muscles.
D) smooth muscles, skeletal muscles, and cardiac muscles.
E) smooth muscles.

A) annelids, including earthworms.
B) insects, including beetles.
C) cartilaginous fishes, including sharks.
D) bivalves, including clams.
E) crustaceans, including lobsters.

A) 3.
B) 4.
C) 5.
D) 6.
E) 7.

A) hormone receptors for digestive hormones were reduced or eliminated, showing that bitter tastes are reinforced by digestive responses.
B) salt-taste cells were altered to express receptors for bitter tastants, suggesting that animals have unregulated salt appetites.
C) visual sense was reduced or eliminated, suggesting that mice learn visual cues about bitter tastes.
D) olfactory sense was reduced or eliminated, suggesting that mice learn odor cues about bitter tastes.
E) sweet-taste cells were altered to express receptors for bitter tastants, suggesting that the sensation of taste depends only on which taste cell is stimulated.

A) white and red
B) red and green
C) loud and faint
D) salty and sweet
E) spicy and cool

A) the radius to the ulna.
B) the radius to the humerus.
C) the ulna to the humerus.
D) the humerus to the scapula.
E) the radius to the scapula.

A) chemical synapses using acetylcholine.
B) chemical synapses using norepinephrine.
C) electrical synapses using gap junctions.
D) myelinated motor neurons.
E) non-myelinated motor neurons.

A) walking on its limbs.
B) crawling with its feet.
C) swimming with its setae.
D) using peristaltic contractions of its circular and longitudinal muscles.
E) alternating contractions and relaxations of its flagellae.

A) 1 and 2.
B) 3 and 4.
C) 5 and 7.
D) 6 and 8.
E) 9 and 10.

A) break cross-bridges by acting as a cofactor in the hydrolysis of ATP.
B) bind with troponin, changing its shape so that the myosin-binding sites on actin are exposed.
C) transmit action potentials from the motor neuron to the muscle fiber.
D) spread action potentials through the T tubules.
E) re-establish the polarization of the plasma membrane following an action potential.

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