1. Warm-Up What is the function of:
Cone cells?
Rod cells?
The perceived pitch of a sound is dependent on… ?
What is the difference between perception and sensation?

2. Warm-Up What is the function of:
Cone cells? Color
Rod cells? Light
The perceived pitch of a sound is dependent on… ?
wavelength (λ)
What is the difference between perception and sensation?

3. Sensory and Motor Mechanisms
Chapter 50
Campbell Biology – 9th Edition

4. You must know
The location and function of several types of sensory receptors
How skeletal muscles contract
Cellular events that lead to muscle contraction

5. Sensory Receptors
Mechanoreceptors: physical stimuli – pressure, touch, stretch, motion, sound
Thermoreceptors: detect heat/cold
Chemoreceptors: transmit solute conc. info – taste (gustatory), smell (olfactory)
Electromagnetic receptors: detect EM energy – light (photoreceptors), electricity, magnetism
Pain receptors: respond to excess heat, pressure, chemicals

6. This rattlesnake and other pit vipers have a pair of infrared receptors, one between each eye and nostril. The organs are sensitive enough to detect the infrared radiation emitted by a warm mouse a meter away.
Eye
Infrared
receptor
Some migrating animals, such as these beluga whales, apparently sense Earth’s magnetic field and use the information, along with other cues, for orientation.
Chemoreceptors: antennae of male silkworm moth have hairs sensitive to sex phermones released by the female

7. Reception: receptor detects a stimulus
Sensation = action potentials reach brain via sensory neurons
Perception: information processed in brain

8. Structure of the Human Ear
Outer ear
Middle
ear
Inner ear
Pinna
Auditory
canal
Tympanic
membrane
Eustachian
tube
Stapes
Incus
Malleus
Skull bones
Semicircular canals
Auditory nerve,
to brain
Oval
window
Round
Cochlea
Eustachian tube
nerve
Cochlea duct
Organ of Corti
Vestibular
Bone
To auditory
Axons of
sensory neurons
Basilar
Hair cells
Tectorial

9. Equilibrium in the inner ear: Semicircular canals (fluid-filled chambers) detect head movements through hairs of receptor cells
Semicircular canals
Flow
of endolymph
Vestibular nerve
Nerve fibers
Vestibule
Utricle
Saccule
Ampulla
Cupula
Body movement
Hairs
Hair
cell

10. Structure of the Vertebrate Eye (also some invertebrates)
Cornea
Ciliary body
Suspensory
ligament
Iris
Pupil
Aqueous
humor
Lens
Vitreous humor
Central artery and
vein of the retina
Optic disk
(blind spot)
Fovea (center
of visual field)
Optic
nerve
Retina
Choroid
Sclera

11. Retina
Optic nerve To
brain
Cone
Photoreceptors
Rod
Neurons
Pigmented
epithelium
Bipolar
cell
Amacrine
Horizontal
Optic
nerve
fibers
Ganglion
Vision
Compound eyes: several thousand ommatidia (light detectors) with its own lens; insects & crustaceans
Vertebrates:
Rods: sense light
Cones: color vision
Rhodopsin: light-absorbing pigment that triggers signal transduction pathway that leads to sight

12. Types of Skeletons
Hydrostatic: fluid held under pressure in closed body compartment
Hydra, nematodes, annelids
Exoskeletons: hard encasements on surface of animal
Insects, mollusks, crustaceans
Endoskeleton: hard supporting elements buried within soft tissues
Human bony skeleton

13. Shoulder
girdle
Scapula
Clavicle
Sternum
Skull
Appendicular
skeleton
Axial skeleton
Key
Rib
Humerus
Vertebra
Radius
Examples
of joints
Fibula
Ulna
Tibia
Pelvic
Carpals
Phalanges
Metacarpals
Femur
Patella
Tarsals
Metatarsals
Pivot joints allow us to rotate our forearm at the elbow and to move our head from side to side.
Hinge joints, such as between the humerus and the head of the ulna, restrict movement to a single plane.
Ball-and-socket joints, where the humerus contacts the shoulder girdle and where the femur contacts the pelvic girdle, enable us to rotate our arms and legs and move them in several planes.
Head of
humerus

14. Muscles always contract
Muscles work in antagonistic pairs to move parts of body
Biceps
contracts
Human
Triceps
relaxes
Forearm
flexes
extends
Extensor
muscle
Flexor
Grasshopper
Tibia

15. Skeletal Muscle Structure
Bundle of
muscle fibers
Single muscle fiber
(cell)
Plasma membrane
Nuclei
Muscle
Myofibril
Dark band
Sarcomere
Z line
Light
band
I band
TEM
A band
0.5 µm
M line
Thick filaments
(myosin)
H zone
Thin filaments
(actin)
Attached to bones by tendons
Types of muscle:
smooth (internal organs)
cardiac (heart)
Skeletal (striated)
1 long fiber = single muscle cell
Each muscle fiber = bundle of myofibrils, composed of:
Actin: thin filaments
Myosin: thick filaments

16. Sarcomere: basic contractile unit of the muscleZ H A
Relaxed muscle fiber I
Contracting muscle fiber
Fully contracted muscle fiber
Z lines – border
I band – thin actin filaments
A band – thick myosin filaments

17. (Note: Filaments do NOT shorten!)
Muscle Contraction:
Sarcomere
0.5 µm Z H A
Relaxed muscle fiber I
Contracting muscle fiber
Fully contracted muscle fiber
Sarcomere relaxed: actin & myosin overlap
Contracting:
Muscle fiber stimulated by motor neuron
Length of sarcomere is reduced
Actin slides over myosin
Fully contracted: actin & myosin completely overlap
Sliding-filament model: thick & thin filaments slide past each other to increase overlap
(Note: Filaments do NOT shorten!)

18. Muscle fibers only contract when stimulated by a motor neuron
Ca2+ released
from sarcoplasmic
reticulum
Mitochondrion
Motor
neuron axon
Synaptic
terminal
T tubule
Sarcoplasmic
Myofibril
Plasma membrane
of muscle fiber
Sarcomere

19. Muscle fiber depolarizes Ca2+ released Initiate sliding of filaments
Synaptic terminal of motor neuron releases acetylcholine
Muscle fiber depolarizes
Ca2+ released
Initiate sliding of filaments
Ca2+
CYTOSOL SR
PLASMA
MEMBRANE
T TUBULE
Synaptic cleft
Synaptic terminal
of motor neuron
ACh

20. Depolarization of muscle cell releases Ca2+ ions  binds to troponin  expose myosin sites on actin
Myosin-binding sites blocked.
Myosin-binding sites exposed.
Tropomyosin
Ca2+-binding sites
Actin
Troponin complex
Myosin-
binding site
Ca2+

21. Hydrolysis of ATP by myosin  cross-bridge formed  thin filament pulled toward center of sarcomere
Thin filaments
Thick filament
Thin filament
Thick
filament
Myosin head (low-energy
configuration)
Cross-bridge
binding site
Myosin head (high-
energy configuration)
Actin
Myosin head (low-
Thin filament moves
toward center of sacomere.

22. Speed of muscle contraction:
Fast fibers – brief, rapid, powerful contractions
Slow fibers – sustain long contractions (posture)

23. Problems
ALS (Lou Gehrig’s disease): degeneration of motor neurons, muscle fibers atrophy
Botulism: block release of acetylcholine, paralyzes muscles
Myasthenia gravis: autoimmune disorder, produce antibodies to acetylcholine
Calcium deficiency: muscle spasms and cramps
Rigor mortis (after death): no ATP to break actin/myosin bonds; sustained muscle contraction until breakdown (decomposition)