1. Chapter 49: Sensory & Motor Mechanisms
Our focus: Movement & Locomotion
What do skeletons do?
Support
Protect
Allow movement
What are the 3 types of skeletons?
Hydrostatic
Fluid under pressure in a closed body compartment
Muscles are used to change the shape of the compartment
Cnidarians, flatworms, nematodes, annelids
Exoskeleton
Outside surface of the animal
Chitin & other structural proteins
Many molt
Endoskeleton
Support from within

2. Figure 49.25 Peristaltic locomotion in an earthworm
(a) Body segments at the head and just in front of the rear are short and thick (longitudinal muscles contracted; circular muscles relaxed) and anchored to the ground by bristles. The other segments are thin and elongated (circular muscles contracted; longitudinal muscles relaxed.)
(b) The head has moved forward because circular muscles in the head segments have contracted. Segments behind the head and at the rear are now thick and anchored, thus preventing the worm from slipping backward.
(c) The head segments are thick again and anchored in their new positions. The rear segments have released their hold on the ground and have been pulled forward.
Longitudinal
muscle relaxed
(extended)
Circular
muscle
contracted
relaxed
Head
Bristles

3. Figure 49.26 Bones and joints of the human skeleton
1 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.
2 Hinge joints, such as between the humerus and the head of the ulna, restrict movement to a single plane.
3 Pivot joints allow us to rotate our forearm at the elbow and to move our head from side to side.
Key
Axial skeleton
Appendicular skeleton
Skull
Shoulder girdle
Clavicle
Scapula
Sternum
Rib
Humerus
Vertebra
Radius
Ulna
Pelvic girdle
Carpals
Phalanges
Metacarpals
Femur
Patella
Tibia
Fibula
Tarsals
Metatarsals 1
Examples of joints 2 3
Head of humerus

4. Chapter 49: Sensory & Motor Mechanisms
Our focus: Movement & Locomotion
What do skeletons do?
What are the 3 types of skeletons?
What does a muscle cell look like?

5. Figure 49.28 The structure of skeletal muscle
Bundle of muscle fibers
Single muscle fiber
(cell)
Plasma membrane
Myofibril
Light band
Dark band
Z line
Sarcomere
TEM
0.5 m
I band
A band
M line
Thick filaments (myosin)
Thin filaments (actin)
H zone
Nuclei
Made of many fibers
A single fiber is a muscle cell (multinucleated)
Each muscle fiber has many myofibrils
Myofibrils made of actin (thin) & myosin (thick)
has head
Sarcomere – functional unit of a muscle

6. Students
-Get test folders from center table
-Remaining essays
-Review session – Monday 7AM
-AP exam $$ - March 9

7. Chapter 49: Sensory & Motor Mechanisms
Our focus: Movement & Locomotion
What do skeletons do?
What are the 3 types of skeletons?
What does a muscle cell look like?
How do myosin & actin cause muscle contraction?

8. Fig. 49.30 Myosin-actin interactions underlying muscle fiber contraction
Thick filament
Thin filaments
Thin filament
ATP
Myosin head (low- energy configuration)
Thick filament
At rest:
ATP bound to myosin head
Head is cocked down &
away from actin

9. Fig. 49.30 Myosin-actin interactions underlying muscle fiber contraction 
Thick filament
Thin filaments
Thin filament
ATP
ADP
P i
Myosin head (low- energy configuration)
Thick filament
Actin
Cross-bridge binding site
-Myosin head hydrolyzes ATP
-Head cocked up & close
to actin

10. Fig. 49.30 Myosin-actin interactions underlying muscle fiber contraction 
Thick filament
Thin filaments
Thin filament
ATP
ADP
P i
Cross-bridge
Myosin head (low- energy configuration)
Thick filament
Actin
Cross-bridge binding site
Myosin head binds to actin
forming a cross-bridge

11. Fig. 49.30 Myosin-actin interactions underlying muscle fiber contraction
Thick filament
Thin filaments
Thin filament
ATP
ADP
P i
Cross-bridge
Myosin head (low- energy configuration) +
Thin filament moves toward center of sarcomere.
Thick filament
Actin
Cross-bridge binding site
The Sliding Filament Model
-ADP & Pi release from myosin sliding actin across myosin.
Binding of a NEW ATP breaks the cross-bridge
How much ATP is directly used in a muscle contraction?
NONE

12. Chapter 49: Sensory & Motor Mechanisms
Our focus: Movement & Locomotion
What do skeletons do?
What are the 3 types of skeletons?
What does a muscle cell look like?
How do myosin & actin cause muscle contraction?
Why is Ca+2 important for a muscle contraction?

13. (a) Myosin-binding sites blocked (b) Myosin-binding sites exposed
Figure 49.31 The role of regulatory proteins and calcium in muscle fiber contraction
Actin
Tropomyosin
Ca2+-binding sites
Troponin complex
(a) Myosin-binding sites blocked
Myosin- binding site
Ca2+
(b) Myosin-binding sites exposed
-Ca+2 binds to troponin complex causing tropomyosin to roll off of actin.
-This exposes myosin-binding site on actin.

14. Chapter 49: Sensory & Motor Mechanisms
Our focus: Movement & Locomotion
What do skeletons do?
What are the 3 types of skeletons?
What does a muscle cell look like?
How do myosin & actin cause muscle contraction?
Why is Ca+2 important for a muscle contraction?
What is the signal that causes a muscle contraction?

15. Figure 49.32 The roles of the sarcoplasmic reticulum and T tubules in muscle fiber contraction
Acetylcholine (Ach) depolarizes
plasma membrane
-Depolarization is carried deep
into muscle by T tubules
-Depolarization causes SR to
release Ca+2
-Recall Ca+2 binds to troponin
Motor neuron axon
Mitochondrion
Synaptic terminal
T tubule
Sarcoplasmic reticulum
Myofibril
Plasma membrane of muscle fiber
Sarcomere
Ca2+ released from sarcoplasmic reticulum

16. Figure 49.33 Review of contraction in a skeletal muscle fiber
ACh
Synaptic terminal of motor neuron
Synaptic cleft
T TUBULE
PLASMA MEMBRANE SR
ADP
CYTOSOL
Action potential is propa-
gated along plasma
membrane and down
T tubules.
Action potential
triggers Ca2+
release from sarco-
plasmic reticulum
(SR).
Acetylcholine (ACh) released by synaptic terminal diffuses across synaptic cleft and binds to receptor proteins on muscle fiber’s plasma membrane, triggering an action potential in muscle fiber. 1 2 3
Tropomyosin blockage of myosin-
binding sites is restored; contraction
ends, and muscle fiber relaxes. 7
Cytosolic Ca2+ is
removed by active
transport into
SR after action
potential ends. 6
Myosin cross-bridges alternately attach
to actin and detach, pulling actin
filaments toward center of sarcomere;
ATP powers sliding of filaments. 5
Calcium ions bind to troponin;
troponin changes shape,
removing blocking action
of tropomyosin; myosin-binding
sites exposed. 4
Ca2 P2

17. Chapter 49: Sensory & Motor Mechanisms
Our focus: Movement & Locomotion
What do skeletons do?
What are the 3 types of skeletons?
What does a muscle cell look like?
How do myosin & actin cause muscle contraction?
Why is Ca+2 important for a muscle contraction?
What is the signal that causes a muscle contraction?
How are muscles contractions graded?
By varying the number of muscle fibers that contract
By varying the rate at which muscle fibers are stimulated

18. Figure 49.34 Motor units in a vertebrate skeletal muscle
Spinal cord
Nerve
Motor neuron cell body
Motor unit 1
Motor unit 2
Motor neuron axon
Muscle
Tendon
Synaptic terminals
Muscle fibers
Recruitment – when more muscle fibers are activated to increase tension (force)

19. Figure 49.35 Summation of twitches
Action potential
Pair of action potentials
Series of action potentials at high frequency
Time
Tension
Single twitch
Summation of two twitches
Tetanus

20. Chapter 49: Sensory & Motor Mechanisms
Our focus: Movement & Locomotion
What do skeletons do?
What are the 3 types of skeletons?
What does a muscle cell look like?
How do myosin & actin cause muscle contraction?
Why is Ca+2 important for a muscle contraction?
What is the signal that causes a muscle contraction?
How are muscles contractions graded?
By varying the number of muscle fibers that contract
By varying the rate at which muscle fibers are stimulated
What are the different types of muscle fibers?
Slow oxidative
sustain long contractions
core muscles – posture
aerobic
Fast oxidative
brief, rapid, powerful contractions
Fast glycolytic
Primarily use glycolysis

21. Table 49.1 Types of Skeletal Muscle Fibers