Chapter 49 –Sensory and Motor Mechanisms
Animal Skeletons Function in support, protection, and movement Hydrostatic – fluid held under pressure in a closed body compartment (cnidarians, flatworms, nematodes, and annelids) Exoskeleton – hard encasement deposited on the surface of an animal (molluscs = mantle, calcium carbonate; arthropods = cuticle, chitin) Endoskeleton – hard supportive elements embedded within the soft tissue
Human Skeleton 2 main parts: Axial – skull and vertebral column Appendicular – limbs, pelvic and pectoral girdles
Human Joints Ball and socket – where the humerus contacts the shoulder girdle and the femur contacts the pelvic girdle, enable arms and legs to rotate and legs in several planes Hinge joints – between the humerus and head of the ulna, restrict movement in a single plane Pivot joints – allows for forearm rotation at the elbow and head movement from side to side
Vertebrate Skeletal Muscle Attached to bone, responsible for movement Bundles of long fibers running parallel to the length of the muscle Each fiber is a single cell with multiple nuclei Myofibrils – smaller fibers that make up a muscle fiber Myofilaments – make up myofibrils, two types Thin filaments – actin Thick filaments - myosin
Vertebrate Skeletal Muscle (cont.) Striated – because of regular arrangement of filaments causing light and dark bands Sarcomere – contractile unit of a muscle Z line – sarcomere border M line – center or middle of the sarcomere I band – only actin, a region of no overlap A band – actin and myosin protein fibers overlap H zone – only myosin, center of sarcomere, no overlap
Sliding-Filament Model Sarcomere length reduced Myosin = purple, actin = orange (a) relaxed muscle fiber – the I band and H zone are relatively wide (b) contracting muscle fiber – actin and myosin slide past each other, reducing I band and H zone width (c) fully contracted muscle fiber – H zone and I band are eliminated
Actin/Myosin Interaction Myosin head is bound to ATP and is in low energy conformation Myosin head hydrolyzes ATP to ADP and is in high energy conformation Myosin head binds to actin forming a cross-bridge Myosin returns to low energy conformation by releasing ADP, slides actin Binding of new ATP releases myosin from actin and begins a new cycle Extra energy for contractions stored as creatine phosphate (transfers P to ADP) and glycogen (broken down to make ATP)
Muscle Contraction Regulation Relaxation: tropomyosin blocks myosin binding sites on actin Contraction: calcium binds to troponin complex; tropomyosin changes shape, exposing myosin binding sites
Muscle Contraction Regulation (cont.) T (transverse) tubules – travel channels in plasma membrane for action potential Sarcoplasmic reticulum – a specialized endoplasmic reticulum, stores calcium Stimulated by action potential in a motor neuron, opens calcium channels allowing calcium to enter the cytosol Ca2+ then binds to troponin complex triggering a muscle contraction
Review of muscle contraction ACh released, triggers action potential in muscle fiber Propagated along membrane and down T tubules Triggers Ca2+ release from SR Ca2+ bind to troponin, change shape, exposing myosin-binding sites Myosin cross-bridges attach to actin and detach pulling actin towards center of sarcomere Ca2+ is removed by active transport into SR Tropomyosin blocks myosin binding sites, muscle fiber relaxes
Muscle Contraction Summary Action potentials and muscle contraction animation Part 2