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ANIMAL PHYSIOLOGY AND ENDOCRINOLOGY

ANIMAL PHYSIOLOGY AND ENDOCRINOLOGY. Nervous System Physiology: Neurotransmitters and synaptic transmission. NEUROTRANSMITTERS. Neurotransmitter is a chemical: I. it must be released from presynaptic terminal, ii. must elicit the normal depolarization,

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ANIMAL PHYSIOLOGY AND ENDOCRINOLOGY

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  1. ANIMAL PHYSIOLOGY AND ENDOCRINOLOGY Nervous System Physiology: Neurotransmitters and synaptic transmission Zool 303 (Dr Saba Butt)

  2. NEUROTRANSMITTERS Neurotransmitter is a chemical: I. it must be released from presynaptic terminal, ii. must elicit the normal depolarization, iii. The effect of the substance must be blocked by the same agents that block synaptic transmission. Neuromodulators alter or modify the functioning of synapses. Agonists are the chemicals that have the same effect as a neurotransmitter. Anatagonists are the chemicals that reduce or prevent the synaptic transmission. Zool 303 (Dr Saba Butt)

  3. Table 4-1. Selected Neurortransmitters and Neuromodulators Zool 303 (Dr Saba Butt)

  4. Zool 303 (Dr Saba Butt)

  5. PRINCIPAL NEUROTRASMITTER SYSTEMS Following is a summarized overview of principal neurotransmitters and their receptors. ACETYLCHOLINE Acetylcholine is the principal neurotransmitter at neuromuscular junctions. The neurons that synthesize and release acetylcholine are called “cholinergic neurons”. Zool 303 (Dr Saba Butt)

  6. Zool 303 (Dr Saba Butt)

  7. Active uptake Zool 303 (Dr Saba Butt)

  8. ECITATORY AMINO ACIDS • Glutamate and aspartate are excitatory amino acids. These depolarizes many mammalian neurons. • Glutamate is calculated as responsible for 75 % excitatory transmission in brain and spinal cord. Zool 303 (Dr Saba Butt)

  9. INHIBITROY AMINO ACIDS • Gamaamino Butyric Acid (GABA) and Glycine are inhibitory amino acid that act as neurotransmitters. • GABA is a major inhibitory neurotransmitter in the brain, where it is transmitter for 20 % synapses. It is also fund in retina. Zool 303 (Dr Saba Butt)

  10. SYNAPTIC TRANSMISSION Zool 303 - Dr Saba Butt

  11. Figure 45-1 Structure of a large neuron in the brain, showing its important functional parts. (Redrawn from Guyton AC: Basic Neuroscience: Anatomy and Physiology. Philadelphia: WB Saunders Co, 1987.) Zool 303 - Dr Saba Butt

  12. Zool 303 - Dr Saba Butt

  13. SYNAPTIC TRANSMISSION Synaptic transmission occur via two systems: • Electrical Synapses Electrical synapses are very closely connected channels between two neurons. It allows transmission of nerve impulse directly from one neuron to the other. • Chemical Synapses In chemical synapse, chemicals (neurotransmitters) are released at synapses and attach at other neuron’s receptors to transmit nerve impulse. Zool 303 - Dr Saba Butt

  14. ELECTRICAL SYNAPSES Zool 303 - Dr Saba Butt

  15. ELECTRICAL SYNAPSES • Electrical synapses transfer impulse by direct ionic coupling. • At electrical synapse, the plasma membranes of pre- and post-synaptic cells are in close apposition and communication between cells takes place by way of protein channels called GAP JUCTIONS. • Ions can flow from one cell to the other by way of these gap junction to produce an almost equal though somewhat attenuated signal in the postsynaptic cell. Zool 303 - Dr Saba Butt

  16. ELECTRICAL SYNAPSES An Electron Micrograph showing CONNEXONS – channels in the membrane for Electrical Synapses. Zool 303 - Dr Saba Butt

  17. In Electrical Synapses action potential directly transmit from presynaptic membrane to the postsynaptic membrane. Zool 303 - Dr Saba Butt

  18. Zool 303 - Dr Saba Butt

  19. Electrical synapses were first discovered in 1959 in study on crayfish. • Electrical transmission of nerve impulse is found at many locations in various animals, e.g., vertebrate retina, some locations of vertebrate nervous system, smooth muscle and cardiac muscle fibers and sensory neurons. • Electrical transmission is possible in both directions at gap junctions but at some places it is in only one direction, such junctions are called rectifying. Zool 303 - Dr Saba Butt

  20. Electrical transmission is quite faster than that of Chemical transmission due to the long pathway of chemical synapses, i.e. release of neurotransmitter – attachment of it to receptors at postsynaptic membrane – opening of ion channels in post synaptic membrane – generation of impulse. • At some locations both chemical and electrical transmission occur. It was first discovered in birds. Zool 303 - Dr Saba Butt

  21. CHEMICAL SYNAPSES Zool 303 - Dr Saba Butt

  22. Neuron – Neuron Synapse Zool 303 - Dr Saba Butt

  23. Fast Chemical Synaptic Transmission • Neurotransmitter attaches to a receptor • Receptor is an ion channel, which opens in response • Ions flow inside. Zool 303 - Dr Saba Butt

  24. Slow Chemical Transmission When the receptor is activated by the neurotransmitter, its G-protein site becomes receptive to the G-protein. That protein moves into this interaction, which yields three major changes: (1) The GDP molecule is released and a GTP replaces it. (2) The alpha portion of the G-protein dissociates from the beta moiety, and moves to connection with the gate molecule.(3) This causes the gate to open and an ionic current occurs. Zool 303 - Dr Saba Butt

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