Synaptic Communication

Question 1

4 benefits of electrical signaling

Answer 1

• covers long distances with minimal loss of signal
• rapid
• quickly repeated
• information can be conveyed in patterns

Question 2

4 limitations of electrical signaling

Answer 2

• binary
• difficult to modify
• energy intensive
• microenvironment dependent

Question 3

What is the resting membrane potential?

Answer 3

• the potential energy in the electrical gradient formed across the plasma membrane
• caused by formation of K+ concentration gradient and permeability of the membrane to K+
• K+ concentration high inside cell, low outside cell; Na+ opposite
• K+ moves out of cell down concentration gradient, and is then pulled back into the cell via the electrical gradient: causes internal membrane to be negative and external membrane to be positive

Question 4

Ohm’s Law

Answer 4

V = IR
V is the voltage (plasma membrane)
I is the current
R is the resistance (ion channels)

Question 5

Electrochemical equilibrium

Answer 5

• When the concentration and electrical gradients for an ion are in balance
• driven by diffusion of ions

Question 6

Na+/K+ ATPase

Answer 6

• important ion transporter
• establishes Na+ and K+ gradients across the neuron membrane
• actively moves Na+ and K+ against concentration gradient

Question 7

Ion channels

Answer 7

• passive proteins
• allow ions to diffuse down concentration gradient
• K+, Na+, Ca2+, and Cl- channels

Question 8

Neuron membrane at rest

Answer 8

• interior of neuron is negatively charged
• separation and slow flow of K+ ions across plasma membrane creates membrane potential
• Na+/K+ ATPase activity maintains electrochemical gradients
• membrane potential allows neuron electrical activity

Question 9

What two equations calculate membrane potentials?

Answer 9

• Nernst equation - equilibrium potential of an individual ion
• Goldman equation - equilibrium potential of the entire plasma membrane

Question 10

Neuron passive electrical state

Answer 10

• cytoplasm is electrically resistant
• neurons electrically inert
• passive current rapidly decays over space and time
• active current flow allows neuron electrical information transfer

Question 11

Passive current flow

Answer 11

• current decays
• cytoplasm resistance
• relative to distance

Question 12

Active current flow

Answer 12

• current repropogates
• active process
• relative to distance

Question 13

The action potential

Answer 13

• rapid change in membrane potential
• caused by sequential opening of Na+ and K+ channels
• requires Na+ and K+ gradients

Question 14

4 types of ion channels

Answer 14

• leakage - constant ion flow along gradient
• voltage-gated - respond to changes in membrane potential
• ligand-gated - respond to ligand binding; NT, proteins, ions, & lipids
• physically-gated - respond to other physical stimuli; mechanical, temperature, light

Question 15

4 types of transporters

Answer 15

• ATPase pumps - use ATP to move one or more substrates
• ion exchangers - energy from moving one+ ions along concentration gradient will move other ions against gradient; opposite directions
• co-transporters - one+ ions move another ion; same direction
• multiple transporter systems - multiple transporters working together to move substrate

Question 16

Voltage-gated ion channels

Answer 16

• physical conformation changes with membrane polarization
• time and charge dependent
• ions move along concentration gradients
• passive
• refractory period

Question 17

Ligand-gated ion channels

Answer 17

• ligand binds, changes conformation of channel to allow ion movement along concentration gradient
• diversity of ligands
• passive
• open in presence of sufficient ligand and appropriate environment state

Question 18

Na+/K+ ATPase pumps

Answer 18

• bind Na+ on inside of cell
• phosphorylated, changing structure of transporter to open to exterior
• Na+ released, K+ binds
• causes dephosphorylation of transporter, allowing K+ inside

Question 19

Is the neurons resting potential positive or negative?

Answer 19

• negative

- in an AP, membrane potential is stimulated, rapidly goes positive, and then returns to the negative state

Question 20

Name the 6 phases of APs

Answer 20

• resting phase
• activation phase
• rising phase
• falling phase
• undershoot phase
• recovery phase

Question 21

What occurs during the resting phase of an AP?

Answer 21

• very little activity

- slow leakage of K+ out of cell through k+ channel from

Question 22

What occurs during the activation phase of an AP?

Answer 22

-stimulus is induced, opening Na+ channels

Question 23

What occurs during the rising phase of an AP?

Answer 23

• voltage-gated Na+ channels open, causing a dramatic and rapid influx of Na+ ions
• charge of membrane is reversed (+ in, - out)
• voltage-gated K+ channels open

Question 24

What occurs during the falling phase of an AP?

Answer 24

• voltage-gated Na+ channels close
• voltage-gated K+ channels open, K+ moves out
• leaves a more negative state on the inside of the cell

Question 25

What happens during the undershoot phase of an AP?

Answer 25

• refractory period prevents voltage-gated Na+ channels from opening
• no AP can occur
• voltage-gated K+ channels close

Question 26

What happens during the recovery phase of an AP?

Answer 26

-leaky K+ channels re-establish the resting potential

Question 27

What part of the neuron is an AP initiated?

Answer 27

axon hillock

Question 28

What direction is an AP conducted?

Answer 28

• anterograde; away from cell body

- unidirectional

Question 29

Two ways to increase AP conductance

Answer 29

1) increase axon caliber
- reduces internal resistance; energy intensive; physically restrictive (squid example)
2) insulate axons (myelination)
- prevents current leakage, requires glial support, oligodendrocytes (CNS), Schwann cells (PNS)
- saltatory conduction

Question 30

2 major classes of neurotransmitters

Answer 30

small molecules and neuropeptides

Question 31

small molecule NTs

Answer 31

• amino acids or derivatives
• synthesized in presynaptic terminal
• stored in small synaptic vesicles
• released from the presynaptic terminal
• examples are glutamate, GABA, & Acetylcholine

Question 32

neuropeptide NTs

Answer 32

• proteins
• synthesized in the body
• stored in large vesicles
• released both pre- and postsynaptically, and into extracellular environment
• Ex. brain gut peptides, opioid peptides, etc.

Question 33

Synaptic transmission steps (8)

Answer 33

• AP
• Ca2+ channel depolarization
• Ca2+ influx
• synaptic vesicle fusion
• NT release
• NT receptor activation
• NT reuptake
• NT sequestration/metabolism

Question 34

3 distinct pools for synaptic vesicles

Answer 34

• readily releasable pool
• recycling pool
• reserve pool; tethered to actin and can be released
• these are important in stages of release

Question 35

SNARE complexes

Answer 35

• proteins that allow vesicle release

- include synaptobrevin, syntaxin, SNAP-25, and synaptotagmin

Question 36

Steps in NT release

Answer 36

• vesicle docks
• SNARE complexes form to pull membranes together
• entering Ca2+ binds to synaptotagmin
• Ca2+-bound synaptotagmin catalyzes membrane fusion by binding to SNAREs and the plasma membrane

Question 37

2 models of membrane reuptake and vesicle reformation

Answer 37

• classic synaptic vesicle cycle

- ultrafast synaptic vesicle cycle (more likely/ faster)

Question 38

2 NT receptor types

Answer 38

• ionotropic

- metabotropic

Question 39

Ionotropic NT receptors

Answer 39

• ligand binding opens ion channel
• variable selectivity for ions
• not necessarily uni-directional
• directly involved in creating postsynaptic electrical current and changing membrane potential
• excitatory (depolarizing) or inhibitory (hyperpolarizing)

Question 40

Metabotropic NT receptors

Answer 40

• G-protein coupled intracellular signals
• relatively slow activation time
• prolonged signal duration
• signals modify the activity of ionotropic receptors, ion channels, and transporters
• signals alter terminal structure and function

Question 41

Change in post-synaptic membrane potential by NT receptors

Answer 41

• Excitatory postsynaptic potential (EPSP) - depolarization; Na+, Ca2+
• Inhibitory postsynaptic potential (IPSP) - hyperpolarization; Cl-, K+

Question 42

Influence of location on synaptic input strength

Answer 42

• membrane potentials decay with space and time

- proximity to the trigger zone dictates the relative influence of a synaptic input

Question 43

Postsynaptic potential summation

Answer 43

• the total change in membrane potential based on the spatial (location) and temporal (frequency) aggregation of postsynaptic potentials
• sufficient depolarization triggers an AP
• think about inhibitory and excitatory signals

Question 44

Where are emotional and abstract states mapped in the brain?

Answer 44

deep brain areas

Question 45

Where are maps overlaid and compared?

Answer 45

association cotrices

Question 46

What are spinal reflexes?

Answer 46

Sensory and motor loops that function independent of descending brain control. Example is hitting the patellar ligament with a mallet and the result is a leg kick.

Question 47

What is the Hebbian Theory?

Answer 47

Neuronal networks undergo activity-dependent plasticity throughout life, and activity drives neural network consolidation, while inactivity leads to decay.

Question 48

You are born with many more neuron than you end up with as an adult. How is this related to the Hebbian Theory?

Answer 48

Synapse pruning (loss of synapses) occurs during development as a result of the strengthening of some synapses and the subsequent loss of others.

Question 49

Name the 6 changes at synaptic terminals that drive neuronal plasticity

Answer 49

1) increased/decreased synaptic vesicle release
2) increase/decreased receptor density
3) changes in receptor sensitivity and conductance
4) changes in receptor subtype expression
5) sprouting of new synapses
6) formation of new connections

Question 50

How do networks change as a result of Long-term Potentiation (LTP) and Long-term Depression (LTD)?

Answer 50

Strength of connections and number of connections can change

Question 51

Explain the somatosensory circuit of touch

Answer 51

Three neurons communicate peripheral sensation to the brain:
1st order: mechanosensory neuron –> brainstem (medulla)
2nd order: brainstem (medulla) –> thalamus
3rd order: thalamus –> somatosensory cortex

Question 52

Explain the decussation of 2nd order neurons in touch

Answer 52

They decussate (cross the midline) at the level of the medulla; information is processed contralaterally within the brain

Question 53

What is a sensory field?

Answer 53

• discrete areas of touch discrimination that fill dermatomes
• sensory fields overlap
• highly variable in size
• -size determined by # of neurons innervation a dermatome and degree of neuronal arborization

Question 54

Characteristics of mechanosensory neurons

Answer 54

• sense touch and pain
• activated by physical distortion
• pseudounipolar
• pseudo - not unipolar; has cell body
• has continuous dendrite to axon tree

Question 55

Name the 4 types of mechanoreceptor cell types

Answer 55

Merkel’s cells, Meissner corpuscles, Ruffini endings, and Pacinian corpuscles

Question 56

Characteristics of mechanoreceptor cells

Answer 56

• encase mechanosensory neurons
• detect & transfer different types of skin distortion information
• sensitivity, response time, and duration of activation vary
• a single neuron innervates a single mechanoreceptor cell type

Question 57

What is a nociceptor?

Answer 57

mechanosensory neuron that detects pain; has free nerve endings

Question 58

What is a thermoreceptor?

Answer 58

mechanosensory neuron that detects temperature; has free nerve endings

Question 59

What is the relationship between density of peripheral innervation and sensitivity?

Answer 59

• the higher the density of peripheral innervation, the greater the sensitivity
• ex. fingers have more neurons that skin on the back, so fingers are more sensitive than the back

Question 60

Name the 5 places in the brain where sensory information is passed along

Answer 60

• secondary somatosensory cortex
• association cortex
• premotor cortex
• limbic cortex
• frontal cortex

Question 61

Where are sensory fields organized?

Answer 61

in the somatosensory cortex

Question 62

Explain how the somatosensory cortex is plastic

Answer 62

• cortical regions expand and contract in size
• use increases connectivity
• disuse decreases connectivity

Question 63

Describe the 3 types of pain

Answer 63

1) somatic - pain perceived from peripheral cutaneous perception; thermal, mechanical, chemical
2) visceral - pain perceived from internal organ systems; referred, perceived as peripheral
3) neuropathic - pain caused by damage to PNS and CNS neurons; perceived as a burning or shocking pain

Question 64

Name the 4 types of nociceptors

Answer 64

• thermal nociceptors
• mechanical nociceptors
• polymodal nociceptors
• silent nociceptors

Question 65

Describe thermal nociceptors

Answer 65

• sense temperature extremes
• fast signals
• separate from thermoreceptors

Question 66

Describe mechanical nociceptors

Answer 66

• sense extreme changes in pressure or tearing

- fast signal

Question 67

Describe polymodal nociceptors

Answer 67

• sense thermal (hot and cold), mechanical, and chemical stimuli
• slow signal

Question 68

Describe silent nociceptors

Answer 68

• respond to visceral disorders

- fast signal

Question 69

Describe the initiation of pain signaling

Answer 69

• cutaneous nociceptors are activated
• inflammation releases modulatory signals (lipids - prostaglandins, thromboxanes, leukotrines, & neuropeptides)
• inflammatory molecules drive inflammation, sensitize nociceptors, & directly activate nociceptors

Question 70

How do NSAIDs reduce inflammation?

Answer 70

-reduce the production of prostaglandins and thromboxanes

Question 71

Describe the afferent connections in pain signaling

Answer 71

• 1st, 2nd, and 3rd order neurons
• somatosensory cortex destination
• 1st order neurons synapse in the spinal cord
• 2nd order neurons decussate in the spinal cord
• pain can be gated at the spinal cord

Question 72

What is a function of silent nociceptors?

Answer 72

• they refer pain
• important because brain doesn’t have a map of internal organs, so the silent nociceptors allow our brain to process visceral pain by referring the pain

Question 73

What is a similarity between silent nociceptors and peripheral nociceptors?

Answer 73

they synapse onto the same 2nd order neurons

Question 74

What is the Gate Theory of pain?

Answer 74

• pain is gated & regulated at the level of the spinal cord; nociceptor & second order connection
• peripheral touch inhibits nociception
• no descending (brain) signaling required
• descending signals can influence spinal gating

Question 75

How do opiates help the brain gate pain at the spinal cord?

Answer 75

• they interact with central pain receptors (brain and spinal cord) to block the transmission of nociceptive stimuli to the somatosensory cortex
• nociceptor can’t send signal to 2nd order neuron

Question 76

Comparison of NSAIDs and opiates

Answer 76

• both can inhibit pain
• NSAIDs prevent pain peripherally
• opiates prevent pain centrally