chapter 48 neurons, synapses and signaling
myelin sheath
-The electrical insulation that surrounds vertebrate axons -which causes an action potential's speed to increase
temporal summation occurs when
If two EPSPs are produced in rapid succession
glia, or glial cells
Most neurons are nourished or insulated by cells
Myelin sheaths are made by
glia— oligodendrocytes in the CNS and Schwann cells in the PNS -The membranes forming these layers are mostly lipid, which is a poor conductor of electrical current and thus a good insulator
Biogenic amines have a central role in a number of
nervous system disorders
presynaptic neuron
neuron that sends the signal
The summed effect of EPSPs and IPSPs determines
whether an axon hillock will reach threshold and generate an action potential
Postsynaptic potentials fall into two categories
-Excitatory postsynaptic potentials (EPSPs)are depolarizations that bring the membrane potential toward threshold a.(depolarization) -Inhibitory postsynaptic potentials (IPSPs)are hyperpolarizations that move the membrane potential farther from threshold (stop a neuron) b. (hyper polarization)
crash course def of action potential
-In order to send long distant signals to move along the axon, strong enough to trigger voltage
membrane potential
-Every cell has a voltage (difference in electrical charge) across its plasma membrane
Graded portential in a neuron can be
-Excitatory -inhibitory
Unlike most neurotransmitters, NO is not stored in
-NO is not stored in cytoplasmic vesicles, but is synthesized on demand -It is broken down within a few seconds of production
endorphins
-Neuropeptides include substance P and endorphins, which both affect our perception of pain
depolarization
-Opening other types of ion channels triggers -reduction in the magnitude of the membrane potential -n involves gated sodium channels. If a stimulus causes gated sodium channels to open, the mem-brane's permeability to Na+ increases. Na+ diffuses into the cell along its concentration gradient, causing a depolarization as the membrane potential shifts toward ENa (+62 mV at 37°C).
Resting potential can be modeled by an artificial membrane that separates two chambers
-The concentration of KCl is higher in the inner chamber and lower in the outer chamber -K+ diffuses down its gradient to the outer chamber -Negative charge (Cl-) builds up in the inner chamber
Termination of Neurotransmitter Signaling: After a response is triggered, the chemical synapse returns to its resting state. How does this happen?
-The key step is clearing the neurotransmitter molecules from the synaptic cleft -the chemical synapse returns to its resting state
neurotransmitters
-The synaptic terminal of one axon passes information across the synapse in the form of chemical messengers
what toxins disrupt acetylcholine neurotransmission
-These include the nerve gas sarin and the botulism toxin produced by certain bacteria -Acetylcholine is just one of more than 100 known neurotransmitters -The remainder fall into four classes: amino acids, biogenic amines, neuropeptides, and gases
Termination of Neurotransmitter Signaling: The neurotransmitter molecules are cleared from
-the synaptic cleft -Blocking this process can have severe effects
threshold
If a depolarization increases the membrane potential to a level
At some chemical synapses, the ligand-gated ion chan-nels are permeable to
K+ and Na+ ca+
If a depolarization shifts the membrane potential sufficiently, it results in a massive change in membrane voltage
action potential in which ca+ enters
The combination of EPSPs through spatial and temporal summation can trigger
an action potential
hyperpolarization
an increase in magnitude of the membrane potential -makes the inside of the membrane more negative -Although opening potassium channels in a resting neu-ron causes hyperpolarization, opening some other types of ion channels has an opposite effect, making the inside of the membrane less negative
Mutations in genes that encode ion channels lead to
disorders affecting the nerves or brain—or the muscles or heart
In a resting neuron, the currents of K+ and Na+ar
equal and opposite, and the resting potential across the membrane remains steady
resting neuron
has a slight positive charge on the exterior and negative inside
Unipolar neuron
having or pertaining to one pole process -sensory
dendrites
highly branched extensions that receive signals from other neurons
The cell body of a postsynaptic neuron may receive inputs from
hundreds or thousands of synaptic terminals
As a result, action potentials are not generated in
in the regions between the nodes. Rather, the inward current produced dur-ing the rising phase of the action potential at a node travels within the axon all the way to the next node.
Glycine acts at
inhibitory synapses in parts of the CNS outside the brain
The rate at which action potentials are produced in a neuron is proportional to
input signal strength
Formation of the Resting Potential: the concentration of K+ is higher
inside the cell, while the concentration of more Na+is higher outside the cell
Interneurons
integrate (analyze and interpret) the information -bipolar neuron
Parkinson's disease
is associated with a lack of dopamine in the brain
When an action potential arrives at a chemical synapse
it depolarizes the plasma membrane at the synaptic terminal, opening voltage-gated channels that allow Ca2+ to diffuse in. The Ca2+ concentration in the terminal rises, causing synaptic vesicles to fuse with the terminal membrane and release the neurotransmitter.
Two or more IPSPs occurring nearly simultaneously at synapses in the same region or in rapid succession at the same synapse have a
larger hyperpolarizing effect than a single IPSP. Through summation, an IPSP can also counter the effect of an EPSP
Gases such as nitric oxide (NO) are ___ in PNS
local regulators in the PNS
A single neurotransmitter may bind specifically to
more than a dozen different receptors
When gated K+ channels open, K+ diffuses out, making the inside of the cell more
negative
Gated ion channels and action potentials play an important role in
nervous system activity
In myelinated axons, Voltage-gated sodium channels are restricted to
nodes of Ranvier, gaps in the myelin sheath
bipolar neurons
one axon and one dendrite -interneurons
A neuron at resting potential contains many
open K+ channels and fewer open Na+channels; K+ diffuses out of the cell
Neurotransmitter binding causes ion channels to
open, generating a postsynaptic potential
how is Information is transmitted from neurons
presynaptic cell (a neuron) to a postsynaptic cell (a neuron, muscle, or gland cell)
neuropeptides
relatively short chains of amino acids, also function as neurotransmitters
The neurotransmitter diffuses across the
synaptic cleft and is received by the postsynaptic cell
Conduction of Action Potentials: Inactivated Na+ channels behind the zone of depolarization prevent
the action potential from traveling backwards
Evolutionary Adaptations of Axon Structure: The speed of an action potential increases with
the axon's diameter
Through summation, an IPSP can counter
the effect of an EPSP
central nervous system (CNS)
where integration takes place; this includes the brain and a nerve cord or ganglia
ligand-gated ion channel,
at many chemical synapses the receptor protein that binds and respond to neurotransmitter
Action potentials propagate more rapidly in myelinated axons because
axons because the time-consuming process of opening and closing of ion channels occurs at only a limited number of positions along the axon.
Opiates is used to
treat pain is a depressant
Hyperpolarization and Depolarization steps
(a) Graded hyperpolarizations producedby two stimuli that increasemembrane permeability to K+ (b) Graded depolarizations producedby two stimuli that increasemembrane permeability to Na+. (c) Action potential triggered by a depola-rization that reaches the threshold.
The presynaptic neuron does what
- synthesizes the neurotrans-mitter at each synaptic terminal,and packages the neurotransmitter in synaptic vesicles located in the synaptic terminal
Modulated Signaling at Synapses: chemical synapses in which the receptor for the neurotransmitter is not part of an ion channel. At these synapses, the neurotransmitter binds to a
-(metabotropic) to a G protein-coupled receptor, activating a signal transduction pathway in the post-synaptic cell involving a second messenger
Neurons communicate with other cells at synapses At electrical synapses At chemical synapses Most synapses are
-At electrical synapses, the electrical current flows from one neuron to another through gap junctions (cardiac muscle) -At chemical synapses, a chemical neurotransmitter carries information between neurons -Most synapses are chemical synapses
Conduction of Action Potentials: what happens at the site where the action potential is generated
-At the site where the action potential is generated (usually the axon hillock), an electrical current depolarizes the neighboring region of the axon membrane
gated ion channels
-Changes in membrane potential occur because neurons contain -that open or close in response to stimuli
Opiates bind to
-the same receptors as endorphins and can be used as painkillers
The positive-feedback loop of channel opening and depolarization triggers an -what happens once initiated
-action potential whenever the mem-brane potential reaches threshold, about -55 mV for many mammals. -the action potential has a mag-nitude that is independent of the strength of the triggering stimulus. Because action potentials either occur fully or do not occur at all, they represent an all-or-none response to stimuli
Steps to a stimulus such as a spider crawling on your leg
-activate sensory neurons (unipolar neurons) -travels up axon of schanw cells -reaches spinal cord passed to motor neurons (multi polar neurons) -trigging you to kick it off -then it travels to your brain
refractory period result of after complete
-after an action potential, a second action potential cannot be initiated -The refractory period is a result of a temporary inactivation of the Na+ channels -After the refractory period is complete, depolarization of the axon hillock to threshold will trigger a new action poten-tial. In many neurons, action potentials last less than 2 mil-liseconds (msec), and the firing rate can thus reach hundreds of action potentials per second.
Graded potentials
-are changes in polarization where the magnitude of the change varies with the strength of the stimulus -Graded potentials induce a small elec-trical current that dissipates as it flows along the membrane. Graded potentials thus decay with time and with distance from their source.
Neurons Neurons use two types of signals to communicate
-are nerve cells that transfer information within the body -electrical signals (long-distance) and chemical signals (short-distance)
Generation of Action Potentials: Depolarization opens what what channels open first what blocks it? potassium channels remain
-both types of channels, but they respond independently and sequentially. -Sodium channels open first, initiatingg the action potential @-55 mv As the action potential proceeds, sodium channels remain open but become inactivated: @30mv a. A portion of the channel protein called an inactivation loop blocks ion flow through the open channel. -Sodium channels remain inactivated until after the membrane returns to the resting potential and the channels close. -Potassium channels open more slowly than sodium channels, but remain open and functional until the end of the action potential.
When an action potential arrives at a chemical synapse,
-depolarizes the plasma membrane at the synaptic terminal, opening voltage-gated channels that allow Ca2+ to diffuse in. The Ca2+ concentration in the terminal rises, causing synaptic vesicles to fuse with the terminal membrane and release the neurotransmitter.
ganglia
-in a central nervous system (CNS), which may include a brain or simpler clus-ters called ganglia. -Processing of information takes place in simple clusters of neurons or a more complex organization of neurons called a brain
Biogenic amines
-include norepinephrine, epinephrine, dopamine, and serotonin
Acetylcholine
-is a common neurotransmitter in vertebrates and invertebrates -muscle stimulation formation, and learning
Glutamate
-is one of several amino acids that can act as a neurotransmitter, in vertebrates and invertebrates
resting potential
-is the membrane potential of a neuron not sending signal - reflecting the fact that the attrac-tion of opposite charges across the plasma membrane is a source of potential energy. For a resting neuron—one that is not sending a signal
Gamma-aminobutyric acid (GABA)
-is the neurotransmitter at most inhibitory synapses in the brain
axon The cone-shaped base of an axon is called
-is typically a much longer extension that transmits signals to other cells at synapses -axon hillock
Generation of Action Potentials: An action potential results from changes in
-membrane potential as ions move through voltage-gated channels -At resting potential 1.Most voltage-gated sodium (Na+) and potassium (K+) channels are closed -When an action potential is generated, 2.Voltage-gated Na+ channels open first, and Na+ flows into the cell 3.During the rising phase, the threshold is crossed, and the membrane potential increases During the falling phase, voltage-gated Na+channels become inactivated; voltage-gated K+channels open, and K+flows out of the cell 5.During the undershoot, membrane permeability to K+ is at first higher than at rest, then voltage-gated K+ channels close and resting potential is restored
Graded potential: inhibitory steps
-moves away from threshold by -neuron transmitters bind to a receptor on a chemically gated channel -gate opens and allows rush K out a neuron
Graded potential: Excitatory steps
-moves towards threshold depolarization By -neuro transmitter will bind to a receptor on chemically-gated channels - gate will open and let in NA deep
Vertebrates have two major classes of acetylcholine receptor
-one that is ligand gated and one that is metabotropic
Voltage-gated ion channels
-open or close in response to a change in voltage across the plasma membrane of the neuron
Termination of Neurotransmitter Signaling: The nerve gas sarin triggers
-paralysis and death due to inhibition of the enzyme that breaks down the neurotransmitter controlling skeletal muscles
what are the three steps to crate a signal in a neuron
-resting potential (-70mv) -graded potential (-55mv) trigger all or nun action potential -action potential
crash course action potential steps
-resting state a. stimulus occurs which trigger the sodium channels open -depolarization a.voltage gates sodium ions open positive sodium ions rush in -reploarization a. voltaged gated potassium ions open letting them out -hyperpolarization a. voltage drops negative closes channels
Nervous systems process information in three
-sensory input, integration, and motor output -example: a. The part of each axon branch that forms this specialized junction b.During the integration stage, networks of neurons in the snail brain process this information to determine if a fish is in fact pres-ent and, if so, where the fish is located c.During the integration stage, networks of neurons in the snail brain process this information to determine if a fish is in fact pres-ent and, if so, where the fish is located
A single EPSP is usually too small to why?
-trigger an action potential in a postsynaptic neuron -consider an EPSP arising at a single synapse. As a graded potential, the EPSP becomes smaller as it spreads from the synapse. Therefore, by the time a particular EPSP reaches the axon hillock, it is usually too small to trigger an action poten-tial
the sodium channels are what is the result of this process
-voltage gated, the increased depolarization causes more sodium channels to open, leading to an even greater flow of current. -a process of positive feedback that triggers a very rapid opening of many voltage-gated sodium channels and the marked temporary change in membrane potential that defines an action potential
peripheral nervous system (PNS)
-which carries information into and out of the CNS -The neurons of the PNS, when bundled together, form nerves
Conduction of an action potential. steps
1. An action potential is generated as Na+ flows inward across the membrane in one region 2.The depolarization of the action potential spreads to the neighboring region of the membrane, reinitiating the action potential there. To the left of this region, the membrane is repolarizing as K+ flows outward. 3.The depolarization-repolarization process is repeated in the next region of the membrane. In this way, local currents of ions across the plasma membrane cause the action potential to be propagated along the length of the axo
what are the steps of Binding of a neurotransmitter to a metabotropic receptor activates
1. G protein-coupled receptor activates a G pro-tein, which in turn activates adenylyl cyclase the enzyme that converts ATP to cAMP 2.Cyclic AMP activates protein kinase A 3.which phosphorylates specific ion channel proteins in the postsynaptic membrane, caus-ing them to open or close.
Generation of Action Potentials: states
1. resting state 2.Depolarization 3.Rising phase of the action potential 4.Falling phase of the action potential 5.undershoot
The role of voltage-gated ion channels in the generation of an action potential.
1. resting state The gated Na+ and K+ channels are closed. Ungated channels (not shown) maintain the resting potential. 2. Depolarization A stimulus opens some sodium channels. Na+ inflow through those channels depolarizes the membrane. If the depolarization reaches the threshold, it triggers an action potential 3.rising phase of the action potential Depolarization opens most sodium channels, while the potassium channels remain closed. Na+ influx makes the inside of the membrane positive with respect to the outsid 4.falling phase of the action potential Most sodium channels become inactivated, blocking Na+ inflow. Most potassium channels open, permitting K+ outflow, which makes the inside of the cell negative again. 5. undershoot The sodium channels close, but some potassium channels are still open. As these potassium channels close and the sodium channels become unblocked (though still closed), the membrane returns to its resting state
A chemical synapse steps
1.An action potential arrives, depolarizing the presynaptic membrane. 2.The depolarization opens voltage-gated channels, triggering an influx of Ca2+. 3.The elevated Ca2+ concentration causes synaptic vesicles to fuse with the presynaptic membrane, releasing neurotransmitter into the synaptic cleft. 4.The neurotransmitter binds to ligand-gated ion channels in the postsynaptic membrane. In this example, binding triggers opening, allowing Na+ and K+ to diffuse through.
multipolar neuron
A neuron with a single axon and multiple dendrites; the most common type of neuron in the nervous system. -motor
Sodium-potassium pumps use the energy of
ATP to maintain these K+ and Na+ gradients across the plasma membrane -pumps in 2 potassium and three sodium
ligand-gated ion channels
Direct synaptic transmission involves binding of neurotransmitters in the postsynaptic cell
In spatial summation
EPSPs produced nearly simultaneously by different synapses on the same postsynaptic neuron add together
synapse
Each branched end of an axon transmits information to another cell at a junction called a
summation
Individual postsynaptic potentials can combine to produce a larger potential
cell body
Most of a neuron's organelles are in
synaptic terminal
The part of each axon branch that forms this specialized junction
Changes in membrane potential
are called action potentials
Although inhaling CO can
be deadly, the vertebrate body synthesizes small amounts of it, some of which is used as a neurotransmitter
When a neuron receives a stimulus, the membrane potential
changes Rapid shifts in membrane potential are what enable us to see the intricate structure of a spiderweb, hear a song, or ride a bicycle.
These concentration ion channels gradients represent
chemical potential energy
the opening of ion channels in the plasma membrane converts
chemical potential to electrical potential
The resulting buildup of negative charge within the neuron is
the major source of membrane potential
postsynaptic neuron
the neuron on the receiving end of the synapse
The action potential causes the release of
the neurotransmitter
Action potentials in myelinated axons jump between
the nodes of Ranvier in a process called saltatory conduction
Neurotransmitter released from the synaptic terminus diffuses across
the synaptic cleft, the gap that separates the presynaptic neuron from the postsynaptic cell.
Conduction of Action Potentials: Action potentials travel in only one direction
toward the synaptic terminals
Sensory neurons
transmit information about external stimuli such as light, touch, or smell -unipolar
Motor neurons
transmit signals to muscle cells, causing them to contract -multipolar
action potential occurs where ?
trigger zone through axon
