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Professor G�bor L.
Kov�cs Ph.D.,
Institute of
Diagnostics and Management,
University of
P�cs and Central Laboratory,
Markusovszky
Teaching Hospital,
Markusovszky
St. 3.,
H-9700 Szombathely Hungary
Neurons in
the human brain communicate with each other by releasing chemical
messengers called neurotransmitters (electrical synapses are
present, but in the distinct minority). The
utility cycle of all neurotransmitter molecules is similar: they
are synthesized and packaged into vesicles in the presynaptic cell;
they are released from the presynaptic cell and bind to receptors
on one or more postsynaptic cells, and once released into the
synaptic cleft, they are rapidly removed or
degraded. The total number of neurotransmitters
is not known, but is likely to be well over 100.
Despite this diversity, these agents can be classified into three
broad categories: small-molecule neurotransmitters, neuropeptides,
and unconventional transmitters. In general,
small-molecule neurotransmitters mediate rapid reactions, whereas
neuropeptides tend to modulate slower, ongoing brain
functions. Abnormal transmitter functions may
cause a wide range of neurological and psychiatric disorders; as a
result altering the actions of neurotransmitters by pharmacological
or other means is central to many modern therapeutic
strategies.
Neurotransmitters are chemical signals released from
presynaptic nerve terminals into the synaptic
cleft. The subsequent binding of
neurotransmitters to specific receptors on postsynaptic neurons (or
other cell classes) briefly changes the electrical properties of
the target cells. Over the years, a number of
formal criteria have emerged that definitively identify a substance
as a neurotransmitter. Identifying the
neurotransmitter active at any particular synapse remains a
difficult undertaking, and for many synapses (particularly in the
brain), the nature of the neurotransmitter is not yet
known. Substances that have not met all the
criteria are referred to as putative
neurotransmitters.
The special
characteristics of neurotransmitters are made clearer by comparing
their actions to another type of chemical signal, the hormones
secreted by the endocrine system. Hormones
typically influence target cells far removed from the
hormone-secreting cell. This �action at a
distance� is achieved by the release of hormones into the
bloodstream. In contrast, the distance over
which neurotransmitters act is always much less.
At many synapses, transmitters bind only to receptors on the
postsynaptic cell that directly underlies the presynaptic terminal,
in such cases, the transmitters act over distances less than a
micrometer. At other synapses, neurotransmitters
diffuse locally to alter the electrical properties of multiple
postsynaptic (and sometimes presynaptic) cells in the vicinity of
the presynaptic release sites. While the
distinction between neurotransmitters and hormones is generally
clear-cut, a substance can act as a neurotransmitter in one region
of the brain while serving as a hormone
elsewhere. For example, vasopressin and
oxytocin, two peptide hormones that are released into the
circulation from the posterior pituitary, also function as
neurotransmitters at a number of central
synapses. A number of other peptides also serve
as both hormones and
neurotransmitters.
By the
1950s, the list of neurotransmitters had expanded to include three
amines � epinephrine, dopamine, and serotonin � in addition to
acetylcholine (Ach). Over the following decade,
four amino acids � glutamate, aspartate, γ-aminobutyric acid
(GABA), and glycine � were also shown to be
neurotransmitters. Subsequently, other small
molecules, including nor-epinephrine and histamine, were identified
a transmitters, and considerable evidence now suggests that several
purines (such as ATP, adenosine, and AMP) should be added to the
list. The most recent class of molecules now
know to be transmitters are a large number of polypeptides; since
the 1970s, more than 100 such molecules have been shown to meet at
least some of the criteria for a
neurotransmitter. For purposes of discussion, it
is useful to separate this variety of agents into two board
categories based on size. Neuropeptides are
relatively large transmitter molecules composed of 3 to 36 amino
acids. Individual amino acids, such as glutamate
and GABA, as well as acetylcholine, serotonin, and histamine, are
much smaller than neuropeptides and are therefore called
small-molecule neurotransmitters. Within the
category of small-molecule neurotransmitters, the biogenic amines
(dopamine, nor-epinephrine, epinephrine, serotonin, and histamine)
are often discussed separately because their chemical properties
and postsynaptic actions are distinct from the other
neurotransmitters in this group.
Until
recently, it was believed that a given neurone produced only a
single type of neurotransmitter. There is now
convincing evidence, however, that many neurones contain and
release two or more different neurotransmitters.
There are numerous examples of different peptides in the same
terminal, as well as cases in which two small-molecule
neurotransmitters are found within the same neurone, or in which a
peptide neurotransmitter is found along with a small-molecule
neurotransmitter. When more than one transmitter
is present within a nerve terminal, the molecules are called
co-transmitters. Because each class of
transmitter is usually packaged in a separate population of
synaptic vesicles, co-transmitters often are segregated within a
presynaptic terminal (although there are also instances in which
two or more co-transmitters are present in the same synaptic
vesicle). The presence of co-transmitters lends
considerable versatility to synaptic
transmission. In particular, if a presynaptic
terminal packages co-transmitters in different types of vesicles,
then these transmitters need not be released
simultaneously. In fact, co-transmitters release
varies with the frequency of presynaptic stimulation: empirically,
low-frequency stimulation often releases only small
neurotransmitters, whereas high-frequency stimulation is required
to release neuropeptides from the same presynaptic
terminals. In this way, the presence of
co-transmitters allows the chemical signaling properties of a
synapse to changes according to the level of presynaptic
activity.
The
differential release of co-transmitters is probably based on the
distribution of Ca++ and vesicles in presynaptic
terminals. Typically, a presynaptic terminal
packages small-molecule co-transmitters into relatively small
synaptic vesicles (often with a clear core), some of which are
docked at the plasma membrane, in contrast, peptide co-transmitters
are contained within large dense-core synaptic vesicles that are
farther away from the plasma membrane. At low
firing frequencies, the concentration of Ca++ may
increase only in the vicinity of presynaptic Ca++
channels, limiting release to small-molecule transmitters because
of the selective fusion of small vesicles located immediately
adjacent to the channels. High-frequency
stimulation increases the Ca++ concentration more evenly
throughout the presynaptic terminal, thereby inducing the release
of neuropeptides from the larger, more distant
vesicles.
Effective
synaptic transmission requires close control of the concentration
of neurotransmitters within the synaptic cleft.
Neurones have therefore developed a sophisticated ability to
regulate the synthesis, packaging, release, and degradation (or
removal) of neurotransmitters. In general, each
of these processes is specific for a particular transmitter and
requires a number of enzymes that are found only in neurons that
use the transmitter at their synapses. As a
rule, the synthesis of small-molecule neurotransmitters occurs
locally within presynaptic terminals. The
enzymes needed for transmitter syntheses are transported to the
nerve terminal cytoplasm at a rate of 0.5 to 5 millimetres a day,
by a mechanism known as slow axonal transport.
The precursor molecules used by these enzymes are usually taken
into the nerve terminal by transport proteins found in the plasma
membrane of the terminal. The synthetic enzymes
generate a cytoplasmic pool of free neurotransmitter that must then
be loaded into synaptic vesicles by vesicular membrane transport
proteins.
The
mechanisms responsible for the synthesis and packaging of peptide
transmitters are fundamentally different from those of the
small-molecule neurotransmitters.
Peptide-secreting neurones, like other cells, carry out gene
transcription in their cell bodies.
Transcription often results in the synthesis of polypeptides that
are much larger than the final, �mature�
peptide. Processing these polypeptides, called
pre-propeptides (or pre-proproteins), takes place by a sequence of
reactions in a number of intracellular
organelles. Pre-propeptides are synthesized in
the rough endoplasmic reticulum, where the signal sequence of amino
acids � that is, the sequence indicating, that the peptide is to be
secreted � is removed. The remaining
polypeptide, called a propeptide (or proprotein), then traverses
the Golgi apparatus and is packaged into vesicles in the
trans-Golgi network. The final stages of peptide
neurotransmitter processing occur after packaging into vesicles,
and involve proteolytic cleavage, modification of the ends of the
peptide, glycosylation, phosphorylation, and disulphide bond
formation.
In general,
neuropeptide synthesis is much like the synthesis of proteins
secreted from non-neuronal cells (e.g. hepatic
enzymes). A major difference, however, is that
the neuronal axon often presents a very long distance between the
site of a peptide�s synthesis and its secretion.
The peptide-filled vesicles must therefore be transported along the
axon to the synaptic terminal. The mechanism
responsible for such movement, known as fast axonal transport,
carries vesicles at rates up to 400 mm/day along cytoskeletal
elements called microtubules. Microtubules are
long, cylindrical filaments, 25 nm in diameter that is present
throughout neurones and other cells.
Peptide-containing vesicles are moved along these microtubule
�tracks� by ATP-requiring �motor� proteins such as
kinesin. Following their synthesis,
neurotransmitters are stored within synaptic
vesicles. The nature of these vesicles varies
for different transmitters. Some of the
small-molecule neurotransmitters � acetylcholine and the amino acid
transmitters � are packaged in small vesicles 40-60 nm in diameter,
the centers of which appear clear in electron micrographs,
accordingly, these vesicles are referred to as small clear-core
vesicles. Neurotransmitters are concentrated in
synaptic vesicles by transporter proteins in an energy-requiring
mechanism. Neuropeptides, in contrast, are
packaged into larger synaptic vesicles that range from 90 to 250 nm
in diameter and, with appropriate fixation, appear electron-dense
in electron micrographs � hence, these are referred to as large
dense-core vesicles. The biogenic amine
neurotransmitters are packaged into at least two types of vesicles
that are different from either the small clear-core vesicles or the
large dense-core vesicles. Vesicles containing
biogenic amines can either be small (40-60 nm diameter) dense-core
vesicles, or larger (60-120 nm diameter) irregularly shaped,
dense-core vesicles, depending on the particular class of
neurone.
Once filled
with transmitter molecules, vesicles associate with the presynaptic
membrane and fuse with it in response to Ca2+
influx. The mechanisms of exocytotic release are
similar for all transmitters, although there are differences in the
speed of this process. In general,
small-molecule transmitters are secreted more rapidly than
peptides. For example, while secretion of ACh
from motor neurones requires only a fraction of a millisecond, many
neuroendocrine cells, such as those in the hypothalamus, require
high-frequency bursts of action potentials for many second to
release peptide hormones from their nerve
terminals. These differences in the rate of
transmitter release make neurotransmission relatively rapid at
synapses employing small-molecule transmitters and slower at
synapses that use peptides. Such differences in
the rate of release probably arise from spatial differences in
vesicle localization and presynaptic Ca++
signaling. Thus, the small clear-core vesicles
used to store small-molecule transmitters are often docked at
active zones (specialized regions of the presynaptic membrane),
whereas the large dense-core vesicles used to store peptides are
not. Biogenic amines are packaged into small
vesicles that dock at active zones in some neurones, while in
others they are packaged and released much like
peptides.
When the
transmitter has been secreted into the synaptic cleft, it binds to
specific receptors on the postsynaptic cell to engage in another
cycle of neurotransmitter release, binding, and signal
generation. The mechanisms by which
neurotransmitters are removed vary, but always involve diffusion in
combination with reuptake into nerve terminals or surrounding glial
cells, degradation by specific enzymes, or in some cases a
combination of these. For most of the
small-molecule neurotransmitters there are transporters that remove
the transmitters (or their metabolites) from the synaptic cleft,
ultimately delivering these molecules back to the presynaptic
terminal. Not surprisingly, the particulars of
the processes of synthesis, packaging, release and removal differ
for each neurotransmitter.
17.1
Classical neuro-transmitters
17.1.1 Acetylcholine
(ACh)
ACh is the
neurotransmitter at neuromuscular junctions, at synapses in
sympathetic and parasympathetic ganglia of the peripheral autonomic
nervous system, and at many sites within the central nervous
system. Two major cholinergic neuronal groups
are the basal forebrain nuclear complex and the cholinergic nuclei
of the brain-stem tegmentum. ACh may also act in
some pain and chemosensory pathways. Whereas a
great deal is known about the function of cholinergic transmission
at the neuromuscular junction and at ganglionic synapses, the role
of ACh in the central nervous system is not as well
understood.
ACh is
synthesized in nerve terminals from acetyl coenzyme A (acetyl CoA)
and choline, in a reaction catalyzed by choline acetyltransferase
(CAT). In contrast to most other small-molecule
neurotransmitters, the postsynaptic actions of ACh are not
terminated by reuptake, but by a powerful hydrolytic enzyme,
acetylcholine-esterase (AChE). This enzyme is
concentrated in the synaptic cleft, ensuring a rapid decrease in
ACh concentration after its release from the presynaptic
terminal. AChE has a very high catalytic
activity (5000 molecules of ACh per AChE molecule per second) and
hydrolyzes ACh into acetate and choline.
Cholinergic nerve terminals contain a high-affinity,
Na+-dependent transporter that takes up the choline
produced by ACh hydrolysis. Among the many
interesting drugs that interact with cholinergic enzymes are the
organo-phosphates. These compounds include
mustard gas (a chemical widely used in World War I), numerous
insecticides, and sarin, the agent recently made notorious by a
group of Japanese terrorists. Organo-phosphates
can be lethal to humans (and insects) because they inhibit AChE,
causing ACh to accumulate at cholinergic
synapses. This build-up of ACh depolarizes the
postsynaptic cell and renders it refractory to subsequent ACh
release, causing neuromuscular
paralysis.
17.1.2 Glutamate
Glutamate
is generally conceded to be the most important transmitter for
normal brain function. Nearly all excitatory
neurons in the central nervous system are glutamatergic, and it is
estimated that over half of all brain synapses release this
agent. Glutamate plays an especially important
role in clinical neurology because elevated concentrations of
extracellular glutamate, released as a result of neural injury, are
highly toxic to neurones. The most prevalent
glutamate precursor in synaptic terminals is
glutamine. Glutamine is released by glial cells
and, within presynaptic terminals, is metabolized to glutamate by
the mitochondrial enzyme glutaminase. Following
its packaging and release, glutamate is removed from the synaptic
cleft by high-affinity glutamate transporters present in both glial
cells and presynaptic terminals. Glial cells
contain the enzyme glutamine synthetase, which converts glutamate
into glutamine. Glutamine is then transported
out of the glial cells and into terminals. In
this way, synaptic terminals work together with glial cells to
maintain an adequate supply of the
neurotransmitter. This synthetic pathway is
referred to as the glutamate-glutamine cycle.
17.1.3 GABA and
glycine
Most
inhibitory neurons in the brain and spinal cord use either
γ-aminobutyric acid (GABA) or glycine as a
neurotransmitter. Remarkably, as many as
one-third of the synapses in the brain appear to use GABA as their
neurotransmitter. Unlike glutamate, GABA is not
an essential metabolite, nor is it incorporated into
protein. Thus, the presence of GABA in neurones
and terminals is a good initial indication that the cells use GABA
as a neurotransmitter. GABA is most commonly
found in local-circuit interneurones, although the Purkinje cells
of the cerebellum provide an example of a GABAergic projection
neurone. GABA is synthesized from glutamate by
the enzyme glutamic acid decarboxylase (GAD), which is found almost
exclusively in GABAergic neurons. GAD requires a
cofactor, pyridoxal phosphate, for activity.
Because pyridoxal phosphate is derived from vitamin B6, a dietary
deficiency of B6 can lead to diminished GABA
synthesis. The significance of this fact became
clear after a disastrous series of infant deaths was linked to the
omission of vitamin B6 from infant formula. The
lack of B6 resulted in a large reduction in the GABA content of the
brain, the subsequent loss of synaptic inhibition caused seizures
that in some cases were fatal. The mechanism of
GABA removal is similar to that for glutamate; both neurones and
glia contain high-affinity transporters for
GABA. Most GABA is eventually converted to
succinate, which is metabolized further in the tricarboxylic acid
cycle that mediates cellular ATP synthesis. The
enzymes required for this degradation, GABA aminotransferase and
succinic semialdehyde dehydrogenase, are both mitochondrial
enzymes. Inhibition of GABA breakdown causes a
rise in tissue GABA content and an increase in the activity of
inhibitory neurones. Because epileptic seizures
can arise from a decrease in neuronal inhibition, a GABA
aminotransferase inhibitor, sodium dipropylacetate, is widely used
as an anticonvulsant. Drugs that act as agonists
or as modulators on postsynaptic GABA receptors, such as
barbiturates, are also used clinically to treat epilepsy, and are
effective sedatives and anesthetics. The
distribution of the neutral amino acid glycine in the central
nervous system is more localized than that of
GABA. Glycine inhibits the firing of spinal cord
and brainstem motor neurones but has only a weak effect on neurones
of the cerebral cortex. About half of the
inhibitory synapses in the spinal cord use glycine, most of the
others use GABA. Glycine is synthesized from
serine by the mitochondrial isoform of serine
hydroxymethyltransferase. Once released from the
presynaptic cell, glycine is rapidly removed from the synaptic
cleft by specific membrane transporters.
Mutations in the genes that code for some of these enzymes result
in hyperglycinaemia, a devastating neonatal disease characterized
by lethargy, seizures, and mental
retardation.
17.1.4 The biogenic
amines
There are
five established biogenic amine neurotransmitters: the three
catecholamines � nor-epinephrine (nor-adrenaline), epinephrine
(adrenaline) and dopamine � and histamine and
serotonin. Some aspects of the synthesis and
degradation of the amine neurotransmitters are still not well
defined, but many of the properties of these processes fall
somewhere between those of the other small-molecule
neurotransmitters and those of the
neuropeptides. Drugs that interfere with
biogenic amine metabolism are especially important as treatments
for a variety of clinical disorders. All the
catecholamines are derived from a common precursor, the amino acid
tyrosine. The first step in catecholamine
synthesis is catalyzed by tyrosine hydroxylase and results in the
synthesis of dihydroxy-phenylalanine (DOPA).
Because tyrosine hydroxylase is rate-limiting for the synthesis of
all three transmitters, its presence is a valuable criterion for
identifying catecholaminergic
neurons.
Dopamine is produced by the action of DOPA
decarboxylase on DOPA. Although present in
several brain regions, the major dopamine-containing area of the
brain is the substantia nigra, which plays an essential role in the
control of body movements. In Parkinson�s
disease, the dopaminergic neurones of the substantia nigra
degenerate, leading to a characteristic motor
dysfunction. Because dopamine does not readily
cross the blood-brain barrier, the disease can be treated by
administering DOPA together with drugs that prevent catacholamine
breakdown.
Norepinephrine synthesis requires
dopamine β-hydroxylase, which catalyzes
the production of norepinephrine from dopamine.
Neurones that synthesize norepinephrine are largely restricted to
the locus coeruleus, a brainstem nucleus that projects diffusely to
the midbrain and telencephalon. These neurones
are especially important in modulating sleep and
wakefulness.
Epinephrine is present at much lower levels
in the brain than any of the other
catecholamines. The enzyme that synthesizes
epinephrine, phenyl-ethanolamine-N-methyltransferase, is present
only in adrenaline-secreting neurones. Sensitive
methods that identify epinephrine have confirmed the existence of
epinephrine-containing neurones in the central nervous system and
shown them to be located in two groups in the rostral
medulla. The function of these
epinephrine-containing neurones in the brain is not
known. All three catecholamines are removed by
reuptake into terminals, or into surrounding glial cells, by an
Na+-dependent transporter. The two
major enzymes involved in the catabolism of catecholamines are
monoamine oxidase (MAO) and catechol O-methyltransferase (COMT),
both of which are present within catecholaminergic nerve terminals
and are the targets of numerous psychotropic
drugs.
Histamine has long been known to be released
from mast cells and platelets in response to allergic reactions or
tissue damage. Only recently, however, has this
amine been implicated as a neurotransmitter.
Histamine is produced from the amino acid histidine by a histidine
decarboxylase. High concentrations of histamine
and histamine decarboxylase are found in the hypothalamus, from
whence histaminergic neurones send sparse but widespread
projections to almost all regions of the brain and spinal
cord. Their function remains
uncertain.
Serotonin, or 5-hydroxytryptamine (5-HT), is
also synthesized from one of the common amino acids � in this case,
tryptophan. An essential dietary requirement,
tryptophan is taken up into neurones by a plasma membrane
transporter and hydroxylated in a reaction catalyzed by the enzyme
tryptophan-5-hydroxylase. As in the case of the
catecholamines, this reaction is the rate-limiting step for 5-HT
synthesis. Serotonin is located in discrete
groups of neurons in the raphe regions of the pons and upper
brain-stem, these cells send widespread projections to the
telencephalon and diencephalon and have also been implicated in the
regulation of sleep and
wake-fullness.
17.1.5 ATP and other
purines
All
synaptic vesicles contain ATP, which is co-released with one or
more �classical� neurotransmitters. There is now
strong evidence that ATP acts as an excitatory neurotransmitter in
the periphery. Postsynaptic actions of ATP have
also been demonstrated in the central nervous system, specifically
at dorsal horn neurons and in a subset of hippocampal
neurons. Purines act on a large and diverse
family of receptors, many of which have recently been
cloned. Whether or not purines play a role in
synaptic transmission depends on the presence and/or distribution
of purinergic receptors near the sites of
release. These receptors have been separated
into two major families: the P1 receptors, activated predominantly
by ATP and ADP, and the P2 receptors, activated predominantly by
AMP and adenosine. These receptors can be either
ion channels or G-protein-coupled receptors, and their activation
may subtly shape postsynaptic responses to classical
neurotransmitters. Alternatively, if purinergic
receptors are located presynaptically, their activation could
modulate neurotransmitter release. In any event,
it seems likely that excitatory synaptic transmission mediated by
purinergic receptors is widespread in the mammalian
brain.
17.2
Peptide neurotransmitters (neuropeptides)
Many peptides
are well known as hormones in endocrine cells, including neurons in
the neuroendocrine regions of the brain such as the hypothalamus
and pituitary. Advances in the ability to detect
and isolate these molecules have now shown that peptides may also
act as neurotransmitters, often being co-released with
small-molecule neurotransmitters. The biological
activity of the peptide neurotransmitters depends on the sequence
of their amino acids. Propeptide precursors are
often many times larger than their active peptide products and can
given rise to more than one species of neuropeptide (Table
1).
Table 1. The
processing of neuropeptides
Since each
of these peptide products can be separately contained in synaptic
vesicles, transmission based on peptides often elicits complex
postsynaptic responses. Peptide transmitters
have been implicated in modulating emotions, and some, such as
substance P and the opioid peptides, are involved in the perception
of pain. Still other peptides, such as
melanocyte-stimulating hormone, adrenocorticotropin, and
β-endorphin, regulate complex responses to
stress, whereas neuronal vasopressin and oxytocin are implicated in
learning and memory processes.
Table 2.
Neuropeptides with verified (or putative) transmitter
functions
|
Vasopressin
|
Somatostatin
|
|
Oxytocin
|
Cortistatin
|
|
ACTH
|
CCK-8
|
|
a-MSH
|
Coerulein
|
|
g-Endorphin
|
NPY
|
|
a-Endorphin
|
Galanin
|
|
β-Endorphin
|
Substance P
|
|
Endomorphin-2
|
ANP
|
|
Dynorphine
|
BNP
|
|
Astressin
|
CNP
|
|
Orphanin/nociceptin
|
Angiotensin II
|
|
Nocistatin
|
CRF
|
17.2.1 Substance P
Substance P
is an 11-amino acid peptide present in high concentrations in the
human hippocampus and neocortex. It is also
released from C fibers, the small-diameter afferents in peripheral
nerves that convey information about pain and temperature (as well
as postganglionic autonomic signals). Substance
P is a sensory neurotransmitter in the spinal cord, where its
release can be inhibited by opioid peptides released from spinal
cord interneurones, resulting in the suppression of
pain. The protease responsible from the
inactivation of Substance P is associated with synaptic
membranes.
17.2.2 Opioid
peptides
Morphine
has long been known to be an especially effective
analgesic. This and other opiate drugs affect
the perception of pain by interacting with specific receptors
expressed at a number of sites in the central and peripheral
nervous systems. The endogenous opioid peptides
were discovered during a search for endogenous compounds that
mimicked the actions of morphine. It was hoped
that such compounds would be analgesics, and that their
understanding would shed light on addiction to morphine and other
narcotics. The endogenous ligands of the opioid
receptors have now been identified as a family of more than 20
opioid peptides grouped into three classes: the endorphins, the
enkephalins, and the dynorphins, each class being liberated from an
inactive pre-propeptide. These precursors are
the product of three distinct genes: pre-pro-opiomelanocortin,
pre-pro-enkephalin A, and pre-pro-dynorphin.
Opioid precursor processing is tissue-specific due to the
differential expression of the processing
enzymes. The pro-opiomelanocortin precursor also
contains the sequences for several non-opioid neuropeptides, such
as the stress hormone adrenocorticotropic hormone (ACTH) and
α-, β-, and
γ-melanocyte stimulating hormone (MSH). Opioid
peptides are widely distributed throughout the
brain. In general, these peptides tend to be
depressants. When injected intracerebrally, they
act as analgesics, and have been implicated in the mechanisms
underlying acupuncture-induced analgesia.
Unfortunately, the repeated administration of endorphins leads to
tolerance and addiction. Although the results of
opioid research have not yet provided a complete understanding of
narcotic addiction, a solid basis of knowledge has been established
that promises ultimately to solve this extraordinary social and
medical problem.
17.2.3 Posterior pituitary
peptides (vasopressin, oxytocin)
Vasopressin
exerts a long-term facilitating effect on learning and memory
processes, and also prevents and reverses retrograde
amnesia. In contrast to vasopressin, oxytocin is
an amnesic neuropeptide. Endogenous vasopressin
and oxytocin in the dorsal septum or in the ventral hippocampus is
of particular importance for learning and memory
processes. The two nonapeptides are not only
secreted from the neurohypophysis into the general circulation,
but - probably upon some specific stimuli, and
largely independently of their peripheral release - are also
released intracerebrally (e.g. into septum). The
experiments provide additional evidence for an involvement of
endogenous vasopressin and oxytocin in the regulation of learning
and memory processes. Based on
electrophysiological findings, one might conclude that a
neurotransmitter-like effect is associated with vasopressin in
limbic brain structures. Vasopressin is capable
of modulating long-term potentiation, which is believed to be an
electrophysiological basis of memory processes, and to enhance the
response to glutamate, which might be an indication that
vasopressin acts as a neuromodulator of excitatory pathways in the
limbic-midbrain. Interestingly, the
coerulo-telencephalic noradrenaline system may mediate the effects
of vasopressin on memory consolidation, providing a functional
evidence for the interactions of classical transmitters with
neuropeptides. Vasopressin and oxytocin are
converted to highly selective memory molecules in the brain
as [Cyt6]AVP4-9/5-9 and
[Cyt6]AVP4-8/4-9. These peptide fragments are
more effective than the parent nonapeptides on behavioral
processes.
17.3 Unconventional transmitters
(nitric oxide: new mechanisms of neurotrasnmitter
action)
Some years
ago nitric oxide (NO) was thought about primarily as a toxic gas
relevant to air pollution. The discovery, in
1987, that NO is a signalling molecule that modulates vascular tone
has sparked tremendous interest in the biological effects of this
molecule, which is now recognized as a novel chemical messenger for
a number of cell types, including neurones.
Nitric oxide is certainly not a classical neurotransmitter in the
central nervous system, it is a short-lived radical that interacts
with surrounding neurones by diffusing across membranes, rather
than being released by exocytosis and interacting with
membrane-bound receptors. In this sense, NO
represents a significant departure from all neurotransmitter
mechanisms characterized to date. Nitric oxide
is synthesized from L-arginine following stimulation of the enzyme
nitric oxide synthase (NOS). Neuronal-type
nitric oxide synthase (nNOS) is a widely distributed
calmodulin-regulated enzyme and is coupled to a variety of
neurotransmitter systems in the brain and in peripheral
tissues. Once generated, NO can diffuse locally
and interact with target molecules such as guanylyl cyclase, the
enzyme catalyzing cGMP synthesis. NO and cGMP
together comprise an especially wide-ranging signal transduction
system that may also play an important role in neurological
disease. An emerging hypothesis is that the
balance between nitric oxide and superoxide generation is a
critical factor in the etiology of some neurodegenerative
diseases. Nitric oxide defies current
classification schemes in that it can function both as a
neurotransmitter and a second messenger. In any
event, it demonstrates that, despite a century-long analysis of
neurotransmitter mechanisms, this field still has some surprises in
store.
17.4
Summary
The large
number of neurotransmitters in the nervous system can be divided
into three broad classes: small-molecule (classical) transmitters,
neuropeptides and unconventional transmitters.
Neurotransmitters are synthesized from defined precursors by
regulated enzymatic pathways, packaged into one of a variety of
vesicle types, and released into the synaptic cleft in a
Ca++-dependent manner. Many synapses
release more than one type of neurotransmitter, and multiple
transmitters are sometimes packaged in the same synaptic
vesicle. The postsynaptic effects of
neurotransmitters are terminated by the transmitter back into
cells, or by diffusion out of the synaptic
cleft. Glutamate is the major excitatory
neurotransmitter in the brain, whereas GABA and glycine are the
major inhibitory neurotransmitters. The actions
of these small-molecule neurotransmitters are typically faster than
those of the neuropeptides. Thus, the
small-molecule transmitters usually mediate synaptic transmission
when a speedy response is essential, whereas the neuropeptide
transmitters, as well as the biogenic amines and some other
small-molecule neurotransmitters, can regulate or modulate ongoing
activity in the brain or in peripheral target
tissues. The enormous importance of drugs that
influence transmitter actions in the treatment of neurological and
psychiatric disorders guarantees that a steady stream of new
information in this filed will be
forthcoming.
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