Cell Communication Processes in Biology PDF

Summary

This document describes different types of cell signaling. It covers topics like cell signaling cascades, responses to external signals, and the chemical synapse, including neurotransmitters and their modulation. The document also discusses cell communication between yeast mating types, effects of external signals on animal cells, and responses to external signals, including fast and slow responses. It also explains communication junctions (gap junctions and plasmodesmata), juxtacrine signaling, and signaling through secreted molecules (including endocrine, autocrine, paracrine, and synaptic signaling). Additional topics include the role of neurotransmitters in signaling, different types of neurotransmitters, and the vertebrate limbic system.

Full Transcript

Communication Between Cells
cell signals and signaling cascades
responses to external signals
modes of cell signaling
the chemical synapse:
-signaling at the synapse
-excitatory and inhibitory signals
-the neuromuscular junction
neurotransmitters and their
modulation

References: p. 554-560,
434-438, 574-575
 Cell communication between yeast mating types

“Shmoo”

The fusion of haploid yeast cells of opposite mating types
(a and a) results in a diploid cell (a/a). The cells synthesize
and secrete mating factors to communicate with each other
and initiate fusion. The initial response to receiving the signal
from the other cell is a change in cell shape (B).
 Effects of external signals on cells in animals
Cells need signals for survival and function.
cells need signals to survive (A, B, and C)
external signals (D & E) can induce a cell to divide (to enter
the cell division cycle)
cells also require signals (F & G) to differentiate (to
become specialized during development
if a cell receives no signals: death by apoptosis
 Effects of
external signals on
cells in animals
 A signal molecule can induce different
responses in different target cells

Acetylcholine (Ach):
the neurotransmitter is released by parasympathetic neurons
of the autonomous nervous system, causing a reduced
frequency of cardiac muscle contraction and an increase in
salivary secretions
it is also the neurotransmitter released by motor neurons in
neuromuscular junctions, causing skeletal muscle
contraction
 Effect of acetylcholine in parasympathetic regulation

Decreased Food
heart rate digestion

Lower AP
frequency
Effect of acetylcholine on skeletal muscle cells
Note: while the receptor
for acetylcholine from
parasympathetic neurons
is a G protein-coupled
receptor, the receptor
for acetylcholine from
motor neurons is an
acetylcholine-gated ion
channel.

Force generation
 Requirements for cell-to-cell communication

1. A signal (and the means to deliver it).
2. A receptor in the responsive cell.
3. Intracellular signaling proteins.
4. The modification of target proteins.
Result: a response.
Signaling
cascades

Responses
 Responses to external signals

Fast: the intracellular cascade depends on already present
enzymes and target proteins, and does not require gene
expression (takes < one second to a few minutes). No gene
expression is induced. Fast responses are short-lived.

Slow: the signal results in gene expression, and the response
to the signal depends on the gene products (this slows
down the process: it takes minutes to hours). Slow
responses are longer lasting.
Responses to external signals
 Modes of cell signaling communication junctions
Communication junctions:
gap junctions
plasmodesmata

Gap junctions
occur in animals
the cytoplasms of adjacent cells are connected through
connexons: hollow transmembrane complexes of
connexin proteins
 Modes of cell signaling communication junctions

Gap junctions

p. 701
 Modes of cell signaling communication junctions

Plasmodesmata
occur in plants
no transmembrane protein systems
plasma membranes of adjacent cells are fused through holes
in the cell walls
 Modes of cell signaling: juxtacrine

Juxtacrine signaling
direct cell-to-cell contact
the signal and the receptor are both cell surface molecules
Modes of cell signaling: signaling through secreted molecules

Endocrine signaling: hormones
the secreted signals enter the circulatory system
the signals are stable and can reach distant target cells
 Modes of cell signaling: signaling through secreted molecules

Autocrine signaling: the secreted signal can trigger
responses in the same cell that secretes it.
Paracrine signaling:
the secreted signals can only reach neighboring cells
the signals do not enter the circulatory system
Modes of cell signaling: signaling through secreted molecules

Synaptic signaling
a special type of paracrine signaling: the target is a specific
cell (the postsynaptic cell) in a permanent interaction
the signals are neurotransmitters (stored in synaptic
vesicles at the axon terminal of the neuron) that are
released and reach the target cell (or cells) over a small
space, or gap (the chemical synapse)
 The neuron

Electric signals travel along the axon to the nerve terminal.
The propagation of electric signals is caused by ion currents
through the axon membrane by the alternating opening,
inactivation, and closing of voltage-gated ion channels.
 Signaling to the post synaptic cell
In the neuron (the presynaptic cell):
the electrical signal (voltage changes due to Na+/K+ currents
through voltage gated channels) reaches the axon terminal
where it opens voltage-gated Ca2+ channels
the inflow of Ca2+ causes the neurotransmitter-containing
synaptic vesicles to fuse to the presynaptic membrane,
and the neurotransmitters are released to the synapse
=> The signal is converted to a chemical signal.
In the synapse and postsynaptic cell:
the released signals reach receptors on the post-synaptic cell
(typically, neurotransmitter-gated ion channels)
ion channels in the post-synaptic membrane open
ion currents occur, changing the voltage of the membrane
=> The signal is converted back to an electrical signal.
Conversion of an electrical signal into a chemical signal

AP

Presynaptic membrane: in the axon terminal.
Postsynaptic membrane: in the target cell.
Conversion of an electrical signal into a chemical signal
and then back to an electrical signal
 Two types of neurotrasmitters
The ions that flow through the postsynaptic membrane after
a neurotransmitter opens ion channels may have an
excitatory or inhibitory effect.
1. Excitatory neurotransmitters cause the depolarization of
the post-synaptic membrane.
they open Na+ channels on the postsynaptic membrane and
cause an inflow of the ion, causing:
membrane depolarization: an excitatory post-synaptic
potential (EPSP)
this can trigger action potentials
 Two types of neurotrasmitters
The ions that flow through the postsynaptic membrane after
a neurotransmitter opens ion channels may have an
excitatory or inhibitory effect.
2. Inhibitory neurotransmitters cause the hyperpolarization
of the post-synaptic membrane.
they open Cl- channels on the postsynaptic membrane and
cause an inflow of the ion
membrane hyperpolarization: inhibitory post-synaptic
potential (IPSP)
this blocks action potentials from happening
 Two types of neurotrasmitters
Why are neurotransmitters categorized
as either excitatory or inhibitory?
Excitatory neurotrasmitters bring the cell membrane closer
to the threshold potential, increasing the probability of
triggering action potentials.
Inhibitory neurotrasmitters decrease the probability of
triggering action potentials by hyperpolarizing the cell
membrane.
 Examples of neurotransmitters and their regulation

Excitatory neurotransmitter in the neuromuscular junctions:
Acetylcholine (ACh) is the neurotransmitter that crosses the
synapse between a motor neuron and a skeletal muscle.
opens ACh-gated Na+ channels
its overall effect is the depolarization of the muscle cell
membrane (EPSP)
the depolarization of the membrane due to the Na+ current
triggers action potentials and the contraction of the
muscle cell (and force generation)
The innervation of a muscle to form neuromuscular junctions
(the synapses between motor neurons and muscle fibers):
the axon terminal of a motor neuron branches to innervate
multiple muscle fibers (muscle cells).
 Examples of neurotransmitters and their regulation

Na+
The acetylcholine receptor in the neuromuscular junction
is an example of a ligand-gated ion channel: the ligand
(Ach) opens Na+ channels for facilitated diffusion.
Acetylcholinesterase is an enzyme that degrades ACh to
terminate the signal and allow the muscle to relax.
 Amino acid neurotransmitters

Excitatory amino acid neurotransmitter in the CNS:
Glutamate (glutamic acid)
the glutamate receptors are gated Na+ and Ca2+ channels
modulated by reuptake into the neuron
also modulated by GABA
excessive stimulation by glutamate results in
neurodegeneration (Huntington’s disease)
 Amino acid neurotransmitters

Inhibitory amino acid neurotransmitter in the CNS:
GABA (gamma-aminobutyric acid)
GABA receptors are gated Cl- channels
important for the neural control of body movements and
other brain functions
modulated by reuptake
Valium and Xanax (sedative drugs) enhance the binding of
GABA to its receptor
 Amino acid-derived neurotransmitters
(Biogenic amines)

Excitatory biogenic amine in the CNS:
Dopamine
causes EPSP
it is a controller of body movements and pleasure sensations
if dopamine-releasing neurons degenerate: tremors occur
(Parkinson’s disease)
 The vertebrate limbic system

The limbic system are functionally and anatomically interconnected
structures that are located in the brain. Their main role is the control of
functions necessary for self preservation and species preservation.
 Modulation of dopamine activity in limbic system
Dopamine is active in the pleasure pathways in the
amygdalae (part of the limbic system of the brain).
the activity of dopamine is controlled by reabsorption:
neurotransmitter molecules are removed from the synapse
by transporters
The reabsorption of dopamine can be blocked by cocaine:
cocaine resembles dopamine and binds to the transporters
dopamine is not removed from the synapse and remains
stimulating the limbic system
pleasure sensations are heightened
if too much dopamine is present in the synapses (and
excessive stimulation persists): the down-regulation of
the dopamine receptors in the post-synaptic cell begins
Modulation of dopamine activity in limbic system
 Modulation of dopamine activity in limbic system

(dopamine)

(cocaine)
Normal stimulation of Excessive stimulation due to
the post-synaptic cell. the presence of the analog.
 Modulation of dopamine activity in limbic system

The post-synaptic cell responds by decreasing the number of
surface dopamine receptors (down-regulation). The cell
balances the signal received by controlling the activity of
the receptor
Drug dependence:
insufficient neurotransmitter stimulation if no drug is present
(fewer receptor means more neurotransmitter is needed
for normal stimulation)
withdrawal symptoms occur if the drug is removed
 Modulation of dopamine activity in limbic system

The number of dopamine The synapse is less sensitive
receptors in the postsynaptic when the drug is removed
membrane decreases. (drug addiction).
 Amino acid-derived neurotransmitters
(Biogenic amines)

Biogenic amine in the CNS:
Serotonin
effect: EPSP/IPSP, depending on the receptor
a regulator of sleep and emotional states
its activity is controlled by reabsorption
insufficient serotonin activity in the synapses may result in
clinical depression
Serotonin and
depression

Prozac ® is a selective
serotonin reuptake
inhibitor (SSRI).
 Peptide neurotransmitters (neuropeptides)
Neuropeptides are short chains of amino acids.

Substance P
released at the synapses in the CNS by sensory neurons
activated by painful stimuli (P: pain)
excitatory (EPSP): results in pain sensations
the intensity of the pain is modulated by the effect of
endogenous opiates (enkephalins and endorphins,
which are inhibitory neuropeptides)
 Peptide neurotransmitters (neuropeptides)
Endorphins and enkephalins are endogenous opiates.
They are produced by the brain to block the perception
of pain.

Endorphin

Morphine and heroin are exogenous opioids. They have an
analgesic (pain-reducing) effect because they can bind to
enkephalin and endorphin receptors.
 Gas signals
Synthesis of Nitric oxide (NO) from the deamination
of arginine

NO synthase

Gas signals such as NO are synthesized upon the stimulation
of the secreting cell. They diffuse to the target cell rapidly but
are very short-lived: 1/2 life of only a few seconds.
 Effects of nitric oxide
The synthesis of NO in endothelial cells is stimulated by
acetylcholine, which activates NO synthase (NOS).
the specific ACh-releasing neurons do not synapse with
smooth muscle cells, but instead synapse with the
endothelial cells inside blood vessel
NO is synthesized and diffuses rapidly to the surrounding
smooth muscle cells
Results:
the relaxation of the smooth muscles surrounding the blood
vessels
the dilatation of the blood vessels and increased blood flow
not to be confused with laughing gas (nitrous oxide, N2O)
Effects of nitric oxide