Transcript ppt

The Membrane Plays a Key Role in
a Cell’s Response to
Environmental Signals
Cells can respond to many signals if they
have a specific receptor for that signal.
A signal transduction pathway is a
sequence of molecular events and
chemical reactions that lead to a
cellular response, following the
receptor’s activation by a signal.
Cells are exposed to
many signals and
may have different
responses:
• Autocrine signals
affect the same cells
that release them.
• Paracrine signals
diffuse to and affect
nearby cells.
• Hormones travel to
distant cells.
Only cells with the
necessary receptors
can respond to a
signal—the target
cell must be able to
sense it and
respond to it.
A signal transduction
pathway involves a
signal, a receptor,
and a response.
A common mechanism of signal transduction is
allosteric regulation.
This involves an alteration in a protein’s shape as
a result of a molecule binding to it.
A signal transduction pathway may produce short
or long term responses.
A signal molecule, or ligand, fits into a threedimensional site on the receptor protein.
Binding of the ligand causes the receptor to
change its three-dimensional shape.
The change in shape initiates a cellular response.
Ligands are generally not
metabolized further, but
their binding may
expose an active site
on the receptor.
Binding is reversible and
the ligand can be
released, to end
stimulation.
An inhibitor, or
antagonist, can bind in
place of the normal
ligand.
Transduction
Receptors can be classified by their location in
the cell.
This is determined by whether or not their ligand
can diffuse through the membrane.
Cytoplasmic receptors have ligands, such as
estrogen, that are small or nonpolar and can
diffuse across the membrane.
Membrane receptors have large or polar ligands,
such as insulin, that cannot diffuse and must
bind to a transmembrane receptor at an
extracellular site.
Receptors are also classified by their activity:
Ion channel receptors, or gated ion channels, change their
three-dimensional shape when a ligand binds.
Protein kinase receptors change their shape when a ligand
binds.
The new shape exposes or activates a cytoplasmic domain
that has catalytic (protein kinase) activity.
Protein kinases catalyze the following
reaction:
ATP + protein  ADP + phosphorylated
protein
Each protein kinase has a specific target
protein, whose activity is changed when it
is phosphorylated.
Ligands binding to G protein–linked receptors
expose a site that can bind to a membrane
protein, a G protein.
The G protein is partially inserted in the lipid
bilayer, and partially exposed on the
cytoplasmic surface.
Signal activation of a specific receptor leads to a
cellular response, which is mediated by a signal
transduction pathway.
Signaling can initiate a cascade of protein
interactions—the signal can then be amplified
and distributed to cause different responses.
A second messenger is an intermediary between
the receptor and the cascade of responses.
In the fight-or-flight response, epinephrine
(adrenaline) activates the liver enzyme
glycogen phosphorylase.
The enzyme catalyzes the breakdown of
glycogen to provide quick energy.
Researchers found that the cytoplasmic enzyme could
be activated by the membrane-bound epinephrine in
broken cells, as long as all parts were present.
They discovered that another molecule delivered the
message from the “first messenger,” epinephrine, to the
enzyme.
The second messenger was later discovered to be cyclic
AMP (cAMP).
Second messengers allow the cell to respond to a single
membrane event with many events inside the cell—they
distribute the signal.
They amplify the signal by activating more than one
enzyme target.
Signal transduction pathways involve multiple
steps—enzymes may be either activated or
inhibited by other enzymes.
In liver cells, a signal cascade begins when
epinephrine stimulates a G protein–mediated
protein kinase pathway.
Epinephrine binds to its receptor and activates a
G protein.
cAMP is produced and activates protein kinase
A—it phosphorylates two other enzymes, with
opposite effects:
• Inhibition—protein kinase A inactivates
glycogen synthase through
phosphorylation, and prevents glucose
storage.
• Activation—Phosphorylase kinase is
activated when phosphorylated and is
part of a cascade that results in the
liberation of glucose molecules.
Figure 5.17 A Cascade of Reactions Leads to Altered
Enzyme Activity (Part 1
)
Figure 5.17 A Cascade of Reactions Leads to Altered
Enzyme Activity (Part 2)
Signal transduction ends after the cell responds—
enzymes convert each transducer back to its
inactive precursor.
The balance between the regulating enzymes
and the signal enzymes determines the cell’s
response.
Cells can alter the balance of enzymes in two
ways:
• Synthesis or breakdown of the enzyme
• Activation or inhibition of the enzymes by other
molecules
Cell functions change in response to
environmental signals:
• Opening of ion channels
• Alterations in gene expression
• Alteration of enzyme activities
Question #2: 1999
Communication occurs among the cells in a multicellular organism.
Choose THREE of the following examples of cell-to-cell
communication, and for each example, describe the
communication that occurs and the types of responses that result
from this communication.
• Communication between two plant cells
• Communication between two immune system cells
• Communication either between a neuron and another neuron,
or between a neuron and a muscle cell
• Communication between a specific endocrine-gland cell and
its target cell