CHAPTER 11 cell signaling
I. Local regulators Ex) growth factors – paracrine signaling
and synaptic signaling
II. Long distance signaling - Hormones (insulin, ethylene) - nervous system
3 stages of signaling
Earl Sutherland (1971) Epinephrine and glycogen breakdown
1) Reception – binding to signal receptor 2) Transduction-often a series of changes (signal
transduction pathway)3) Response-end result – a specific cellular
response
Receptor types
• I. Bound to plasma membrane G protein couple receptors Receptor Tyrosine Kinases Ion channel receptors• II. Intracellular• Located in cytosol or nucleus• require hydrophobic or small messengers• Steroid hormones, thyroid hormones, NO
Membrane receptors up close
• G Protein-Coupled receptors widespread, very common, involved with
neurotransmitters(nervous), many hormones (epinephrine), and embryonic development
Involves G protein and GTP
1. G protein (cytoplasmic side) is off when bound to GDP
2. Ligand binds to extracellular side of receptor3. Receptor is actived (shape) and binds to G
protein4. GTP replaces GDP on G protein5. G protein binds to and activates an enzyme6. G protein hydrolyzes GTP to GDP (GTPase) and
returns to start
• Receptor Tyrosine Kinases• kinases transfer phosphate groups• Involved with enzymatic activity• Ex. Growth hormone binding/response
1. Individual receptor tyrosine kinase proteins bind a signaling molecule (ligand)
2. Tyrosine kinase proteins form a dimer3. This activates the kinase region of each, and
each tyrosine kinase phosphorylates its tyrosines via ATP
4. Once activated, it is recognized by relay proteins in cell and binds them
5. Often activates multiple pathways
• Ion Channel Receptors• Involves gated responses involving ion flow• Ex) neurotransmitters (ligands) and neurons
(action potentials)• Ions flowing across membranes create
currents
1. Ligand binds to channel receptor while receptor is in closed conformation
2. Receptor changes shape to open gate3. Very specific ion(s) begin to flow down their
electrochemical gradient4. This flow of ions affects cell function5. Ligand dissociates, ending the process
Intracellular receptor model
Results in gene expression (ex. Testosterone effects)
1. Steroid hormone passes through plasma membrane and binds to receptor protein in cytoplasm
2. Activated receptor protein enters the nucleus and acts as a transcription factor for a particular gene
Cascading……….
Can greatly amplify the signal to numerous molecules at each step
*usually involves “phosphorylating” proteins a)protein kinase – transfers phosphates to
other proteins(targeting serine or threonine)
b) Protein phosphatase – de-phosphorylates proteins, making them available again and terminating the signal.
Second Messengers
• Involves small, non-protein , water soluble molecules or ions
• Focus: cyclic AMP (cAMP) and Calcium(Ca++)
cAMP figure 11.10/11.11
• 1. Epinephrine binds to receptor protein• 2. Receptor activates “adenylyl cyclase” which
converts many ATP to cAMP• 3. cAMP is short lived due to
“phosphodiesterase”, which converts cAMP to AMP
• 4. Some G protein pathways can inhibit adenylyl cyclase
Calcium
Typically low in cytosol (why?)
IP3 (inositol triphosphate) acts before Calcium FIGURE 11.13
Calcium ions are involved in muscle contractions and neurotransmitter release
FINE tuning
I. Signal Amplification – a small amount of signaling molecule can cause large changes
II. Different responses to same signaling molecule (epinephrine)
III. Signaling efficiency – scaffolding proteins – pathways are often complex, not linear(11.18)
IV. Termination is necessary
APOPTOSIS
• -programmed cell death via “digestion” (internally and externally)
• Signal can be external (from other cells) or internal from nucleus or ER
• Proteins for such events are always present, but inactive
• Caspases are proteases of apoptosis
• C. elegans (nematode) ced-3 and Ced-4 genes for appropriate apoptosis proteins
Learning outcome
Objectives: 1) students will be able to relate cell
differentiation and specialization to different cellular responses to a particular ligand.
2) Students will be able to discuss various mechanisms by which cells can communicate with other cells via signaling molecules.
Multiple choice
I. One major characteristic of cell signaling is that the pathway must be able to be “turned on and shut off” when needed. Which pathway involves an activation mechanism not initiated by the binding of a ligand to and external cellular receptor?
a) the phosphorylation of tyrosines b) the opening and closing of voltage regulated ion
channels c) reception of a hormone to form a transcription
factor d) the binding of GTP to activate a G protein
Open Response
I. a) Discuss the three stages of “cell signaling.”
b) Explain how just one particular ligand can ultimately stimulate different types of body cells to respond in very different ways. Also, describe why some body cells might not respond at all to a given ligand.