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Cell Communication
Chapter 9
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Communication between cells requiresLigand – signaling molecule
Receptor protein – molecule to which the receptor binds
Interaction of these two components initiates the process of signal transduction, which converts the information in the signal into a cellular response
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Four basic mechanisms for cellular communication1. Direct contact
2. Paracrine signaling
3. Endocrine signaling
4. Synaptic signaling• Some cells send signals to themselves (autocrine
signaling)
Important in early development
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Signal transduction
• Events within the cell that occur in response to a signal
• When a ligand binds to a receptor protein, the cell has a response
• Different cell types can respond differently to the same signal– Epinephrine example
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Phosphorylation
• Addition of phosphate group• A cell’s response to a signal often involves
activating or inactivating proteins• Phosphorylation is a common way to
change the activity of a protein• Protein kinase – an enzyme that adds a
phosphate to a protein• Phosphatase – an enzyme that removes a
phosphate from a protein
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Receptor Types
• Receptors can be defined by their location
1. Intracellular receptor – located within the cell
2.Cell surface receptor or membrane receptor
1).located on the plasma membrane to bind a ligand outside the cell
2). Transmembrane protein in contact with both the cytoplasm and the extracellular environment
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3 subclasses of membrane receptors
1. Chemically gated ion channels – channel-linked receptors that open to let a specific ion
pass in response to a ligand
• Enzymatic receptors – receptor is an enzyme that is activated by the ligand– Almost all are protein kinases
1. G protein-coupled receptor – a G-protein (bound to GTP) assists in transmitting the
signal from receptor to enzyme (effector)
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Intracellular Receptors
• Steroid hormones – Common nonpolar, lipid-soluble structure– Can cross the plasma membrane to a steroid
receptor– Binding of the hormone to the receptor
causes the complex to shift from the cytoplasm to the nucleus
– Act as regulators of gene expression
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• A steroid receptor has 3 functional domains
1.Hormone-binding domain
2.DNA-binding domain
3.Domain that interacts with coactivators to affect level of gene transcription
• In its inactive state, the receptor typically cannot bind to DNA because an inhibitor protein occupies the DNA binding site
• Binding of ligand changes conformation
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Coactivators
• Target cell’s response to a lipid-soluble cell signal can vary enormously, depending on the nature of the cell
• Even the same type of cell may have different responses
• Depends on coactivators present • Estrogen has different effects in uterine tissue
than mammary tissue– Not presence or absence of receptor– Presence or absence of coactivator
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Receptor Kinases
• Protein kinases phosphorylate proteins to alter protein function
• Receptor tyrosine kinases (RTK)– Influence cell cycle, cell migration, cell
metabolism, and cell proliferation• Alteration to function can lead to cancer
– Membrane receptor– Plants possess receptors with a similar overall
structure and function
• RTKs have – A single transmembrane domain
• Anchors them in membrane
– Extracellular ligand-binding domain– Intracellular kinase domain
• Catalytic site of receptor acts as protein kinase
• When a ligand binds, dimerization and autophosphorylation occur
• Cellular response follows – depends on cellular response proteins
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• Insulin receptor• Activated receptor
has phosphorylated sites that allow docking
• Insulin is a hormone that helps to maintain a constant blood glucose level
• Lowers blood glucose
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Kinase cascade
• Mitogen-activated protein (MAP) kinases– Important class of cytoplasmic kinases– Mitogens stimulate cell division– Activated by a signaling module called a
phosphorylation cascade or kinase cascade– Series of protein kinases that phosphorylate
each other in succession– Amplifies the signal because a few signal
molecules can elicit a large cell response
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Scaffold proteins
• Thought to organize the components of a kinase cascade into a single protein complex
• Binds to each individual kinase such that they are spatially organized for optimal function
• Benefit in efficiancy• Disadvantage in reducing
amplification effect
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G-Protein Coupled Receptors
G-protein – protein bound to GTP
G-protein-coupled receptor (GPCRs) – receptors bound to G proteins
G-protein is a switch turned on by the receptorG-protein then activates an effector protein
(usually an enzyme)
Ras proteins
• Small GTP-binding protein (G protein)• Link between the RTK and the MAP kinase
cascade• Ras protein is mutated in many human tumors,
indicative of its central role in linking growth factor receptors to their cellular response
• Ras can regulate itself – stimulation by growth factors is short-lived
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G-Protein Coupled Receptors
• Single largest category of receptor type in animal cells is GPCRs
• Receptors act by coupling with a G protein• G protein provides link between receptor that
receives signal and effector protein that produces cellular response
• All G proteins are active when bound to GTP and inactive when bound to GDP
• Effector proteins are usually enzymes
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• Often, the effector proteins activated by G proteins produce a second messenger
• 2 common effectors
1.Adenylyl cyclase– Produces cAMP– cAMP binds to and activates the enzyme protein
kinase A (PKA)– PKA adds phosphates to specific proteins
2.Phospholipase C– PIP2 is acted on by effector protein phospholipase C
– Produces IP3 plus DAG
– Both act as second messengers29
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Adenylyl cyclase
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• Calcium
• Ca2+ serves widely as second messenger
• Intracellular levels normally low
• Extracellular levels quite high
• Endoplasmic reticulum has receptor proteins that act as ion channels to release Ca2+
• Most common receptor binds IP3
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Cell-to-Cell Interactions
Cells can identify each other by cell surface markers
-Glycolipids are commonly used as tissue-specific markers
-Major histocompatibility complex (MHC) proteins are used by cells to distinguish “self” from “nonself”
• Different receptors can produce the same second messengers
• Hormones glucagon and epinephrine can both stimulate liver cells to mobilize glucose– Different signals, same effect– Both act by same signal transduction pathway
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• Single signaling molecule can have different effects in different cells
• Existence of multiple forms of the same receptor (subtypes or isoforms)
• Receptor for epinephrine has 9 isoforms– Encoded by different genes– Sequences are similar but differ in their cytoplasmic
domains
• Different isoforms activate different G proteins leading to different signal transduction pathways
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