Last Class: 1. transportation at the plasma membrane A. carrier protein, B. channel protein 2. intracellular compartments A. nucleus, B. Endoplasmic Reticulum
Intracellular Vesicular Traffic
The endocytic and biosynthetic-secretory pathways
Vesicular transport
The intracellular compartments of the eucaryotic cell in the biosynthetic-secretory and endocytic pathways
Utilization of different coats in vesicular traffic
Clathrin-coated pits and vesicles
The structure of a clathrin coat
The assembly and disassembly of a clathrin coat
The role of dynamin in pinching off clathrin-coated vesicles from the membrane Shibire mutant in drosophila
A current model of COPII-coated vesicle formation
The postulated role of SNAREs in guiding vesicular transport
The structure of paired snare
A model for how SNARE proteins may concentrate in membrane fusion
Dissociation of SNARE pairs by NSF after a membrane fusion cycle is completed
A postulated role of Rab protein in facilitating the docking of transport vesicles
The entry of enveloped viruses into cells
Transport from the ER through the Golgi apparatus
The recruitment of cargo molecules into ER transport vesicles
Retention of incompletely assembled antibody molecules in the ER
Vesicular tubular clusters
A model for the retrieval of ER resident proteins
The Golgi apparatus
The functional compartmentalization of the Golgi apparatus Notice of multiple steps involving glycosylation
Two possible models explaining the organization of the Golgi apparatus and the transport of proteins from one cisterna to the next
Transport from the trans Golgi nextwork to Lysosomes
Lysosomes Low pH Full of Acid hydrolases
The structure of mannose 6-phosphate on a lysosome enzyme
The transport of newly synthesized lysosomal hydrolases to lysosomes
Transport into the cell from the plasma membrane endocytosis
Phagocytosis by a macrophage Phagocytosis: large particle, >250nm Pinocytosis: fluid, liquid, 100 nm One macrophage and two red blood cells
The formation of clathrin- coated vesicles from the plasma membrane
Caveolae in the plasma membrane of a fibroblast
A low-density lipoprotein (LDL) particle
Normal and mutant LDL receptor
The receptor-mediated endocytosis of LDL
Possible fates for transmembrane receptor proteins that have been endocytosed
Storage of plasma membrane proteins in recycling endosomes
Transcytosis
Sorting of membrane proteins in the endocytic pathway Green: EGF-EGFR Red: transferrin and its receptor
The sequestration of endocytosed proteins into internal membranes of multivesicular bodies
Transport from the trans Golgi network to the cell exterior: exocytosis
The constitutive and regulated secretory pathways
The three best-understood pathways of protein sorting in the trans Golgi network
Exocytosis of secretory vesicles
Electron micrographs of exocytosis in rat mast cells Release of histamine
Exocytosis as a localized responses Beads attachment localized the release
Model of lipid rafts in the trans Golgi network
The formation of synaptic vesicles
Summary Intracellular vesicular traffic, SNARE, GAB, Clathrin, Dynamin, Adaptin ER->Golgi, COPII, COPI Golgi->lysosome, acid hydrolases, M6P endocytosis, phagocytosis, pinocytosis, clathrin-coated pit, caveolae, Exocytosis, constitutive and regulated mechanisms
Cell Signaling 1: General Concepts
A simple intracellular signaling pathway
Extracellular signaling molecules bind to receptors
Signals can be tranmitted either short or long distances (I)
Signals can be tranmitted either short or long distances (II)
For Long distance, two typical ways Endocrine signaling Different cells need specific ligands and receptors
Synaptic signaling More efficient, same set of ligands and receptors
Signaling via GAP Junctions No ligand-receptor system needed
Combinatory effect of multiple inputs
Different receptor type and intracellular signaling molecules determine the ultimate response
Many signaling molecules have short lifetime
NO (nitric oxide) induces the relaxation of SMC The function of viagra is to inhibit cyclic GMP phosphodiesterase, hence elongate the lifetime of cyclic GMP and relaxation
2 steps of responses may occur upon stimulation Secon
Cell Surface receptors belong to three classes: 1. ion-channel-linked receptors, 2. G-protein-linked receptors, 3. enzyme-linked receptors
Different Kinds of intracellular proteins serving as signaling molecules 1.Relay proteins 2.Messenger proteins 3.Adaptor proteins 4.Amplifier proteins 5.Transducer proteins 6.Bifurcation proteins 7.Integrator proteins 8.Latent gene regulatory proteins
Two kinds of molecule switch events Phosphorylation and GTP binding
Signaling integration
Intracellular signaling complexes enhance the speed, efficiency, and specificity 2 types: Preassembled vs. Assembled after stimulation
Intracellular signaling complexes enhance the speed, efficiency, and specificity 2 types: Preassembled vs. Assembled after stimulation
Binding domains for interactions between proteins and complex assembly
Cells can be sensitive to subtle difference in environment 1. Multiple ligands are needed for one signaling molecule
Cells can be sensitive to subtle difference in environment 2. Multiple ligated molecules are needed to be assembled to be functional
Cells can be sensitive to subtle difference in environment 3. Positive feedback can enhance the response drastically
Cells can adjust their sensitivity to stimuli by desensitization process
Summary Typical signaling transduction pathway: 1. ligand- receptor, 2. gap junctions Different inputs, receptors, intracellular signaling network determine the ultimate response The importance of lifetime of molecules Different steps of responses The types of receptors: ion-channel-linked, G protein coupled, enzyme-linked receptors Intracellular signaling molecules, signaling switches, signaling integration, signaling complex assembly, protein-protein binding modulus, signaling amplification, signaling desensitization