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Explore the process of cell communication through the generation, transmission, and reception of chemical signals. Discover how signal transduction pathways convert external signals into specific cellular responses. Learn about the evolutionary aspects of cell signaling and its role in both unicellular and multicellular organisms.
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Cells communicate by generating, transmitting, and receiving chemical signals.
Signal transduction pathway • Process by which a signal on a cell’s surface is converted into a specific cellular response • Communication involves transduction of stimulatory or inhibitory signals from other cells, organisms or the environment • Occurs in both unicellular and multicellular organisms
Signal transduction pathways • Occurs in 3 steps • Reception: target cell detects signal (ligand) coming from outside of cell (binds with protein usually on cell surface) • Transduction: binding of signal molecule changes protein in some way causing a relay of message inside cell • Response: transduced signal triggers a specific cellular response
Evolution and Cell Communication • Cell communication processes reflect a shared evolutionary history. • Evidence from yeast and animals suggest that early versions of cell signaling mechanisms used today evolved from bacteria
Unicellular organisms • Signal transduction pathways influence how the cell responds to its environment • Examples:
Response to external signals by bacteria that influences cell movement
Use of pheromones to trigger reproduction and developmental pathways • Example: mating yeast cells
Quorum Sensing • Use of chemical messengers by microbes to communicate with other nearby cells and to regulate specific pathways in response to population density • allows one organism to influence the gene expression of other bacteria in close proximity • Regulates: biofilm formation, virulence, and antibiotic resistance
Multicellular Organisms • Signal transduction pathways coordinate the activities within individual cells that support the function of the organism as a whole
Temperature determination of sex in some vertebrate organisms
Cells communicate with each other through direct contact with other cells or from a distance via chemical signaling
Direct Contact Cell to Cell Communication • Cells can communicate by transferring chemical messengers that target cells in close vicinity
Example of Direct contact • Immune cells interact by cell-cell contact, antigen presenting helpers (APCs), helper T cells and killer T Cells • T cells and antigens circulate within blood and detect specific invaders, they produce chemical signals to tell each other that the cells belong
Plasmodesmata (gap junctions) between plant cells that allow material to be transported from cell to cell
Plant immune responses • invading pathogen are deprived of nutrients because the plant sends signals to kill cell surrounding the region where the pathogen infected the plant. Plant also induces the production of antimicrobial proteins. • When herbivores start eating plant, cell sends chemical signals to other regions of the plant • Some chemicals can inhibit leaf digestion in the insect’s gut
Quorum Sensing • Social insects use it to determine where to nest
APOPTOSIS“Cell suicide” Why are “Death proteins“ present in inactive form?
Signal transduction pathways link signal reception with cellular response • Signaling begins with the recognition of a chemical messenger, a ligand, by a receptor protein • Different receptors recognize different chemical messengers, which can be peptides, small chemicals or proteins, in a specific one to one relationship • A receptor protein recognizes signal molecules, causing receptor protein’s shape to change, which initiates transduction of the signal
G protein linked receptors • Plasma membrane receptor • When GDP is bound, G protein is inactive • When GTP is bound, G protein is active
Ligand gated ion channels • Incoming IONS trigger the response
Receptor tyrosine kinases • Receptor for growth factor • KINASE: Protein that “phosphorylates” (adds a phosphate to) another molecule • TYROSINE KINASES: Proteins that form dimers. Tyrosine amino acid residues are active in transfer of phosphates to relay proteins • Remain ACTIVE as long as LIGAND is attached
Cell Communication Part 2
Neurons (Nerves) • Specialized cells to transmit nerve impulses from one part of body to another • 3 main parts • Dendrite (signal receiving end) • Cell body • Axon (signal sending end)
Many axons have a myelin sheath that acts as an electrical insulator. • Schwann cells, which form the myelin sheath, are separated by gaps of unsheathed axon over which the impulse travels as the signal propagates along the neuron
Synapses • junction between two neurons where messages are passed on by neurotransmitters
Resting neuron structure • Contain potassium (K+) ions inside neuron • Sodium (Na+) ions are outside plasma membrane and don’t normally pass inward
Polarized neuron • Inactive (not sending an impulse) • Inside of neuron negatively charged to compared to outside
Stimulated neuron- Depolarization • Na+ gates in membrane open and Na+ rushes into cell causing inside to be more positive than outside of cell which activates neuron to transmit an action potential
Action potential • nerve impulse which causes the axon to release a neurotransmitter into synapse that binds to next neuron stimulating it
Cell Repolarization • After action potential • K+ rushes out of cell causing the inside to become negative again • Must occur before neuron can send another nerve impulse
After repolarization • Na+/K+ pump • Pumps K+ into cell and Na+ out to restore cell to make it polarized again
Transmission of information via neurotransmitters between neurons occur across synapses and result in responses • Responses can be stimulatory or inhibitory • Epinephrine • Acetylcholine • Norepinephrine • Dopamine • Serotonin • GABA
Signals released by one cell type can travel long distances to target cells of another type • Endocrine signals (hormones) are produced by endocrine cells that release signaling molecules, which are specific and can travel long distances through the blood to reach all parts of the body • Examples: • Insulin • Human growth hormone • Thyroid hormone • Testerone • Estrogen