Basic Principles Underlying Cellular Processes
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Transport

Transport in the Cell

Transport Schematic

Basics

  • Transport refers to the cell transporting molecules and ions across membranes - cellular or organelle membranes.
    • Transport is critical to the cell, as it must obtain nutrients, sort molecules, and export waste.
    • Transport can be active or passive.
  • Passive transport occurs when molecules flow from a region of high to low concentration. Such flow requires no free energy, but the cell may use free energy to regulate the flow, by turning it on or off as needed.
    • Example: The action potential in a neuron is gated passive transport.
    • See the discussion of ion concentration gradients to learn the basics of electrostatic influences in passive transport.
  • Active transport uses free energy to pump a molecule against its concentration gradient (i.e., from low to high concentration). This can occur by two generic mechanisms depending on the type of free energy expended to do the pumping:

Transport

Transport in the Cell

Transport Schematic

Basics

  • Transport refers to the cell transporting molecules and ions across membranes - cellular or organelle membranes.
    • Transport is critical to the cell, as it must obtain nutrients, sort molecules, and export waste.
    • Transport can be active or passive.
  • Passive transport occurs when molecules flow from a region of high to low concentration. Such flow requires no free energy, but the cell may use free energy to regulate the flow, by turning it on or off as needed.
    • Example: The action potential in a neuron is gated passive transport.
    • See the discussion of ion concentration gradients to learn the basics of electrostatic influences in passive transport.
  • Active transport uses free energy to pump a molecule against its concentration gradient (i.e., from low to high concentration). This can occur by two generic mechanisms depending on the type of free energy expended to do the pumping: