Ectoplasm (cell biology)

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Ectoplasm (also exoplasm) is the non-granulated outer part of a cell's cytoplasm, while endoplasm is its often granulated inner layer. It is clear, and protects as well as transports things within the cell. [1] Moreover, large numbers of actin filaments frequently occur in the ectoplasm, which form an elastic support for the cell membrane. [2] It contains actin and myosin microfilaments. Amoebae form an outer zone of cytoplasm, known as ectoplasm, where actin and myosin association help move it forward. [3]

The term comes from the Ancient Greek words ἐκτός ektos, "outside" and πλάσμα plasma, "anything formed."

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Amoeboid movement is the most typical mode of locomotion in adherent eukaryotic cells. It is a crawling-like type of movement accomplished by protrusion of cytoplasm of the cell involving the formation of pseudopodia ("false-feet") and posterior uropods. One or more pseudopodia may be produced at a time depending on the organism, but all amoeboid movement is characterized by the movement of organisms with an amorphous form that possess no set motility structures.

Force Spectrum Microscopy (FSM) is an application of active microrheology developed to measure aggregate random forces in the cytoplasm. Large, inert flow tracers are injected into live cells and become lodged inside the cytoskeletal mesh, wherein it is oscillated by repercussions from active motor proteins. The magnitude of these random forces can be inferred from the frequency of oscillation of tracer particles. Tracking the fluctuations of tracer particles using optical microscopy can isolate the contribution of active random forces to intracellular molecular transport from that of Brownian motion.

References

  1. "Paramecium Coloring". www.biologycorner.com. Retrieved 23 April 2018.
  2. Arthur C. Guyton, John E. Hall. Textbook of Medical Physiology, Eleventh Edition. Saunders.
  3. Bogitsh, Burton J.; Carter, Clint E.; Oeltmann, Thomas N. (2019). Human parasitology (Fifth ed.). London: Academic Press. ISBN   978-0-12-813712-3.