This page was automatically generated by NetLogo 3.1.4. Questions, problems? Contact feedback@ccl.northwestern.edu.
The applet requires Java 1.4.1 or higher. It will not run on
Windows 95 or Mac OS 8 or 9. Mac users must have OS X 10.2.6 or higher and use
a browser that supports Java 1.4. (Safari works, IE does not.
Mac OS X comes with Safari. Open Safari and set it as your default
web browser under Safari/Preferences/General.)
On other operating systems, you may obtain the latest Java plugin from
Sun’s Java site. General information on the models, including instructions for running them on your own computer, is available from the NetLogo Simulation Information Page. To download this page, do not use "Save As," but right-click (or on Macs control-click) on this link. You also need to download the NetLogo program, which you can do by right-clicking or control-clicking this link.
created with NetLogo
view/download model file: SlimeStream.nlogo
This program simulates the streaming aggregation of the cellular slime mold Dictyostelium discoideum. When Dictyostelium amoebae are starved on an agar surface they begin to aggregate, forming complex spatial patterns as they do so. Aggregation leads to the formation of a multicellular organism, called a slug, consisting of about 10,000 to 100,000 cells, that can move about on the substrate for some time. Eventually, the slug develops into a fruiting body, a spherical stalk with a cap on top that contains spores. Under the appropriate conditions the spores can be released and germinate, thus completing the cycle.
The amoebae coordinate their movement by secreting cyclic adenosine monophosphate (cAMP) and by moving up the resulting cAMP gradient. More specifically, the aggregating cells follow this set of behavioral rules:
- if a cell senses a concentration of cAMP above the movement threshold, it aligns itself with the cAMP gradient and takes 1/2 step towards the highest cAMP concentration
- if a cell senses a concentration of cAMP above the relay threshold (which is believed to be higher than the movement threshold), the cell (after moving) emits 100 units of cAMP and enters a "refractory" state for a specified number of time steps
- cells that are in the refractory state are insensitive to cAMP, thereby disabling chemotactic movement and cAMP secretion; instead, these cells gradually break down the cAMP in their locality, by means of an enzyme called phosphodiesterase
In reality, the cAMP waves move several times faster than the slime mold cells; THIS PROGRAM EXAGGERATES THE SLIME MOLDS' MOVEMENT in order to illustrate the streaming aggregation. A separate program disables cell motion to illustrate the cAMP waves more clearly.
The model also includes an autonomous cell in the center of the screen that releases cAMP at regular intervals, regardless of the chemical concentration there. These autonomous cells have been observed experimentally. With each time step, patches share 50% of their cAMP content with the eight neighboring patches.
The SETUP button creates a random distribution of slime mold cells and prints a color key in the command window.
The GO button sets the model in motion according to the rules outlined above.
The DENSITY slider specifies the initial density of slime mold cells; if the density is too high given the size of the screen, an error message will appear in the command center when executing setup.
The PERIOD slider controls the length of the refractory period; this is also the number of time steps between cAMP releases by the autonomous cell in the center of the screen.
The MOV_THRESHOLD and REL_THRESHOLD sliders denote the concentration of cAMP required for movement and relay response, respectively.
The FIELD DISP ON and FIELD DISP OFF buttons turn on/off display of the cAMP field. The chemical concentration is displayed as shades of green (from white = highest concentration to black = lowest).
The START MOVIE and STOP MOVIE buttons start and stop the recording of a QuickTime move of the simulation. The movie is left in a file name "sim-movie.mov" in the same directory as the simulation.
The streaming patterns develop gradually and consistently, but can are affected by changes in the slider variables. "Period" must be high enough to allow cAMP waves to remain distinct as they propogate from the center; otherwise, waves can intermingle in areas of irregular density to create self-feeding spirals that serve as new aggregation centers. Also, modification of the thresholds can result in slightly different patterns. The model is generally less sensitive to changes in density.
Experiment with the thresholds to see how they affect the streams and the rate of aggregation.
The slime mold amoebae end up on top of one another. Some device could be used to indicate how many amoebae are occupying each patch.
This section could point out any especially interesting or unusual features of NetLogo that the model makes use of, particularly in the Procedures tab. It might also point out places where workarounds were needed because of missing features.
See Slime in the Biology models for a model of a different aspect of slime mold aggregation.
Original program for StarLogo 2 by Steve Camazine. Modified to run on NetLogo and to show chemical field and allow movie recording by B.J. MacLennan 2003, 2006.
Return to CS 420/594 home page
Return to MacLennan's home page
Send mail to Bruce MacLennan / MacLennan@utk.edu
This page is www.cs.utk.edu/~mclennan/Classes/420/NetLogo/SlimeStream.html