Maker/Moocher Theophylline Producing Cells

No preview image

1 collaborator

Default-person Micah Brown (Author)

Tags

biology 

"it models a biological system"

Tagged by Micah Brown over 11 years ago

cells 

Tagged by Micah Brown over 11 years ago

metabolic pathway 

Tagged by Micah Brown over 11 years ago

Visible to everyone | Changeable by the author
Model was written in NetLogo 5.0.4 • Viewed 589 times • Downloaded 97 times • Run 0 times
Download the 'Maker/Moocher Theophylline Producing Cells' modelDownload this modelEmbed this model

Do you have questions or comments about this model? Ask them here! (You'll first need to log in.)


WHAT IS IT?

We have discovered a concern about using Programmed Evolution for theophylline production in E. coli. It has to do with the ability of theophylline to freely cross the membrane of a bacterial cell that made it. The theophylline could then diffuse to a cell that does not make it, and enter that cell. The cell that did not make theo could then gain fitness (unfairly).

HOW IT WORKS

There are three agents: 1) Maker Cells - E. coli cells that produce theophylline 2) Moocher Cells - E. coli cells that DO NOT produce theophylline 3) Theophylline

Maker cells and moocher cells differ in: a) color b) the ability to produce theophylline Additional traits may be set using the sliders to make them differ more.

*All agents have a lifespan, and will die when that runs out. Theophylline has a lifespan of about (1/3) of the cells *The cells gain energy when theophylline is present in the cell. It takes energy to move, so every tick they slowly spend energy (but gain if theophylline is present) *Cells reproduce when they have reached a certain threshold (user can set). Then a new cell of the same type is formed, and each cell now has half of the energy of the parent. Also, the theophylline is split with its child. *Cells need to wait a certain "downtime" before reproducing again.

HOW TO USE IT

*theo-production: controls the amount (likelihood) that a maker cell produces theophylline on any givin tick.

*diffusion-out-rate: countrols the likelihood that a theophylline will leave a cell when it is located at the membrane.

*diffusion-in-rate: controls the likelyihood that a theophylline will leave a cell when it is located at the membrane.

*initial-amount-makers: sets the amount of makers to be created at setup *initial-amount-moochers: sets the amount of moocher cells to be created at setup *initial-lifespan: sets the lifespan of the E. coli cells at setup *initial-energy: sets the energy of E. coli cells at setup *initial-theophylline: set teh amount ot theophylline to be created at setup *reproduction-energy-thresholds: the threshold of energy that a cell must have before it reproduces. *reproduction-downtimes: the amount of ticks in between reproduction cycles of a cell.

THINGS TO NOTICE

notice graph (plot) over time. Change the sliders and see who will win

THINGS TO TRY

Does changing permeability of membrane help the makers or moochers?

Does starting out with more makers hurt or help the moochers? who is dependent on who?

Can you create a balance (equilibrium) of cell?

EXTENDING THE MODEL

**Give theophylline a faster movement outside of the cell. This will be more realistic and simulate a cellular environment better.

NETLOGO FEATURES

Uses a "membrane" to determine when the theophylline is about to pass through. Uses the cone radius feature of netlogo to determine whether theophylline is entering or leaving a cell.

RELATED MODELS

This model is an independent model. It was created during the summer of 2013 at Davidson College for the Synthetic Biology Summer Research Team.

CREDITS AND REFERENCES

http://modelingcommons.org/browse/one_model/3772 http://gcat.davidson.edu http://www.bio.davidson.edu

Thanks to Dr. Laurie Heyer and Dr. Malcolm Campbell for their guidance. Also thanks to my whole team both at Davidson and Missouri Western for their support and help. Special thanks to Jackson Spell, who has provided countless suggestions and guidance to me during this project. Thanks to Uri Wilensky and his team at Northwestern for creating NetLogo and providing it to the public.

Comments and Questions

Please start the discussion about this model! (You'll first need to log in.)

Click to Run Model

;*********************************************
;Author: Micah Brown
;Model: Maker/Moocher Cells

;*********************************************


breed [ cells cell ]
breed [ theo theophylline-molecule ]

turtles-own [
  energy 
  lifespan
  time-since-reproduction
]

;SETUP

to setup
  ca
  setup-background
  setup-turtles ;turtles set up in random location, ensuring no overlaps. 
  reset-ticks
end 

to setup-background
  ask patches [
    set pcolor white
  
  ]
end 


;------------------------------

to setup-turtles

  
  set-default-shape cells "circle 2"
  set-default-shape theo "lightning"

  
  create-cells (initial-amount-makers + initial-amount-moochers) [
    set color black
    setxy  random-xcor random-ycor
    set size 10
    ifelse who < initial-amount-makers
      [set color red
       set time-since-reproduction random maker-reproduction-downtime]
      [set color cyan
       set time-since-reproduction random moocher-reproduction-downtime]
    set energy initial-energy
    set lifespan initial-lifespan
     
     
  ]
  
  ;overlaps handled by killing overlaping cell :/
  ask turtles [
    if (count turtles in-radius (size + 1) > 1) [
      die
    ]
  ]
  
  create-theo initial-theophylline [
    set color black
    setxy random-xcor random-ycor
    set size 3
    set lifespan initial-lifespan / ( 2 / 3 )
    
  
  ]
end 

;------------------------------

to go
  ;stops when everyone has died
  if (count cells = 0)
    [stop]
  
  move-turtles
  degredation
  reproduce 
  tick
end 

;------------------------------

to move-turtles
  
  ask theo [
    
    let nearest-cell min-one-of other cells [distance myself]  
    let nearest-cell-distance distance nearest-cell
    
    ;test whether theophylline is in "membrane" 4
    if ( nearest-cell-distance <= 6 ) and ( nearest-cell-distance) >= 4 [ 
      ifelse count cells in-cone 6.0 180 < 1
        [if random-float 1 > probability-diffusion-out ;if facing (and moving) away from cell
          [ face nearest-cell
            fd 2 
          ] 
        ]
        [if random-float 1 > probability-diffusion-in ;else must be facing (and moving) towards a cell
          [ face nearest-cell 
            set heading heading + 180
            fd 1.5 
          ] 
        ]
    ]
    random-movement-theo
    set lifespan lifespan - 1
  ] 

  ask cells [
    random-movement-cell
    if count cells in-radius 10.1 > 1 [  ;ensures cells don't "overlap"
      rt 180 
      fd 1
    ]
      
    if color = red [ ;only makers produce theophylline
      if random-float 1 <= theo-production / 2 [

        hatch-theo 1 [
          set size 3 
          set color black
          set lifespan initial-lifespan / ( 2 / 3)  ;we give theophylline a lifespan equal to (1.5) of a cell's.
          setxy ( xcor + (random-float (4 * sqrt 2) ) - (2 * sqrt 2) ) (ycor + (random-float (4 * sqrt 2) ) - (2 * sqrt 2) )
        ]
      ]    
    ]
    if count theo in-radius 6 > 0
      [ set energy energy + log ( count theo in-radius 6 ) 2 + 1 ] ;energy gained from having theophylline is scaled logarithmically 
    
    if energy >= 100 [ ;maximum energy is 100
      set energy 100 
    ]
   
   
    set energy energy - .5
    set lifespan lifespan - 1
    set time-since-reproduction time-since-reproduction + 1
  ] 
end 

;--------------------------------------

to degredation
  
  ask cells [
    if energy <= 0 [
      if random 10 = 1 [die] ;randomness gives more variation
    ]
  ]
  ask turtles [
    if lifespan <= 0 [
      if random 10 = 1 [die]
    ]
  ]
end 

;-----------------------------

;local randomness preserved in order to have theophylline inside of cell move the same way the cell moves.

to random-movement-cell
  with-local-randomness [
    ifelse random 2 = 1
      [right random 30 forward .5]
      [right random -30 forward .5]
  ]
  ask other theo in-radius 6 [     ; moves its theophylline contained in cell in the same direction that it just moved
    ifelse random 2 = 1
      [right random 30 forward .5]
      [right random -30 forward .5]]
end   

;------------------------------

to random-movement-theo
  
    ifelse random 2 = 1
      [right random 30 forward 1 ] 
      [right random -30 forward 1 ]
end  

;--------------------------------

to reproduce
  ;this is an approximate for how many cells will fit into the space given the coordinates that the user sets.
  let carrying-capacity (max-pxcor * max-pxcor) / 50
  if (count cells > carrying-capacity) [ 
    stop
  ]
  
  
  ask cells [
    if ( (color = red) and (energy >= maker-reproduction-energy-threshold) and time-since-reproduction >= maker-reproduction-downtime ) or
       ( (color = cyan) and (energy >= moocher-reproduction-energy-threshold) and (time-since-reproduction >= moocher-reproduction-downtime ) ) [
      set time-since-reproduction 0
      let child-color color
      let half-energy energy / 2
      set energy half-energy
      let num-theo count theo in-radius 6
      
      ;kills half of the theophylline in the cell (but "adds" them to the new cell, later)
      repeat num-theo * 0.5 [
        ask one-of theo in-radius 6 [die]    
      ]
        
      hatch-cells 1 [ 
        set color child-color
        set lifespan initial-lifespan
        set energy half-energy
        set time-since-reproduction 0
        while [count cells in-radius (size + 1) > 1] [ ;attempts to set child cell close to parent cell
          setxy xcor + ((random count cells) - (count cells) / 2 ) ycor + ((random count cells) - (count cells) / 2 )
        ] 
        hatch-theo ( num-theo / 2 ) [
          set size 3
          set color black
        ]
      ] 
    ]
  ]  
end 

;-----------------------------------

There are 7 versions of this model.

Uploaded by When Description Download
Micah Brown over 11 years ago documentation Download this version
Micah Brown over 11 years ago typo fix, formatting Download this version
Micah Brown over 11 years ago update Download this version
Micah Brown over 11 years ago major color change Download this version
Micah Brown over 11 years ago new version Download this version
Micah Brown over 11 years ago recent version. see "note" in code Download this version
Micah Brown over 11 years ago Initial upload Download this version

Attached files

No files

This model does not have any ancestors.

This model does not have any descendants.